US706102A

US706102A - Centrifugal grinding-mill.

Info

Publication number: US706102A
Application number: US6760501A
Authority: US
Inventors: John H Pendleton
Original assignee: PENDLETON TAPSCOTT Co
Current assignee: PENDLETON-TAPSCOTT Co; PENDLETON TAPSCOTT Co
Priority date: 1901-07-09
Filing date: 1901-07-09
Publication date: 1902-08-05
Anticipated expiration: 1919-08-05

Description

No. 706,!02. 1 Patonted Aug. 5, I902.

J. H. PENDLETON.

BENTRIFUGAL GRINDING MILL.

(Application filed July 9, 1901.1

2 Sheik-Shae! I.

(No Model.)

Patented Aug. 5, I902.-

I J. H. PE'NDLETON.

CENTRIFUGAL- GRINDING HILL. 7

(Application flld July 9, 1901.)

2 sheets sh'eiet 2.

(No Model.)

m in

' jive/ 722???- UNITED ESTATES PATENT JOHN H. PENDLETON, OF JAMESBURG, NElV JERSEY, ASSIGNOR TO THE PENDLETON-TAPSCOTT COMPANY, OF NElV YORK, N. Y., A CORPORA- TION OF NEW JERSEY.

CENTRIFUGAL GRINDING-MILL.

SPECIFICATION forming part Of Letters Patent NO. 706,102, dated August 5, 1902.

Application filed July 9, 1901. Serial No. 67,605. No model-) a mortar and grinding-balls therein, a cen tral;

1o shaft which carries said mortar and which may be termed the mortar-shaft, two other shafts alined with each other and with the adjacent ends of which the opposite ends of the mortar-shaft are connected by a universal joint and crank-like connection in suchmannor as to keep it oblique to said alined shafts, which, being driven at different speeds in the same direction, cause the mortar-shaft and the mortar to rotate more or less slowly about;

their own oblique axis while revolving more or less rapidly around the axis of the alined I will describe a mill with reference.

shafts. to the accompanying drawings and afterward point out its novelty in claims.

z 5 Figure 1 is avertical sectional view of the mill; Fig. 2, a sectional view taken trans-- versely to Fig. 1 in the line 2 2 of the latter figure; Fig. 3, a vertical sectional view, on a larger scale, of parts of the mill imperfectly o represented in Fig. 1.

ct b c d e designate the parts of a framing containing suitable bearings for three upright rotary shafts f g h. The shafts f g are in line with each other,with a space between 3 5 them, the-lower one being represented as supported in a step-bearing d on the bed-plate a and working in a bearing in a bracket 0, and the upper one,g,as supported by and working in a bearing in the bracket 6. The shaft h 4.0 is represented as supported in a step-bearing at at in the bed-plate and working in bearings in the standard I).

i is the grinding-mortar, fast on ashaft j, with which it is concentric, the said shaftj being arranged in a position oblique to the common axis of the shafts f g and being retained in suchposition partly by a joint 7a, which is flexible in all directions, represented as a gimbal, and which connects the lower end of said shaft and the mortar with the upper end of the shaftf, and partly by having the pivot or journal 5 on its upper end fitted to a journal hearing or box Z, carried by a rotary disk m, which is affixed to the lower end of the shaft g. This disk constitutes the rigid arm of a crank, the other arm and wrist Of which are flexibly constituted by the oblique mortar-shaftj and its journal 5 and the gimbal-joint 7a. The mortar i contains any number of grinding-balls 25 of any suitable mate- 6o rial, as chilled iron or steel, and of any desirable size and number, according to the nature of the matter to be ground.

The upright shaft h, which is the drivingshaft, is represented as furnished with a pulley n for the reception of a driving-belt and as carrying a larger'and a smaller spur-gear 0 p, gearing, respectively, with smaller and larger spur-gears r s on the shafts f and g, respectively, so that by the rotation of h the two shafts f and g are driven in the same direction, but f is driven faster than 9. By this mounting of the mortar and this system of gearing the oblique shaftj and the mortar are carried around with the shaft f and caused to revolvearound the axis thereof, revolution for revolution, and the mortar and its shaftj are also caused to rotate about their own axis at a speed depending upon the difference in the speed of the shafts f and 9. Thus if g makes nine revolutions, to ten of f the shaftj and mortar will make one revolution about their oblique axes.

The mortar is represented as having an internally-concave bottom 6 in order to bring the center of the universal joint 79 as nearly as possible in the center of the entire mass of the mortar and its contents. Its sides 7 are represented as cylindrical and without opening. Its top or cover 8 has a central opening 0 9 around its shaft for the reception of the material to be ground and for the entrance of air, the said opening being large enough for the entrance also of a rotating feedingspout u, which is carried by the crank disk m, the lower end or nozzle of the said spout entering the lower part of said opening 9 and there being a lateral opening 29 in said tom of which is a delivery-spout c.

spout opposite to the upper part of said opening 9' for the entrance of air to the mortar. This opening 29 is fitted with a screen to prevent the passage through it of any of the material to be ground. The bottom 6 of this mortar and its central hub 10, which receives the shaft j, may be of one casting. The sides and top or cover may be of steel plate. In the bottom there are provided a number of screens 15, the fineness of Whose mesh corresponds with the fineness to which the matters are to be ground. The journal 5 of the shaftj is represented as fitted with a sleeve 11, the exterior of which, fitting to the'journal box Z, is of spheroidal profile to permit it to oscillate within the box sufficiently to accommodate the shaft to any want of truth in the parts that may result from wear.

In Fig. 1 the mortar is represented as surrounded by and entirely inclosed within a stationary casing v, at the upper end of which is affixed a feeding-hopper w and at the hot- The throat 12 of the hopper surrounds the shaft g and the tubular part 16 of its bearing and is entirely surrounded by the hopper-like receiving-mouth 13 of the rotating spout u. The crank-disk m is constructed or provided with a hood 14, which covers the upper part of the hopper. This hood 14 and the spent it are represented in Figs. 1 and 3 of one piece secured on the top of the crank-disk m.

In order to prevent the oil which is employed for lubricating the shaft g from escaping around the bottom of its bearing and so getting into the feeding-spout u and into the matter to be ground, the said bearing is prolonged, as shown at 16 in Figs. 1 and 3, below the said bracket in tubular form, and a flanged sleeve 1 which fits the exterior of the tubular prolongation 16 and is screwed tightly onto the exterior of the hub 17 of the crankdisk m. This sleeve 11 which forms an oilcup, receives any of the lubricating-oil which may escape around the shaft g at the bottom of the prolongation 16 of its hearing, such oil passing up through the said cup and over the flange 18 of its upper end into a little annular trough 19, which is formed around the throat 12 of the hopper w and from which a small spout 20 passes through the casing '2 to deliver the escaping oil outside of the latter.

In order to prevent any of the oil which is used to lubricate the shaft ffrom escaping at the top of the bearing 27, provided on and in the bracket 0 for said shaft, and running into the ground material within the casing 42, a channel 21 is provided, as shown in Fig. 1, in and around the said shaft above the said bearing, and with this channel 21 two channels 22 23 communicate, the channel 22 coming from the interior of the bearing and the channel 23 running downward outside of the bearing and having an outlet below the hearing outside of the delivery-spout w.

The operation of the mill is as follows: Rapid rotary motion being given to the shaft h and through it to the shaftsfand g at unequal velocities, the oblique mortar-shaft and the mortar are caused by the shaft f to revolve horizontally therewith about the common axis of the two alined shafts f g and at the same time to turn slowly about their own oblique axis. The matter to be ground,fed into the stationary hopper 10, passes thence through the rotating spout it into the mortar, wherein it is subjected to the grinding action between the balls 25 t themselves and between the said balls and the sides of the mortar, such action resulting partly from the centrifugal force to which the balls and the said matters are subj ected by the revolution of the mortar around the axis of the alined shafts and resulting partly from the constant interchange of position of the balls and said matters resulting from the slow rotation of the mortar about its own oblique axis by which every part of it is alternately brought to its highest and lowest positions. In this operation the grinding-balls and the matter to be ground are caused by the centrifugal action of the mortar to continually range themselves around the sides of the mortar, as shown in Figs. 1 and 2, in the form of a wall parallel with the axis of the alined shaftsfg. As fast as the matter is reduced to the requisite degree of fineness the reduced particles, being the lightest, are subject to less intense centrifugal action, and consequently Work gradually inward toward the center of the mortar and are sifted out through the screens 15, whence they pass into the lower part of the casing v and out through the delivery-spout 56. This operation of sifting is effected in part by gravitation and in part by currents of air induced into the mortar through the hopper w and spout u and expelled therefrom through the delivery-spout a: by the blower-like action of the mortar itself, which action might be assisted by suction applied at the deliveryspout m.

It is obviously immaterial which of the shafts f 9 should have the higher velocity, it only being necessary that their velocities should be different to produce the slow rotation of the mortar-shaft it about its own axis.

What I claim as my invention is- 1. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the first-named shaft is obliquely arranged and carried as part of a flexible crank connection, and means for rotating said alined shafts at different velocities, substantially as described.

2. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the first mentioned shaft is obliquely arranged, a flexible connection between one of said alined shafts and one end of said obliquely-arranged shaft, a crank-arm on the other of said alined shafts, a pivotal connection between, said crank-arm and the other end of said obliquely-arranged shaft, and means for rotating the'two alined shafts at different velocities, substantially as herein described.

3. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the first-mentioned shaft is obliquelycarried, means for rotating said alined shafts at different velocities, and a rotary feeding-spout carried by one of said alined shafts and entering the mortar, substantially as herein described.

4. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the first mentioned shaft is obliquely arranged, a gimbal-joint between one of said alined shafts and one end of said obliquelyarranged shaft, a crank-arm on the. other of said alined shafts, a journal-bearing in said crank-arm receiving a journal on the other end of said obliquely arranged shaft, and means for rotating the two alined shafts at difierent velocities, substantially as herein described.

5. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the first-mentioned shaft is obliquely arranged and carried as part of a flexible crank connection, means for rotating said alined shafts at diflerent velocities, and a rotary feeding-spout carried by one of said alined shafts and entering the mortar, substantially as herein described.

6. In a mill, the combination of a mortar and grinding balls and screens therein, a shaft which carries said mortar, two shafts alined with each other and by and between the adjacent ends of' which the first-mentioned shaft is obliquely arranged as part of a flexible crank connection, means for driving the two alined shafts at difierent velocities, and a stationary casing surrounding the mortar and the crank connection and having a feeding-inlet above the mortar and a delivery-outlet below the mortar, substantially as herein described.

7. In a mill, the combination of a mortar and grinding-balls therein, a shaft which carries said mortar, two shafts alined with each other and between the adjacent ends of which the firstmentioned shaft is obliquely ar ranged and carried as part of a flexible crank connection, means for rotating said alined shafts at different velocities, a rotary feeding-spout carried by one of said alined'shafts and entering the mortar, and a stationary casing surrounding the mortar and its crank connections and having a feeding-inlet in its upper part communicating with said rotary feeding-spout and a delivery-outlet in its lower part, all substantially as herein described.

In testimony that I claim the foregoing as my invention I have signed my name, in presonce of two witnesses, this 12th day of April,

JOHN H. PENDLETON. Witnesses:

FREDK. HAYNES, L. M. EGBERT.