US3838823A

US3838823A - Apparatus for reducing wood and like articles

Info

Publication number: US3838823A
Application number: US00345664A
Authority: US
Inventors: H Lewis
Original assignee: Montgomery Industries International Inc
Current assignee: Montgomery Industries International Inc
Priority date: 1971-09-30
Filing date: 1973-03-28
Publication date: 1974-10-01
Anticipated expiration: 1991-10-01

Abstract

Mobile apparatus for reducing discarded wooden railroad ties to relatively small fragments comprises a rail vehicle having a set of drive wheels, an engine connected to a two speed drive system for the wheels, a cutting and punching mechanism driven from the engine through a clutch, an interlock for disengaging the clutch when the vehicle is driven in the higher speed range, a conveyor for advancing ties to be reduced into the cutting mechanism, a crane for picking up ties to be reduced and depositing them on the conveyor, and a blower for discharging fragments from the cutting mechanism.

Description

United States Patent 1 Lewis [451 Oct. 1, 1974 1 APPARATUS FOR REDUCING WOOD AND LIKE ARTICLES [75] Inventor: Herbert II. Lewis, Jacksonville, Fla.

22 Filed: Mar. 28, 1973 1211 Appl. No.: 345,664

Related US. Application Data [62] Division of Ser. No. 185,247, Sept. 30, 1971, Pat.

3,220,658 11/1965 Shelton, .Ir 241/32 3,473,742 10/1969 Montgomery 241/32 3,701,483 10/1972 Crosby et a1 241/32 Primary ExaminerGranville Y. Custer, Jr. Attorney, Agent, or Firm-Strauch, Nolan, Neale, Nies & Kurz 157] ABSTRACT Mobile apparatus for reducing discarded wooden railroad ties to relatively small fragments comprises a rail vehicle having a set of drive wheels, an engine connected to a two speed drive system for the wheels, a cutting and punching mechanism driven from the engine through a clutch, an interlock for disengaging the clutch when the vehicle is driven in the higher speed range, a conveyor for advancing, ties to be reduced into the cutting mechanism, a crane for picking up ties to be reduced and depositing them on the conveyor, and a blower for discharging fragments from the cutting mechanism.

2 Claims, 9 Drawing Figures PATENTED 1 1974 SHEET 10F 7 PATENTEB 1 I974 3,838,823 SHEEIEBF 7 PAIENTEDBET 14 3338.823

SHEEI u or T A? may; 5

PAIENTEBnm 11914 SHEEI S0? 7 PATENTEDUCT H974 SHEEI 7 BF 7 mmT APPARATUS FOR REDUCING WOOD AND LIKE ARTICLES This is a division, of application Ser. No. l85,247, filed Sept. 30, 1971, now US. Pat. No. 3,752,409, issued Aug. ]4, I973.

WOODEN ARTICLE AND LIKE DESTROYER The invention in its preferred embodiment will be disclosed in a mobile machine adapted for the efficient and rapid destruction of worn out and discarded wooden railroad ties and corresponding articles. When a section of railroad track is rebuilt, deteriorated or damaged wooden ties are thrown to the side of the right of way and their disposal creates a problem.

Since these ties are usually impregnated with creosote for resisting decay, they cannot be burned in a fireplace or the like without objectionable odor. They cannot be burned alongside the tracks, because of the ob jectionable smoke conditions. They have been offered free to the public, but no one seems to want them.

It has been decided that the preferred mode of disposing of these unwanted ties is to cut or shred them into small bits and fragments, and machines have been proposed for the purpose. These prior machines have been characterized however by inefficient loading techniques, inadequate cutting power and generally slow performance.

The major object of the invention is to provide a cutting and punching mechanism embodying a novel anvil and associated shear pin structure.

A further object of the invention is to provide a novel feed roll arrangement and construction for an article destroying machine.

Further objects will appear as the description proceeds in connection with the appended claims and the annexed drawings.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a side elevation showing a machine according to a preferred embodiment of the invention;

FIG. 2 is a top plan view of the machine of FIG. 1;

FIG. 3 is an enlarged fragmentary view mainly in section showing detail of the article advancing and shredding mechanism;

FIG. 4 is an enlarged fragmentary view in section showing an improved structure in the shear pin area;

FIG.5 is an elevational view of an element of the feed roll assembly;

FIG. 6 is a section showing the feed roll assembly;

FIG 7 is a plan view showing the anvil;

FIG. 8 is a plan view showing the cutting and punching means; and

FIG. 9 is a mainly schematic view showing the pneumatic and hydraulic control arrangements.

PREFERRED EMBODIMENTS The machine 11 is shown in FIG. 1 as mounted on a railroad track 12 by means of front and rear wheel sets I3 and 14 respectively on trucks connected by suitable suspensions to a chassis l5.

Mounted on the chassis is a prime mover in the form of a powerful engine assembly 16, preferably a Diesel motor unit. A transverse power output shaft 17 extends at one side to be supported at its outer end by outboard bearing 18 as shown in FIG. 2. A pulley 19 on shaft 17 is connected by drive belt 21 to a pulley (not shown) on a transverse shaft 22 journalle d at opposite ends in

bearings

23 and 24 on the chassis to rotate parallel to shaft 17. Mounted on shaft 22 is a cutting and punching mechanism 25 shown in more detail in FIG. 3 and 8 and later to be described.

In the drive line-between the motor unit 16 and shaft 17 is a clutch 26 and a gear reduction unit 27. The clutch is engaged or disengaged by a lever indicated at 28 in FIGS. 2 and 9. Lever 28 may be operated manually, or by a control cylinder 29 as will be explained in connection with FIG. 9.

Another pulley on shaft 17 is connected by a drive belt 31 to a pulley on a transverse shaft 32 suitably rotatably supported on the chassis and connected at one end to a hydraulic impeller pump 33, shown in circuit in FIG. 9, and at its other end to a fan drive pump 34 connected by conduits 35 to a hydraulic fan motor 36.

At its other side motor unit 16 is connected to drive a hydraulic main pump 37 which as will be described in more detail is connected by suitable conduits to drive one or more hydraulic motors 38 (FIG. 1) suitably supported beneath the chassis and connected by chain drive 39 to the rear wheels. As will appear, suitable controls are provided whereby the hydraulic circuit between the main pump 37 and motor or motors 38 is selectively controlled to drive the wheels 14 to move the machine along the tracks at two operational speeds, one a normal travel speed for moving the vehicle along the tracks between points at a steady relatively fast speed, about 25 miles per hour, and the other a slow or creeper speed at about 1-10 miles per hour while the machine is picking up ties from the roadside and destroying them. The hydraulic circuit, which is diagrammatically shown in FIG. 9 is controlled from suitable devices in the elevated cab structure 41 where the machine operator is seated.

Forwardly of the cab, a crane 42 is based on a tumtable 43 and comprises a longitudinally extensible telescopic arm 44 terminating in a pickup jaw section 45. Turntable 43 is laterally centered on the chassis, and the crane may swing equally to either side of the tracks.

ing mechanism enters the open end 5] of a conveyor tube 52. Tube 52 leads into the intake of a fan assembly 53 at the outlet of which is a vertically upwardly extending discharge conduit 54 terminating in a distributor nozzle 55. The upper section of conduit 54 has a rotatable jointat 56 for directing nozzle 55 to discharge the fragments over a wide angle. A hydraulic motor (not shown) selectively operates a chain drive 57 at joint 56 to select the discharge direction of nozzle 55. The rotor of fan assembly 53 is driven from the hydraulic motor 36.

The nozzle 55 pivots up and down to discharge shredded fragmented material away from or close to the tracks or to deflect material into hopper trucks or cars located behind or to either side of the machine. The

nozzle 55 is selectively operated by a hydraulic cylinder 204.

Referring now to FIGS. 2 and 3, a hydraulic motor 61 drives a shaft 62 suitably journalled on a fixed axis on the chassis and mounting a sprocket 63 over which passes the rear end of chain conveyor 49.

A pair of

hydraulic motors

64 and 65 are mounted on opposite ends of a rotatable transverse vertically floating feed roll shaft 66. By driving feed roll 68 at a controlled speed, the feed of the article being reduced is closely controlled to prevent jamming of the cutting and punching mechanism. The opposite reduced diameter ends 60 of shaft 66 are disposed in parallel opposed arcuate guide slots 67 (one shown in FIG. 3) to permit automatic raising and lowering of the feed roll 68 thereon during operation. When there is no tie being fed into the destroying mechanism the shaft ends will descend to the stockets 60 at the lower ends of the slots to support the feed roll above the level of the anvil. Flexible hydrauilc conduits connected to

motors

64 and 65 permit this floating operation. The vertical float of the feed roll adapts it automatically to articles of different vertical dimension being advanced on the con veyor. The vertical float of the feed roll may also be controlled by air cylinders (not shown) to lift the weight of the feed roll.

Feed roll 68 may be of particularly novel structure as will appear in connection with FIG. 6.

Referring to FIGS. 3 and 8, the shaft 22 has fixed thereon a cutting and punching rotor consisting oflarge diameter rings 71 and small diameter rings 72 arranged in alternate side by side relation. In the illustrated embodiment, there are two large diameter rings 71 each having a cutting tooth 73 interposed between three small diameter rings 72 each havg a cutting tooth 74. Each ring is a separate element fixed to rotate with shaft 22, as by key 75.

Adjacent the cutting and punching rotor is mounted an anvil assembly 76 comprising (FIG. 3 and 7)

side plates

77 and 78 provided with aligned

apertures containing bushings

79 and 81 whereby the anvil assembly is pivotally mounted on opposed fixed stub shafts 82, only one of which is indicated in FIG. 7. The side plates are rigidly connected by a transverse structure 83 (FIG. 3) to form an anvil holder that is prevented from rocking downwardly about the pivots 82 by the shear pin structure indicated at 84 in FIG. 3 and shown in detail in FIG. 4.

Referring to FIG. 4, anvil side plate 77 is apertured at 85 for receiving a metal sleeve 86 having an enlarged flange 87 secured to plate 77 as by a series of bolts 88. Sleeve 86 has a central bore in which is pressed a hardened steel or like metal bushing 89. Similarly fixed chassis wall 91 adjacent the anvil is apertured at 92 to receive a sleeve 93 having an enlarged flange 94 secured to wall 91 as by a series of bolts 95. Sleeve 39 has a central bore within which is pressed a hardened steel or like metal bushing 96.

Preferably bushings 89 and 96 are exactly alike, so as to be interchangeable, and in any event they have

internal bores

97 and 98 respectively of the same size in axial alignment to receive a cylindrical shear pin 99 extending between them. At the other side another shear pin 99 extends between plate 78 of the anvil support and the fixed chassis wall 101.

Pins 99 are preferably of bronze or some suitable metal that will shear when subjected to a predetermined load.

Referring to FIG. 7, the upper end of the anvil structure mounts relatively fixed long and

short breaker elements

102 and 103 respectively. there being three long elements 102 for cooperating with smaller toothed rings 72 and two short elements 103 disposed between the long elements to cooperate with the larger toothed rings 71. As shown in FIG. 3 the shear pins are located below the horizonal level of pivots 82, and connect the anvil holder to the frame beneath the normally fixed breaker elements on the anvil holder.

In operation, as the rotor turns in the direction of the arrow in FIG. 3, the teeth on the two larger rings 71 move on the circle indicated at L in FIG. 3 to pass through the spaces between long anvil elements into association with cooperating short anvil points 104, and the teeth on the three smaller rings 72 move on the circle indicated at S in FIG. 3 to pass in association with the long anvil elements points 105.

This association of toothed large and small rotor rings and long and short anvil elements is preferably essentially the same as disclosed in US. Letters Pat. No. 2,869,793 to Montgomery issued Jan. 20, I959 to which reference is made for further detail.

The present structure however is an improvement in that, should a large piece of iron or the like become trapped between the rotor and anvil teeth, the shear pins will shear before there is any damage to either the rotor teeth or the fixed breaker elements of the anvil. When the pins 99 shear, the entire anvil assembly 76 will swing downwardly by its weight clockwise about the fixed pivots at 82, until the side plate edges 106 abut the vertical buffer stop 107 in FIG. 3. As the anvil drops the trapped chunk of iron causing the problem will usually drop free onto the ground below the vehicle.

The disclosed shear pin mounting structure has particular merit in that it provides for speedy efficient removal and replacement of damaged shear pins. Very often the shear pins 99 become progressively bent or have one end displaced in a stepped region relative to the other, which makes it impossible to replace a pin that is so weakened if the pins merely extend through two aligned bores in metal frame members. In' the structure of the invention, should for example shear pin 99 become bent or misaligned at the inner end passing through plate 77, the operator need only remove sleeve 93 and its bushing 96 endwise from the outer end of the pin and then drive pin 99 in the other direction out of bushing 89. If necessary a new bushing may be provided in sleeve 86 which is then ready to receive a fresh pin 99.

The foregoing reduces the down time of the machine as compared to that required to extract and replace damaged or broken shear pins disposed between the rotor rings and shaft as disclosed in said Montgomery patent. Besides being more accessible, providing the shear pins at the anvil eliminates the need to angularly relocate the teeth on the large and small rings which is necessary during reassembly when the shear pins are located as in the patent.

Referring to FIGS. 5 and 6, the feed roller shaft 66 has an enlarged cylindrical portion 111 at its central portion, and a plurality of identical toothed discs 112 are non-rotatably mounted on portion 111. Each disc 112 may have the configuration shown in FIG. 5 wherein its periphery is a series of sharp pointed teeth 113. Each disc 112 has a cylindrical bore 114 to fit with a longitudinal fixed key 116 on the shaft. The discs 112 are equidistantly spaced along the shaft by similar spacer collars 117 disposed between adjacent discs, and at opposite ends annular retainer rings 118 and 119 engage the end discs and are secured on the shaft as by

screws

121 and 122 to prevent axial displacement of the toothed discs. Should any disc 112 be damaged it can be readily repaired by removing a retainer ring for access without otherwise disturbing the assembly.

Referring to the control system shown in FIG. 9, the main hydraulic drive pump 37 is a reversible pump connected by

conduits

130 and 131 to a main propulsion motor and gearbox assembly 132. The assembly 132 supplies power for the hydraulic motors 38 (FIG. 1). The

conduits

130 and 131 connecting the main hydraulic drive pump 37 and propulsion motor and gearbox assembly 132 are further connected by

conduits

133 and 134 through a valve 135. The valve 135 is normally closed to block off the flow of hydrauilc fluid through the

conduits

133 and 134 but in the event of an emergency and the machine has to be towed the valve 135 is opened to allow passage of fluid through

conduits

133 and 134 by-passing the main hydraulic motor or motors 38. Motors 38 have a common return conduit 137 back to sump or reservoir 138 to which the inlet conduit 139 of pump 37 is also connected.

Impeller pump 33 has its inlet conduit 141 connected to sump 138. The outlet conduit 142 from pump 33 is connected through an adjustable restriction 143 to a valve assembly 144 for controlling drive of chain conveyor 49. Similarly the outlet conduit 142 from pump 33 is connected through an adjustable restriction 143 to a valve assembly 145 for controlling drive of feed roll 68.

Valves

144 and 145 have a common return conduit 146 back to the sump.

The hydraulic circuit includes unidirectional pressure controlled safety bypasses or pressure relief valves (not shown) built into the main propulsion motor or motors 38.

Hydraulic main pump 37 is preferably of the variable displacement type wherein a rotatable angularly adjustable swash plate diagrammatically indicated at 151 in FIG. 9 is normally disposed in a neutral position where it does not reciprocate the oil pressure developing pistons (not shown) so that there would be no hydraulic pressure in the circuit.

As shown in FIG. 9 a control cylinder 152 has a piston 153 connected at 154 to control the angularity of swash plate 151. Return springs in cylinder 152 tend to center piston 153 to dispse swash plate 151 in the neutral position when no air pressure is supplied to the cylinder.

Air conduits

155 and 156 enter the cylinder 152 at opposite sides of piston 153. I

The operators cab 41 contains two control pedal actuated

valves

157 and 158. An air supply source 159 is connected by conduit 161 containing a pressure regulator 162 which reduces the air supply pressure and a unidirectional check valve 163 to

inlet conduits

164 and 165 for the respective pedal control valves.

Valve 157, which controls drive of the vehicle in a forward direction, is interposed in conduit 164 which is connected through an adjustable restriction valve 166 to regulate speed of air through inlet conduit 155 to control cylinder 152. Similarly valve 158, which controls drive of the vehicle in reverse direction. is interposed in conduit 165 which is connected through an adjustable restriction valve 167 to regulate speed of air through inlet conduit 156 to control cylinder 152. Valve 157 is normally held closed by spring 168 and valve 158 is normally held closed by spring 169, as shown in FIG. 9.

Thus when pedal valve 157 is opened by the operator stepping on the pedal, piston 153 is displaced to the left to change the angularity of swash plate 151 and produce hydraulic pressure in conduit for energizing motors 38 to drive the vehicle forward. An increase in angularity of the swash plates produces a greater volume of oil pumped into line 130 toward motors 38 and hence a greater speed for the vehicle.

When pedal valve 157 is opened by the operator stepping on the pedal, piston 153 is displaced to the left to change the angularity of swash plate 151 and produce hydraulic pressure in conduit 130 for energizing motors 38 to drive the vehicle forward. An increase in angularity of the swash plates produces a greater volume of oil pumped into line 130 toward motors 38 and hence a greater speed for the vehicle.

When pedal valve 158 is opened by the operator stepping on the pedal, piston 153 is displaced in the opposite direction to change the angularity of the swash plate in the opposite direction and thereby produce hydraulic pressure in conduit 131 to drive the motors 38 for reverse drive of the vehicle. 7

The

adjustable valves

166 and 167 control the air pressure supplied to cylinder 152 and hence control the speed of the movement of piston 153 against the return springs and this controls the speed of changing the angularity of the swash plate and therefore provides a gradual speed up or down of motors 38 when a pedal valve is opened to keep from jerking the machine in starting and stopping. When a

pedal valve

157 or 158 is released by the operator it is spring closed and no drive torque is transmitted to the vehicle wheels.

Valve 144 in the hydraulic circuit is normally biased to the shut off position of FIG. 9 by spring 176, and may be displaced in either direction by handle 177 to reversely drive motor 61 which rotates shaft 62 of the conveyor sprocket 63. Normally this drive is in the direction to advance a tie into the cutting mechanism but a reverse drive is provided for unblocking or like conditlons.

Valve in the hydraulic circuit is normally biased to the shut off position of FIG. 9 by spring 179, and may be displaced in either direction by handle 181 to reversely drive

motors

64, 65 which rotate shaft 66 of the feed roll 68. Normally this drive is in the direction to feed a tie toward the cutting mechanism, but reverse is provided to take care of jammed conditions.

Referring now to the lower right corner of FIG. 9, there is diagramatically shown the clutch 26 and actuating lever 28 above described and shown in FIG. 2.

Clutch control cylinder 29 contains a piston 183 hav ing a rod 184 pivoted to lever 28.

Air conduits

185 and 186 are connected into the cylinder at opposite sides of piston 183. An air flow regulator 187 is provided in conduit 186.

A valve assembly 188 is connected to a conduit 189 leading from air pressure source 159 and to a conduit 191 leading to an exhaust.

Opposed springs

192 and 193 normally center valve 188 in the shut off position shown in FIG. 9. Handle may be'actuated to shift valve 188 either to the position where valve section 194 connected cylinder 29 to the air supply and exhaust to displace piston 183 to rock lever 28 clockwise in clutch disengaging direction, or where valve section 195 connects cylinder 29 to the air supply and exhaust to oppositely displace piston 183 to rock lever 28 counterclockwise to engage the clutch 26 to transmit drive torque to the fragmentation mechanism at 25.

Conduits

185 and 186 are connected by

conduits

197 and 198 to

actuators

199 and 201 respectively at opposite ends of a shiftable vehicle drive speed setting valve unit 202 disposed in a bypass conduit 203 parallel to air supply conduit 161.

When clutch control valve 188 is in the shut off position of FIG. 9, speed set valve 202 is positioned as shown in FIG. 9 to be in the neutral position and allow no air to be transmitted to the clutch control cylinder 29 allowing the clutch handle 28 to be manually operated without undue force. At the same time when clutch control valve 188 is in the shutoff position of FIG. 9, speed set valve 202 will allow full supply air pressure to be transmitted through the

pedal valves

157 and 158 to the cylinder 152 to move the swash plate 151 to the full volume position, either to the forward or reverse condition, to provide full travel speed of the machine.

When clutch control valve 188 has been shifted to introduce section 195 and rock lever 28 counterclockwise to cause clutch 26 to engage, air supply conduit 189 is connected to conduit 198 and thereby to actuator 201 to shift valve 202 to block the bypass conduit 203, so that only air pressure reduced by regulator 162 is transmitted to the

pedal valves

157 and 158. Thus, the vehicle may be driven only in the creeper speed range when the cutting and punching mechanism is being driven.

When clutch control valve 188 has been shifted to introduce section 194, this causes the air pressure to rock lever 28 clockwise to disengage the clutch and at the same time air pressure is transmitted to actuator 199 to shift valve 202 to open bypass 203 and permit full supply pressure to be transmitted to the pedal valves. The vehicle now may be driven in the higher speed range.

It will be noted that valve 188 must be held in either position at opposite sides of neutral by the operator through handle 190, and when the operator releases handle 190 valve 202 will automatically move to the open position, the clutch will be disengaged and the bypass 203 will be open.

It is an important part of the invention that whenever the clutch 26 in the drive to the cutting and punching mechanism is engaged, the bypass 203 is automatically blocked so that the vehicle can be driven only in the low (l-10 MPH) range. Thus more power from motor unit 16 is available for the cutting and punching mechanism when it is running, and less power is used for driving the vehicle.

When the clutch 26 is disengaged, valve 202 automatically opens bypass 203 and more power is available to the vehicle drive for travel along the track at the higher speed range. At this time the cutting and punching mechanism is not and cannot be operated.

During operation the machine is driven at the higher speed to the region where the ties to be destroyed are located. During this period, the cutting and punching mechanism is automatically maintained disabled, and the implement drives are in neutral.

Upon reaching the desired region, the operator moves handle 190 to engage clutch 26 to start driving mechanism 25, and this automatically shifts the vehicle drive to the creeper speed range. At this time pumps 33 and 34 start supplying hydraulic fluid under pressure to the implement and fan circuits respectively. The crane is operated to pick up ties and deposit them in cradle 47, and

valves

144 and 145 are operated to feed the ties into the mechanism 25 where they are cut into fragments. The fragments leaving mechanism 25 are drawn through conduit 52 and discharged through the fan outlet.

I claim:

1. Apparatus for reducing wood and like articles to small fragments comprising a support, a toothed rotor and a cooperating stationary anvil structure on said support, means for driving said rotor about a horizontal axis, said anvil structure comprising a breaker element holder having fixed teeth thereon adjacent and cooperating with the rotor, means pivotally mounting said anvil holder on said support comprising fixed horizontal axis pivotmeans below and to one side of the axis of rotation of said rotor and shear means connecting said anvil holder to said support below the pivot axis of the anvil holder and beneath said breaker elements so arranged that when said shear means is sheared the anvil holder swings downwardly of its own weight about said pivot means and away from said rotor, said shear means comprising fixed end walls on said anvil holder adjacent respective fixed walls on said support and coaxial shear pins extending between each of said end walls and the adjacent support wall.

2. In the apparatus defined in claim 1, there being aligned apertures in each adjacent pair of said walls, sleeves removably secured to said walls and lining said apertures, hard metal bushings lining each of said sleeves and said shear pins having opposite ends disposed within the respectivebushings.

Claims

1. Apparatus for reducing wood and like articles to small fragments comprising a support, a toothed rotor and a cooperating stationary anvil structure on said support, means for driving said rotor about a horizontal axis, said anvil structure comprising a breaker element holder having fixed teeth thereon adjacent and cooperating with the rotor, means pivotally mounting said anvil holder on said support comprising fixed horizontal axis pivot means below and to one side of the axis of rotation of said rotor and shear means connecting said anvil holder to said support below the pivot axis of the anvil holder and beneath said breaker elements so arranged that when said shear means is sheared the anvil holder swings downwardly of its own weight about said pivot means and away from said rotor, said shear means comprising fixed end walls on said anvil holder adjacent respective fixed walls on said support and coaxial shear pins extending between each of said end walls and the adjacent support wall.

2. In the apparatus defined in claim 1, there being aligned apertures in each adjacent pair of said walls, sleeves removably secured to said walls and lining said apertures, hard metal bushings lining each of said sleeves and said shear pins having opposite ends disposed within the respective bushings.