US1343836A - Jar-molding machine - Google Patents

Jar-molding machine Download PDF

Info

Publication number
US1343836A
US1343836A US348284A US34828419A US1343836A US 1343836 A US1343836 A US 1343836A US 348284 A US348284 A US 348284A US 34828419 A US34828419 A US 34828419A US 1343836 A US1343836 A US 1343836A
Authority
US
United States
Prior art keywords
piston
cylinder
actuating
chamber
working
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US348284A
Inventor
Lewis Wilfred
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to US348284A priority Critical patent/US1343836A/en
Application granted granted Critical
Publication of US1343836A publication Critical patent/US1343836A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22CFOUNDRY MOULDING
    • B22C15/00Moulding machines characterised by the compacting mechanism; Accessories therefor
    • B22C15/10Compacting by jarring devices only

Definitions

  • WILFREID LEWIS OF HAVERFORD
  • PENNSYLVANIA PENNSYLVANIA
  • My invention relates to jar molding machines, either of the kind known as shockless jarring machines or of the more ordinary kind.
  • jar molding machines have been generally operated by compressed air though said machines have also been actuated by cams on a driven shaft.
  • compressed air involves considerable expense as well as extensive and more or less complicated mechanism.
  • cams to actuate the jarring machine is open to many objections; especially where large and heavy machines are involved the wear and tear is great, time is lost in picking up the load, and the speed of the machine must be kept within limits which will avoid the cam being struck by the fallin .table, or parts connected therewith.
  • Fig. 2 is a side elevation on a reduced scale taken at right angles to Fig. 1 and showing a detail.
  • A indicates a cylinder serving to aline and guide the floating anvil B, having, as shown, layers of some compressible material secured to its top, as indicated at C, and supported on springs, as indicated at D.
  • a cylinder B is formed in the anvil, and, as shown, an annular shoulder B projects inwardly into the lower part 'of the cylinder bore.
  • E is a piston working in the cylinder B and supporting the work holding table F.
  • E is a chamber formed in the end of the piston'E, which may be partly or wholly filled with some elastic compressible material such as cork, or may simply con tain compressed air.
  • this chamber serves simply as a cushion and .it is only necessary that some such chamber or some mass of compressible elastic material should communicate with some part of the liquid containing chamber, though it is most convenient to form it or locate it in the end of the piston, as shown.
  • any elastic compressible element interposed in the driving mechanism between the base of which, .in which this passage is j formed, is indicated at A.
  • M is a collar secured on the shaft M and M a clutch member secured on the end of the crank shaft, as shown, and working in connection with the clutch member O, which is journaled on the crank shaft and has a hub formed with inclined or helical cam surfaces as indicated at O.
  • N is the driving wheel having its hub N journaled on the shaft M and formed with cam surfaces N which lie in operative contact with the cam surfaces on the hub of the clutch member 0.
  • P indicates a light spring acting between the driving wheel and the clutch member 0.
  • Q is a power shaft journaled on the bearing K and driving the gear wheel Q, which engages the driven gear wheel N
  • the oil reservoir R communicates through a passage R, having a valve seat R at its bottom, with the by-pass I and the passage R is normally closed by the valve S, having a port S formed through it, which is closed by a valve U, held in place by a spring T.
  • Y, Y are pins secured to a flange B of the anvil B and passing through perforated lugs X, X, of cylinder A. These pins are provided simply to prevent a rotative movement of the anvil in the cylinder.
  • W, W are rods depending from the table F and passing throughthe flange B of the anvil, the lower ends of the rods supporting compression springs V, V, the upper ends of which rest against the flange B as shown in Fig. 2.
  • the gear Q on the driving shaft Q, actuates the driven gear N in the direction which presses the cam surfaces N on its hub against the cam surfaces 0 on the hub of the clutch member 0, pressin this clutch member against the member 1% and driving the shaft M with its crank M, and through this crank to the piston L.
  • the up stroke of this piston will draw oil from the reservoir B through the by-pass I into the passage I and when the lower part of the cylinder J, passage I, and the lower part of the cylinder, B are filled with oil, the down stroke of the piston L will force the oil up against the end of the piston E, raising the table F, and, at the same time, where a spring supported anvil, such as is shown in the drawing, is used the pressure on the head G will force the anvil down against the springs D.
  • a spring supported anvil such as is shown in the drawing
  • the cushion chamber E has the usual function of such chambers in eliminating water hammer, and the valve U has the function of permitting the escape of oil when the pressure in the passage I, and its connections, exceeds a determined amount, and thereby prevents injurious strains in the machine.
  • the springs V, V are provided to supplement the force of gravity and increase the speed of the fall of the table. Their value lies in that they provide means tending to overcome the frictional resistance, weight, and inertia of parts opposing the gravital fall, and while springs or equivalent devices, may obviously be located in many positions to accomplish the same result I believe their location, as shown, is the best. In adjusting these springs care must be taken that they shall not increase the speed of downward movement of the table to a point which would exceed the speed of gravital fall.
  • a spring supported floating anvil having a cylinder formed therein, in combination with a piston working in said cylinder and supporting a work holding table, a liquid containing chamber in communication withthe cylinder in the anvil, apiston working in said chamher and means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving'force of the falling table.
  • a jarring machine having a cylinder and piston for actuating the work holding table
  • a j arring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of "a liquid containing chamber in communication therewith, a liquid reservoir, a port connecting said reservoir with the liquid containing chamber, a check valve in said port opening toward the said chamber, a
  • a jarring machine having a cylinder and piston for actuating the work holding table
  • a jarring machine having a cylinder and, piston for actuating the work holding table

Description

W. LEWIS.
JAR MOLDING MACHINE.
APPLICATION FILED mac. 30. 1919.
Patented June 15,1920.
W/TA/ESSES ATTORNEY OFFICE.
WILFREID LEWIS, OF HAVERFORD, PENNSYLVANIA.
JAR-MOLDING MACHINE.
Specification of Letters Patent. Patented June 15, 1920.
Application filed December 30, 1919. Serial No. 348,284.
To all whom it may concern Be it known that I, WILFRED LEWIS, a
citizen of the United States of America, I'B- sidin in Haverford, county of Montgomery, and tate of Pennsylvania, have invented a certain new and useful Improvement in Jar- Molding Machines, of which the following is a true and exact description, reference being had to the accompanying drawings, which form a part thereof.
My invention relates to jar molding machines, either of the kind known as shockless jarring machines or of the more ordinary kind. Heretofore jar molding machines have been generally operated by compressed air though said machines have also been actuated by cams on a driven shaft. The use of compressed air involves considerable expense as well as extensive and more or less complicated mechanism. On the other hand, the use of cams to actuate the jarring machine is open to many objections; especially where large and heavy machines are involved the wear and tear is great, time is lost in picking up the load, and the speed of the machine must be kept within limits which will avoid the cam being struck by the fallin .table, or parts connected therewith. The 0 ject of my invention is to provide a simple and comparatively inexpensive machine which will be free from the objections which have hindered the development of cam driven machines as heretofore constructed, and, broadly speaking, my invention consists in using as the actuating device for alternately raising and permitting the fall of the piston supported work holding table, a liquid containing chamber in communication with the cylinder in which the table supporting piston works, a piston working in said liquid containing chamber and means for actuating this piston, which is operative during its working stroke and inoperative during its return movement under the driving force of the falling table, and, by preference, and as an important part of my perfected invention, I use a driving shaft for actuating the piston in the liquid containing chamber; a driving wheel journaled on this shaft, and a powerful friction clutch ar= ranged to automatically engage and disengage the driving whe'el with the shaft, the engagement being effected when resistance is encountered in driving the piston and disengagement occurring when, during the return stroke of the piston, it tends to move faster than the driving shaft.
The nature of my invention, and the various features of improvement involved init, will be best understood as described in connection with the drawing in which it is illustrated and in which Figure 1 is a sectional elevation taken through the center of a shockless jarring machine and of the mechanism which I have devised for actuating it, and
Fig. 2 is a side elevation on a reduced scale taken at right angles to Fig. 1 and showing a detail.
In the drawings A indicates a cylinder serving to aline and guide the floating anvil B, having, as shown, layers of some compressible material secured to its top, as indicated at C, and supported on springs, as indicated at D. A cylinder B is formed in the anvil, and, as shown, an annular shoulder B projects inwardly into the lower part 'of the cylinder bore. E is a piston working in the cylinder B and supporting the work holding table F. E is a chamber formed in the end of the piston'E, which may be partly or wholly filled with some elastic compressible material such as cork, or may simply con tain compressed air. The function of this chamber is to serve simply as a cushion and .it is only necessary that some such chamber or some mass of compressible elastic material should communicate with some part of the liquid containing chamber, though it is most convenient to form it or locate it in the end of the piston, as shown. Broadly speaking, any elastic compressible element interposed in the driving mechanism between the base of which, .in which this passage is j formed, is indicated at A.
ing are formed the bearings J J for the driving crank shaft indicated at M M indicates the crank, and L a connecting rod connecting the crank with the iston L, which reciprocates in the cylinder 3. M is a collar secured on the shaft M and M a clutch member secured on the end of the crank shaft, as shown, and working in connection with the clutch member O, which is journaled on the crank shaft and has a hub formed with inclined or helical cam surfaces as indicated at O. N is the driving wheel having its hub N journaled on the shaft M and formed with cam surfaces N which lie in operative contact with the cam surfaces on the hub of the clutch member 0.
P indicates a light spring acting between the driving wheel and the clutch member 0. Q is a power shaft journaled on the bearing K and driving the gear wheel Q, which engages the driven gear wheel N The oil reservoir R communicates through a passage R, having a valve seat R at its bottom, with the by-pass I and the passage R is normally closed by the valve S, having a port S formed through it, which is closed by a valve U, held in place by a spring T. Y, Y, are pins secured to a flange B of the anvil B and passing through perforated lugs X, X, of cylinder A. These pins are provided simply to prevent a rotative movement of the anvil in the cylinder. W, W, are rods depending from the table F and passing throughthe flange B of the anvil, the lower ends of the rods supporting compression springs V, V, the upper ends of which rest against the flange B as shown in Fig. 2.
In operation the gear Q, on the driving shaft Q, actuates the driven gear N in the direction which presses the cam surfaces N on its hub against the cam surfaces 0 on the hub of the clutch member 0, pressin this clutch member against the member 1% and driving the shaft M with its crank M, and through this crank to the piston L. The up stroke of this piston will draw oil from the reservoir B through the by-pass I into the passage I and when the lower part of the cylinder J, passage I, and the lower part of the cylinder, B are filled with oil, the down stroke of the piston L will force the oil up against the end of the piston E, raising the table F, and, at the same time, where a spring supported anvil, such as is shown in the drawing, is used the pressure on the head G will force the anvil down against the springs D. On the completion of the down stroke of the piston L the weight of and on the table F, and the weight of the piston E, causes these parts to move downward with accelerated speed, which soon becomes greater than the speed of the upward movement of the piston L. As a result of this the cam surfaces N and O tend to disengage and the clutch member 0 being no longer pressed into the clutch M can and does release its friction grip on the clutch member M permitting it to turn faster than the gear wheel N as a result of which the table F can and does fall with accelerated speed on the cushion C of the anvil B, which anvil, in the case of the shockless machine illustrated in the drawing, rises to meet the downwardly moving table.
The cushion chamber E has the usual function of such chambers in eliminating water hammer, and the valve U has the function of permitting the escape of oil when the pressure in the passage I, and its connections, exceeds a determined amount, and thereby prevents injurious strains in the machine.
The springs V, V, are provided to supplement the force of gravity and increase the speed of the fall of the table. Their value lies in that they provide means tending to overcome the frictional resistance, weight, and inertia of parts opposing the gravital fall, and while springs or equivalent devices, may obviously be located in many positions to accomplish the same result I believe their location, as shown, is the best. In adjusting these springs care must be taken that they shall not increase the speed of downward movement of the table to a point which would exceed the speed of gravital fall.
While I have illustrated my invention in what I believe to be its best practical form it is obviously capable of useful applications in many modifications, and it will be understood that I do not intend to limit myself to the constructions illustrated in any greater degree than is specifically indicated in the claims.
Having now described my invention, what I claim as new and desire to secure by Letters Patent, is
1. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a piston working in said chamberand means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving force of the falling table.
2. In a arring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a chamber containing compressible material, a liquid containing chamber in communication therewith, a piston working in said chamber and ,means for actuating said piston operative during its Working stroke and inoperative during its return movement under the driving force of the falling table.
3. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a relief valve opening under determined pressure communicating with said chamber, a piston working .in said chamber and means for actuating said piston operative'during its working stroke and inoperative during its return movement under the driving force of the falling table.
4;. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a chamber containing compressible material, a liquid containing chamber in combination therewith, a relief valve opening under determined pressure communicating with said chamber, a piston working in said chamber and means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving force of the falling table.
5. In a jarring machinea spring supported floating anvil having a cylinder formed therein, in combination with a piston working in said cylinder and supporting a work holding table, a liquid containing chamber in communication withthe cylinder in the anvil, apiston working in said chamher and means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving'force of the falling table.
6. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder ofa liquid containin chamber, a piston working in said cham er, a driving shaft connected to actuate said piston, and means for driving said shaft, including a clutch operative during the working stroke of the piston 'andinoperative during its return stroke.
7. In a jarring machine having a cylinder and piston for actuating the .work holding table, the combination with said cylinder of a liquid containing chamber, a piston working in said chamber, a driving shaft connected to actuate said piston, means for driving said shaft, includin a clutch operative during the working stroke of the piston and inoperative during its return stroke, and an elastic element interposed in the driving connection between the shaft and table supporting piston to eliminate excessive strains.
8. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a piston working in said chamber, a crank and crank shaft connected saidshaft, a clutch having a fixed member secured to said shaft, and a movable member journaled thereon, and clutch actuating mechanism operative when the driving wheel is actuatingthe crank shaft and piston.
9. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a piston working in said chamber, a crank and crank shaft connected to said piston, a driving wheel journaled on said shaft, a clutch having a fixed member secured to said shaft, and a movable member journaled thereon, and clutch actuating cams formed on contacting ends of the hubs of the driving wheel, and movable clutch member whereby the clutch is made operative when the driving wheel is actuating the shaft and piston.
10. In a j arring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of "a liquid containing chamber in communication therewith, a liquid reservoir, a port connecting said reservoir with the liquid containing chamber, a check valve in said port opening toward the said chamber, a
piston working in the liquid containing chamber and means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving force of the falling table.
11. In a jarring machine having a cylinder and piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a liquid reservoir, a port connecting said reservoir with the liquid containing chamber, a'check valve in said port opening toward the said chamber, said valve aving a port formed in it, a relief valve seated on said port, a piston working in the liquid containing chamber and means for actuating said piston operative during 1ts working stroke and inoperative during its return movement under the driving force of the falling table.
12. In a jarring machine having a cylinder and, piston for actuating the work holding table, the combination with said cylinder of a liquid containing chamber in communication therewith, a piston working in said chamber, means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving force of the falling table and elastic means for storing energy during the upward movement of the table and giving it up during its downward movement acting table, the combination with said cylinder of a liquid containing chamber in communication therewith, a piston working in said chamber, means for actuating said piston operative during its working stroke and inoperative during its return movement under the driving force of the falling table and elastic means for storing energy during the upward movement of the table and giving it up during its downward movement acting 10 on the table to overcome resistance to the downward movement of the table.
WILFRED LEWIS.
US348284A 1919-12-30 1919-12-30 Jar-molding machine Expired - Lifetime US1343836A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US348284A US1343836A (en) 1919-12-30 1919-12-30 Jar-molding machine

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US348284A US1343836A (en) 1919-12-30 1919-12-30 Jar-molding machine

Publications (1)

Publication Number Publication Date
US1343836A true US1343836A (en) 1920-06-15

Family

ID=23367363

Family Applications (1)

Application Number Title Priority Date Filing Date
US348284A Expired - Lifetime US1343836A (en) 1919-12-30 1919-12-30 Jar-molding machine

Country Status (1)

Country Link
US (1) US1343836A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2597169A (en) * 1947-08-21 1952-05-20 Nowak Alois Karl Hydraulic press in which the thrust of the ram and the reaction of the slide bar areequalized
US2628872A (en) * 1948-02-05 1953-02-17 American Instr Co Inc Fluid pressure intensifier
US4003203A (en) * 1972-06-24 1977-01-18 Koehring Gmbh - Bomag Division Hydraulic exciter of vibrations for a vibratory compactor

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2597169A (en) * 1947-08-21 1952-05-20 Nowak Alois Karl Hydraulic press in which the thrust of the ram and the reaction of the slide bar areequalized
US2628872A (en) * 1948-02-05 1953-02-17 American Instr Co Inc Fluid pressure intensifier
US4003203A (en) * 1972-06-24 1977-01-18 Koehring Gmbh - Bomag Division Hydraulic exciter of vibrations for a vibratory compactor

Similar Documents

Publication Publication Date Title
US1343836A (en) Jar-molding machine
US1827877A (en) Power hammer
US2403582A (en) Power hammer
US1647554A (en) trapnell
US2252017A (en) Mechanical trip hammer
US2913910A (en) Ball bearing, screw jack, pumping mechanism
US1650680A (en) Shock absorber
US2539739A (en) Two-speed hydraulic jack
GB714180A (en) Improvements in or relating to hydraulic dampers
US2613662A (en) Rotary driven percussive tool
US2429947A (en) Deep well pumper
US2684055A (en) Rock-drill having an engine assembled therewith
US2013296A (en) Portable power hammer
US2141951A (en) Air compressor attachment and brake for forging machines
US2581434A (en) Press for metal stamping
US1501151A (en) Hydraulic jack
US2357247A (en) Eccentric driving gear
USRE20365E (en) Portable power hammer
US1504490A (en) Shock-absorbing device for drilling and pumping apparatus
US1718425A (en) Portable power-operated hammer
US1752141A (en) Drop hammer
US1639459A (en) Spring hammer
US2546580A (en) Hydraulic apparatus
US2153558A (en) Counterbalanced stamp mill
US1225964A (en) Safety device.