US568640A - thomson - Google Patents
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- US568640A US568640A US568640DA US568640A US 568640 A US568640 A US 568640A US 568640D A US568640D A US 568640DA US 568640 A US568640 A US 568640A
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- disk
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- bearing
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- 239000000463 material Substances 0.000 description 8
- 238000010276 construction Methods 0.000 description 4
- 229920001875 Ebonite Polymers 0.000 description 2
- 230000003321 amplification Effects 0.000 description 2
- 238000005553 drilling Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 239000002184 metal Substances 0.000 description 2
- 238000003199 nucleic acid amplification method Methods 0.000 description 2
- 230000035939 shock Effects 0.000 description 2
- 239000007787 solid Substances 0.000 description 2
- 241000894007 species Species 0.000 description 2
- 238000009827 uniform distribution Methods 0.000 description 2
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01C—ROTARY-PISTON OR OSCILLATING-PISTON MACHINES OR ENGINES
- F01C9/00—Oscillating-piston machines or engines
- F01C9/005—Oscillating-piston machines or engines the piston oscillating in the space, e.g. around a fixed point
Definitions
- Figure 1 is a vertical central section through a disk-casing A, giving an edge view of the disk and its ballbearing, this illustration indicating such an embodiment of my invention as relates to the arrangement of the three following elements, namely: the disk, the ball, and the spherical wall and the frustums of the disk-casing.
- Fig. 2 is a side view of the disk-casing complete, showing the inlet and Outlet ports and the diaphragm, together with the ball and disk.
- Fig. 3 is a top plan view of the disk,
- Figs. fi and 5 are central detail sections of the ball and disk, respectively, on the lines'B C, Fig. 3.
- the first feature relates to the disposal of the disk 7, this being arranged so that its intersection with the ball S shall be in a zone Of the said ball or sphere of lnaterially less diameter than that of the sphere itself.
- the plane of the disk is above (or below) the center of the ball, and one section of the ball, as the'lower, will extend both above, as 9, and below, as at 10, the plane H of the center of the ball.
- the object of this is to obtain with a flat disk the greatest possible eXtent of bearing-surface for the ball in the lower socket-bearing 12.
- this socket is an exacthemispherical cavity, while that portion of the ball which acts in this socket is, as just described, greater than a hemisphere.
- the advantage of this is to better control the oscillating ⁇ action of the disk to afford greater ball-bearing surface and to maintain the disk concentric with the outer walls of the casing.
- the disposal of the disk as here shown does not require that the angle of the upper-case frustum shall be different from that of the lower with respect to the faces or medium plane X of the disk-casing sections, as is shown by the dimensions expressed in degrees between the dotted lines H of Fig. l and the plane X, although the center of vibration of the disk is at one side of the actual medium plane Of the disk-casings indicated by the broken line Z.
- the second feature relates to the attachment of the disk to the ball by forming two transverse slits, as 14, on opposite sides of the ball, adapted to receive the disk in the manner shown. That is, the usual disk-slot 15, which straddles Ithe diaphragm 16, is simply extended farther through the disk, as to 17, so as to straddle also the connecting section 18 of the ball, between the slots 14, one section acting as a-stop in one direction, and to secure the disk against slipping out backwardly a pin, as 19, may be inserted.
- hollow or solid balls 0f the greatest accuracy and of lowcost to manufacture may be used, while there is a contingent advantage in that no manual fitting is required at the point where the face of the ball meets .the edge of the diaphragm.
- the third feature relates to counterbalancing the disk, either by the attachment of material 21 at or near the edge or edges of the slot or in the removing of material 22 from the body of the disk, opposite from the slot, the said attachment or removal, as the case may be, being sufficient to compensate for the material removed from the disk to form the slot, that is, the slotted side of the disk is of equal weight with the unslotted side.
- counterbalancin g material that is, weight-pieces, as in the form of balls or buttons 21, is added, this necessitates forming cavities in the face or faces of the frustums to receive the same, as indicated in dotted lines 23, Fig. 2.
- the application of such weights is generally preferable in the instance of metal disks; but when hard rubber is employed the alternate method, as indicated by the dotted cavities 23, is the better, as the desired result may thus be IOO IOS
- the fourth feature relates to the ports, essentially consisting in forming each of the ports, that is, the inlet-port 2l and the outlet-port 25, of unequal extent vertically and of unequal area as relates to the upper section 26 and the lower section 27 of the two sections constituting the disk-Casin g A. r1 ⁇ hus in the drawings submitted the area of each port, Fig. 2, measured in direct elevation, equals 2.6 square inches, but each space in the lowerseetion bounded by the lines 2S 20 3() 31 equals only 0.8 square inches, or 2422807 percent., whereas each space in the upper section bounded by the lines 2S 32 33 3l equals 1.8 square inches, or c) (j per cent.
- the fifth feature is comprised in the construction and disposal of the thrust-roller 32 and its bearing 38, this being an amplification in detail of the design shown in my Patent No. 535,011 of March 12, 1895.
- the bearing for the thrust-roller might lie in the plane of the disk, it would not realize the best theoretical conditions in that the center of its rotation is not in a plane coincident with that of the center of the ball.
- the roller as shown in Fig. l, that the longitudinal center or axis Si of the roller-bearing 38 must project to the center of the ball and be at an angle to the plane of the disk.
- roller 32 mounts on a bearing having an outer head or collar 35, as in this wise the radial thrust of the roller when in action, due to the centrifugal force, is not transmitted to the outer wall, as 3G, of the slotin the disk-casing, which would tend to produce a cramping action.
- a disk meter provided with a fiat disk and ball, the said fiat disk being at one side of the center of the ball and having a diskcasing, formed ci' two sections, in which the angles of the frusta are equal but the socketbearings and spherical contour are Of unequal extent and area.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Rolling Contact Bearings (AREA)
Description
(No Model.) y
J. THOMSON.A
DIASKWATBR METER.
' Patented Sept. 29, 1896.
t. wt t UNITED STATES JOHN THOMSON,
PATENTv OFFICE.
DISK WATER-METER.
SPECIFICATION forming part of Letters Patent No. 568,640, dated September 29, 1896.
Application filed December 5, 1895. Serial No. 571,155. (No model.)
T0 all whom t may concern.-
Be it known that I, JOHN THOMSON, a citizen of the United States,residing at Brooklyn, in the county of Kings and State of New York, have invented certain new and useful Improvements in Disk Water-Meters, of which the following is a specication.
This is an invention in disk water-meters, relating in particular to the arrangement of the disk with respect to the ball and the diskcasing, to the manner of attaching the disk to the ball, to the ports of the disk-casing, to the counterbalancing of the disk, and to the disk-thrust-controlling roller.
In view of the advanced and well-known state of the art, the drawings are purposely stripped of all details, such, say, as extraneous casings and waterways, and only such elements are shown as are to be here more particularly dealt with.
Inv said drawings, Figure 1 is a vertical central section through a disk-casing A, giving an edge view of the disk and its ballbearing, this illustration indicating such an embodiment of my invention as relates to the arrangement of the three following elements, namely: the disk, the ball, and the spherical wall and the frustums of the disk-casing. Fig. 2 is a side view of the disk-casing complete, showing the inlet and Outlet ports and the diaphragm, together with the ball and disk. Fig. 3 is a top plan view of the disk,
but with the ball, diaphragm, and a portion of the disk-casing shown in horizontal section. Figs. fi and 5 are central detail sections of the ball and disk, respectively, on the lines'B C, Fig. 3.
The first feature relates to the disposal of the disk 7, this being arranged so that its intersection with the ball S shall be in a zone Of the said ball or sphere of lnaterially less diameter than that of the sphere itself. In other words, the plane of the disk is above (or below) the center of the ball, and one section of the ball, as the'lower, will extend both above, as 9, and below, as at 10, the plane H of the center of the ball. The object of this is to obtain with a flat disk the greatest possible eXtent of bearing-surface for the ball in the lower socket-bearing 12. In fact,as shown in the drawings, this socket is an exacthemispherical cavity, while that portion of the ball which acts in this socket is, as just described, greater than a hemisphere.
The advantage of this is to better control the oscillating` action of the disk to afford greater ball-bearing surface and to maintain the disk concentric with the outer walls of the casing. The disposal of the disk as here shown does not require that the angle of the upper-case frustum shall be different from that of the lower with respect to the faces or medium plane X of the disk-casing sections, as is shown by the dimensions expressed in degrees between the dotted lines H of Fig. l and the plane X, although the center of vibration of the disk is at one side of the actual medium plane Of the disk-casings indicated by the broken line Z.
The second feature relates to the attachment of the disk to the ball by forming two transverse slits, as 14, on opposite sides of the ball, adapted to receive the disk in the manner shown. That is, the usual disk-slot 15, which straddles Ithe diaphragm 16, is simply extended farther through the disk, as to 17, so as to straddle also the connecting section 18 of the ball, between the slots 14, one section acting as a-stop in one direction, and to secure the disk against slipping out backwardly a pin, as 19, may be inserted. In this wise hollow or solid balls 0f the greatest accuracy and of lowcost to manufacture may be used, while there is a contingent advantage in that no manual fitting is required at the point where the face of the ball meets .the edge of the diaphragm.
The third feature relates to counterbalancing the disk, either by the attachment of material 21 at or near the edge or edges of the slot or in the removing of material 22 from the body of the disk, opposite from the slot, the said attachment or removal, as the case may be, being sufficient to compensate for the material removed from the disk to form the slot, that is, the slotted side of the disk is of equal weight with the unslotted side. Then counterbalancin g material, that is, weight-pieces, as in the form of balls or buttons 21, is added, this necessitates forming cavities in the face or faces of the frustums to receive the same, as indicated in dotted lines 23, Fig. 2. The application of such weights is generally preferable in the instance of metal disks; but when hard rubber is employed the alternate method, as indicated by the dotted cavities 23, is the better, as the desired result may thus be IOO IOS
reached by simply drilling a few holes into the edge of the disk. The advantage of thus counterpoising the disk is to adapt it for the highest speed of operation without shock or jar and in producing a more uniform distribution of the working strains upon the bearingsurfaces.
The fourth feature relates to the ports, essentially consisting in forming each of the ports, that is, the inlet-port 2l and the outlet-port 25, of unequal extent vertically and of unequal area as relates to the upper section 26 and the lower section 27 of the two sections constituting the disk-Casin g A. r1`hus in the drawings submitted the area of each port, Fig. 2, measured in direct elevation, equals 2.6 square inches, but each space in the lowerseetion bounded by the lines 2S 20 3() 31 equals only 0.8 square inches, or 2422807 percent., whereas each space in the upper section bounded by the lines 2S 32 33 3l equals 1.8 square inches, or c) (j per cent. In this connection reference may be made to my Patent No. 375,023 of Deceniber 20, 1387, in which the design here contemplated would be undesirable, not to say impracticable. If the sections were separable on a different plane, the port-area would still be unequally proportioned upon opposite sides of the plane of the center of the ball. Se, too, the spherical contour of the upper section at K would be greater than that of the lower section at M.
The fifth feature is comprised in the construction and disposal of the thrust-roller 32 and its bearing 38, this being an amplification in detail of the design shown in my Patent No. 535,011 of March 12, 1895. Thus when the disk is mounted out of the equatorial center of the ball, while the bearing for the thrust-roller might lie in the plane of the disk, it would not realize the best theoretical conditions in that the center of its rotation is not in a plane coincident with that of the center of the ball. Hence I so arrange the roller, as shown in Fig. l, that the longitudinal center or axis Si of the roller-bearing 38 must project to the center of the ball and be at an angle to the plane of the disk. It has also been found preferable to mount the roller 32 on a bearing having an outer head or collar 35, as in this wise the radial thrust of the roller when in action, due to the centrifugal force, is not transmitted to the outer wall, as 3G, of the slotin the disk-casing, which would tend to produce a cramping action.
I donot limit myself to the precise construction and arrangement of parts shown, and it will be evident that the individual features of my invention maybe used separately apart from the others, and some of them in meters of a diiferent character from that shown.
That I claim is- 1. A disk meter provided with a fiat disk and ball, the said fiat disk being at one side of the center of the ball and having a diskcasing, formed ci' two sections, in which the angles of the frusta are equal but the socketbearings and spherical contour are Of unequal extent and area.
2. The combination in a meter, of a ball, a disk secured to the ball at one side of the center thereof, and a disk-easin g formed of two sections, the spherical contour, as K, M, being of unequal extent, and having frusta with bearing-faces for the opposite faces of the disk whose angles, as Il, from thc faces of the two sections, as X, are equal, substantially as described.
3. The combination in a meter, of a ba-ll, a Ilat disk secured to the ball at one side of the center thereof, a easing formed of two sections each having an unequal portion of the spherical contour, frusta with bearing-faces of equal angles for the opposite faces of the disk, and with a socket-bearing adapted to the said iiat disk and the ball, substantially as described.
4:. The combination in a disk water-meter, of the ball having side grooves and a flat slotted disk extendinginto said grooves, substantially as described.
5. The combination in a meter, of a ball having side grooves, and. a slotted disk having portions at the center on opposite sides of the slot extending into the said grooves, substantially as described.
(i. The combination with the ball of a meter, of a disk of substantially equal weight on all'sides of the ball, substantially as and for the purpose herein described.
7. In a meter, a easing, adisk, a ball central with the disk, and ports unequally arranged en opposite sides of a plane extending centrally through the ball, substantially as described.
S. In a disk water-meter, the combination with the ball and disk, of a sectional casin having inlet and outletports formed unequally in both sections, substantially as described.
9. The combination with the ball and disk, of the thrust-roller bearing turning on an axis in a plane which radiates from the center of the ball at an angle to the plane of the disk, substantially as described.
10. rllhe combination with the disk and diskcasin g, of the roller-bearin g, the roller mounted thereon, and the head or collar secured to the' outer end of the bearing, whereby the outward end thrust of the roller is resisted by said head or collar, substantially as described.
In testimony whereof I have signed my name to this speci ication in the presence of two subscribing witnesses.
JOHN THOMSON.
'Wi tncsses:
Marian KnAsNnn, Guo. A. MAiinANn.
IOO
IIO
Publications (1)
Publication Number | Publication Date |
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US568640A true US568640A (en) | 1896-09-29 |
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US568640D Expired - Lifetime US568640A (en) | thomson |
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