H. 0. BBHR. PNEUMATIC PERGUSSIVE APPARATUS. APPLICATION FILED JUNE 10, 1911.
1,026,555. A Patented May14, 1912.
3 SHEETS-SHBET l.
H. c. BEHR. PNEUMATIC PERGUSSIVE APPARATUS.
APPLICATION FILED JUNE 10, 1911. 1,026,555. Patented May 14, 1912.
3 SHEETS-SHEET 2.
H. G. BEHR. ,PNEUMATIG PEROUSSIVE APPARATUS.
APPLIOATION FILED JUNE 10, 1911. 1,026,555.
Patented May 14, 1912.
s SHEETS-SHBET a.
UNITED STATES PATENT orrrdn.
HANS enemas BEER, or JOHANNESBURG, TRANSVAAL.
PNEUMATIC PERcUssivE APPARATUS.
Specification of Letters Patent.
Patented May 142, 1912.
Application filed June 10, 1911. Serial No. (32,459.
To all whom it may concern:
Be it known that I, HANS CHAnnEs BEER, consulting mechanical engineer, a citizen of the United States of America, residing at Consolidated Goldfields Building, Johannesburg, Transvaal, have invented certain newand useful Improvements in Pneumatic Per-'3 The principal object of the invention is to construct a percussive apparatus capable of working at high speed and of imparting an unretarded stroke of high velocity, and so constructed as to reduce to aminimum thecapable of producing an unretarded stroke.
Steam stamps of course,have been employed,
but they are objectionable on account of the high cost of fuel and for other reasons.
Figure I- of the accompanying drawings is a front elevation of an ore stamp embodying the invention Figs. II and III are partial side elevations seen from opposite directions,.
the frame being shown as broken away; Fig. IV is a plan on line A--A of Fig. I; Fig. V is a vertical section showing the parts after striking the blow and when the. cylinder-is at the forward or, lower end of its stroke; Fig. VI is a similar artial section illustrat ing the completion of the return stroke; and Figs. VII-IX are similar sections showing modified constructions.
The cylinder 1 is mountedonthe frame 2 to be reciprocated by thecrank 3 and connecting rod 4.-.' For the purpose of adjusting the-apparatus toward or from the die 5, the'connectin rod. may be attached to the top of the cylinder by across head 6 secured 55 bynuts 7 to the/upright screw studs 8.
Within the cylinder 1 is apiston 9 from from the are which projects a piston rod 'lO'carrying the stamp head 11. The end of the cylinder from which thepiston rod 10 projects will be called the front end and the op osite end the rear end. The movement of t e apparatus by which the stamp head is urged toward. the die will be referred to as the forward stroke and the reverse movement as the re turn stroke.
An opening controlled by avalve 12 affords 7 communication between the front end of the cylinder and a reservoir of air. This reservoir may be the external atmosphei e; but as the stamp illustrated is intended to work with an artificially dense atmosphere, the
reservoir shown consists of a-- chamber .13 annexed to the cylinder 1, a flexible connectingpipe 14 and areceiver 15. The receiver is fed by a. smallcom ressor 16 the function of which, after it has produced the required working pressure, is simply to make up leakage. Y
Valve 12 is held to its seat by a light spring 17 and is free to open when the reservoir pressure slightly exceeds that within the front end of the cylinder. For lifting the valve positively there is provided awiper 1.8 secured to aspindle 19, both ends of which pass out ofchamber 13 through s'tufling boxes. At one end ofspindle 19 is secured onelink 20 of a toggle theother arm 21 of which is pivoted to astifl spring 22; said device operating in the well known manner to retain thewiper 18 either in its lowered position shown 1n Fig. V, or in its raised position shown in Fig. VI, while permitting it to be forcibly moved from one such position to the other. At the other end of thespindle 19 is the tappet'arm 23 and in the path thereof are thestops 24 and 25.Stops 24 and 25 are adj ustably secured upon aplate 26 which itself is adjustably fixedtoframe 2. The functions ofvalve 12 will appear from the following description of the operation. During the return stroke of cylinder 1,tappet arm 23 comes intocontactwith sto 25 and liftswiper 18. During the succee ing ferward stroke thereforevalve 12 is held open and by affording free communication .betweenthe frontend of the cylinder and the reservoir, permits thepiston 9, piston rodlO, andhead 11 to. move forward freely and strike an unretarded blow. The forward stroke of theListon 9 is completed and the blow struck be ore the cylinder 1 comes to the end of its forward travelg immediately upon which stop 24 forces uptappet arm 23 and permitsvalve 12 to close thereby imprisoning a body of air in the front of the cylinder, through which the latter acts on the piston to retract the same. During the return stroke the piston 9-will usually acquire sufiicient momentum to cause it to over-run the cylinder, and thereby lower the pressure of the air body in the front end of the cylinder.Valve 12 will thereupon open automatically and admit air from the reservoir at substantially the same pressure as that in the front end of the cylinder, thus avoiding loss of energy due to-inrush of air under great difference of pressure and also preventing undesirable retardation of the piston on its return stroke.
The rear end of the cylinder is, similarly to the front end, put into communication with a reservoir of air. This may be the external atmosphere, or thechamber 13,pipe 14 andreceiver 15, or as shown in Fig. VII, a separate chamber 27 andreceiver 28 containing air at a different pressure from that inreceiver 15. Such communication may in the case of a stamp or hammer which is required to fall solely by gravity, be entirely free. For working at high speed however, said communication is controlled by a valve device which, as shown in Figs. V-VIII, comprises avalve 29 retained to its seat by a light spring 30 and adapted to open bya slight preponderance of pressure in the reservoir over that in the rear end of the cylinder. A'wiper 31 for lifting the valve is pressed down by aspring 32 and rigidly mounted upon aspindle 33 which carries theexternal tappet arm 34. A latch 35- for holding the wlper 31 .in-its raised position is rigidly mounted uponspindle 36 together with the external tappet arm 37 (Fig. III), against which bears aspring 38 tending to force thelatch 35 under the wiper 31. An adjustable stop 39 (Figs. I and II) is fixed to theplate 26 in the path oftappet arm 34;
and an adjustable cam plate 40 (Figs. I
and III) in the path ofpin 64 extending from tapet arm 37. During the return stroke 0 the cylinder contact ofpin 64 withcam plate 40 throws out thelatch 35 and permits wiper 31 to drop andvalve 29 to close. A body of air is thus entrapped in the rear end of the cylinder, which both cushions the return stroke of the piston and also enables the cylinder to propel the same on its next forward stroke. During the forward stroke, so long as the cylinder presses upon said air body to maintain its pressure,valve 29 remains closed. If however the pis-, ton gains on the cylinder so as to cause the pressure at the rear end of the cylinder to fall below that acting on the underside ofvalve 29, the latter W111 open and admit air to follow up the piston. In any case said valve is opened just before thetermination valve 29 open.
of the forward stroke owingtotappet arm 34 coming Into contact withstop 39. As
soon as wiper 31 is lifted,thelatch 35, urgedby thespring 38, falls under it and locks the )Vhenever the cylinder 1 is adjusted to or from the die 5 (by means of the adjustable cross head 6), thestops 24,
25 and 39, andcam plate 40 are correspondingly shifted on theframe 2 withoutchanging their relative position;plate 26 enablingstops 24, 25 and 39 to be shifted together. Again, the individual adjustability of said stops and said cam plate enables their relative positions to be changed to adjust the apparatus for different conditions of working, such as changes in the weight of the percussive parts, or in the rate of working.
In the construction shown in Fig. IX, the
piston 9 takes the place of the separate valve.
29, by coiiperating with theports 41 ati'ording communication between the rear end of the cylinder and thechamber 13, which ports it covers during its return stroke and re-opens during its forward stroke.- The point of the stroke at which such closing and opening occurs may be made adjustable.
According to Fig. IX this is effected byformingthe ports 41 in asleeve 42 which is adjustable axially of the cylinder by means of set screws 43. Said sctscrews are inclosed by fluidtight covers 44 and the sleeve is made fluid tight in the cylinder by packing 45. The recurrent flow of the working fluid intochamber 13 affords a convenient method of disposing of the heat produced by its repeated compression within the cylinder. To this end cooling water is applied to saidchamber 13, either by spraying it externally, or as shown, by passing cooling water from aSource 46 through apipe coil 47 fitted within said chamber. The water withdrawn from thecoil 47 may be conducted bypipe 48 into the mortar box 4.9.
A modified apparatus which embodies the compressor within itself is shown in Fig. VIII. Acompressor cylinder 50 in communication withchamber 13 is furnished with a compressor piston 51. Air may pass from the atmosphere through the inwardly openbeneath piston 51 intochamber 13 through the non-return valve 53 controlled by spring 1 65. Apiston rod 54 projects through a stufiing box 55-not shown in Fig. VIII and is fitted with a spring 56tending to force it outwardly, such motion being limited by an adjustable stop 58 on the cylinder. On the frame 2- is carried an adjustablestationary stop 57. As the main cylinder 1 travels forward, rod 54strikes stop 57 and causes displacement of the compressor piston' 51 relatively to itscylinder 50, whereby air is drawn in throughvalve 52. .On the return of the main cylinder, piston 51 is retracted by itsspring 56 and air is forced intochamber 13 through valve 53. The inward travel of piston 51 is controlled by stop 58 and its outward travel bystop 57 whereby both the extent of the travel of said piston and the volume of the clearance space remaining under it at the end of its outward stroke, may-be adjusted. Thus for a predetermined working pressure inchamber 13, the amount of air delivered by the compressor may be regulated to'equal that lost by leakage; the clearance space below the compressor piston 51 being so adjusted that the terminal pressure produced therein upon the completion of the outward stroke of piston 51 is insuflicient to lift valveo3 so long as said predetermined pressure is maintained. Upon the pressure inchamber 13 falling owing to increased leakage,-the pressure beneath piston 53 will overcome that inchamber 13 plus'the resistance of the valve spring 65 and will lift valve 53 and replenishchamber 13. Agage 59 indicates the pressure withinchamber 13 and a blow-offvalve 60 disposes of any surplus air.
For guiding the stamp head 11, there is provided aslider 61 adjustably clamped thereto and sliding uponguides 62. The latter are spaced clear of theopening 63 of the mortar box so that lubricant from them falls clear of said opening. As .the shoe and die wear down,.theslider 61 is loosened from the head 11 and'shifted higher up the same; while rotation of the head to insure even wear is similarly eflected from time to timeafter it has been loosened from the slider'61.
In connection with the operation of my invention it should be pointed out that-if neither of thevalves 12 and 29 were employed, as thecross head 6 reaches its lowest position, air would first be compressed in the rear portion of the cylinder 1, while as the front portion of said cylinder moved forward, air in front of thepiston 9 would be expanded. But, as thepiston 9 gained velocity, it would compress the air in the front portion of the cylinder 1 and thereupon lose most of the velocity gained. It I would, therefore, result from this action that the blow delivered by the stamp would be greatly lessened. Again, if we suppose thevalve 12 to be permanently closed, then as thecross head 6 approaches its extreme position shown in Fig. 5 air which was first compressed will now be expanded in the rear of the cylinder 1, and thepiston 9 driven forward as in the first case, but in this last case, with the valve-12 closed, air will be highly'compressed in the front end of the cylinder 1 between said piston and saidvalve 12; and since the intensity of theblotv will depend entirely upon the veloclt closed, as is done in this invention, while thecross head 6 is reaching the position shown in Fig. 5, then air will be at first compressed and then expanded in the rear portion of the cylinder 1, which will drive theunretarded piston 9 forward with a maximum velocity owing to the fact that air can freely escape past thevalve 12, and a maximum blow will be therefore delivered by the hammer. Further, in this lastcase, should the forward movement of thepiston 9 compress the air in front of said piston more highly than is the air in the rear of said piston, then thevalve 29 will lift and allow an equilibrium-of pressure to take place. It results from this construction that by the mechanism disclosed, I
provide a rotating means which is capable, of'delivering sudden and powerful blows at a high efficiency which would not be possible were a rigid connection employed.
It is "obvious that those skilled-in the art may vary the details of construction and the arrangement of parts without departing from the spirit of my invention, and therefore I do not wish to be limited to the above disclosure except as may be required by the claims.
What I claim and desire to secure by Letters Patent is 1. The combination of a cylinder, a piston working therein, means for causing a relative reciprocation between said cylinder and piston,.a piston rod projecting from thefro-nt end of the cylinder, a valve for the front end of the cylinder controlling communication between the same and a reservoir of air, and automatic means causing said valve to be open during the forward stroke of the piston and closed during the rearward stroke of thesame.
2. The combination of a cylinder, :means for reciprocating the same, a piston working therein, a piston rod projecting from the front end of the cylinder, a valve for the front end of' the cylinder controlling communication between the same and a .reservoir of air, and automatic means causing said valve to be open during the forward stroke of the cylinder and closed during the rearward stroke of the same.
3. The combination of a cylinder, means for reciprocating the same, a piston working therein, a piston rod prO ect-ing from the front end of the cylinder, a valve for the front end of the cylinder controlling communication between the same and a reservoirof air,.'said valve being free to open upon the reservoir pressure exceeding that in the front end of the cylinder and tending to close when the reservoir pressure is less than thatin the front end of the cylinder, and automatic mechanism adapted to open and close said valve.
4. The combination of a cylinder, means for reciprocatingthe same, a piston working therein, a piston rod projecting from the front end of the cylinder, a valve for the front end of the cylinder controlling communication between the same and a reservoir of air,'nieans causing said valve to be open during the forward stroke of the cylinder and closed during the rearward stroke of the same, and automatic means controlling communication between the rear end of the cylinder and areservoir of air, and adapted to open suchcommunication while the cylinder is effecting its forward stroke and to close the same before the termination of the return stroke.
5. The combination of a cylinder, means for reciprocating the same, a piston working therein, a piston rod projecting from the front end of the cylinder, a valve for the front end of the cylinder controlling communication between the same and a reservoir' of air, means causing said valve to be open during the forward stroke of the cylinder and closed during the rearward stroke ofi the same, a valve controlling communication between the rear end of the cylinder and a reservoir of air, said latter valve being free to open when the reservoir pressure exceeds that in the rear end of the cylinder, automatic means for opening said latter valve during the forward stroke of the termination of the return stroke.
6. The combination of a cylinder,means for reciprocating the same, a piston working therein, a chamber communicating with the cylinder, automatic valve means controlling communication between said chamber and the cylinder and cooling means for said chamber.
7 The combination of a cylinder, means for reciprocating the same, a piston working therein, a chamber communicating with the cylinder, automatic valve means controlling communication between said chamber and the cylinder, a pipe coil within the chamber, and means forflowing cooling liquid through said coil.
' '8. In combination, a cylinder, means for reciprocating the same, a piston working in the cylinder, means providing a storage of high pressure fluid, and automatic valve means controlling communication between both ends of the cylinder and said storage means.
In testimony whereof I affix my signature in the presence of two witnesses.
HANS CHARLES BEHR. Witnesses:
E. N. GUNsAuLUs, C. B. HENDERSON.