Jaw crusher machine

Abstract

A jaw crusher machine has a double-acting jaw (110) that linearly reciprocates to reduce abrasive wear and tilts back and forth during the crushing and discharge strokes to create a peristaltic action that, depending on the direction of rotation of the driven shaft (118), aids the ingestion, crushing and discharge of either hard or soft feed materials.

Claims

1. A jaw crusher machine comprising: a. a substantially rectangular frame having a horizontal base and spaced apart interconnected side walls extending upwardly from said base, b. a pair of fixed jaws mounted transversely between said side walls so as to form the opposing walls of a downwardly tapering chamber, and c. a substantially vertical jaw member having crushing surfaces on opposite sides thereof, d. said vertical jaw member being pivotally connected substantially at the midpoint of its height to linear jaw bearings affixed to each sidewall between said fixed jaws, e. said linear jaw bearings supporting and constraining said vertical jaw to substantially horizontal reciprocating pivotal motion, f. a bearing housing extending across one end of said frame between said side walls and spaced above said base, g. a driven shaft rotatably mounted within said bearing housing, h. a flywheel concentrically attached to one end of said shaft, i. a reversible driving means for rotating said flywheel and shaft, j. an eccentric fixed on said shaft near each of its ends, k. substantially horizontally inclined connecting rods carried by and operably connected at one of their ends to said eccentrics, l. the opposite ends of said connecting rods being rigidly connected to said vertical jaw member.

2. A jaw crusher machine as in claim 1 wherein the crushing surfaces on one or more jaw members are made of chrome white iron.

3. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially perpendicular to the opposed fixed jaw.

4. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially parallel to the opposed fixed jaw.

5. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially parallel to the opposed fixed jaw.

6. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially perpendicular to the opposed fixed jaw.

7. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more quickly above the midpoint of said vertical jaw than below it.

8. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more slowly above the midpoint of said vertical jaw than below it.

9. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more slowly above the midpoint of said vertical jaw than below it.

10. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more quickly above the midpoint of said vertical jaw than below it.

11. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more quickly below the midpoint of said vertical jaw than above it.

12. A jaw crusher machine as in claim 1 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more slowly below the midpoint of said vertical jaw than above it.

13. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more slowly below the midpoint of said vertical jaw than above it.

14. A jaw crusher machine as in claim 1 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more quickly below the midpoint of said vertical jaw than above it.

15. A jaw crusher machine comprising: a. a substantially rectangular frame having a horizontal base and spaced apart interconnected side walls extending upwardly from said base, b. a pair of fixed jaws mounted transversely between said side walls so as to form the opposing walls of a downwardly tapering chamber, and c. a substantially vertical jaw member having crushing surfaces on opposite sides thereof, d. said vertical jaw member being pivotally connected substantially at the midpoint of its height to linear jaw bearings affixed to each sidewall between said fixed jaws, e. said linear jaw bearings supporting and constraining said vertical jaw to substantially horizontal reciprocating pivotal motion, f. a bearing housing extending across one end of said frame between said side walls and spaced above said base, g. a driven shaft rotatably mounted within said bearing housing, h. a flywheel concentrically attached to one end of said shaft, i. a reversible driving means for rotating said flywheel and shaft, j. an eccentric fixed on said shaft near each of its ends, k. inclined first connecting rods carried by and operably connected at one of their ends to said eccentrics, l. said first connecting rods being pivotally supported at a point along their length by linear rod bearings affixed to each adjacent sidewall, m. said linear rod bearings constraining said first connecting rods to substantially horizontal reciprocating pivotal motion, n. the opposite ends of said first connecting rods being pivotally connected to one end of substantially horizontally inclined second connecting rods, o. the opposite ends of said second connecting rods being rigidly connected to said vertical jaw member.

16. A jaw crusher machine as in claim 15 wherein the crushing surfaces on one or more jaw members are made of chrome white iron.

17. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially perpendicular to the opposed fixed jaw.

18. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially parallel to the opposed fixed jaw.

19. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially parallel to the opposed fixed jaw.

20. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means rotates the flywheel to cause an elliptical motion of the vertical jaw substantially perpendicular to the opposed fixed jaw.

21. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more quickly above the midpoint of said vertical jaw than below it.

22. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more slowly above the midpoint of said vertical jaw than below it.

23. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more slowly above the midpoint of said vertical jaw than below it.

24. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to close the crushing zone between said vertical jaw and the opposed fixed jaw more quickly above the midpoint of said vertical jaw than below it.

25. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more quickly below the midpoint of said vertical jaw than above it.

26. A jaw crusher machine as in claim 15 wherein, during the initial portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more slowly below the midpoint of said vertical jaw than above it.

27. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more slowly below the midpoint of said vertical jaw than above it.

28. A jaw crusher machine as in claim 15 wherein, during the final portion of a stroke, the driving means moves the vertical jaw to open the discharge zone between said vertical jaw and the opposed fixed jaw more quickly below the midpoint of said vertical jaw than above it.

Description

DRAWINGSFIGURES

(1) In the drawings, closely related figures have the same number but different alphabetic suffixes.

(2) FIG. 1 shows an illustrative side view of a single-stage crusher mechanism showing an embodiment wherein the eccentrics drive the moveable jaw by means of connecting rods rigidly connected to the jaw.

(3) FIG. 2 shows an illustrative side view of an alternative embodiment of a single-stage crusher wherein the eccentrics drive the moveable jaw by means of first connecting rods pivotally connected to second connecting rods.

(4) FIG. 3a shows the sequence of jaw positions defining four stages of crushing and discharge for clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1, wherein the jaw moves continuously through positions 1, 2, 3 and 4 in sequence, then repeats.

(5) FIG. 3b shows a text chart outlining key processes occurring within four stages of crushing and discharge for clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1, wherein the jaw moves continuously in sequence through positions 1, 2, 3 and 4 of FIG. 3a.

(6) FIG. 4a shows the sequence of jaw positions defining four stages of crushing and discharge for counter-clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1, wherein the jaw moves continuously through positions 4, 3, 2 and 1 in reverse sequence, then repeats.

(7) FIG. 4b shows a text chart outlining key processes occurring within four stages of crushing and discharge for counter-clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1, wherein the jaw moves continuously in sequence through positions 4, 3, 2 and 1 of FIG. 4a.

(8) FIG. 5 shows details of the motion ellipses and force vectors at six points A to F on the moveable jaw for clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1.

(9) FIG. 6 shows details of the motion ellipses and force vectors at six points A to F on the moveable jaw for counter-clockwise rotation of the driveshaft of the crusher embodiment of FIG. 1.

(10) FIG. 7 provides an illustrative side view of an embodiment of a two-stage crusher wherein the eccentrics drive horizontally sliding dual jaws by means of connecting beams rigidly connected to the dual jaws.

(11) FIG. 8 provides an illustrative side view of an alternative embodiment of a two-stage crusher wherein the eccentrics drive dual jaws by means of horizontally sliding connecting beams rigidly connected to the dual jaws.

(12) FIG. 9 provides an illustrative side view of an alternative embodiment of a two-stage crusher wherein the eccentrics drive horizontally sliding dual jaws by means of horizontally sliding connecting beams pivotally connected to arms rigidly connected to the dual jaws.

(13) TABLE-US-00002 Drawings - Reference Numerals 100 frame 102 base 104 side wall 106 fixed jaw 108 tapering chamber 110 vertical jaw 112 crushing surface 114 linear jaw bearing 116 bearing housing 118 driven shaft 120 flywheel 122 driving means 124 eccentric 126 connecting rod 200 first connecting rod 202 linear rod bearing 204 second connecting rod 206 pivot bearing 700 connecting beam 702 upper connecting arm 704 lower connecting arm 706 fixed upper jaw 708 fixed lower jaw 710 upper vertical jaw 712 lower vertical jaw 714 upper crushing chamber 716 lower crushing chamber 800 linear beam bearing 900 upper pivot bearing 902 lower pivot bearing 904 upper linear bearing 906 lower linear bearing

DETAILED DESCRIPTIONFIG. 1FIRST EMBODIMENT

(14) One embodiment of the jaw crusher machine is illustrated in FIG. 1. This embodiment provides a jaw crusher machine comprising a substantially rectangular frame 100 having a horizontal base 102 and spaced apart interconnected side walls 104 extending upwardly from said base, a pair of fixed jaws 106 mounted transversely between said side walls so as to form the opposing walls of a downwardly tapering chamber 108, and a substantially vertical jaw member 110 having crushing surfaces 112 on opposite sides thereof, said vertical jaw member being pivotally connected substantially at the midpoint of its height to linear jaw bearings 114 affixed to each sidewall between said fixed jaws, said linear jaw bearings supporting and constraining said vertical jaw to substantially horizontal reciprocating pivotal motion, a bearing housing 116 extending across one end of said frame between said side walls and spaced above said base, a driven shaft 118 rotatably mounted within said bearing housing, a flywheel 120 concentrically attached to one end of said shaft, a reversible driving means 122 for rotating said flywheel and shaft, an eccentric 124 fixed on said shaft near each of its ends, substantially horizontally inclined connecting rods 126 carried by and operably connected at one of their ends to said eccentrics, the opposite ends of said connecting rods being rigidly connected to said vertical jaw member.

FIG. 2SECOND EMBODIMENT

(15) FIG. 2 illustrates an alternative embodiment of the present invention which provides a jaw, crusher machine comprising a substantially rectangular frame 100 having a horizontal base 102 and spaced apart interconnected side walls 104 extending upwardly from said base, a pair of fixed jaws 106 mounted transversely between said side walls so as to form the opposing walls of a downwardly tapering chamber 108, and a substantially vertical jaw member 110 having crushing surfaces 112 on opposite sides thereof, said vertical jaw member being pivotally connected substantially at the midpoint of its height to linear jaw bearings 114 affixed to each sidewall between said fixed jaws, said linear jaw bearings supporting and constraining said vertical jaw to substantially horizontal reciprocating pivotal motion, a bearing housing 116 extending across one end of said frame between said side walls and spaced above said base, a driven shaft 118 rotatably mounted within said bearing housing, a flywheel 120 concentrically attached to one end of said shaft, a reversible driving means 122 for rotating said flywheel and shaft, an eccentric 124 fixed on said shaft near each of its ends, inclined first connecting rods 200 carried by and operably connected at one of their ends to said eccentrics, said first connecting rods being pivotally supported at a point along their length by linear rod bearings 202 affixed to each adjacent sidewall, said linear rod bearings constraining said first connecting rods to substantially horizontal reciprocating pivotal motion, the opposite ends of said first connecting rods being pivotally connected to one end of substantially horizontally inclined second connecting rods 204 by pivot bearings 206, the opposite ends of said second connecting rods being rigidly attached to said vertical jaw member.

(16) OperationFIGS. 1, 2, 3a, 3b, 4a, 4b, 5, 6

(17) The manner of using the jaw crushers embodied in FIGS. 1 and 2 is similar to that for jaw crushers in present use. Material to be crushed enters the top of the crushing chamber while a driveshaft with attached eccentric is rotated to drive a reciprocating jaw within the crushing chamber. Crushed material falls out the bottom of the chamber while fresh feed enters above.

(18) A unique aspect of the present invention that provides advantages over existing machines is the versatile design that gives the ability to control and, when required, change important details of the crushing action. For example, component dimensions (e.g. bearing diameters, connecting arm lengths, linear bearing placements, etc.) chosen by the machine designer determine the magnitude and timing of small-scale jaw movements. These experience-guided design choices, in combination with operator-controlled reversible rotation, provide a means to control important aspects of the crushing action in the field.

(19) Clockwise Rotation

(20) Consider first the details of jaw movement for clockwise rotation as shown in FIGS. 3a and 3b. Clockwise rotation of the jaw crusher embodiment of FIG. 1 causes the vertical jaw to move continuously in sequence through positions 1, 2, 3 and 4, and on around to 1 again. Position 1 puts the jaw in its left-most position, from where 90 of clockwise rotation moves the jaw to mid-chamber position 2, another 90 of rotation moves the jaw to its right-most position 3, and a third increment of 90 moves the jaw to mid-chamber position 4. A final 90 of rotation puts the jaw back in position 1, and the cycle repeats.

(21) As the jaw begins its first (right-side) crushing stroke by moving right from position 1 to 2, the jaw tilts clockwise so the feed chamber behind the moving jaw at first opens wider at the top than it does at the bottom. Fresh feed material cannot enter the crusher until material crushed on the previous stroke has been discharged. Thus, for clockwise rotation, ingestion of fresh feed at the top left is impeded during the initial 1-2 portion of the stroke because the relatively narrow jaw opening at the bottom left holds back the discharge of crushed material at that point.

(22) As the jaw completes its right-side clockwise crushing stroke by moving from position 2 to 3, the jaw straightens up to vertical as it moves to its right-most position. The feed chamber finally opens wide at the bottom left, fully releasing the crushed material and allowing fresh feed to enter the left chamber. Inspection of FIGS. 3a and 3b reveals that, for clockwise rotation, the first half of the right-side discharge stroke from position 3 to 4, and the last half of the stroke from position 4 to 1, are essentially a repeat of the left-side discharge stroke in terms of obstructing material flow due to the late timing of jaw opening and discharge.

(23) With clockwise rotation, the free discharge of crushed material (and subsequent ingestion of fresh feed) is delayed to the last half of each discharge stroke. Thus a distinctive effect of clockwise rotation is to impede material passage through the crusher. There are, however, offsetting advantages of clockwise rotation that provide flexibility when processing different types of feed material, and these will be discussed later below.

(24) Counter-Clockwise Rotation

(25) Now consider the details of jaw movement for counter-clockwise rotation as illustrated in FIGS. 4a and 4b. Counter-clockwise driving rotation causes the vertical jaw to move continuously in sequence through positions 1, 4, 3, 2 and back to 1. As before, position 1 starts the jaw in its left-most position, then 90 of counter-clockwise rotation moves the jaw to mid-chamber position 4, another 90 of rotation moves the jaw to its right-most position 3, and a third increment of 90 moves the jaw to mid-chamber position 2. A final 90 of rotation puts the jaw back in position 1, and the cycle repeats.

(26) As the jaw begins its first (right-side) crushing stroke by moving right from position 1 to 4, the jaw tilts counter-clockwise so the feed chamber behind the moving jaw at first opens wider at the bottom than it does at the top. Early in the first half of the stroke, crushed material in the left chamber is free to discharge and quickly makes room for crushed material to move down through the crusher. Thus, for counter-clockwise rotation, ingestion of fresh feed at the top left is assisted during the initial 1-4 portion of the stroke because the relatively wide jaw opening at the bottom left allows crushed material to freely discharge at that point, making room to ingest fresh feed material.

(27) As the jaw completes its right-side counter-clockwise crushing stroke by moving from position 4 to 3, the jaw straightens back to vertical as it moves to its right-most position. The feed chamber finally opens wide at the top left, allowing unimpeded and quick ingestion of fresh feed into the crusher. Inspection of FIGS. 4a and 4b reveals that, for counter-clockwise rotation, the first half of the right-side discharge stroke from position 3 to 2, and the last half of the stroke from position 2 to 1, are essentially a repeat of the left-side discharge stroke in terms of assisting material flow due to the early timing of jaw opening and discharge.

(28) With counter-clockwise rotation, the free discharge of crushed material (and subsequent ingestion of fresh feed) begins quickly in the first half of each discharge stroke. Thus a distinctive effect of counter-clockwise rotation is to assist material passage through the crusher. There are also other advantages of counter-clockwise rotation that provide flexibility when processing different types of feed material, and these will now be discussed.

(29) Jaw Motion Ellipses for Clockwise Drive Rotation

(30) Consider FIG. 5, which shows jaw motion ellipses at six points on the vertical jaw for clockwise rotation of the jaw crusher drive shaft. Details 5A, 5B and 5C show the elliptical path at three points on the vertical jaw's left surface during one complete clockwise rotation of the drive mechanism. The elliptical motion begins with the left-hand discharge/intake stroke (which is also the right-hand crushing stroke) as the jaw moves first from position 1 to position 2, then on to position 3. The left-hand crushing stroke completes the ellipse as the jaw moves from position 3 to position 4, then on to position 1.

(31) Details 5D, 5E and 5F show the corresponding elliptical paths of motion at three similar points directly opposite on the vertical jaw's right side. The ellipses begin with the right-hand crushing stroke as the jaw moves first from position 1 to position 2, then on to position 3. The ellipse is completed by the right-hand discharge/intake stroke as the jaw moves from position 3 to position 4, then on to position 1.

(32) The arrows drawn perpendicular and tangential to the fixed jaws illustrate respectively the compressive and shearing forces developed on either side of the vertical jaw during the crushing strokes. In Detail 5D for example, during the initial part of the right-hand crushing stroke when the jaw moves from position 1 to position 2, the elliptical path of motion is substantially perpendicular to the fixed jaw and the crushing forces developed are thus mostly compressive. In the final part of the right-hand crushing stroke as the jaw moves from position 2 to position 3, the elliptical path of motion curves up and parallel to the fixed jaw and the crushing forces develop a significant up-angled shear component parallel to the fixed jaw.

(33) The jaw motion ellipses of FIG. 5 show how clockwise rotation of the drive flywheel produces a crushing stroke that starts with compression perpendicular to the fixed jaws, and ends with a shearing movement directed up along the surface of the fixed jaws. This two-step crushing and shearing movement is quite similar to human jaw motions when chewing food, wherein the teeth first crush down to grip and cut the food material and then shear sideways to tear and shred it.

(34) A two-step chewing action of initial compression and final shear works well to break up feed materials that are relatively soft and adhesive. With clockwise drive rotation, the final upward-angled shearing motion of the crushing stroke tends to scrape adhered material off the fixed jaws and thereby helps prevent plugging with softer materials such as asphalt. A brief period of clockwise operation is also useful to help free up the crusher if it plugs during counter-clockwise operation.

(35) When crushing hard materials with clockwise drive rotation, upward-angled shear forces at the end of the crushing stroke unfortunately tend to spit hard stones and chunks back upwards against the incoming feed, thereby reducing throughput. Clockwise drive rotation also causes the chamber of crushed material to open relatively slowly at the bottom compared with the top. Slow opening at the bottom reduces throughput by impeding the discharge of crushed material from below, which then delays ingestion of new material at the top. Thus, although clockwise drive rotation of the present invention is advantageous for crushing soft feed materials, clockwise rotation is less satisfactory for crushing hard materials.

(36) Jaw Motion Ellipses for Counter-Clockwise Drive Rotation

(37) Now consider FIG. 6, which shows jaw motion ellipses at six points on the vertical jaw for counter-clockwise rotation of the jaw crusher drive shaft. Details 6A, 6B and 6C show the elliptical path at three points on the vertical jaw's left surface during one complete counter-clockwise rotation of the drive mechanism. The ellipses begin with the left-hand discharge/intake stroke as the jaw moves first from position 1 to position 4, then on to position 3. The left-hand crushing stroke completes the ellipse as the jaw moves from position 3 to position 2, then on to position 1.

(38) Details 6D, 6E and 6F show the corresponding elliptical paths of motion at three similar points directly opposite on the vertical jaw's right side. The ellipses begin with the right-hand crushing stroke as the jaw moves first from position 1 to position 4, then on to position 3. The right-hand discharge/intake stroke (which is also the left-hand crushing stroke) completes the ellipse as the jaw moves from position 3 to position 2, then on to position 1.

(39) The arrows drawn perpendicular and tangential to the fixed jaws illustrate respectively the compressive and shearing forces developed on either side of the vertical jaw during the crushing strokes. In detail 6D for example, during the initial part of the right-hand crushing stroke when the jaw moves from position 1 to position 4, the motion ellipse curves up parallel to, then toward, the fixed jaw, giving the initial crushing forces a significant up-angled shear component parallel to the fixed jaw. In the final part of the right-hand crushing stroke as the jaw moves from position 4 to position 3, the elliptical motion is substantially perpendicular to the fixed jaw and the crushing forces developed are thus mostly compressive.

(40) The jaw motion ellipses of FIG. 6 show how counter-clockwise rotation of the drive flywheel produces a crushing stroke that begins with shear forces upwardly-directed parallel to the fixed jaws. The crushing stroke ends with compressive crushing forces directed perpendicular to the surface of the fixed jaws. This sequence of shear and compression is similar to that in a roll crusher, wherein the feed material is initially placed in partial shear parallel to the fixed jaw before it is crushed by compression. The shear force rotates the feed chunks until they brace themselves on a flat spot and stop rolling, at which point the moving jaw pins the chunks in place and the crushing force becomes compressive. The shear-induced spit-back rejection of feed sometimes encountered with clockwise drive rotation is reduced or eliminated because the large crushing forces at the end of the stroke are mainly compressive.

(41) On a counter-clockwise discharge stroke, the crushing chamber opens more quickly at the bottom and more slowly at the top. Quick opening at the bottom increases throughput by hastening the discharge of crushed material from below to make room for ingestion of new material at the top (i.e. one must breath out before breathing in). Thus, counter-clockwise drive rotation of the present invention reduces feed rejection and increases throughput, making it particularly effective with hard materials.

FIGS. 7, 8, 9ADDITIONAL EMBODIMENTSMULTI-STAGE CRUSHING

(42) The performance envelope of the single-stage crushers shown in FIGS. 1 and 2 can be extended by, for example, adapting their mechanisms to perform the crushing action in multiple stages.

(43) FIG. 7 illustrates an alternative embodiment of the crusher of FIG. 1 wherein crushing takes place in two stages. Eccentrics 124 drive upper jaws 710 and lower jaws 712 by means of connecting beams 700 rigidly connected to the upper and lower jaws via connecting arms 702 and 704 respectively. The upper and lower jaws are jointly constrained to horizontally sliding pivotal motion by linear bearings 114. The upper jaw reciprocates horizontally within a downwardly tapering chamber 714 formed by fixed upper jaws 706, while the lower jaw reciprocates within a downwardly tapering chamber 716 formed by fixed lower jaws 708.

(44) FIG. 8 illustrates another alternative embodiment for two-stage crushing wherein eccentrics 124 drive upper jaws 710 and lower jaws 712 by means of connecting beams 700 constrained to horizontally sliding pivotal motion by linear bearings 800. The connecting beams rigidly connect to the upper and lower jaws via connecting arms 702 and 704 respectively. The upper jaw reciprocates within a downwardly tapering chamber 714 formed by fixed upper jaws 706, while the lower jaw reciprocates within a downwardly tapering chamber 716 formed by fixed lower jaws 708.

(45) FIG. 9 illustrates still another alternative embodiment for two-stage crushing which effectively combines the mechanisms of FIGS. 2, 7 and 8. Eccentrics 124 drive upper jaws 710 and lower jaws 712 by means of connecting beams 700 constrained to horizontally sliding motion by linear bearings 800. The connecting beams pivotally connect to upper and lower connecting arms 702 and 704 via upper and lower pivot bearings 900 and 902 respectively. The upper and lower connecting arms are rigidly connected to the upper and lower jaws respectively. The upper and lower jaws are constrained to horizontally sliding pivotal motion by linear bearings 904 and 906 respectively. The upper jaw reciprocates within downwardly tapering chamber 714 formed by fixed upper jaws 706, while the lower jaw reciprocates within downwardly tapering chamber 716 formed by fixed lower jaws 708.

Advantages

(46) From the descriptions above, a number of advantages of some embodiments of my jaw crusher machine become evident:

(47) (a) Linear bearings reduce the unintended shear forces that encourage abrasive wear in other designs.

(48) (b) Straightforward machine design parameters such as arm length and pivot location of connecting arms, etc., give the designer great flexibility to fine-tune the jaw motion and crushing forces for best performance.

(49) (c) By simply changing the direction of drive rotation, the crushing action can be varied to suit either hard or soft feed materials.

(50) (d) Briefly changing the direction of drive rotation is helpful for clearing the machine if it becomes plugged during operation.

(51) (e) The machine can be operated so that crushing forces begin with compression and end with shear, thereby providing a self-cleaning jaw action that encourages throughput and helps to reduce plugging when crushing soft feed materials.

(52) (f) The machine can be operated so that crushing forces begin with gentle shear and end with strong compression, permitting the use of hard but slippery wear-resistant jaw materials such as chrome white iron without encountering spit-back rejection of hard feed materials.

(53) (g) The machine design is compact, sturdy, runs smoothly and is easy to operate, making it well suited for portable use under harsh field conditions.

CONCLUSIONS, RAMIFICATIONS AND SCOPE

(54) Accordingly, the reader will see that the jaw crusher machines of the various embodiments can be used to crush a wide range of feed materials either hard or soft, at field locations suitable for permanent or portable installations, and when plugged can be easily cleared, sometimes with just the press of a button. Furthermore, the jaw crusher machine has additional advantages in that: it is less vulnerable than other designs to abrasive wear due to unpurposed shear forces; it can be configured to process either hard or soft materials simply by pressing a button to control the direction of drive rotation; the machine designer can, via small changes to the machine geometry, precisely control the elliptical jaw motions that determine the magnitude and timing of jaw openings during the discharge stroke, and of compressive and shear forces during the crushing stroke.

(55) Although the descriptions above are quite specific, this should not be construed as limiting the scope of the embodiments but as merely providing illustrations of some of several embodiments. For example, the vertical jaws may be asymmetrical either vertically or horizontally; the fixed jaws may be curved rather than flat; the vertical and fixed jaws need not be made of the same materials, etc.

(56) Thus the scope of the embodiments should be determined by the appended claims and their legal equivalents, rather than by the examples given.