US3067958A

US3067958A - Shredding machine for foam material

Info

Publication number: US3067958A
Application number: US62010A
Authority: US
Inventors: Garwin Robert
Original assignee: Individual
Current assignee: Individual
Priority date: 1960-10-11
Filing date: 1960-10-11
Publication date: 1962-12-11
Anticipated expiration: 1979-12-11

Description

Dec. 11, 1962 R. GARWIN SHREDDING MACHINE FOR FOAM MATERIAL Filed 001;. 11, 1960 FIG. I.

24 k-Z 42a INVENTOR ROBERT GARWIN MW1,M I

ATTORNEYS.

Patented Dec. 11, 1962 line 3,067,958 SHREDDING MACHHNE FOR FOAM MATERHAL Robert Garwin, 47 Arden St, New York, N.Y. Filed Oct. 11, 1960, Ser. No. 62,010 2 Claims. (Cl. 241-55) This invention relates to an improved machine for shredding materials.

This machine is of the general type shown in prior US. Patents Nos. 1,735,749 and 1,802,249. The machines of said prior patents were particularly suitable for the processing of fibrous filling materials. The machine in accordance with the present invention is particularly suitable for shredding materials such as foam rubber and foam polyurethane, and other foam plastic materials.

An important object of the invention is to provide an improved machine for shredding materials of this type, which is economical to manufacture, has a minimum number of parts, is highly eiiicient in operation and is readily adaptable to produce particles of varying sizes.

As an important feature of the invention, 1 provide means for selectively varying the size of the outlet opening of the throat through which the material is fed during the cutting operation. I have found that this structure makes it possible to regulate the size of the particles of foam material effectively.

Other objects and advantages of this invention will become apparent from the following description, in conjunction with the annexed drawing, in which a preferred embodiment of the invention is disclosed.

In the drawings,

FIG. 1 is a vertical section, partly in elevation of my improved machine.

FIG. 2 is a section on line 22 of FIG. 1, showing the machine adjusted to produce particles of minimum size.

FIG. 3 is a view similar to FIG. 2, showing the machine adjusted to produce particles of maximum size.

Upon reference to the drawing in detail, it will be noted that it shows a frame having a raised horizontal platform 11. Casing 12 is supported on platform 11 adjacent the front thereof and extends vertically therefrom. Casing 12 has a longitudinal axis. Frame 10 has an extension 13 located behind casing 12 and extending upwardly from platform 11. The upper end of frame extension 13 supports a pair of longitudinally spaced bearings 14 and 15, through which shaft 16 extends turnably. Pulleys 17, 18 and 19 are mounted upon shaft 16 behind bearing and serve for connection of shaft 16 to various sources of power (not shown) so as to rotate shaft 16 at selected rate of speed.

Casing 12 has a vertically and laterally extending front wall 20 and a vertically and laterally extending rear wall 21, both of which rest upon platform 11. Walls 20 and 21 are parallel to each other. The top space of casing 12, between walls 20 and 21, is closed by top wall 22. The casing is further closed by side walls 23 which extend vertically and longitudinally.

Vertically and laterally extending wall 24 is located intermediate walls 29 and 21. Wall 24 is parallel to walls 20 and 21 and extends between the top and the bottom and also between the sides of casing 12.

Shaft 16 extends forwardly through an opening 21a in rear wall 21, which opening is sealed by any suitable packing 25. Fan blade assembly 26 which has radial blades 26a, is mounted upon shaft 16 in fan chamber 16a between rear Wall 21 and intermediate wall 24 and also between walls 22 and 9.

Front wall 20 has an opening 20a which is circular and which is co-axial with shaft 16. Intermediate wall 24 has an opening 24a which is circular and which is coaxial with opening 20a and shaft 16. Opening 24a is of greater diameter than opening 20a. A frusto-conical wall 27 is disposed between walls 21 and 24 with the opening of smaller diameter of wall 27 coinciding with opening 29a, and with the opening of larger diameter of wall 27 coinciding with opening 24a. Accordingly, the frustoconical wall 27 is co-axial with shaft 16.

Hopper 28 is mounted upon the front of front Wall 20. Hopper 28 has a top opening 28a for reception of material to be shredded and has a rear opening 2812 which communicates with opening 29a for passage of material from hopper 28 to the shredding mechanism. A portion of the rear wall 230 of hopper 28 projects into opening 20a.

Frusto-conical rotor 30 is fixably mounted upon shaft 16. The smaller end of rotor 39 is at the front thereof. Rotor 30 extends into the bore of wall 27, but the front face of rotor 30 is located rearwardly of opening 26a. Rotor 34} projects rearwardly of wall 24, into fan chamber 16a, and extends substantially to the front face of fan assembly 26. The blades 26a of fan assembly 26 project radially beyond the periphery of rotor 31 and eyond opening 24a.

Teeth 31 are mounted upon the periphery of rotor 30, forwardly of opening 24a. The inner face of wall 27 serves as the stator of the mechanism and has stator teeth 32 mounted thereon.

The rotor teeth 31 are disposed in a plurality of longitudinally spaced sets, with teeth 31 of each set preferably equally spaced around the circumference of rotor 3t} and extending radially outwardly therefrom. Optionally, there are two longitudinally spaced sets of teeth 31, as shown illustratively in the drawing.

Similarly, the stator teeth 32 are divided into a plurality of longitudinally spaced sets, the teeth of each set being preferably equally spaced around the circumference of wall 27. Optionally, there are three such longitudinally spaced sets of stator teeth 32, as shown illustratively in the drawing.

Preferably, each set of rotor teeth 31 are disposed longitudinally between successive sets of stator teeth 27, as shown in the drawing. Preferably, the

teeth

31 and 32 are pointed, and the pointed ends of the teeth 31 project radially ouwardly of the pointed ends of the teeth 32.

The annular, frusto-conical space between rotor 30 and stator wall 27 is designated by the reference numeral 42 and is defined as a throat. The material is fed into hopper 28, in the direction of arrow 33, and hence is drawn by the suction of fan assembly 26 into throat 42, in the direction of arrows 34. The material passes through throat 42 and is discharged rearwardly therefrom, in the direction of arrows 35, into fan chamber 16a. Said chamber 16a has a side outlet opening 36 through which the shredded material is discharged from the machine.

As an important feature of the invention, means are provided for regulating the size of the outlet of throat 42, so as to control the size of the particles shredded by the machine. It will be appreciated that the outlet of throat 42 is in the form of an annulus 42a, the outer periphery of which coincides with the periphery of opening 24a, and the inner periphery of which coincides with the surface of rotor 36.

A pair of plates 4% are respectively pivotally mounted upon the rear face of wall 24. Each said plate 40 is rectangular and has an inner semi-circular cutout 41. Each said plate dit is connected at its inner lower end to plate 24, below opening 244:, by means of longitudinal pivot 45. Each said plate 40 has a co-planar handle 43 extending laterally outwardly from the side edge thereof at the top thereof. Each said handle 43 extends through a slit 23a in the side wall 23 associated therewith. Accordingly, the two handles 43 are accessible outside the machine for manipulation of the plates 48.

FIG. 2 shows the plates 40 in a first position thereof. In both positions of plates 4%, their lower inner edges 40a, below the cutouts 41, substantially abut each other, as clearly shown in FIGS. 2 and 3. In the first position of plates 40, their upper inner edges 4%, above the cutouts 41, substantially abut each other. Accordingly, the two cutouts 41 cooperate to define a circular opening through the combined plates 40. The plates 40 are of combined size, greater than the opening 24a, so that in the position of FIG. 2, the plates 49 completely cover the opening 24a, with the exception of the central opening in the plate defined by the cooperating cutouts 41. This central opening defined by the cooperating cutouts 41 is of sma ler diameter than opening 24a but of slightly greater diameter than rotor 30. It will be appreciated, therefore, that the plates 46, in the position of FIG. 1, completely block outlet opening 42a of throat 42, with the exception of the space between cutouts 41 and rotor 39. The distance between the edge of cutout 41 and the surface of rotor 30 may be on the order of approximately one quarter of an inch, by way of example.

FIG. 3 shows the plates 40 in their spread condition, corresponding to a substantially complete clearance by the plates 46 of the throat outlet opening 42a. This corresponds to the condition of the maching for producing particles of maximum size. It will be apparent that the plates 4% may be located in any selected intermediate position, so as to provide an exit opening of throat 42 which is intermediate the minimum opening of FIG. 2 and the maximum opening of FIG. 3. Accordingly, the plates 46 provide a simple means for control of the size of the exit space from throat 42, and accordingly provide a simple means for control of the particle size.

While the speed of rotation of the fan may be varied, to secure optimum results, the main control, once the desired fan speed has been obtained, is based upon manipulation of the plates 40. By using the proper number of teeth, in conjunction with the proper speed of rotation of the fan, relatively uniform particle size may be obt-ained for any size of throat opening.

The machine, as above-described, represents a substantial improvement over existing machines for shredding plastic foam material, such as foam rubber and foam polyurethane, most of which rely upon the use of knives to shred the material. Such machines are not as adaptable as the present machine for producing particles of varying diameters.

It will be apparent that the two plates 40 may be adjusted independently of each other. If it is desired to produce particle sizes of varying diameters, one plate 40 may be left in the position of FIG. 2, by way of example, and the other plate 4% may be moved at least partly toward its position of FIG. 3, by way of example.

While I have disclosed a preferred embodiment of my invention and have indicated various changes, omissions and additions which may be made therein, it will be apparent that various other changes, omissions and additions may be made in the invention without departing from the scope and spirit thereof.

For example, while I have described the longitudinal axis of the machine as extending horizontally, it will be apparent that the parts may be positioned so as to permit the machine to be mounted in any desired orientation.

What is claimed is:

l. A machine for shredding foam rubber, foam polyurethane and the like, comprising a casing having a longitudinal axis and having a rear fan chamber and a front shredding chamber in communication with each other, said shredding chamber having an inlet for reception of material to be shredded, said fan chamber having an outlet for shredded pieces of material, a suction fan mounted in said fan chamber for rotation about said axis to draw material through said shredding chamber, said shredding chamber having a frusto-conical peripheral stator wall which is co-axial with said axis and whose end of smaller diameter is at its front, a frusto-conical rotor mounted in said shredding chamber and co-axial with said axis and coupled to said fan for rotary movement in unison therewith, the end of said rotor of smaller diameter being at its front, said rotor having rotor teeth extending from its periphery, said stator having stator teeth extending therefrom toward said rotor, said rotor teeth and said stator teeth being cooperatively shaped and positioned to shred material in said shredding chamber when said rotor is rotated, said rotor and said stator defining an angular outlet opening of said shredding chamher, the inner diameter of said outlet opening being large with respect to the outer diameter thereof, and a pair of blocking plates slidably mounted on said casing adjacent said outlet opening, said plates being transversely movable to inner positions thereof in which they have opposing abutting edges, said abutting edges having opposing semi-circular cutouts which together define a circular cutout in the inner position of said plates which is co-axial with said axis and of diameter intermediate the inner and outer diameters of said outlet opening to thereby restrict said outlet opening to a minimum radial width thereof and thereby determine a minimum diameter of said pieces of shredded material, said plates being outwardly slidable to a position substantially clearing said outlet opening to permit said outlet opening to determine a maximum diameter of said pieces of shredded material, the opening between said plates remaining predominantly generally circular and said outlet being restricted to a predominantly generally annular opening until said plates reach their clearing positions.

2. A machine for shredding foam rubber, foam polyurethane and the like, comprising a casing having a longitudinal axis and having a rear fan chamber and a front shredding chamber in communication with each other, said shredding chamber having an inlet for reception of material to be shredded, said fan chamber having an outlet for shredded pieces of material, a suction fan mounted in said fan chamber for rotation about said axis to draw material through said shredding chamber, said shredding chamber having a frusto-conical peripheral stator wall which is co-axial with said axis and whose end of smaller diameter is at its front, a frusto-conical rotor mounted in said shredding chamber and co-axial with said axis and coupled to said fan for rotary movement in unison therewith, the end of said rotor of smaller diameter being at its front, said rotor having rotor teeth extending from its periphery, said stator having stator teeth extending therefrom toward said rotor, said rotor teeth and said stator teeth being cooperatively shaped and positioned to shred material in said shredding chamber when said rotor is rotated, said rotor and said stator defining an angular outlet opening of said shredding chamber, the inner diameter of said outlet opening being large with respect to the outer diameter thereof, and a pair of blocking plates pivotally mounted on said casing adjacent said outlet opening, said plates being turnable about longitudinal axes to inner positions thereof in which they ac eage-e have opposing abutting edges, said abutting edges having opposing semi-circular cutouts which together define a circular cutout in the inner position of said plates which is co-axial with said axis and of diameter intermediate the inner and outer diameters of said outlet opening to thereby restrict said outlet opening to a minimum radial width thereof and thereby determine a minimum diameter of said pieces of shredded material, said plates being outwardly turnable to a position substantially clearing said outlet opening to permit said outlet opening to tie termine a maximum diameter of said pieces of shredded material, the opening between said plates remaining predominantly generally circular and said outlet being restricted to a predominantly generally annular opening until said plates reach their clearing positions.

References Cited in the file of this patent UNITED STATES PATENTS 281,911 Morgan July 24, 1883 765,281 Hermann July 19, 1904 10 2,265,622 Basler Dec. 9, 1941 2,522,027 Evans Sept. 12, 1950 2,552,037 Elverum May 8, 1951