US2955388A - Snagging grinder - Google Patents

Snagging grinder Download PDF

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Publication number
US2955388A
US2955388A US627020A US62702056A US2955388A US 2955388 A US2955388 A US 2955388A US 627020 A US627020 A US 627020A US 62702056 A US62702056 A US 62702056A US 2955388 A US2955388 A US 2955388A
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valve
pipe
carriage
frame
movement
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US627020A
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Helge V Lavner
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Saint Gobain Abrasives Inc
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Norton Co
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24BMACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
    • B24B7/00Machines or devices designed for grinding plane surfaces on work, including polishing plane glass surfaces; Accessories therefor
    • B24B7/07Machines or devices designed for grinding plane surfaces on work, including polishing plane glass surfaces; Accessories therefor involving a stationary work-table
    • B24B7/075Machines or devices designed for grinding plane surfaces on work, including polishing plane glass surfaces; Accessories therefor involving a stationary work-table using a reciprocating grinding head mounted on a movable carriage

Definitions

  • the invention relates to grinding machines and'more particularly to a heavy-duty floor-type snagging Vgrinder for surfacing steel billets and the like.
  • One object of the invention is to make-a simple and thoroughly practical heavyduty yHoor-type snagging grinder.
  • Another object of the invention is to provide a snagging grinder in which a longitudinally moveable carriage serves as a support for a transversely moveable carriage for imparting a transverse movement to the grinding wheel in a horizontal plane;
  • a suitable driving mechanism is provided for traversing the carriage longitudinally comprising a iluid motor 25 (Fig. 1 and 3) which is connected by a coupling 26 with a speed reducer unit 27.
  • the speed reducer 27 may'be any of the well known commercial speed reducer units.
  • the driven shaft of the speed reducer unit 27 is connected by the coupling 28 with a shaft 29.
  • the shaft 29 is provided with a fixedly mounted gear 30 (Fig. 4) which meshes with an intermediate gear 31.
  • a similar driving mechanism is provided for driving the axle 18 comprising a fluid motor 35 which is connected by a coupling 36 with a speed reducer unit 37.
  • the driven shaft of the speed reducer unit 37 is connected to a rotatable shaft 39 having a gear 40 xedly mounted thereon.
  • the gear 40 meshes with an intermediate gear -41 (Fig. 4) which, in turn, meshes with a gear 42 iixedly mounted on the axle 42.
  • the iluid motors 25 and 35 are controlled by a single control valve mechanism to be hereinafter described to control the determined high or low grinding pressure between the grinding wheel and the work being ground while being traversed either longitudinally or transversely.
  • Fig. l is a side elevation of the snagging grinder
  • Fig. 2. is a front elevation of the grinder
  • Fig. 3 is a plan View of the grinder;
  • Fig. 4 is a rear elevation, partly in section, taken approximately on the line 4 4 of Fig. l;
  • Fig. 5 is a fragmentary horizontal sectional view, on an enlarged scale, taken approximately onthe line 5-5 of Fig. 1; K
  • Fig. 6 is a fragmentary vertical sectional view, on an enlarged scale, taken approximately on the lines 6 6 of Fig. 4, showing the roller support for the transversely movable slide; and Y Fig. 7 is a combined hydraulic and electric diagram of the actuating mechanisms and the controls therefor.
  • a heavy-duty floor-type snagging grinder has been illustrated in the drawings comprising a longitudinally movaf ble carriage 10 which is arranged to travel longitudinally on a pair of spaced parallel rails 11 and 12.
  • the carriage 10 is provided with a traversely extending axle 13 which is rotatably journalled in spaced bearings 14 and 15 (Fig. 3).
  • the axle 13 is provided with a wheel 16 which rides on the rail 11,.
  • the axle 13 is also provided with a flanged wheel 17 which is arrangedto ride upon the rail 12 so as to guide the longitudinally movable carriage 10 during its longitudinal movement.
  • the carriage 10 is also provided with a rotatable axle 18 rotatably journalled in spaced bearings 19 and ⁇ 2l) which are supported on the longitudinally movable carriage 10.
  • the axle 18 is provided with a wheel 21 which Arides upon the rail 11 and is also provided with a anged wheel 22 which rides upon the rail 12. It will be readily apparent 'from the foregoing disclosureV that the flanged l longitudinal movement of the carriage 10.
  • a uid pressure system for supplying fluid under pressure to the various mechanisms of the machine.
  • This system comprises a uid pump 45 which is driven by an electric motor l46 (Fig. 7).
  • the pump 45 draws uid through a pipe 47 from a reservoir 48 and forces fluid under pressure through a pressure pipe 49 to the iiuid motors 25 and 35.
  • a balanced pressure relief valve 50 is connected in the pipe line 49 to facilitate passing excess uid under pressure directly through a pipe 51 into the reservoir 48 to facilitate maintaining a substantially constant fluid pressure throughout the system.
  • a piston type control valve 55 is provided for controlling the admission to and exhaust of fluid from the uid motors 25 and 35.
  • the valve 55 comprises a valve stem 56 having a plurality of spaced valve pistons formed integrally therewith to form a plurality of spaced val've chambers 57, 58, 59, and 60.
  • the Valve is provided with a central passage 61 which interconnects the valve chamber 57 with the valve chamber 59.
  • a compression spr-ing serves normally to hold the valve stem 56 in the position illustrated in Fig. 7.
  • a manually operable control lever 62 is provided for actuating the control Valve 55.
  • the lever 62 is pivotally supported by a stud 63 carried by the upper end of a link 64.
  • the lower end of the link 64 is supported by a stud 65 carried by the control valve 55.
  • a stud 66 connects the valve stem 56 with the control lever 62.
  • -V pipe 49 is arranged to convey uid under pressure from lthe pump 45 to the valve chamber 59 of the control valve 55.
  • a pipe 67 is connected between the control valve 55 and a throttle valve 68 which serves to control the rate of exhaust of iiuid from the control valve 55 into the reservoir 48.
  • a pipe 69 is connected between the control valve 55 and one side of each of the iluid motors 25 and v35.
  • a pipe 70 is connected between the control valve and the other side of each of the iluid motors 25 and 35.
  • VThe control valve 55 is arranged to simultaneously Vcontrol the admission to and exhaust of iiuid from the uid motors 25 and 35.
  • a balance pressurerelief valve 71 is connectedbetween the pipe 70 and the pipe 69.
  • a balance pressure relief valve 72 is similarly connected between the pipe 69 and the-pipe 70. T'he balance presl. sure relief valves 71 and 72 are provided so that when r, J fluid under pressure to the motors 25 and 35 is reversed fluid may readily pass between the pipes 69 and 70 respectively thereby preventing an excessive build up of pressure in the pipe lines and motors at the time of rever-4 sal.
  • control lever 62 When it is desired to impart a longitudinally traversing movement of the carriage the control lever 62 may jbe moved in a clockwise or counter-clockwise direction (Fig. 7). When the control lever 62 is moved ina clockwise direction (Fig. 7) the valve stem 65 is moved downwardly against the compression spring. In this position of ⁇ the parts lluid under pressure from the pipe 49 entering the valve chamber 59 passes through the pipe 70 A'to sta-rt both the uid motors to impart a longitudinal traversing movement to the carriage 1'0.
  • this movement uid may simultaneously exhaust from the other side of the fluid motors 25 and 35 through ⁇ the ⁇ pipe 69 into the valve chamber 58 and pass through apassage 73,through the pipe 67, through the throttle valve 68 and through the exhaust pipe '51 into the reservoir 48.
  • the rate of movement of vthe carriage 10 may be readily controlled by manipulation of the throttle valve 68.
  • control lever 62 When it is desired to stop the carriage 10 the control lever 62 may be released by the operation at which time the released compression of the spring causes an upward movement of the valve stem 56 to position the valve 55 in a central or neutral position, as shown in Fig. 7.
  • Vthe control valve 55 When Vthe control valve 55 is in a central or neutral position, uid under pressure from the pressure pipe 49 entering the valve chamber 59 may pass through Vthe central passage 60 into the valve chamber '57 and ⁇ through the pipe 67 through the throttle valve 68 and exhausts through the pipe 51 into the reservoir 48.
  • control lever 62 When it is desired to traverse the carriage 10 longitudinally in the opposite direction, the control lever 62 may be moved in a counter-clockwise direction so as to cause an upward movement of the valve stem 56 so 'that uid under pressure entering the valve chamber 59 may pass through the pipe 69 to the other side of both of the uid motors 25 and 35 thereby causing the motors to rotate in opposite directions and to traverse the carriage 10 in an opposite direction. It will be apparent 'from the foregoing disclosure that by manipulation of the control lever 62 the carriage 10 may be traversed in either direction.
  • the movement of the carriage in either direction may be stopped at any time by releasing the control lever 62 to allow the released compression of the spring to return the valve 55 to a central position or the lcarriage may be reversed in its direction of travel by manually shifting the lever 62 in the opposite direction.
  • the longitudinally movable carriage 10 serves as a support for a transversely movable carriage 75 (Figs. 2 and 4).
  • the longitudinally movable carriage 10 is provided with a pair of spaced parallel rails 76 and 77.
  • the traversely movable carriage 75 is provided with a plurality of flanged wheels or rollers 78 and 79 which ride upon the rails 76 and 77 respectively.
  • the carriage 10 is also provided with a pair of spaced parallel depending rails 80 and 81 (Figs. 2 and 4) which serve to hold the traversely movable carriage 75 against a lifting movement.
  • the traversely movable carriage is provided with a plurality of spaced wheels or rollers 82 (Fig. 6) which ride upon the lower surface of the rail 80.
  • Either the set of rollers 78 or the set of rollers 82 may be provided with adjustments so that lost motion may be taken up between the rails 76 and 80.
  • a similar set of rollers 83 are carried by the carriage 75 and rolled upon the lower surface of the depending rail 81.
  • a hydraulically operated mechanism for imparting a traverse movement to the carriage 75 comprising a pair of spaced parallel cylinders 90 and 91 (Figs. 3 and 7) which are ixedly mounted on the carriage 75.
  • the cylinders 90 and 91 contain the pistons 92 and 93 respectively which are connected to one end of a Ypair of piston rods 94 and 9S respectively.A
  • the other'euds -of the piston rods 94 and 95 are connected by brackets 96 and 97 respectively with a rearwardly extending portion of the longitudinally movable carriage 10.
  • the cylinders 90 and 91 are arranged on opposite sides of the transversely movable carriage 75 to facilitate the transverse traversing moving of the carriage 75.
  • the control valve 100 is vprovided for simultaneously controlling the admission to and exhaust of fluid from the cylinders 90 and "91 respectively.
  • the control valve 100 is fa .piston ytype valve comprising a valve stem 101 having'a plurality-of spaced valve pistons -formed integrally therewith to form a plurality of spaced valve chambers 102, 103 and 104.
  • VA compression spring is provided normally “to "holdthe valve stem 101 in a central or neutral positionv as ⁇ illustrated in Fig. 7.
  • a manually operable control lever 105 is pivotally supported by a stud 106 carried by an upper end of the link 107.
  • the lower end of the link 107 is supported by a 'stud 108 carried by the valve '100.
  • a stud 109 connects the valve stem 101 with the control lever 105.
  • a uid pressure pipe 110 is provided for conveying uid under pressure to the valve chambers 102 and 104.
  • a pipe '112 is "connected to a ball check valve 113 which is connected by a'pipe 114 with the upper-ends of the cylinders 90 and 91 respectively. Fluid passing through the pipe 114 simultaneously enters a cylinder chamber 115 and a cylinder chamber 116 formed in the upper ends of the cylinders 90 and 91, respectively.
  • a throttle valve 121 is connected between the -p'ipes 112 and 114.
  • a ball check valve 122 l is connected between the pipes 119 and the valve 100.
  • the control 'lever 10S When it is desired to traverse the transversely movable carriage 75, the control 'lever 10S may be rocked in either -a'clockwise or counter-clockwise direction (Fig. 7) depending upon the direction of movement of carriage 75 desired. fWhen it is desired to move the carriage 75 rearwardly, that is, -in an upward direction (Fig. 3) the control lever 105 is rocked in a clockwise direction to move the valve stem 101 -downwardly so that tiuid under pressure within the valve chamber '102 may pass through the pipe 112, through the ball check valve 113 and the throttle valve 121 ⁇ into the pipe 114 to simultaneously convey fluid under pressure into the cylinder chamber and 116 respectively.
  • yFluid under pressure entering the cylinder chambers 115 and 116 causes an upward movement of the cylinders so as to cause a rearward movement of the carriage 75.
  • this movement uid within the cylinder chambers 117 and 118 simultaneously exhausts through the pipe 119, through the throttle. valve into .the valve chamber 103 into an exhaust pipe ⁇ 13:1.
  • vvthe rate of exhaust 'of uid from the cylinder chambers 117 Vand 118 may be readily controlled to control the Vspeed of the rearward movement of the carriage 75.
  • the control lever 105 is rocked in a counter-clockwise direction (Fig.
  • An independent fluid pressure system is provided for supplying fluid under pressure to the mechanism above described and also to other mechanisms to be hereinafter described.
  • This system compirses a tluid pump 125 (Fig. 7) which is driven by an electric motor 126.
  • 'Ihe pump 125 draws iluid through a pipe 127 from a reservoir 128 and forces fluid under pressure through a pipe 129, through a balanced pressure relief valve 130 into the pressure pipe 110.
  • the exhaust pipe 131 is connected to the relief valve 130 to return excess iluid under pressure directly to the reservoir 128.
  • the relief valve 130 is preferably adjusted to open at 300 lbs. per square inch so as to maintain an operating pressure in the lluid system of 300 lbs. persquare inch.
  • transversely movable slide or carriage 75 serves as a support for a pivotally mounted frame 140 which is provided with horizontally extending portions 141 and 142.
  • the portion 141 is provided with a trunnion 143 which is supported in a bearing 144 mounted in an upwardly extending bracket 145 on the carriage 75.
  • the horizontally extending portion 142 of the frame 140 is provided with a trunnion 146 which is journalled in a bearing 147 supported by an upwardly extending bracket 148 lixedly mounted on'the carriage 75.
  • the frame 140 is provided with an opening 149 to facilitate passing a driving mechanism for a grinding Wheel to be hereinafter described.
  • the frame 140 is provided with a horizontally extending arm 150 (Figs. l and 3).
  • a hydraulically operated mechanism is provided to facilitate rocking the frame 140 about the axis of the trunnion 143-146 as a pivot.
  • This mechanism comprises a cylinder 155 which is pivotally supported by a bearing 154 mounted on the transversely movable carriage 75 (Fig. 1).
  • the cylinder 155 contains a slidably mounted piston 156 which is connected to the lower end of a piston rod 157.
  • the upper end of the piston rod 157 is connected by the stud 158 carried by a bracket 159 formed integral with the arm 150 of the frame 140.
  • the effective 4area of the upper surface of the piston is less than the effective area of the lower surface thereof due to the piston rod 157.
  • Fluid under pressure from the pipe 110 is con tinuously passed through the check valve 160 and -a throttle valve 166, through a pipe 161 into a cylinder chamber 162 to exert a downward thrust on the piston 156 tending to ⁇ rock the frame 140 in a counter-clockwise direction (Fig. 1).
  • the throttle valve 166 controls the rate of exhaust of iluid from -the cylinder chamber 162 against the pressure in the pipe 110 when lluid under pressure is passed into the cylinder chamber 164. Due to the greater area of the under side of the piston 156, a controlled swinging movement is imparted to the frame 140 to produce the -desired grinding pressure.
  • a control valve 170 is provided for controlling the admission to and exhaust of uid from the cylinder chamber 164.
  • the valve 170 is a piston type valve having a valve stem 171 formed with a plurality of spaced pisf tons to form a plurality of spaced valve chambers 172, 173 and 174.
  • a manually operable control lever 175 is pivotally supported by a stud 176 to the upper end of a llink 177. The lowerend of the link 177 is connected by a stud 178 with the valve 170.
  • a stud 179 connects the control lever 175 with the valve stem 171.
  • a spring pressed detent 180 is arranged to engage one of a plurality of spaced grooves 181, 182, -and 183 to maintain the Valve stem 171 in -a predetermined position.
  • a pipe 185 is connected between the valve 170 and a pressure reducing valve 186 which contains a vertically arranged sldable valve member 187.
  • the valve 186 is connected by a pipe 188 with a ball check valve 189 and a throttle valve 190 with the pipe 163 leading to the cylinder chamber 164.
  • a ball check valve191 (Fig. 7) is connected between the pipe 188 and the pipe 185.
  • the slidably mounted valve member 187 of the pressure reducing valve 186 is provided with ya central passage 192 Vwhich is arranged so that when the sldable valve member 187 moves upwardly iluid may pass through the central passage 192 and through a vent pipe 193 to a rotary control valve 194.V
  • the control valve 194 is operatively connected in a manner to be hereinafter described to pass lluid from the venting pipe 193 either to an adjustable relief valve 196 or to an adjustable relief valve 197 which are adjusted to operate at different pressures so as to facilitate controlling the pressure conveyed to the cylinder chamber 164.
  • the valve 194 contains a valve rotor 198 which is actuated by a manually ⁇ operable control lever 199.
  • a valve rotor 198 In the position of the valve 194 (Fig. 7) fluid passing through the venting pipe 193 enters a valve chamber 200 in the valve 194 and passes through a pipe 201 to the relief valve 196 which allows excess fluid under pressure to pass through the exhaust pipe 131 into the reservoir 128 thereby reducing the lluid pressure passed tol the cylinder chamber 194.
  • control lever 199 may be swung into position 199e to turn the valve rotor 198 so that fluid under A pressure entering the valve chamber 200 may pass through a passage 202 in the valve rotor'198 into a valve chamber 203 and through a pipe 204 to the relief valve 197 so that excess iluid may be passed through the re' lief valve 197 into the exhaust pipe 131 which exhausts into the reservoir 128.
  • the pressure reducing valve 186 is provided with a pilot control piston 205.
  • the pilot control piston 205 is spring pressed ⁇ and adjustable so that iluid passing through the central passage 192 into the pipe 193 may move the piston 205 toward the right (Fig. 7) to allow a variabile amount of lluid to pass through a drain pipe 206 into the exhaust pipe 131.
  • the pilot control piston 205 is preferably adjusted to open at pressure in excess of the setting of relief valve to allow excess fluid to exhaust through pipe 131 into the reservoir 128.
  • valve 170 lluid from the pipe 110 passes through the valve chamber 174, through the pipe 185, through the pressure reducing valve 186, through the pipe 188, through the ball check Valve 189 and the throttle valve 190, through the pipe 163 into the valve chamber 164 to cause an upward movement of the piston 156 at a predetermined controlled rate.
  • excess iluid under pressure within the pipe 188 causes an upward movement of the valve member 187 (Fig. 7) which serves to allow fluid under pressure to pass through the pipe 193 to -the rot-ary control valve 194 and through either the relief valve 196 or the relief valve 197 into the exhaust pipe 131.
  • the relief Valves 196 and 197 are adjustable to faci-litate varying the grinding pressure of the grinding wheel 228 and the work piece 285.
  • the valve 196 may be set to open at 75 lbs. per square inch and the valve 197 may be set to open at 200 lbs. per square inch to facilitate obtaining either a low or a high grinding pressure.
  • the pilot control piston 205 may be moved toward the right to allow a portion of the excess fluid to pass through the venting pipe 206 into the exhaust pipe 131. It will be readily apparent from the foregoing disclosure that by applying a predetermined pressure toward the upper face of the piston 156 and applying a controlled pressure to the lower surface of the piston 156 ⁇ having a greater piston area will cause a controlled upward movement of the piston 156 (Fig. 7) thereby imparting acontrolled feeding movement to the frame 140 in aclockwise direction (Fig. 1).
  • the control lever 175 When it ⁇ is desiredto rock the frame 140 in a countercloekwise direction (Fig. l), the control lever 175 may be moved in a clockwise direction until the detent 180 engages lthe groove 181. In this position of the valve fluid under pressure from the pipe 110 is cut oi from the valve 170 and 'iiuid from lthe cylinder chamber 164 may exhaust through the pipe 163 through the throttle valve 190, through the ball check valve 191, through the pipe 185, 'through the valve chamber 173 into the exhaust pipe 131 which exhausts into the reservoir 128.
  • the pressure reducing valve 186 and the relief valves 196 and 197 a precise control of fluid under pressure entering the cylinder chamber 164 may be obtained.
  • the grinding unit 220 is arranged to rock about the axis of the cylindrical member 221.
  • the longirtudinally movable carriage 10, the transversely movable carriage 75, the pivotally mounted frame 140 together with lassociated parts are massive in structure so that a large diameter grinding wheel, such as, ya 36 diameter grinding wheel 228 driven by a 75 H.P. driving motor may be employed to facilitate rapid stock removal from the billet or work piece being ground.
  • a driving mechanism is provided for the grinding wheel 228 comprising ⁇ an open-ended box-like frame 230 which is xedly keyed onto the left hand end of the cylindrical member 221 (Fig. 5).
  • the opposite side ofthe boxlike frame 230 is provided with a ixedly mounted trunnion 231 "which is supported in a bearing 232 carried by a downwardly projecting bracket 233 which is fastened Ito the left hand end of the arm 150 of the frame 148.
  • An adjusting screw 234 is provided to facilitate taking up the end thrust of the grinder unit 220 in ⁇ a direction toward the left (Fig. 5).
  • the box-like frame 230 supports a wheel driving motor 235 haiving a cog pulley 236 which is connected by a cog driving belt 237 with a cog pulley 238 which is keyed onto the upper end of a rotatable shaft 239.
  • the Ishaft 239 is iournalled in a pair of spaced bearings 240 and 241 which ⁇ are supported in a bracket 242 tixedly mounted on the boxalike frame 230.
  • the yaxis of the shaft 239 is preferably in axial alignment with the trunnions 143 and 146 of the frame 140 in order to facilitate the swinging movement of the frame 140 about the axis of the trunnions.
  • a cog pulley 243 is keyed onto the lower end of the shaft 239 (Fig. 5
  • the pulley 243 is connected by a cog driving ybelt 244 with a cog pulley 245 which is carried by the wheel sleeve 227.
  • a Wheel guide cover 246 encloses the open side of the frame 224. It will be readily apparent from the foregoing disclosure that the motor 235 will transmit power to rotate the grinding wheel 228 during a swinging or feeding movement of the frame 140.
  • a hydraulically operated mechanism comprising a pair of cylinders 250 and 251, the upper ends of which are connected by studs 252 and 253, respectively, with a bracket 254 which is ixedly mounted relative .to the .frame .140.
  • the .cylinders 25.0 and A251 contain slidably mounted pistons 255 and 256 respectively.
  • the pistons 255 and 256 are connected to the upper ⁇ ends of a vpair of piston rods 257 and 258 respectively.
  • the lower ends of the piston -rods y257 and 258 are connected by a pair of studs 259 and 260 respectively with a pair of brackets 261 and 262 which are fixcdly mounted on ⁇ the rear surface of the box like frame 230.
  • a control valve 265 is provided for controlling the admission to and exhaust of uid from the'cylinders 250 and 251 respectively to obtain the desired rocking movement of the wheel supporting frame 224.
  • the control valve 265 is a piston -type valve having ⁇ a valve stern 266 which is actuated Vby a control lever 267.
  • the control lever is pivotally supported by a stud 268 on the upper end of a link 269.
  • the lower end of the link 269 is connected by a stud 270 carried by the valve 265.
  • the valve stem 266 is provided with a plurality of spaced valve pistons vforming a plurality of spaced valve chambers 271, 272, and 273.
  • a compression spring 274 serves normally to maintain the valve 265 in a central or neutral position, as indicated in Fig. 7.
  • a pipe 275 connects the valve 265 with a lower cylinder chamber 276 in the cylinder 250 and an upper cylinder chamber 277 in the cylinder .251.
  • a pipe 278 connects the valve 265 with a lower cylinder chamber 279 in the cylinder 251 and an upper cylinder chamber 280 in the cylinder 250.
  • the valve 265 is provided with a passage 281 which receives fluid under pressure from the pressure pipe 110. With the valve 265 in a central or neutral position, fluid under pressure is conveyed by the passage 281 into the valve chambers 271 and 273.
  • the control lever 267 is rocked in a clockwise direction to cause a downward movement of the valve stem 266 so that tluid under pressure entering the valve chamber 271 passes through the pipe 275 simultaneously into the cylinder chambers 276 and 277.
  • this rocking movement of the frame 140 iluid within the cylinder chambers 279 and 280 exhausts through the pipe 278, through the valve chamber 272 into the exhaust pipe 131 which exhausts into the reservoir 128.
  • the control lever 267 is rocked in a counter-clockwise direction thereby causing an upward movement of the valve stem 266 so that iluid under pressure from the valve chamber 273 passes through the pipe 278 into the cylinder chambers 279 and 280 to impart a counter-clockwise swinging of the box-like frame 230 and the frame 140.
  • fluid may exhaust from the cylinder chambers 276 and 277, through the pipe 275 into the valve chamber 272 and pass through the exhaust pipe 231 into the reservoir 128.
  • a work piece 285, such as a billet or slab of steel to be snagged may be placed on a work supporting base 286.
  • the grinding wheel 228 may then be fed downwardly by a swinging movement of the frame 140 into operative engagement with the surface to be ground.
  • the carriage 10 may be traversed longitudinally by imparting a longitudinal traversing movement to the carriage 10.
  • the grinding wheel 228 may be moved transversely to present the wheel to a different portion of the work piece being snagged by imparting a traverse movement to the carriage 75. Due to the opposed roller support for the transversely movable carriage 75, any desired grinding pressure may be imparted to the grinding wheel 228.
  • the grinding unit 220 may be rocked about a horizontal axis so as to tilt -the grinding wheel in either direction as shown in Fig. 2.
  • the arm of the frame 140 has been illustrated in broken line position 150a when the ⁇ frame 140 is swung in a clockwise direction to swing the grinding wheel 228 ⁇ in-to its extreme lower position 228a.
  • Arm 150 has also been shown in broken line position 150b when lthe frame 140 is swung in a counter-clockwise direction to swing the grinding Wheel 228 into its extreme upper position 228b.
  • the arm 150 has also been shown in broken line position 150C when the slide 75 is moved toward the left (Fig. 1) to position the grinding wheel 228 in broken line position 228e.
  • the broken positions 228d and 228e of the grinding wheel 228 illustrate extreme positions of the grinding Wheel 228 when the grinding wheel unit 220 is swung within theV bearings 221-222 (Fig. 5).
  • An operators seat 290 (Figs. 1 and 2) is provided at a control station 291 on the transversely movable slide 75.
  • the control levers 62, 105, 175, 199 and 267 for actuating the control valves 55, 100, 170, 194 and 265, respectively', are positioned wi-thin easy reach of the operator.
  • the wheel driving motor 235 is started by closing a switch 287.
  • the pump driving motor 46 is started by closing the switch SW2.
  • the pump driving motor 1264 is started by closing Ithe switch SW1.
  • valve 170 may be actuated to swing the frame 140v in a clockwise direction (Fig. 1) to feed the grinding wheel 22S into grinding engagement with the work piece 285 at a desired and predetermined pressure.
  • the grinding pressure may be varied by manipulation of the valve 194 and by adjustment of the relief valves 196 and 197.
  • the carriage 10 may then be traversed longitudinally by actuation of the control lever 62 which in turn actuates the control valve 55 to start the iluid motors 25 and 35 in either direction.
  • the direction of movement of the carriage being determined by the direction of movement of the control lever 62.
  • the carriage 75 may be traversed transversely by lactuation of the -control lever 105 to present a new portion of the work surface to be ground during the next longitudinal traverse of the carriage 10. ⁇ If desired the surface of the work piece being snagged or ground may be ground by successive longitudinal movement of the carriage 10 combined with a transverse movement of the carriage 75 at the ends of the longitudinal stroke of the carriage 10.
  • a transverse movement of the carriage 75 controlled by the control lever 105 may be utilized to traverse the grinding wheel 228 transversely across the' work piece 285.
  • the longitudinal moveable grinding wheel carriage may be moved longitudinally to present the grindin-g wheel to an adjacent portion of the surface. This sequence may be continued until the entire surface has been ground to the desired and predetermined extent.
  • the carriage 10 may be traversed longitudinal-ly to present the grinding wheel to the other end portion of the work piece to be ground.
  • a similar portion of the face of the work piece may be ground to the desired extent by a transverse movement of the carriage 75.
  • the longitudinally movable carriage 10 may be traversed longitudinally to grind the area between -the two end portions. Between longitudinal strokes by the carriage l() ⁇ the carriage 75 may be advanced transversely so as to present the grinding wheel to
  • the wheel axis m-ay be mounted parallel to the plane of the work surface or may be tilted into either the position 228e or 228d when desired. If it is desired to change the pressure of the grinding wheel against the l0 work piece, the control valve 194 may be actuated to render -the relief valve 196 or the relief valve 197 operative.
  • a snagging grinder comprising a traversable longitudinal carriage, a iluid motor to traverse said carriage, a transversely movable slide on said carriage, a iiuid motor interposed between the carriage and the slide to move said slide transversely of the carriage, a pivotally mounted swing frame .supported on said slide, spaced axially aligned horizontally arranged trunnions on said frame, spaced bearings on said slide for said trunnions ⁇ having their common axis arranged parallel to the direction of movement of the longitudinal carriage, a fluid motor to swing said frame relative to said slide, an elongated grinding unit on said frame including a support for said unit projecting through and rotatably mounted on said frame, ythe axis of said support being rotatable about the axis of said trunnions in a vertical plane parallel to .the path of movement of said slide, a grinding wheel rotatably mounted on one end of said unit, a box-like frame iixedly mounted on
  • a snagging grinder comprising a traversable longitudinal carriage, a fluid motor to traverse said carriage, a
  • the ⁇ uid motor for swinging the grinder frame relative to the transverse slide comprises a piston and cylinder, operative connections between the frame and transverse slide, said piston having differential piston areas, means for applying pressure direct from a source to the upper end of said cylinder to exert a downward pressure on the smaller piston area, and means including a manually operable control valve operatively connected to apply a lower pressure to the greater piston area on the under side of said piston so as to impart a controlled swinging movement to :the frame and grinder unit lto obtain the desired grinding pressure.
  • means including a pressure regulating valve to pass fluid under pressure to the lower end of said cylinder, means including a pair of independent adjustable relief va-lves one of which -is ⁇ set lfor a low grinding pressurel and the other set for Ia high grinding pressure, said relief valves -being arranged to exhaust excess uid under pressure from the pressure regulating valve, and means including a manually operable valve to render either of said relief valves operative to facilitate obtaining either a controlled high or low pressure between the grinding Wheel and the work piece being ground.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Finish Polishing, Edge Sharpening, And Grinding By Specific Grinding Devices (AREA)

Description

Oct. l1, 1960 H. v. LAVNER v SNAGGING GRINDER 6 Sheets-Sheet 1 Filed Dec. 7, 1956 /lTTo/QNEY Oct. 11, 1960 H. V. LAVNER SNAGGING GRINDER Filed Dec. 7, 1956 6 Sheets-Sheet 2 Hag? l lNveNToR HELGE V LA V/VEE BY kwQhLeJ-ch.
HTTOENEX Oct.A ii, i960 H. v. LAvNr-:R 2,955,383
sNAGGING GRINDER Filed Dec. 7, 1956 6 Sheets-Sheet 5 Fig.; INVENTOR HELGE VLA VNER Oct. 11, 1960 H. v. LAVNER SNAGGING GRINDER 6 Sheets-Sheet 4 Filed Dec. 7, 1956 INVENTOR HELGE V LA VME/E @www QTTOENEY Oct. 1l, 1960 H. V, LAVNER A. 2,955,388
SNAGGING GRINDER Filed Dec. 7, 1955 6 Sheets-Sheet 5 111 III@ IIII lllllIl-I .228
Hag. 5
I l v Z lNvENToR Hg. 6 HELGE V LAVA/ER Oct. 11, 1960 H. v. LAVNER 2,955,388
SNAGGING GRINDER Filed Dec. 7, 1956 6 Sheets-Sheet 6' Ll 7 o 7/ Z55 /4 Z55 l 6 INVENTOR EL GE V LA v/vE/e Hg. 7 Mnuws TTOENEY 2,955,388 Patented Oct. l1, 1960 2,955,388 SNAGGING GRINDER t Helge V. Lavner, Worcester, Mass., Iassignor to Norton Company, Worcester, Mass., a corporation of Massachusetts Filed Dec. 7, 1956, SerfNo. 627,020
4 claims. (c1. 51-35) l The invention relates to grinding machines and'more particularly to a heavy-duty floor-type snagging Vgrinder for surfacing steel billets and the like.
`One object of the invention is to make-a simple and thoroughly practical heavyduty yHoor-type snagging grinder. Another object of the invention is to provide a snagging grinder in which a longitudinally moveable carriage serves as a support for a transversely moveable carriage for imparting a transverse movement to the grinding wheel in a horizontal plane;
Another object of the invention is to provide a dual driving mechanism synchronously torotate the carriage supporting axles which are controlled by a -single control valve. Another object of the invention is to provide a fluid pressure operated mechanism for imparting a swinging movement to the grinding wheel to provide a pre- Wheels 17 and 22 serve to guide the carriage 10 as it is traversed longitudinally.
A suitable driving mechanism is provided for traversing the carriage longitudinally comprising a iluid motor 25 (Fig. 1 and 3) which is connected by a coupling 26 with a speed reducer unit 27. The speed reducer 27 may'be any of the well known commercial speed reducer units. The driven shaft of the speed reducer unit 27 is connected by the coupling 28 with a shaft 29. The shaft 29 is provided with a fixedly mounted gear 30 (Fig. 4) which meshes with an intermediate gear 31.
The gear 31 'in turn meshes with a gear 32 which is iixedly mounted on the axle 13. It will be readily apparent from the foregoing disclosure that rotary motion transmitted from the uid motor 25 will be imported to give a longitudinal movement of the carriage 10.
A similar driving mechanism is provided for driving the axle 18 comprising a fluid motor 35 which is connected by a coupling 36 with a speed reducer unit 37. The driven shaft of the speed reducer unit 37 is connected to a rotatable shaft 39 having a gear 40 xedly mounted thereon. The gear 40 meshes with an intermediate gear -41 (Fig. 4) which, in turn, meshes with a gear 42 iixedly mounted on the axle 42. The iluid motors 25 and 35 are controlled by a single control valve mechanism to be hereinafter described to control the determined high or low grinding pressure between the grinding wheel and the work being ground while being traversed either longitudinally or transversely. Other objects will be in part obvious or in part pointed out hereinafter. In lthe accompanying drawings in which lis kshown one of various possible embodiments of the mechanica-l features of this invention:
. Fig. l is a side elevation of the snagging grinder;
Fig. 2. .is a front elevation of the grinder;
Fig. 3 is a plan View of the grinder; Fig. 4 is a rear elevation, partly in section, taken approximately on the line 4 4 of Fig. l;
Fig. 5 is a fragmentary horizontal sectional view, on an enlarged scale, taken approximately onthe line 5-5 of Fig. 1; K
Fig. 6 is a fragmentary vertical sectional view, on an enlarged scale, taken approximately on the lines 6 6 of Fig. 4, showing the roller support for the transversely movable slide; and Y Fig. 7 is a combined hydraulic and electric diagram of the actuating mechanisms and the controls therefor. A heavy-duty floor-type snagging grinder has been illustrated in the drawings comprising a longitudinally movaf ble carriage 10 which is arranged to travel longitudinally on a pair of spaced parallel rails 11 and 12. The carriage 10 is provided with a traversely extending axle 13 which is rotatably journalled in spaced bearings 14 and 15 (Fig. 3). The axle 13 is provided with a wheel 16 which rides on the rail 11,. The axle 13 is also provided with a flanged wheel 17 which is arrangedto ride upon the rail 12 so as to guide the longitudinally movable carriage 10 during its longitudinal movement.
The carriage 10 is also provided with a rotatable axle 18 rotatably journalled in spaced bearings 19 and `2l) which are supported on the longitudinally movable carriage 10.
The axle 18 is provided with a wheel 21 which Arides upon the rail 11 and is also provided with a anged wheel 22 which rides upon the rail 12. It will be readily apparent 'from the foregoing disclosureV that the flanged l longitudinal movement of the carriage 10.
` A uid pressure system is provided for supplying fluid under pressure to the various mechanisms of the machine. This system comprises a uid pump 45 which is driven by an electric motor l46 (Fig. 7). The pump 45 draws uid through a pipe 47 from a reservoir 48 and forces fluid under pressure through a pressure pipe 49 to the iiuid motors 25 and 35. A balanced pressure relief valve 50 is connected in the pipe line 49 to facilitate passing excess uid under pressure directly through a pipe 51 into the reservoir 48 to facilitate maintaining a substantially constant fluid pressure throughout the system. Y
A piston type control valve 55 is provided for controlling the admission to and exhaust of fluid from the uid motors 25 and 35. The valve 55 comprises a valve stem 56 having a plurality of spaced valve pistons formed integrally therewith to form a plurality of spaced val've chambers 57, 58, 59, and 60. The Valve is provided with a central passage 61 which interconnects the valve chamber 57 with the valve chamber 59. A compression spr-ing serves normally to hold the valve stem 56 in the position illustrated in Fig. 7.
A manually operable control lever 62 is provided for actuating the control Valve 55. The lever 62 is pivotally supported by a stud 63 carried by the upper end of a link 64. The lower end of the link 64 is supported by a stud 65 carried by the control valve 55. A stud 66 connects the valve stem 56 with the control lever 62. The
-V pipe 49 is arranged to convey uid under pressure from lthe pump 45 to the valve chamber 59 of the control valve 55. A pipe 67 is connected between the control valve 55 and a throttle valve 68 which serves to control the rate of exhaust of iiuid from the control valve 55 into the reservoir 48. A pipe 69 is connected between the control valve 55 and one side of each of the iluid motors 25 and v35. A pipe 70 is connected between the control valve and the other side of each of the iluid motors 25 and 35. VThe control valve 55 is arranged to simultaneously Vcontrol the admission to and exhaust of iiuid from the uid motors 25 and 35. A balance pressurerelief valve 71 is connectedbetween the pipe 70 and the pipe 69. A balance pressure relief valve 72 is similarly connected between the pipe 69 and the-pipe 70. T'he balance presl. sure relief valves 71 and 72 are provided so that when r, J fluid under pressure to the motors 25 and 35 is reversed fluid may readily pass between the pipes 69 and 70 respectively thereby preventing an excessive build up of pressure in the pipe lines and motors at the time of rever-4 sal.
When it is desired to impart a longitudinally traversing movement of the carriage the control lever 62 may jbe moved in a clockwise or counter-clockwise direction (Fig. 7). When the control lever 62 is moved ina clockwise direction (Fig. 7) the valve stem 65 is moved downwardly against the compression spring. In this position of `the parts lluid under pressure from the pipe 49 entering the valve chamber 59 passes through the pipe 70 A'to sta-rt both the uid motors to impart a longitudinal traversing movement to the carriage 1'0. During this movement uid may simultaneously exhaust from the other side of the fluid motors 25 and 35 through `the `pipe 69 into the valve chamber 58 and pass through apassage 73,through the pipe 67, through the throttle valve 68 and through the exhaust pipe '51 into the reservoir 48. The rate of movement of vthe carriage 10 may be readily controlled by manipulation of the throttle valve 68.
When it is desired to stop the carriage 10 the control lever 62 may be released by the operation at which time the released compression of the spring causes an upward movement of the valve stem 56 to position the valve 55 in a central or neutral position, as shown in Fig. 7. When Vthe control valve 55 is in a central or neutral position, uid under pressure from the pressure pipe 49 entering the valve chamber 59 may pass through Vthe central passage 60 into the valve chamber '57 and `through the pipe 67 through the throttle valve 68 and exhausts through the pipe 51 into the reservoir 48.
When it is desired to traverse the carriage 10 longitudinally in the opposite direction, the control lever 62 may be moved in a counter-clockwise direction so as to cause an upward movement of the valve stem 56 so 'that uid under pressure entering the valve chamber 59 may pass through the pipe 69 to the other side of both of the uid motors 25 and 35 thereby causing the motors to rotate in opposite directions and to traverse the carriage 10 in an opposite direction. It will be apparent 'from the foregoing disclosure that by manipulation of the control lever 62 the carriage 10 may be traversed in either direction. The movement of the carriage in either direction may be stopped at any time by releasing the control lever 62 to allow the released compression of the spring to return the valve 55 to a central position or the lcarriage may be reversed in its direction of travel by manually shifting the lever 62 in the opposite direction.
The longitudinally movable carriage 10 serves as a support for a transversely movable carriage 75 (Figs. 2 and 4). The longitudinally movable carriage 10 is provided with a pair of spaced parallel rails 76 and 77. The traversely movable carriage 75 is provided with a plurality of flanged wheels or rollers 78 and 79 which ride upon the rails 76 and 77 respectively. The carriage 10 is also provided with a pair of spaced parallel depending rails 80 and 81 (Figs. 2 and 4) which serve to hold the traversely movable carriage 75 against a lifting movement. The traversely movable carriage is provided with a plurality of spaced wheels or rollers 82 (Fig. 6) which ride upon the lower surface of the rail 80. Either the set of rollers 78 or the set of rollers 82 may be provided with adjustments so that lost motion may be taken up between the rails 76 and 80. A similar set of rollers 83 are carried by the carriage 75 and rolled upon the lower surface of the depending rail 81.
A hydraulically operated mechanism is provided for imparting a traverse movement to the carriage 75 comprising a pair of spaced parallel cylinders 90 and 91 (Figs. 3 and 7) which are ixedly mounted on the carriage 75. The cylinders 90 and 91 contain the pistons 92 and 93 respectively which are connected to one end of a Ypair of piston rods 94 and 9S respectively.A The other'euds -of the piston rods 94 and 95 are connected by brackets 96 and 97 respectively with a rearwardly extending portion of the longitudinally movable carriage 10. The cylinders 90 and 91 are arranged on opposite sides of the transversely movable carriage 75 to facilitate the transverse traversing moving of the carriage 75.
The control valve 100 is vprovided for simultaneously controlling the admission to and exhaust of fluid from the cylinders 90 and "91 respectively. The control valve 100 is fa .piston ytype valve comprising a valve stem 101 having'a plurality-of spaced valve pistons -formed integrally therewith to form a plurality of spaced valve chambers 102, 103 and 104. VA compression spring is provided normally "to "holdthe valve stem 101 in a central or neutral positionv as `illustrated in Fig. 7.
A manually operable control lever 105 is pivotally supported by a stud 106 carried by an upper end of the link 107. The lower end of the link 107 is supported by a 'stud 108 carried by the valve '100. A stud 109 connects the valve stem 101 with the control lever 105. A uid pressure pipe 110 is provided for conveying uid under pressure to the valve chambers 102 and 104. A pipe '112 is "connected to a ball check valve 113 which is connected by a'pipe 114 with the upper-ends of the cylinders 90 and 91 respectively. Fluid passing through the pipe 114 simultaneously enters a cylinder chamber 115 and a cylinder chamber 116 formed in the upper ends of the cylinders 90 and 91, respectively. A pair of cylinder chambers 117 and 118 formed in the lower end of the cylinders Y90 and 91, respectively, are connected by a pipe 119with a throttle valve 120 which is in turn connected with `the valve 100. A throttle valve 121 is connected between the -p'ipes 112 and 114. A ball check valve 122 lis connected between the pipes 119 and the valve 100.
When it is desired to traverse the transversely movable carriage 75, the control 'lever 10S may be rocked in either -a'clockwise or counter-clockwise direction (Fig. 7) depending upon the direction of movement of carriage 75 desired. fWhen it is desired to move the carriage 75 rearwardly, that is, -in an upward direction (Fig. 3) the control lever 105 is rocked in a clockwise direction to move the valve stem 101 -downwardly so that tiuid under pressure within the valve chamber '102 may pass through the pipe 112, through the ball check valve 113 and the throttle valve 121 `into the pipe 114 to simultaneously convey fluid under pressure into the cylinder chamber and 116 respectively. yFluid under pressure entering the cylinder chambers 115 and 116 causes an upward movement of the cylinders so as to cause a rearward movement of the carriage 75. During this movement uid within the cylinder chambers 117 and 118 simultaneously exhausts through the pipe 119, through the throttle. valve into .the valve chamber 103 into an exhaust pipe `13:1. By manipulation of the throttle valve 120, vvthe rate of exhaust 'of uid from the cylinder chambers 117 Vand 118 may be readily controlled to control the Vspeed of the rearward movement of the carriage 75. Y lSimilarly if it is desired to cause a forward movement to the carriage 75, the control lever 105 is rocked in a counter-clockwise direction (Fig. 7) `thereby causing an upward 'movement of the valve Vstem 101 Aso that Huid under pressure entering `the valve chamber 104 passes through the ball check valve 122, through the pipe 119 simultaneously into the 'cylinder ' chambers 117 and 118 respectively thereby vmoving `the cylinders 90 and 91 respectively `together with the transversely movable carriage 75 in a forward direction. During this movement huid Within Athe 'cylinder chambers 115 and 116 simultaneously exhausts through the pipe 114, through the throttle valve 121, through the pipe 112 through the valve chamber 1031in the valve 1'00 and exhausts through the pipe '131. 'The rate of the forward movement of the carriage`75 may be readily controlled by manipulation of the throttle valve 131. Y
An independent fluid pressure system is provided for supplying fluid under pressure to the mechanism above described and also to other mechanisms to be hereinafter described. This system compirses a tluid pump 125 (Fig. 7) which is driven by an electric motor 126. 'Ihe pump 125 draws iluid through a pipe 127 from a reservoir 128 and forces fluid under pressure through a pipe 129, through a balanced pressure relief valve 130 into the pressure pipe 110. The exhaust pipe 131 is connected to the relief valve 130 to return excess iluid under pressure directly to the reservoir 128. The relief valve 130 is preferably adjusted to open at 300 lbs. per square inch so as to maintain an operating pressure in the lluid system of 300 lbs. persquare inch.
'Ihe transversely movable slide or carriage 75 serves as a support for a pivotally mounted frame 140 which is provided with horizontally extending portions 141 and 142. The portion 141 is provided with a trunnion 143 which is supported in a bearing 144 mounted in an upwardly extending bracket 145 on the carriage 75. The horizontally extending portion 142 of the frame 140 is provided with a trunnion 146 which is journalled in a bearing 147 supported by an upwardly extending bracket 148 lixedly mounted on'the carriage 75. The frame 140 is provided with an opening 149 to facilitate passing a driving mechanism for a grinding Wheel to be hereinafter described.
The frame 140 is provided with a horizontally extending arm 150 (Figs. l and 3). A hydraulically operated mechanism is provided to facilitate rocking the frame 140 about the axis of the trunnion 143-146 as a pivot. This mechanism comprises a cylinder 155 which is pivotally supported by a bearing 154 mounted on the transversely movable carriage 75 (Fig. 1). The cylinder 155 contains a slidably mounted piston 156 which is connected to the lower end of a piston rod 157. The upper end of the piston rod 157 is connected by the stud 158 carried by a bracket 159 formed integral with the arm 150 of the frame 140. It will be readily apparent from the foregoing disclosure that movement of the piston 156 within the cylinder 155 will impart a rocking motion to the arm 150 and the frame 140 to control the feeding movement of a grinding wheel to be hereinafter described.
In order to provide a controlled movement of the piston 156, it is desirable to rely upon the differential effective area of the piston 156. The effective 4area of the upper surface of the piston is less than the effective area of the lower surface thereof due to the piston rod 157. Fluid under pressure from the pipe 110 is con tinuously passed through the check valve 160 and -a throttle valve 166, through a pipe 161 into a cylinder chamber 162 to exert a downward thrust on the piston 156 tending to` rock the frame 140 in a counter-clockwise direction (Fig. 1). The throttle valve 166 controls the rate of exhaust of iluid from -the cylinder chamber 162 against the pressure in the pipe 110 when lluid under pressure is passed into the cylinder chamber 164. Due to the greater area of the under side of the piston 156, a controlled swinging movement is imparted to the frame 140 to produce the -desired grinding pressure.
A control valve 170 is provided for controlling the admission to and exhaust of uid from the cylinder chamber 164. The valve 170 is a piston type valve having a valve stem 171 formed with a plurality of spaced pisf tons to form a plurality of spaced valve chambers 172, 173 and 174. A manually operable control lever 175 is pivotally supported by a stud 176 to the upper end of a llink 177. The lowerend of the link 177 is connected by a stud 178 with the valve 170. A stud 179 connects the control lever 175 with the valve stem 171. A spring pressed detent 180 is arranged to engage one of a plurality of spaced grooves 181, 182, -and 183 to maintain the Valve stem 171 in -a predetermined position. A pipe 185 is connected between the valve 170 and a pressure reducing valve 186 which contains a vertically arranged sldable valve member 187. The valve 186 is connected by a pipe 188 with a ball check valve 189 and a throttle valve 190 with the pipe 163 leading to the cylinder chamber 164. A ball check valve191 (Fig. 7) is connected between the pipe 188 and the pipe 185.
The slidably mounted valve member 187 of the pressure reducing valve 186 is provided with ya central passage 192 Vwhich is arranged so that when the sldable valve member 187 moves upwardly iluid may pass through the central passage 192 and through a vent pipe 193 to a rotary control valve 194.V The control valve 194 is operatively connected in a manner to be hereinafter described to pass lluid from the venting pipe 193 either to an adjustable relief valve 196 or to an adjustable relief valve 197 which are adjusted to operate at different pressures so as to facilitate controlling the pressure conveyed to the cylinder chamber 164.
The valve 194 contains a valve rotor 198 which is actuated by a manually `operable control lever 199. In the position of the valve 194 (Fig. 7) fluid passing through the venting pipe 193 enters a valve chamber 200 in the valve 194 and passes through a pipe 201 to the relief valve 196 which allows excess fluid under pressure to pass through the exhaust pipe 131 into the reservoir 128 thereby reducing the lluid pressure passed tol the cylinder chamber 194.
If desired the control lever 199 may be swung into position 199e to turn the valve rotor 198 so that fluid under A pressure entering the valve chamber 200 may pass through a passage 202 in the valve rotor'198 into a valve chamber 203 and through a pipe 204 to the relief valve 197 so that excess iluid may be passed through the re' lief valve 197 into the exhaust pipe 131 which exhausts into the reservoir 128.
The pressure reducing valve 186 is provided with a pilot control piston 205. The pilot control piston 205 is spring pressed `and adjustable so that iluid passing through the central passage 192 into the pipe 193 may move the piston 205 toward the right (Fig. 7) to allow a variabile amount of lluid to pass through a drain pipe 206 into the exhaust pipe 131. The pilot control piston 205 is preferably adjusted to open at pressure in excess of the setting of relief valve to allow excess fluid to exhaust through pipe 131 into the reservoir 128.
When it is desired to impart a clockwise feeding movement to the frame 140, the control lever is'rocked in a counter-clockwise direction until the spring pressed detent engages the groove 183. In this position of the valve 170 lluid from the pipe 110 passes through the valve chamber 174, through the pipe 185, through the pressure reducing valve 186, through the pipe 188, through the ball check Valve 189 and the throttle valve 190, through the pipe 163 into the valve chamber 164 to cause an upward movement of the piston 156 at a predetermined controlled rate. During this feeding movement excess iluid under pressure within the pipe 188 causes an upward movement of the valve member 187 (Fig. 7) which serves to allow fluid under pressure to pass through the pipe 193 to -the rot-ary control valve 194 and through either the relief valve 196 or the relief valve 197 into the exhaust pipe 131.
The relief Valves 196 and 197 are adjustable to faci-litate varying the grinding pressure of the grinding wheel 228 and the work piece 285. The valve 196 may be set to open at 75 lbs. per square inch and the valve 197 may be set to open at 200 lbs. per square inch to facilitate obtaining either a low or a high grinding pressure. lAt the same time the pilot control piston 205 may be moved toward the right to allow a portion of the excess fluid to pass through the venting pipe 206 into the exhaust pipe 131. It will be readily apparent from the foregoing disclosure that by applying a predetermined pressure toward the upper face of the piston 156 and applying a controlled pressure to the lower surface of the piston 156` having a greater piston area will cause a controlled upward movement of the piston 156 (Fig. 7) thereby imparting acontrolled feeding movement to the frame 140 in aclockwise direction (Fig. 1).
When it `is desiredto rock the frame 140 in a countercloekwise direction (Fig. l), the control lever 175 may be moved in a clockwise direction until the detent 180 engages lthe groove 181. In this position of the valve fluid under pressure from the pipe 110 is cut oi from the valve 170 and 'iiuid from lthe cylinder chamber 164 may exhaust through the pipe 163 through the throttle valve 190, through the ball check valve 191, through the pipe 185, 'through the valve chamber 173 into the exhaust pipe 131 which exhausts into the reservoir 128. By manipulation of the pressure reducing valve 186 and the relief valves 196 and 197 a precise control of fluid under pressure entering the cylinder chamber 164 may be obtained.
The 'frame 140 serves as a support for a grinding unit 220. The grinding unit 220 comprises a cylindrically shaped support 221 which is journalled in spaced bearings 222 and 223 which are iixedly mounted within an aperture formed in the frame 140. The grinding unit further comprises a frame 224 which serves as a combined support for a grinding wheel 'and as a wheel guard. The frame 224 (Fig. 5) supports a lixedly mounted non-rotatable spindle 225. The spindle 225 supports a pair of spaced roller bearings 226 which in turn support a rotatable wheel sleeve 227 upon which a grinding wheel 228 is mounted. The grinding unit 220 is arranged to rock about the axis of the cylindrical member 221. In order to perform a heavy duty snagging operation, the longirtudinally movable carriage 10, the transversely movable carriage 75, the pivotally mounted frame 140 together with lassociated parts are massive in structure so that a large diameter grinding wheel, such as, ya 36 diameter grinding wheel 228 driven by a 75 H.P. driving motor may be employed to facilitate rapid stock removal from the billet or work piece being ground.
A driving mechanism is provided for the grinding wheel 228 comprising `an open-ended box-like frame 230 which is xedly keyed onto the left hand end of the cylindrical member 221 (Fig. 5). The opposite side ofthe boxlike frame 230 is provided with a ixedly mounted trunnion 231 "which is supported in a bearing 232 carried by a downwardly projecting bracket 233 which is fastened Ito the left hand end of the arm 150 of the frame 148. An adjusting screw 234 is provided to facilitate taking up the end thrust of the grinder unit 220 in `a direction toward the left (Fig. 5).
The box-like frame 230 supports a wheel driving motor 235 haiving a cog pulley 236 which is connected by a cog driving belt 237 with a cog pulley 238 which is keyed onto the upper end of a rotatable shaft 239. The Ishaft 239 is iournalled in a pair of spaced bearings 240 and 241 which `are supported in a bracket 242 tixedly mounted on the boxalike frame 230. The yaxis of the shaft 239 is preferably in axial alignment with the trunnions 143 and 146 of the frame 140 in order to facilitate the swinging movement of the frame 140 about the axis of the trunnions.
A cog pulley 243 is keyed onto the lower end of the shaft 239 (Fig. 5 The pulley 243 is connected by a cog driving ybelt 244 with a cog pulley 245 which is carried by the wheel sleeve 227. A Wheel guide cover 246 encloses the open side of the frame 224. It will be readily apparent from the foregoing disclosure that the motor 235 will transmit power to rotate the grinding wheel 228 during a swinging or feeding movement of the frame 140.
It is desirable to rock the grinding wheel in a vertical plane passing through its axis. This rocking movement is obtained by a hydraulically operated mechanism comprising a pair of cylinders 250 and 251, the upper ends of which are connected by studs 252 and 253, respectively, with a bracket 254 which is ixedly mounted relative .to the .frame .140. The .cylinders 25.0 and A251 contain slidably mounted pistons 255 and 256 respectively. The pistons 255 and 256 are connected to the upper `ends of a vpair of piston rods 257 and 258 respectively. The lower ends of the piston -rods y257 and 258 are connected by a pair of studs 259 and 260 respectively with a pair of brackets 261 and 262 which are fixcdly mounted on `the rear surface of the box like frame 230.
A control valve 265 is provided for controlling the admission to and exhaust of uid from the'cylinders 250 and 251 respectively to obtain the desired rocking movement of the wheel supporting frame 224. The control valve 265 is a piston -type valve having `a valve stern 266 which is actuated Vby a control lever 267. The control lever is pivotally supported by a stud 268 on the upper end of a link 269. The lower end of the link 269 is connected by a stud 270 carried by the valve 265.
The valve stem 266 is provided with a plurality of spaced valve pistons vforming a plurality of spaced valve chambers 271, 272, and 273. A compression spring 274 serves normally to maintain the valve 265 in a central or neutral position, as indicated in Fig. 7. A pipe 275 connects the valve 265 with a lower cylinder chamber 276 in the cylinder 250 and an upper cylinder chamber 277 in the cylinder .251. A pipe 278 connects the valve 265 with a lower cylinder chamber 279 in the cylinder 251 and an upper cylinder chamber 280 in the cylinder 250.
The valve 265 is provided with a passage 281 which receives fluid under pressure from the pressure pipe 110. With the valve 265 in a central or neutral position, fluid under pressure is conveyed by the passage 281 into the valve chambers 271 and 273. When it is desired to impart a clockwise rocking motion to the frame (Fig. 7), the control lever 267 is rocked in a clockwise direction to cause a downward movement of the valve stem 266 so that tluid under pressure entering the valve chamber 271 passes through the pipe 275 simultaneously into the cylinder chambers 276 and 277. During this rocking movement of the frame 140 iluid within the cylinder chambers 279 and 280 exhausts through the pipe 278, through the valve chamber 272 into the exhaust pipe 131 which exhausts into the reservoir 128.
Similarly when a rocking motion in a counter-clockwise direction of the frame 140 is desired, the control lever 267 is rocked in a counter-clockwise direction thereby causing an upward movement of the valve stem 266 so that iluid under pressure from the valve chamber 273 passes through the pipe 278 into the cylinder chambers 279 and 280 to impart a counter-clockwise swinging of the box-like frame 230 and the frame 140. During this movement fluid may exhaust from the cylinder chambers 276 and 277, through the pipe 275 into the valve chamber 272 and pass through the exhaust pipe 231 into the reservoir 128.
A work piece 285, such as a billet or slab of steel to be snagged may be placed on a work supporting base 286. The grinding wheel 228 may then be fed downwardly by a swinging movement of the frame 140 into operative engagement with the surface to be ground. The carriage 10 may be traversed longitudinally by imparting a longitudinal traversing movement to the carriage 10. The grinding wheel 228 may be moved transversely to present the wheel to a different portion of the work piece being snagged by imparting a traverse movement to the carriage 75. Due to the opposed roller support for the transversely movable carriage 75, any desired grinding pressure may be imparted to the grinding wheel 228. If desired the grinding unit 220 may be rocked about a horizontal axis so as to tilt -the grinding wheel in either direction as shown in Fig. 2.
In Fig. l, the arm of the frame 140 has been illustrated in broken line position 150a when the `frame 140 is swung in a clockwise direction to swing the grinding wheel 228 `in-to its extreme lower position 228a. Arm 150 has also been shown in broken line position 150b when lthe frame 140 is swung in a counter-clockwise direction to swing the grinding Wheel 228 into its extreme upper position 228b. The arm 150 has also been shown in broken line position 150C when the slide 75 is moved toward the left (Fig. 1) to position the grinding wheel 228 in broken line position 228e.
. `In Fig. 2, the broken positions 228d and 228e of the grinding wheel 228 illustrate extreme positions of the grinding Wheel 228 when the grinding wheel unit 220 is swung within theV bearings 221-222 (Fig. 5). v
An operators seat 290 (Figs. 1 and 2) is provided at a control station 291 on the transversely movable slide 75. The control levers 62, 105, 175, 199 and 267 for actuating the control valves 55, 100, 170, 194 and 265, respectively', are positioned wi-thin easy reach of the operator. Y
The operation of the improved snagging grinder will be readily apparent from the foregoing disclosure. After a work piece 285 has been positioned on the work support 286, the wheel driving motor 235 is started by closing a switch 287. The pump driving motor 46 is started by closing the switch SW2. The pump driving motor 1264is started by closing Ithe switch SW1.
By manipulation of the control lever 175, the valve 170 may be actuated to swing the frame 140v in a clockwise direction (Fig. 1) to feed the grinding wheel 22S into grinding engagement with the work piece 285 at a desired and predetermined pressure. The grinding pressure may be varied by manipulation of the valve 194 and by adjustment of the relief valves 196 and 197. The carriage 10 may then be traversed longitudinally by actuation of the control lever 62 which in turn actuates the control valve 55 to start the iluid motors 25 and 35 in either direction. The direction of movement of the carriage being determined by the direction of movement of the control lever 62. At the end of a longitudinal stroke of the grinding wheel 228, the carriage 75 may be traversed transversely by lactuation of the -control lever 105 to present a new portion of the work surface to be ground during the next longitudinal traverse of the carriage 10. `If desired the surface of the work piece being snagged or ground may be ground by successive longitudinal movement of the carriage 10 combined with a transverse movement of the carriage 75 at the ends of the longitudinal stroke of the carriage 10.
If desired, a transverse movement of the carriage 75 controlled by the control lever 105 may be utilized to traverse the grinding wheel 228 transversely across the' work piece 285. After the grinding wheel has ground the surface to the desired extent, the longitudinal moveable grinding wheel carriage may be moved longitudinally to present the grindin-g wheel to an adjacent portion of the surface. This sequence may be continued until the entire surface has been ground to the desired and predetermined extent. After a predetermined area has been ground at one end of the work piece in a manner above described, the carriage 10 may be traversed longitudinal-ly to present the grinding wheel to the other end portion of the work piece to be ground. A similar portion of the face of the work piece may be ground to the desired extent by a transverse movement of the carriage 75. After an area at each end of the work piece has been ground to the desired extent by a transverse movement of the carriage 75, the longitudinally movable carriage 10 may be traversed longitudinally to grind the area between -the two end portions. Between longitudinal strokes by the carriage l()` the carriage 75 may be advanced transversely so as to present the grinding wheel to |a new portion of the work piece on each successive longitudinal stroke.
In both methods of operation, that is, by grinding with fa longitudinal stroke or grinding by a transverse stroke of the wheel, the wheel axis m-ay be mounted parallel to the plane of the work surface or may be tilted into either the position 228e or 228d when desired. If it is desired to change the pressure of the grinding wheel against the l0 work piece, the control valve 194 may be actuated to render -the relief valve 196 or the relief valve 197 operative.
It will therefore be seen that there has been provided by this invention apparatus in which the various objects hereinafter set forth together wtih many thoroughly practical advantages are successfully achieved. As many possible embodiments may be made of the above invention and as many changes might be made in the embodiments above set forth, it -is to be understood that all matter herein-before set forth or shown in the accompanying drawings is-to be interpreted as illustrative and not in a llimiting sense.
I claim:
1. A snagging grinder comprising a traversable longitudinal carriage, a iluid motor to traverse said carriage, a transversely movable slide on said carriage, a iiuid motor interposed between the carriage and the slide to move said slide transversely of the carriage, a pivotally mounted swing frame .supported on said slide, spaced axially aligned horizontally arranged trunnions on said frame, spaced bearings on said slide for said trunnions` having their common axis arranged parallel to the direction of movement of the longitudinal carriage, a fluid motor to swing said frame relative to said slide, an elongated grinding unit on said frame including a support for said unit projecting through and rotatably mounted on said frame, ythe axis of said support being rotatable about the axis of said trunnions in a vertical plane parallel to .the path of movement of said slide, a grinding wheel rotatably mounted on one end of said unit, a box-like frame iixedly mounted on the other end of said unit, an electric motor adjustably supported on said boxlike frame, a trunnion `iixedly mounted on said box-like frame in axial alignment with the said rotatable Support, -a bearing on said swing frame to support said trunnion, a rota-table shaft, spaced bearings supported on said grinding unit for supporting said shaft in a common plane with the spaced trunnions on sia-id swing fname, belt driving connections between said motor and said shaft, and belt driving connections between said shaft and said grinding wheel to facilitate driving .the grinding wheel in any position of the swing frame or grinding unit without disturbing the belt driving connections between the motor and the grinding wheel.
2. A snagging grinder comprising a traversable longitudinal carriage, a fluid motor to traverse said carriage, a
transversely .movable slide on said carriage, a fluid motor interposed between the carriage and the slide to move said slide transversely of the carriage, a pivotally mounted swing frame supported on said slide, spaced axially aligned horizontally arranged trunnions on said frame, spaced bearings on said slide for said trunnions having their common axis arranged parallel to the direct-ion of movement of the longitudinal carriage, a fluid motor to swing said frame relative to said slide, an elongated support for a grinding wheel projecting through and mounted rotatably on said frame, the axis of rotation of said support being rotatable about the axis of said trunnions in a vertical plane parallel to the path of movement of said slide, a grinding Wheel rotatably journalled in bearings mounted on one end of said support, Ia box-like frame fixedly mounted on the other end of s-aid support, an electric motor supported within said box-like frame, a trunnion fixedly mounted on said boxlike frame in axial alignment with said rotatable support, la lbearing on said swing frame to support said trlmnion, a rotatable driven shaft, spaced bearings supported on said box-like frame for supporting said shaft for angular ldisplacement about the axis of said support in a plane intersecting the spaced ltrunnions on said swing frame, bel-t driving connections between said motor and said shaft, and belt driving connections between said shaft and said grinding wheel to facilitate driving the grinding wheel in any position of the swing frame 9i' 1 1 grinding unit without imparting a. ltwist to saidy driving belts.
3. `In a snagging grinder, as claimed in claim 1, in combination with the parts and features therein specified in which the `uid motor for swinging the grinder frame relative to the transverse slide comprises a piston and cylinder, operative connections between the frame and transverse slide, said piston having differential piston areas, means for applying pressure direct from a source to the upper end of said cylinder to exert a downward pressure on the smaller piston area, and means including a manually operable control valve operatively connected to apply a lower pressure to the greater piston area on the under side of said piston so as to impart a controlled swinging movement to :the frame and grinder unit lto obtain the desired grinding pressure.
v4. In a snagging grinder as claimed in claim 3, in combination with the parts and features therein specified of means including a pressure regulating valve to pass fluid under pressure to the lower end of said cylinder, means including a pair of independent adjustable relief va-lves one of which -is `set lfor a low grinding pressurel and the other set for Ia high grinding pressure, said relief valves -being arranged to exhaust excess uid under pressure from the pressure regulating valve, and means including a manually operable valve to render either of said relief valves operative to facilitate obtaining either a controlled high or low pressure between the grinding Wheel and the work piece being ground.
Hamilton May 25, 1948 Muehling June 19, 1956
US627020A 1956-12-07 1956-12-07 Snagging grinder Expired - Lifetime US2955388A (en)

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Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3052067A (en) * 1960-09-09 1962-09-04 Lukens Steel Co Hydraulic counterbalance and lift for slab grinder
US3086331A (en) * 1959-07-15 1963-04-23 Edqvist Folke Evald Grinding machine for billets and the like
US3156072A (en) * 1962-11-09 1964-11-10 Loewy Machinery Supplies Compa Grinding apparatus
US3245176A (en) * 1963-06-27 1966-04-12 Mid West Abrasive Co Grinding machine
US3253368A (en) * 1963-10-08 1966-05-31 Pettibone Mulliken Corp Surface conditioning grinding machine
US3335525A (en) * 1963-06-27 1967-08-15 Mid West Abrasive Co Hydraulic system for grinding machines
US3656261A (en) * 1970-08-28 1972-04-18 Everett Ind Inc Cutting device control
FR2327034A1 (en) * 1975-10-08 1977-05-06 Sunds Ab MACHINE FOR GRINDING BILLETS AND THE LIKE
US4248019A (en) * 1977-11-28 1981-02-03 Western Gear Corporation Workpiece conditioning grinder control system
US5355631A (en) * 1992-11-19 1994-10-18 Robotics And Automation Corporation Regulated force and speed control of a surface treating wheel
US5435751A (en) * 1991-03-18 1995-07-25 Raychem Gmbh Device for connecting a coaxial cable end to a contact socket

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2442042A (en) * 1946-03-19 1948-05-25 Alfred E Hamilton Grinding apparatus
US2750714A (en) * 1950-12-04 1956-06-19 Mid West Abrasive Co Swing grinder

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2442042A (en) * 1946-03-19 1948-05-25 Alfred E Hamilton Grinding apparatus
US2750714A (en) * 1950-12-04 1956-06-19 Mid West Abrasive Co Swing grinder

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3086331A (en) * 1959-07-15 1963-04-23 Edqvist Folke Evald Grinding machine for billets and the like
US3052067A (en) * 1960-09-09 1962-09-04 Lukens Steel Co Hydraulic counterbalance and lift for slab grinder
US3156072A (en) * 1962-11-09 1964-11-10 Loewy Machinery Supplies Compa Grinding apparatus
US3245176A (en) * 1963-06-27 1966-04-12 Mid West Abrasive Co Grinding machine
US3335525A (en) * 1963-06-27 1967-08-15 Mid West Abrasive Co Hydraulic system for grinding machines
US3253368A (en) * 1963-10-08 1966-05-31 Pettibone Mulliken Corp Surface conditioning grinding machine
US3656261A (en) * 1970-08-28 1972-04-18 Everett Ind Inc Cutting device control
FR2327034A1 (en) * 1975-10-08 1977-05-06 Sunds Ab MACHINE FOR GRINDING BILLETS AND THE LIKE
US4248019A (en) * 1977-11-28 1981-02-03 Western Gear Corporation Workpiece conditioning grinder control system
US5435751A (en) * 1991-03-18 1995-07-25 Raychem Gmbh Device for connecting a coaxial cable end to a contact socket
US5355631A (en) * 1992-11-19 1994-10-18 Robotics And Automation Corporation Regulated force and speed control of a surface treating wheel

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