US3292310A - Apparatus for grinding bricks or the like - Google Patents

Apparatus for grinding bricks or the like Download PDF

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Publication number
US3292310A
US3292310A US346339A US34633964A US3292310A US 3292310 A US3292310 A US 3292310A US 346339 A US346339 A US 346339A US 34633964 A US34633964 A US 34633964A US 3292310 A US3292310 A US 3292310A
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United States
Prior art keywords
brick
station
bricks
grinding
cradles
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US346339A
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English (en)
Inventor
Martial A Lefevre
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International Diamond Products Ltd
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International Diamond Products Ltd
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Publication date
Application filed by International Diamond Products Ltd filed Critical International Diamond Products Ltd
Priority to US346339A priority Critical patent/US3292310A/en
Priority to FR4726A priority patent/FR1433414A/fr
Priority to CH172065A priority patent/CH427548A/fr
Priority to BE659451D priority patent/BE659451A/xx
Priority to AT128065A priority patent/AT258752B/de
Priority to DE1965I0027523 priority patent/DE1502456A1/de
Priority to GB6748/65A priority patent/GB1067604A/en
Priority to NO156815A priority patent/NO119899B/no
Priority to DK88465AA priority patent/DK108956C/da
Priority to NL6502089A priority patent/NL6502089A/xx
Priority to ES309951A priority patent/ES309951A1/es
Application granted granted Critical
Publication of US3292310A publication Critical patent/US3292310A/en
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Expired - Lifetime legal-status Critical Current

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G47/00Article or material-handling devices associated with conveyors; Methods employing such devices
    • B65G47/74Feeding, transfer, or discharging devices of particular kinds or types
    • B65G47/84Star-shaped wheels or devices having endless travelling belts or chains, the wheels or devices being equipped with article-engaging elements
    • B65G47/846Star-shaped wheels or wheels equipped with article-engaging elements
    • B65G47/847Star-shaped wheels or wheels equipped with article-engaging elements the article-engaging elements being grippers
    • 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
    • B24B41/00Component parts such as frames, beds, carriages, headstocks
    • B24B41/005Feeding or manipulating devices specially adapted to grinding machines
    • 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
    • B24B7/20Machines or devices designed for grinding plane surfaces on work, including polishing plane glass surfaces; Accessories therefor characterised by a special design with respect to properties of the material of non-metallic articles to be ground
    • B24B7/22Machines or devices designed for grinding plane surfaces on work, including polishing plane glass surfaces; Accessories therefor characterised by a special design with respect to properties of the material of non-metallic articles to be ground for grinding inorganic material, e.g. stone, ceramics, porcelain
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B28WORKING CEMENT, CLAY, OR STONE
    • B28DWORKING STONE OR STONE-LIKE MATERIALS
    • B28D1/00Working stone or stone-like materials, e.g. brick, concrete or glass, not provided for elsewhere; Machines, devices, tools therefor
    • B28D1/18Working stone or stone-like materials, e.g. brick, concrete or glass, not provided for elsewhere; Machines, devices, tools therefor by milling, e.g. channelling by means of milling tools
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B28WORKING CEMENT, CLAY, OR STONE
    • B28DWORKING STONE OR STONE-LIKE MATERIALS
    • B28D7/00Accessories specially adapted for use with machines or devices of the preceding groups
    • B28D7/04Accessories specially adapted for use with machines or devices of the preceding groups for supporting or holding work or conveying or discharging work

Definitions

  • the present invention relates generally to an apparatus for grinding bricks or similar -blocklike articles and has particular reference to an apparatus by means of which the surface irregularities that are ordinarily present in connection with building bricks as they issue from the kiln may be rectified and the various faces of the bricks ground with a precision that has heretofore been unattainable economically by conventional brick surfacing apparatus or equipment to the end that each finished brick presents flat and accurately rectangular side and end faces which possess a remarkable degree of smoothness, with the twelve edges of the brick being linearly straight and devoid of burrs or interruptions, with opposite faces of the brick being truly parallel and with all of the rectified or ground bricks being of uniform size.
  • Bricks which are thus rectified or conditioned are capable of use in the gang forming of wall sections which are themselves of precision dimensions. Due to the high degree of flatness of all six faces of each brick in a gang formed wall section, close proximity of adjacent opposed 'brick faces may be attained with the bricks being separated from one another by a thin layer of a strong bonding agent, for example, an epoxy resin, resulting in an immeasurably stronger bond than when the bricks are bonded by a relatively thick layer of conventional mortar.
  • a strong bonding agent for example, an epoxy resin
  • the usual lath and plaster installation may be omitted and the inside wall surfaces of a building structure thus erected from gang formed wall sections may be brush or spray painted, or otherwise decorated or surfaced directly.
  • similar treatment may be resorted to and, additionally, a building constructed of gang formed wall sections according to the present invention will present a finished appearance that is commensurate with standards of modern architecture.
  • brick surfacing operations are carried out by means of a novel grinding apparatus which may be comprised of a single surfacing or grinding apparatus which employs rotary grinding wheels and through which the bricks of a given run are successively passed three times, the first pass serving to condition one pair of opposite brick faces, the second pass serving to condition another pair of opposite brick faces, and the third pass serving to condition the third pair of opposite brick faces and comple the brick surfacing operations.
  • the apparatus may be comprised of three basically identical brick surfacing or grinding apparatuses which are arranged side-by-side or in series and through which a given run of 'bricks is successively passed.
  • the first apparatus will be adjusted to handle bricks which are so oriented that, when passing through the grinding station, one pair of opposite faces of each brick will be operated upon by the rotary grinding wheels. It is also contemplated that transfer means will be provided for conducting the bricks from the first apparatus to the second apparatus, the latter being so conditioned or adjusted as to receive and handle the bricks for presentation of a second pair of opposite faces of each 'brick to the grinding wheels of the second apparatus. Similarly, it is contemplated that transfer means will be provided for conducting the bricks from the second apparatus to the third apparatus, such third apparatus being so conditioned or adjusted as to receive and handle the bricks for presentation of the third and last pair of opposite faces to the grinding wheels at the grinding station of the third apparatus.
  • the essential features of the invention are at all times preserved, one such feature being that after the first pass of a given run of bricks, the two opposite faces which are treated then become reference faces for accurate clamping of the bricks during the next pass, whether in the same or in a different surfacing or grinding apparatus. Similarly, after the second pass of a given run of bricks, the two opposite faces which are treated during such pass become reference faces for accurate clamping of the bricks during the third pass.
  • a brick grinding apparatus of the character briefly outlined above being among the principal and general objects of the invention, this object is attained by the provisions of one or more apparatuses, each of which embodies a power-driven feed conveyor which receives the bricks at a receiving station and delivers them to a grinding stand where the bricks are processed.
  • the grinding stand includes a rotary drum which receives the bricks from the feed conveyor at a transfer station and conducts the bricks in a securely held manner to a grinding head at a grind ng station Where the bricks pass between the opposed parallel planar sides of at least one pair of rotating grinding wheels which serve to condition the bricks by smoothing and rendering parallel two opposite faces of the bricks. From the grinding station, the bricks are conducted by the drum to a delivery station where they are discharged from the apparatus.
  • the feed conveyor includes an endless series of articulated traveling brick-supporting trays, each of which is adapted to receive therein one of the bricks to be ground. Releasable brick-supporting means is associated with each tray for holding the associated brick in an approximately oriented position.
  • the feed conveyor is of the endless link type and the rotary drum to which it delivers the bricks includes a series of brick-receiving cradles.
  • the cradles of the drum are provided with brick-clamping means which serve fixedly to secure the bricks within the pockets of the cradles during passage of the bricks between the rotating grinding wheels at the grinding station.
  • the movements of the feed conveyor and the cradle- J equipped drum are correlated so that successive trays arriving at the transfer station may deliver their bricks to successive cradles on the drum arriving in synchronism at such station.
  • the operation of the brick-supporting means on the trays and the clamping mechanisms on the cradles is also correlated so that substantially at the same time that the brick-supporting means of a given tray at the transfer station releases a brick to open" the tray and discharge the brick, the clamping mechanism of the corresponding drum cradle in register with the tray seizes the brick, thus closing the cradle uponthe brick and capturing the same.
  • the thus captured brick rigidly positioned in the particular cradle, is conducted by the cradle through the grinding station and, after two opposite faces thereof have been conditioned, the brick is conducted to the discharge station where the cradle is caused to open and release the brick to a power-driven discharge conveyor.
  • a fixed centering station is provided between the transfer station and the grinding station.
  • the bricks which are transferred from the powerdriven feed conveyor to the rotary drum of the grinding stand are thus caused to pass through the centering station.
  • two centering shoes on opposite sides of the bricks and in associated relation with a brick centering device are caused to engage the adjacent brick faces and thus forcethe bricks to accurately centered positions in circumferential register with the space existing between the two grinding wheels at the grinding station which lies ahead of the centering station.
  • the operation of the brick-supporting trays that are associated with and form a part of the feed conveyor is purely mechanical, novel cam means, including fixed cam tracks on the conveyor frame and cooperating movable cam fingers on the endless conveyor proper, being provided for effecting opening and closing movements of the various trays.
  • the brick-clamping mechanisms that are associated with the rotary drum are hydraulically operated, a novel system of trip fingers and stops being provided on the drum-supporting structure and the drum respectively for effecting proper timing of the drum cradle opening and closing movements.
  • FIG. 1 is a side elevational view of a brick grinding apparatus constructed according to the principles of the present invention and involving a feed conveyor for conducting bricks to a grinding machine proper forming a part of the apparatus;
  • FIG. 2 is a vertical transverse sectional view taken
  • FIG. 7 is a vertical sectional view taken substantially along the line 7-7 of FIG. 6;
  • FIG. 8 is a circuit diagram of the hydraulic control mechanism for controlling the opening and closing movements of certain brick-conveying cradles that are employed in connection with the invention
  • FIG. 9 is a circuit .diagram of the hydraulic control mechanism for controlling the opening and closing move ments of a pair of brick-centering shoes that are employed in connection with the invention.
  • FIG. 10 is an enlarged transverse sectional view taken substantially along the line 1010 of FIG. 1;
  • FIG. 10a is a sectional view taken substantially along the line 10a10a of FIG. 10;
  • FIG. 11 is a sectional view taken substantially along the line 1111 of FIG. 10;
  • FIG. 12 is an enlarged plan view of the brick centering device
  • FIG..13 is a perspective view, entirely schematic in its representation, showing a brick which is to :be operated upon by the apparatus of the present invention and illustrating the orientational relationship of its side and end faces with relation to the grinding head during successive passes of the brick through the apparatus;
  • FIG. 14 is a schematic diagram further illustrating the orientational relationship between the brick and the.
  • FIG. 15 is a schematic diagram illustrating the orientational relationship of a brick with respect to the grin-ding head during the first pass of the brick through the appa ratus;
  • FIG. 16 is a schematic diagram, similar to FIG. 15, but
  • FIG. 17 is a schematic diagram, similar to FIGS. 14 and 15, but illustrating the orientational relationship of a brick with respect to the grinding head during the third or final pass of the bricks through the apparatus. 7
  • FIGS. 1 to 4, inclusive wherein a preferred form of brick-grinding apparatus constructed according to the present invention has been illustrated, the apparatus involves in its general organization a power-driven feed conveyor 10 which extends between a brick-receiving station R and a brick-transfer station T.
  • the bricks are transferred from the feed conveyor 10 to a grinding machine proper 12 including a brick-clamping conveyor in the form of a rotary powerdriven drum 14 by means of which the, bricks are conducted through a centering station C to a grinding station G and from thence to a discharge station D where the bricks are discharged onto an endless power-driven conveyor 16 by means of which the bricks are conducted from the apparatus as a whole.
  • a grinding machine proper 12 including a brick-clamping conveyor in the form of a rotary powerdriven drum 14 by means of which the, bricks are conducted through a centering station C to a grinding station G and from thence to a discharge station D where the bricks are discharged onto an endless power-driven conveyor 16 by means of which the bricks are conducted from the apparatus as a whole.
  • the power-driven feed conveyor 10 is provided with a series of articulated brick-supporting and transporting trays 18 which transport the bricks from the receiving station R to the transfer station T.
  • the trays 18 are automatically manipulated into an open position in order to discharge the bricks by gravity.
  • the rotary power-driven drum 14 is provided with a series of articulated brick-receiving and damping cradles 20.
  • the drum 14 and the feed conveyor are driven in timed relationship so that the cradles arrive at the transfer station T in correlation with the trays 18, successive trays 18 arriving at such station being met by a corresponding cradle 20.
  • the trays 18 Upon successive arrival at the transfer station T, the trays 18 become automatically open to release the bricks carried thereby so that they may be discharged by gravity into the cradles 20 which arrive at the transfer station in an open condition. As soon as a brick is thus received in a given cradle 20, the cradle automatical ly becomes closed in order securely to seize the brick and conduct the same to the centering station C. The empty and open trays 18 return to the receiving station R and, immediately prior to arrival thereat, they again become closed for repetitious reception of bricks at such station.
  • the cradles 20 on the drum 14 proceed successively from the transfer station T to the centering station, at which station a pair of coacting centering shoes 22 forming parts of a centering device 24 closes upon the opposite sides of the successive bricks on their associated cradle 20 and circumferentially aligns the bricks with two spaced apart rotary grinding wheels 25 which are disposed at the grinding station G and constitute the abrasive grinding elements of a grinding stand 26.
  • the bricks then pass between the grinding wheels 25 which operate upon one pair of opposite faces of each brick and, thereafter, from the grinding station G, the bricks are conducted to the discharge station D where the cradles 20 automatically become open to discharge the bricks onto the conveyor 16.
  • the bricks which are thus discharged onto the conveyor 16 will each have one pair of opposite faces rendered smooth and planar, and what is equally important, truly parallel to each other. These two conditioned faces of each brick may then constitute accurate reference faces for further brick conditioning operations when the thus preliminarily treated bricks are passed through the grinding apparatus during subsequent runs, as will be described in detail subsequently.
  • the feed conveyor 10 is of the endless link type and comprises identical functional link components which are connected together in end-to-end relationship for travel in a closed path including a feed reach section 27 (see FIG. 4) and a return reach section 28; At the ends of the conveyor 10 the link components pass around driving and driven sprocket wheels 29 and 30.
  • the conveyor 10 is of the horizontal pass type in that its driving and driven sprocket wheels rotate in respective horizontal planes, both reach sections being elevated above the floor 31 of the establishment wherein the grinding apparatus is located.
  • the individual link components are designated by the reference numeral 32, and these components are guided in their endless path of travel by conveyor rails 33 in the usual manner of conveyor link travel. In the medial region of the conveyor 10 and as shown in FIG. 1, the conveyor rails 33 are inclined in order that the rear end of the conveyor is higher than is the front end thereof, the rear end overlying the grinding machine proper 12 at the transfer station T.
  • the effective contour of the conveyor 10 may be varied in order to accommodate different kinds or types of installations.
  • the function of the conveyor 10 is to transfer bricks from a stockpile or source of such bricks to the grinding machine proper 12 and, thus, under certain circumstances, it may be necessary to employ a conveyor of great effective length, especially if the grinding machine proper 12 is located an appreciable distance from the stockpile of bricks.
  • the conveyor may be linearly straight or it may have curves or bends, as, for example, when the stockpile is disposed in a different room or enclosure from the grinding machine proper, or when an intervening object or machine requires such curves of bends. Irrespective, however, of the particular contour of the conveyor 10, the essential features of the invention are not altered.
  • the driving sprocket wheel 29 is rotatably supported in a superstructure 34 which forms a part of the stationary conveyor framework, the superstructure being in turn supported by vertical posts 35 from a masonry base 36 on the floor 31.
  • the rotary drum 14 of the grinding machine proper 12 is mounted on a horizontal shaft 38 which is supported in bearings 40 on the masonry base 36.
  • the driving sprocket wheel 29 of the feed conveyor is mounted on the upper end of a vertical drive shaft 42. The lower end of such shaft is operatively connected in driven relationship through a gear box 44 and an articulated or universal coupling 45 to the horizontal shaft 38.
  • the shaft 38 is operatively driven from an electric motor M through a gear reduction device 46 in the form of a conventional speed change transmission having a control handle 48 by means of which the speed ratio drive may be varied at will. It will be seen, therefore, that the brick feed conveyor and the rotary drum 14 are operatively connected in driving relationship for movement in unison for purposes that will be made clear presently.
  • the lower front end of the conveyor 10 which embodies the driven sprocket wheel 30 is operatively supported on standards or posts 50 forming a part of the conveyor framework.
  • the various link components 32 are identical and each includes a carriage 52 which is slidable on the conveyor rails 33 (see FIG. 5) and from the lower end of which there depends a lug 54.
  • a downwardly extending swinging tray-supporting arm 56 is pivotally connected at its upper end to each of the lugs 54 and the lower end of the arm serves removably to support one of the composite articulated brick-supporting and transporting trays 18.
  • One of the articulated brick-supporting and transporting trays 18 is illustrated in detail in FIGS. 10 and 11 and will be fully described presently.
  • Swinging movements of the tray-supporting arms 56 are restrained and limited by means of a series of curved hook-like fingers 62 which are connected to and depend from the carriages 52, cooperate with fixed laterally extending pins 64 on the medial regions of the arms 56, and limit the extent of swinging movement of the arms in one direction.
  • the pins 64 are also designed for cooperation with fixed cam rails 66 and 68 which are positioned in their path of movement, the cam rail 66 being positioned ahead of the cam rail 68 and underlying the inner region of the horizontal rear end of the feed conveyor, and the cam rail 68 being disposed above the drum 14.
  • the cam rail 66 serves to retract or swing upwardly the various arms 56 as they approach the transfer station T and cause the trays 18 that are supported thereby to make accurate register with the series of articulated brick-receiving and transporting cradles 20 which are mounted on the periphery of the drum 14 and arrive at the transfer station T in correlation with the trays 18.
  • the cam rail 68 extends horizontally and serves to elevate the trays 18 after they have discharged their respective bricks and deposited them in the cradles 20.
  • the effective diameter of the drum 14, the effective diameter of the driving sprocket wheel 29, and the gear ratio drive which obtains through the gear box 44 are such that precisely at the time that one of the cradles 20 arrives at the transfer station T, a tray 18 arrives at this station to transfer its brick to the subjacent cradle 20.
  • the trays 18 arrive at the transfer station T in a closed condition, while the cradles 20 arrive at the transfer station in an open condition.
  • interengaging means on the trays 18 and the cradles 20 become effective to cause the trays 18 to become open so that the latter discharge their bricks by gravity into the cradles 20.
  • interengaging means on the cradles 20 and a fixed portion of the drum framework become eflective to close the cradles upon the deposited bricks in order thus securely to clamp the bricks and conduct them in succession to the grinding station where they are rigidly held during passage thereof between the two spaced apart grinding wheels 25.
  • each of the brick transporting trays 18 involves in its general organization a crosshead 100 from which there projects laterally from one side thereof a central spindle 102. From the other side of the crosshead 100, there project laterally two spaced apart jaw-supporting spindles 104 and 106 and they carry opposed brick-confining jaws 108 and 110, respectively.
  • the two opposed jaws 108 and 110 depend from the spindles 104 and 106 and are movable back and forth between the open position in which they are shown in dotted lines in FIG. 10 and the closed full-line position thereof.
  • each jaw carries a shelf-like tray section 112 including a bottom wall 114, a side wall 116, and an end wall 118.
  • the bottom walls 114 of the tray sections 112 are adapted to underlie the side edges of a brick which is supported within the tray 18 with the brick being supported by gravity upon such bottom walls and with the end walls 118 abutting or at least in register with the trailing end wall of the brick.
  • the two tray sections 112 clear the lower side edges of the brick so that the latter. may fall by gravity from the tray and be thus transferred to a cooperating cradle at the transfer station T in a manner that will be made clear presently.
  • each tray 18 Normally, the jaws 108 and 110 of each tray 18 are yieldingly maintained in their open position by a helical tension spring 120, the ends of which are connected by links 122 to upstanding lugs or extensions 124 on the two opposed jaws 108 and 110.
  • a horizontally extending limit stop bar 126 is secured to the crosshead and has its ends designed for engagement with additional extensions 128 on the two jaws. The bar 126 and the extensions 128 coact to determine the fully open position of the two jaws.
  • Meansyare provided for releasably latching the jaws 108 and of each tray 18 in their closed position, such means comprising a pair of inwardly extending oppositely directed latch arms 130 and 132 on the jaws 108 and 110, respectively.
  • the latch arm 130 is pivoted as at 131 to the jaw 108 and is formed with a hook portion 134 which is designed for latching engagement with a horizontally and laterally extending latch pin 136 on the latch arm 132 when the jaws are in their closed position.
  • a depending guide shoe 138 is formed on the latch arm 130 and has a guide surface 140 which is designed for engagement with the latch pin 136 and serves to guide the same into the hook portion 134 during closing movement of the two jaws 108 and 110.
  • toggle links 142 In order to stabilize the movements of the two jaws 108 and 110 of each tray so that when the jaws are in their closed position, the bricks that are carried thereby will be centered beneath the crosshead 100, two substantially horizontal toggle links 142 are provided.
  • the toggle links extend outwards in opposite directions and have their outer ends pivotally connected to short extensions or lugs 143 on the jaws 108 and 110, respectively.
  • the inner ends of the toggle links are pivotally connected to the.
  • the toggle links 142 are of equal efiective length and serve to equalize the movements of the two jaws 108 and 110 during opening and closing thereof.
  • the guide shoe 138 is adapted to be engaged by a cooperating trip finger 148 in associated relation with one of the cradles 20 at such time as the tray 18 arrives at the transfer station T so that the tray will assume its open position and discharge the brick carried thereby to the cooperating or underlying cradle 20, all in a manner that will be made clear when the nature of the drum 14 and its associated brick-conveying cradles 20 is better understood.
  • each tray 18 carry on their outer side portions individual rollers 150, the latter being rotatably supported in brackets 152 which are suitably secured to the jaws and project outwards therefrom.
  • the rollers are designed for camming engagement with two converging rail sections 154 which are suitably supported on a fixed base 155 (see FIG. 1) adjacent to the receiving station R.
  • the grinding machine proper 12 includes the drum 14, the centering device 24, and the grinding stand 26.
  • the drum 14, as previously stated, is generally of cylindrical or disc-like design and is supported upon the horizontal shaft 38 which is rotatably mounted in the bearings 40 on the masonry base 36. It comprises a pair of spaced apart generally circular side plates 200 having formed therein access opening 202 which are normally closed by means of removable cover plates 204 (see FIG. 6).
  • a cylindrical peripheral wall 201 extends between the two side plates 200.
  • An annular series of radial gusset webs 206 in the central region of each side plate 200 serves to reinforce and strengthen the side plate.
  • the various articulated brickreceiving and transporting cradles 20 are mounted on the periphery of the drum 14 at equally and circumferentially spaced regions therearound, eight such cradles being disclosed in the illustrated form of the invention, although it will be understood that a greater or lesser number of such cradles may be employed if desired. Articulation of these cradles is effected under the control of an hydraulic system which subsequently will be described and the details of which are illustrated in FIG. 8.
  • this hydraulic system includes a series of eight piston and cylinder assemblies 210, one for each cradle, a series of eight directional control valves 212, one for each piston and cylinder assembly, and a series of eight high pressure accumulators 214, one for each piston and cylinder assembly.
  • An additional low pressure accumulator 216 is also included in the aforementioned hydraulic system and the function of such accumulator will be made clear presently. All of these hydraulic instrumentalities, together with the piping and other fluid connections therefor, are operatively installed on the drum and assume positions within the space existing between the two side plates 200.
  • each cradle 20 involves in its general organization two side plates 220 which straddle the drum and are connected by bolts 222 to the drum side plates 200.
  • the two side plates 220 of each cradle are identical and the leading end regions thereof are formed with fixed substantially radially extending fingers 224, the outer ends of which have pivoted thereto spider-like jaw elements I225.
  • Each jaw element is provided with a pair of outwardly divergent members at the outer ends thereof having resilient brick-engaging clamping strips 226?. So far :as each cradle 20 is concerned, the jaw elements 225, together with the radially extending fingers 224, constitute, in effect, a fixed composite reaction jaw 227 that is designed for engagement with the leading region of a brick in the cradle.
  • the outer edges 22% of the side plates 220 of each cradle are linearly straight and constitute, in effect, a cradle bottom on which a brick, such as the brick shown at B in FIG. 7, is adapted to be supported with the brick bridging the distance between the two side plates and overhanging the latter at the sides thereof.
  • Each cradle also comprises a composite movable jaw 260 in the form of two side arms 232, the inner ends of which are pivoted on a pin 234.
  • the latter extends between the side plates 226 and supportsthe movable jaws 230 so that it is capable of swinging movement toward and away from the fixed jaw 227 between open and closed positions as shown in full and dotted lines respectively in FIG. 6.
  • the outer ends of the side arms 232 are provided with pivoted jaw elements 235 which are substantially indentical with the jaw elements 225.
  • each movable cradle jaw 230 The inner ends of the side arms 232 of each movable cradle jaw 230 are provided with extensions 236 the distal ends of which are provided with longitudinally extending slots 238. These extensions 236 constitute actuating levers for each movable jaw 230 and the slots 23S receive therein horizontally extending pins 240 which are connected to and extend outwards from the distal ends of a pair of arms 242.
  • a crank arm 246 has one end thereof fixedly secured to each rock shaft 244.
  • the other ends of the crank arms 246 are pivotally connected to plungers 248 which are fixedly connected to the pistons of the piston and cylinder assemblies 210.
  • the cylinder 250 of each piston and cylinder assembly 216 is pivot-ally connected at one end thereof to the drum 14- by means of a horizontally extending cross shaft 252 which extends between the two
  • a fixed source 300 of fluid under pressure communicates through leadout and return lines 302 and 304 with first and second pressure chambers 306 and 308, respectively.
  • These pressure chambers are in the form of relatively deep sockets which are formed in the ends of the rotary drum-supporting shaft 38.
  • the connections between the lines 302 and .304 and the pressure chambers 306 and 308 are effected by means of suitable rotary mechanical seals 310.
  • a local hydraulic control circuit is provided for each of the eight cradles 24 one of the eight circuits being schematically illustrated in FIG. 8.
  • This circuit extends from the pressure chamber 306 through a fluid line 312 to one of the directional control valves 212 through the inlet port 314 thereof.
  • This valve 212 is in the form of a three-way directional valve in which the movable valve element 316 thereof is capable of selectively assuming three different positions under the control of an actuating finger 318. These three positions are labelled 1, 2 and 3 in FIG.
  • the common port 320 is connected through a line 324 to one end of one of the cylinders 250 of one of the piston and cylinder assemblies 219.
  • the other end of the cylinder 250 is connected through a branch fluid line 626 to a distribution manifold 328.
  • the fluid line 324 is connected through a three-way fitting or T 329 to one of the pressure accumulators 214.
  • the distribution manifold 328 is connected through a single fluid line 334) to the pressure chamber 306 and a pressure regulator 332 is interposed in the line 330.
  • the outlet port 322 of the valve 212 is connected through a fluid line 334 to the pressure chamber 308.
  • the manifold 328 also is connected to the pressure chamber 30-3 through a single fluid line 336 having a pressure regulator 338 interposed therein.
  • the distribution manifold 328 is fed by the single pressure accumulator 216 through a line 340.
  • Hydraulic timing cam controls Referring again to FIG. 5, the various actuating fingers 318 of the eight directional control valves 212, in following their common circular path of movement during rotation of the drum 14 make successive engagement with three circumferentially spaced fixed control cams 350, 352 and 354.
  • These fixed control cams are fixedly mounted on a suitable support (not shown) and are disposed exteriorly of the drum 14 and in the path of movement of the various actuating fingers 318.
  • Said support preferably constitutes a portion of the drum-supporting framework.
  • the cam 351 ⁇ constitutes a cradle-closing cam inasmuch as when one of the actuating fingers 318 engages it, the associated directional control valve 212 is actuated in such a manner as to institute closing movements of its respective or associated articulated cradle 20.
  • This cam is so positioned with respect to the drum that it will be engaged by one of the actuating fingers 318 at approximately the time that its associated open cradle arrives at the transfer station T and receives a brick therein by deposition from one of the trays 13.
  • the cam 352 is so positioned with respect to the drum that it will be engaged by one of the actuating fingers 318 at approximately the time that its associated closed cradle 2t) arrives at the centering station C. Its function at this 1 1 time is to actuate the adjacent directional control valve 212 in such a manner that holding fluid under pressure is applied to the movable jaw 230 of the associated cradle, such holding fluid under pressure being supplied by the associated high-pressure pressure accumulator 214.
  • the cam 354 is a cradle-opening cam and is so positioned with respect to the drum 14 that it will be engaged by one of the actuating fingers 318 at approximately the time that its associated cradle 20 arrives at the discharge station D. Its function is to actuate the adjacent directional valve 212 in such a manner as to institute cradleopening movements to the end that the brick which has been operated upon at the grinding station G and is carried by the cradle 20 will be discharged by gravity onto the discharge conveyor 16.
  • the control cam 350 when engaged by one of the actuating fingers 318, serves to move the movable valve element 316 of the associated directional control valve 212 to its previously described first position, so labelled in FIG. 8.
  • the control cam 352 When engaged by an actuating finger 318, the control cam 352 serves to move the associated movable valve element 316 to its second position.
  • the third control cam 354 When engaged by a finger 318, the third control cam 354 serves to move the valve element 316 to its third position.
  • the centering device 24 is disposed at the centering station C and is provided for the purpose of centering the bricks which have been transferred to the cradles 20 from the trays 18 so that their center lines will lie in the medial plane of the drum 14, and what is more important, so that they will become circumferentially aligned with the medial plane passing between the two grinding wheels 25 at the grinding station G. With the bricks thus centered, the abrasive work performed by the grinding wheels will be equalized and each wheel will remove an approximately equal amount of material from the faces of the bricks on which it operates.
  • the centering device 24 is best illustrated in FIGS. 5 and 12 and the hydraulic control circuit by means of which it is actuated is shown in FIG. 9. Referring now to FIG. 5, the centering device 24 is carried on a laterally projecting shelf 360 which, in turn, is supported from the aforementioned vertical posts 35.
  • the device 24 includes a support in the form of an outer housing or casing 362 which is of rectangular box-like design and within which there is disposed a pair of oppositely disposed coacting pivoted rocker arms 364 and 366 (see FIG. 12).
  • rocker arms are pivoted on spaced apart vertically extending pins 370 and 372,re spectively, in order that they are permitted to swing towards and away from each other under the control of a piston and cylinder assembly 374.
  • the latter comprises a horizontally disposed cylinder 376 which is pivoted at one end to the rocker arm 364, and a plunger 378 which has one end thereof connected to the piston of the assembly 374 and its other end pivoted to the rocker arm 366.
  • the movements of the two rocker arms are equalized by means of a pin and slot connection 380 which exists between laterally extending lugs or extensions 380 and 382 on the rocker arms 364 and 366, respectively.
  • the proximal ends of the rocker arms 364 and 366 have connected thereto jaw extensions 384 and 386 and they carry at their outer ends the previously mentioned centering shoes 22 which oppose each other on opposite sides of the drum 14 and are designed for centering engagement with the adjacent opposite faces of successive bricks passing through the centering station C and carried by the cradles 20.
  • the shoes 22 are provided with resilient lining strips 12 392.
  • a helical tension spring 394 is connected at its ends to the two rocker arms 364 and 366, thus drawing these two arms together to retract the plunger 378 and spread the centering shoes 22 apart so that they assume their fully open position for entry of the successive bricks.
  • Hydraulic control circuit for actuating the centering device 24 Referring now to FIGS.5 and 9, the centering device 24 is operable under the control of a directional reversing valve 400 which is suitably fixedly supported in the path of movement of a series of eight trip cams 402. The lat-.
  • trip cam 402 for each of the cradles 20.
  • Said trip cams 402 are designed for engagement with a pivoted actuating finger 404 in associated relation with the direc-v tional reversing valve 400.
  • the valve 400 is a simple two-way reversing valve in which the movable valve element 406 thereof is capable of assuming first and second positions, labelled, respectively, 1 and 2 in FIG. 9.
  • the movable valve element 406 and the actuating finger 404 are spring-biased to the normal first position wherein fluid under pressure is permitted to flow from a sump 408 through a fluid line 410, a motor-driven pump 412, a line 414, the valve element 406, and a line 416 to one end of the cylinder 376 of the centering device 24 in order to retract the plunger 378 (see FIG. 9) and thus maintain the centering shoes '22 in their spaced apart or open relationship.
  • a fluid line 410 a fluid line 410
  • a motor-driven pump 412 a line 414
  • the valve element 406, and a line 416 to one end of the cylinder 376 of the centering device 24 in order to retract the plunger 378 (see FIG. 9) and thus maintain the centering shoes
  • the movable valve element 406 Upon engagement of the actuating finger 404 of the directional reversing valve 400 by one of the trip cams 402, the movable valve element 406 will be moved to its second position and fluid under pressure will flow from p the sump 408, through the line 410, the pump 412,,the
  • centering shoes 22 serving merely to tap, so to speak
  • the clamping elements on the pivoted jaw elements 225 and 235 of the adjacent cradle allowing such sidewise movement of said adjacent brick so that it will be brought into centered relationship with the medial plane of the drum 14 and into circumferential alignment with the grinding wheels 25 as previously described.
  • the two centering shoes 22 return to their normal widely separated position, thus releasing the adjacent centered brick for passage to the grinding station G.
  • the grinding stand 26 at the grinding station G includes a fixed base support 450, the upper face of which provides an elon gated dovetail guideway 452 within which there is slidably disposed a pair of mounting carriages 454 and 456.
  • the carriage 454 has mounted thereon a bearing support 458 for the horizontal drive shaft 460 of one of the two spaced apart grinding wheels 25, while the carriage 456 has mounted thereon a similar bearing support 462 for the horizontal drive shaft 464 of the other grinding wheel.
  • the carriage 454 further serves to support an electric motor M1 which is operatively connected in driving relationship to the drive shaft 460 by way of a belt 13 and pulley arrangement 466.
  • the other grinding wheel 25 is similarly driven from an electric motor M2 on the carriage 456.
  • the two carriages 454 and 456 are capable of horizontal adjustment toward and away from each other to vary the effective distance between the two grinding wheels 25 and, accordingly, these two carriages are operatively connected together by way of an elongated horizontally extending worm shaft 48% which has its medial portions supported in a bearing block 482 and embodies oppositely threaded end portions 484 and 486. The latter are threadedly received in the bearing supports 458 and 462, respectively.
  • the worm shaft 48% is provided with a hand wheel 490 by means of which it may be manually turned in either direction to vary the distance between the two carriages 454 and 456, and consequently, between the operative working faces of the two grinding wheels 25.
  • the grinding stand 26 is so positioned with respect to the drum 14 that the two grinding wheels 25 are centered with relation to the medial plane of the drum, which is to say,'that the respective and effective grinding planes of the two grinding wheels 25 are equally spaced on opposite sides of the medial plane of the drum.
  • the wheels of the first brick-encountered pair may be constructed to effect a quick coarse grind and the wheels of the second brick-encountered pair may be designed or constructed to produce a fine grind.
  • FIGS. 13 and 14 The operation of the herein described brick grinding apparatus will be facilitated by reference to FIGS. 13 and 14 in conjunction with the other views of the drawings, particularly FIGS. 1 and 5.
  • the disclosure of FIGS. 13 and 14 is purely schematic, little attention to the specific details of the feed conveyor and the drum being given.
  • the positional relationship between the feed conveyor and the grinding machine proper 12 including the drum 14 and the grinding wheels 25 has been illustrated with particular reference to the positional relationship of a representative brick B undergoing treatment in the apparatus, this brick being of enlarged proportions and disposed above its path of travel along the feed conveyor 10. 7
  • an operator such as theoperator O of FIG. 1 will be positioned at the receivingstation R for the purpose of feeding the bricks B, one at a time, to the successive trays 18 passing through this station.
  • the trays 18 having, as previously described, been operated upon by the converging rail sections 154 immediately prior to their entry into the receiving station R, are in their closed condition at the time they arrive at the receiving station in order that the bricks may be placed upon the bottom walls 114 of the tray sections 112 and caused to rest thereon with the bricks being loosely confined between the opposed side walls 116 as best shown in FIG. 10.
  • the exemplary brick B that is shown in triplicate and in enlarged form in FIG. 13 is in the form of a hexahedron of generally rectangular design and has a long dimension or length I, an intermediate length dimension or width w, and a short dimension or height h.
  • the brick B is shown in each of three positions of orientation which it assumes for three successive passes through the apparatus. In the oriented position of the brick shown in this view for the first run, the. brick resents upper and lower side faces a and b, side faces cand d, and end faces e and f.
  • the first pass serving to condition the side faces 0 and d
  • the second pass serv- 14 ing to condition the side faces a and b
  • the third pass serving to condition the end faces 2 and 1.
  • the bricks B will be successively placed by the operator 0 in the trays 18 and with the bottom side faces b resting on the bottom walls 114 of the tray sections 112 and with the end faces e leading the trailing end faces 7 in the direction of movement of the trays from the receiving station R to the transfer station T.
  • the bricks B will progress along the feed reach section 27 of the feed conveyor 10 in the manner indicated in FIGS. 1 and 14 and arrive at the transfer station T in an approximately horizontal position.
  • the associated valve-actuating finger 318 will move into engagement with the fixed control cam 350 (see FIG. 5), thus actuating the associated directional control valve 212 (see FIGS. 6 and 8) in such a manner as to supply fluid under pressure to the associated cylinder 250 and extend the plunger 248 of the associated piston and cylinder assembly 210 in such manner that the associated crank arm 246 is actuated in a direction to swing the movable jaw member 239 toward the fixed reaction jaw 227 and clamp the brick B therebetween.
  • Bricks issuing from the kiln are posssessed of numerous irregularities.
  • the side faces of a brick are non-rectangular; opposite faces are out-of-parallel; adjacent faces are at either obtuse or acuate inclinations; the faces are non-planar; and burrs and other irregularities are present on the various faces of the brick, particularly along the edge regions of the brick.
  • the pivoted spiderlike jaw elements 235 and 225 insure firm gripping of a given brick irrespective of such abnormal shape characteristics.
  • the cradles 20 move toward the centering station C, while at the same time, the trays 18 are swung to an out-of-the-way position by means of the cam rail 68 which is successively engaged by the laterally extending pins 64 on the supporting arms 54.
  • a corresponding trip earn 402 engages the actuating finger 404 of the reversing valve 400 (see FIG. 9) and actuates the valve in such a manner that fluid under pressure is conducted to the cylinder 376 (see also FIG. 12) to extend the plunger 378 and effect closing movements of the two centering shoes 22 in the manner previously described.
  • the centering shoes 22 engage the adjacent opposite faces of the brick and center the brick with respect to the medial plane of the drum 14, thus circumferentially aligning the brick with the two grinding wheels 25 at the grinding station G. As soon as the aforementioned trip cam 402 releases the actuating finger 404, the latter is restored to its normal position and the centering shoes 22 automatically return to their positions of max'unum separation.
  • the thus centered bricks are then conducted past the grinding station G where they pass between the two grinding wheels 25 and have their adjacent opposite faces operated upon by the opposed planar circular surfaces of the grinding wheels. Due to the centering action which is efl'ected immediately prior to arrival of the bricks at the grinding station, the work that is performed by the two grinding wheels will be substantially equalized with neither adjacent brick face presenting an undue amount of grinding wheel overhang suflicient to cause damage to either the grinding wheels or the bricks.
  • the actuating finger 318 of the associated directional control valve 212 has moved out of engagement with the control cam 350 and into engagement with the control cam 352 (see FIG.
  • This latter control cam serves to move the finger 318 in such manner as to shift the movable valve element 316 of said associated valve from its #1 position to its #2 position as labelled in FIG. 8.
  • the pressure accumulator 214 serves to supply holding fluid under pressure to the cylinder 250 as previously described to maintain jaw pressure on the faces of the brick which is disposed within the aforementioned particular cradle 20.
  • This position of the valve element 316 is maintained throughout the remainder of the travel of the brick through the apparatus and until such time as the actuating finger 318 engages the cradle-opening control cam 354 when the cradle is at the discharge station D.
  • each brick B through the grinding station G the opposite side faces c and d of the brick will encounter the opposed inside faces of the two spaced apart grinding wheels 25 as schematically portrayed in FIG. 14 and be rendered smooth, planar and precisely parallel irrespective of any irregularities or lack of parallelism existing in or between the four faces a, b, e and which are engaged by the pivoted spider-like jaw elements 235 and 225.
  • the resilient clamping strips 226 allow the brick to assume a floating condition between the two grinding surfaces, each surface serving as a reaction surface for the other.
  • Each brick, with its two faces c and d thus conditioned, is conducted by cradle 20 from the grinding station G to the discharge station D where the actuating finger 318 of the associated directional valve 212 encounters the fixed control cam 354, thus causing the movable valve element 316 (see FIG. 8) of said associated directional valve 212 to move to its #3 position and effect retraction of the plunger, 248 so as to open the cradle :and release the brick so that it drops onto the upper reach of the endless discharge conveyor 16.
  • the bricks which comprise the first run of bricks and have their side faces 0 and d conditioned in the manner indicated above, may now be returned to the receiving station R where they are again individually and successively loaded upon the trays 18 of the feed conveyor 10 for a second run through the apparatus.
  • the grinding wheels operate upon the faces a and b as schematically shown in FIG. 16.
  • trays having dimensions or shapes which are commensurate with the interchanged dimensions of the bricks will be substituted for the original trays 18..
  • This substitution of trays may readily be accomplished by removing the spindles 102 and their associated original trays from the lower ends of the downwardly extending swinging supporting arms 56 of the feed conveyor 10 and re-applying the spindles of the substitute trays. It may also be necessary to effect substitution of the various cradle 20 on the drum 14 in order to accommodate the differently oriented bricks B. This may readily be accomplished by proper manipulation of the fastening bolts 222. Additionally, the spacing between the two grinding wheels 25 may be altered in the manner previously described to accommodate the different transverse dimension of the bricks during the second run or pass.
  • the substitute cradles employed during the second run of bricks through the apparatus are, in essence and other than shape and dimensions, substantially the same as the original cradles 20 employed during the first run of bricks with the single exception that the pivoted spider-like jaw elements 235 and 225 may be omitted and the leading and trailing faces 0 and d of the bricks clamped directly in the cradles between the jaws 230 and 227, the endfaces of the bricks bearing directly against'the inside edge of the upstanding jaw fingers 224 of the fixed jaws 227,and the jaw side arms 232 of the removable jaws 230.
  • the bricks After the bricks have been subjected to their second 1 run and deposited on the discharge conveyor 16 with their faces a and b accurately ground so that they are precisely parallel and normal to the. previously ground faces o and d, they are returned to the receiving station R for a third run or pass through the apparatus. During this third run of bricks, the bricks will be fed to the trays 18 of the feed conveyor 10 withrthe faces 0 constituting the d and the grinding wheels 25 will operate upon the end faces e and f of the bricks as schematically shown "in FIG. 17.
  • the bricks which are discharged upon the conveyor 16 during the third run of bricks will have all of their six faces not only planar within a high degree of flatness, but these faces will all be truly rectangular with opposite faces beingparallel to each other and with the bricks being devoid of burrs and other irregularities.
  • three of the apparatuses may be arranged in sideby-side or series relation with the receiving station of the second apparatus being positioned adjacent to the discharge station of the first apparatus, and with the re DCving station of the third apparatus being positioned adjacent to the discharge station of the second apparatus.
  • a brick grinding apparatus for conditioning pairs of opposite faces of bricks, in combination, means establishing a receiving station, a transfer station, a grinding station and a discharge station, a feed conveyor having a fixed framework and including a series of brick-supporting trays movable in feed and return relation between the receiving and transfer stations and adapted to receive a succession of bricks at the former station and transfer them to the latter station, a brick-clamping conveyor having a fixed framework and including a series of brickclamping cradles movable in advance and return relation between the transfer and grinding stations and adapted to receive the bricks from the feed coveyor at the transfer station and conduct them to the grinding station, a pair of grinding wheels at the grinding station and having opposed grinding surfaces between which the clamped bricks in the cradles are adapted to pass, each tray including a pair of tray sections movable between closed brick-supporting and open brick-releasing positions, spring means yieldingly urging said tray sections toward their open positions, latch means automatically operable to maintain the tray sections in their closed
  • the combination set forth in claim 1 and wherein said means for tripping the latch means of the trays at the transfer station comprises interengaging latch-tripping fingers on the cradles and trays and movable into engagement with each other as the matched pairs of cradles and trays arrive at the transfer station.
  • each jaw is provided with a shelf-like supporting tray adapted to underlie one edge region of a brick which is positioned in the associated cradle.
  • the combination set 6 In a brick grinding apparatus, the combination set 1'8 forth in claim 1 and wherein said cam means for moving said tray sections to their closed position includes a cam rail on the framework of the feed conveyor and successively engageable with the tray sections during return movement of the trays.
  • said means for tripping the latch means on the trays at the transfer station comprises interengaging latch-tripping fingers on the cradles and trays and movable into engagement with each other as the matched pairs of cradles and trays arrive at the transfer station
  • the means for closing the jaws of the brick-clamping cradles comprise a jaw-actuating linkage connected to each pair of brick-clamping jaws and including an actuating finger
  • a jaw-closing trip'cam fixedly mounted on the framework of the brick-clamping conveyor and positioned in the path of movement of the successive actuating fingers
  • the means for opening the jaws of the brick-clamping cradles comprises a jaw-opening trip cam fixedly mounted on the framework of the brick-clamping conveyor and likewise positioned in the path of movement of the successive actuating fingers.
  • a brick grinding apparatus for conditioning pairs of opposite faces of bricks, in combination, means establishing a transfer station, a grinding station and a discharge station, rotatable grinding wheels at said grinding station and having opposed operative surfaces, a rotatable drum having peripherally spaced cradles movable successively through the transfer station to receive bricks therein, the grinding station to carry the bricks between said opposed operative surfaces of the grinding wheels, and the discharge station to discharge the conditioned bricks thereat, each cradle including a fixed reaction jaw and a movable clamping jaw movable between an open brick-releasing position and a closed brick-clamping position wherein it engages one end face of a brick and forces the opposed end face against the fixed reaction jaw, each fixed and movable jaw including a pivoted jaw element directly engageable with the brick and embodying a pair of diverging yoke arms adapted to straddle an adjacent transverse ege of the brick with one arm bearing against an adjacent face of the brick and the other arm bearing against an adjoining face of
  • each yoke arm includes a resilient friction strip engageable with an adjacent face of the brick.
  • a rotatable drum having peripherally spaced cradles mounted thereon, means establishing a transfer station, a centering station, a grinding station and a discharge station in circumfer entially spaced relation about the drum in the order named,
  • a centering device including a pair of centering jaws at the centering station and movable between an'open position and a closed position wherein the jaws engage the adjacent opposite faces of the bricks to align the bricks with the grinding wheels, a fluid pressure cylinder for actuating said centering jaws, a plurality of cradles on the periphery of said drum and movable in succession repeatedly past said station, each cradle including a fixed reaction jaw and a movable clamping jaw movable between an open brick-releasing position and a closed position wherein it engages a brick and forces the same against the fixed reaction jaw, fluid pressure, means including a first source of fluid under pressure for actuating each movable clarnping jaw to effect closing movement thereof during passage of the associated cradle through the transfer station, to maintain the same closed during passage of the associated cradle through the centering and grinding stations, and to open the same
  • said fluid pressure means for actuating'each movable clamping jaw comprises a pressure cylinder operatively connected to the movable jaw, a pressure accumulator, and a control valve having a control finger movable between first, second and third positions, said control finger when in its first position being effective to connect the fluid pressure device to the first source of'fluid under pressure so as to effect closing of the movable clamping jaw, said pressure accumulator being connected to the pressure cylinder and biasing the latter to effect closing of the movable clamping jaw, said control finger when in its second position being effective to seal off the pressure cylinder from said first source of fluid under pressure and permit the pressure accumulator to become effective, said control finger when in its third position being effective to connect the fluid pressure device to said first source of fluid under pressure so as to effect opening of the movable clamping jaw, and a series of fixed cams positioned in the path of movement of said control finger for moving the latter between the three positions thereof.
  • said second fluid pressure means for effecting momentary closing movement of the centering jaws comprises a pressure cylinder operatively connected to said centering jaws, a fixed reversing valve for the pressure cylinder and having a movable actuating finger movable between a first position wherein the valve is effective to open said centering jaws, and a second position wherein the valve is effective to close said centering jaws, and a pair of finger-engaging cams on said drum successively engageable with said actuating finger for moving the same between said first and second positions.
  • a feed conveyor for transporting the bricks from a receiving station to the transfer station and for releasing the bricks at the transfer station in such similarly oriented positions
  • said feed con v veyor comprising an endless conveyor carrier having feed and return reach sections extending between the receiving station and the transfer station, a series of articulated brick-supporting and transporting trays mounted on said carrier, each tray including a crosshead, a pair of brickengaging jaws pivoted to the crosshead and movable relatively toward and away from each other between closed brick-engaging and open brick-releasing positions, spring means yieldingly urging said jaws toward their open posi-.
  • means operatively connecting said jaws for equalize ing the movements thereof, a fixed latch arm on one of said jaws, and a pivoted latch arm on the other jaw and designed for latching engagement with the fixed latch arm when saidjaws are moved to their closed position for maintaining the jaws in such closed position against the action of said spring means, cam means operable during movement of the trays along said return reach section for effecting sequential closing of the jaws of said trays and consequent latching engagement of the associated latch arms, and means operable upon arrival of each tray at, the transfer station and engageable with the associated 1 pivoted latch arm for moving the latter out of latching engagement with its respective fixed latch arm to effect opening of the associated jaws and consequent release of the brick supported thereby.
  • a brick grinding apparatus for conditioning pairs of end faces of bricks, in combination, means establishing a receiving station, a transfer station, a grinding station and a discharge station, a feed conveyor adapted to receive bricks successively deposited thereon at the receiving station, transport them in similarly oriented positions,
  • a clamping conveyor adapted to receive the released bricks at the transfer station, transport the same through the grinding station to the discharge station and release them at said latter station
  • said feed conveyor comprising an endless carrier having feed and return reach sections extending between the feed and transfer stations and horizontal reversing sections at said feed and transfer stations
  • said clamping conveyor comprising a drum mounted for rotation about a horizontal axis below the reversing section of the feed conveyor at the transfer station whereby the region of closest approach between
  • the two conveyors lies above the drum and constitutes the transfer station
  • a series of suspension arms pivotally mounted on the carrier at spaced points therealong and depending therefrom, an articulated brick-supporting tray carried at the lower end of each suspension arm and movable between closed brick-supporting and open brickreleasing positions, said suspension arms normally depending below the level of the transfer, station so that the cradles supported thereby are normally disposed below such level
  • a fixed cam rail positioned in the path of movement of said suspension arms and engageable therewith for deflecting said arms as they approach the transfer station to raise the level of the trays to that of the transfer station and guide the trays through the transfer station
  • a series of suspension arms pivotally mounted on the carrier at spaced points therealong and depending therefrom
  • an articulated brick-supporting tray carried at the lower end of each suspension arm and movable between closed brick-supporting and open brickreleasing positions, said suspension arms normally depending below the level of the transfer, station so that the cradles supported thereby are normally disposed below such level
  • a fixed grinding stand including a pair of spaced apart grinding wheels presenting opposed parallel grinding surfaces for simultaneously grinding the adjacent opposite faces of successive bricks moving between said surfaces, a rotatable brick-supporting drum for conducting the bricks endwise and successively between said grinding surfaces, and a plurality of brick-supporting and clamping cradles carried on the periphery of said drum and movable past a loading station where the bricks may be applied to the cradles and past a discharge station where the bricks are discharged from the cradles, each cradle comprising a pair of side plates secured to opposite sides of the drum and presenting straight outer edges which extend generally tangentially of the drum and across which edges a brick received Within the cradle is adapted to extend with the end regions of the brick overhanging the same on opposite sides of the drum, the leading ends of said plates being provided with generally radially outwardly projecting extensions constituting a fixed clamping jaw, a yoke pivoted to
  • the combination set forth in claim 18 and including, additionally, a yoke pivoted to the outer end of each clamping jaw, and a pair of anti-friction members mounted on each yoke and designed for clamping engagement with adjacent brick faces, said anti-friction members, when in contact with said brick faces, allowing for lateral shifting of the bricks in the cradles under the influence of grinding pressure on the brick faces being ground.
  • a support a bricksupporting and clamping drum mounted on said support for' rotation about an axis, a motor drivingly connected t6 the drum for rotating the latter, a plurality of brickclamping cradles mounted on the periphery of said drum and movable through a loading station, a centering station, a grinding station and a discharge station successively and in the order named, a pair of brick-clamping jaw-s associated with each cradle and movable between closed brick-clamping and open brick-releasing position, a pressure cylinder operatively connected to each pair of jaws for actuating the same, a control valve for each cylinder, a pressure accumulator for each cylinder, said pressure accumulator being effective to actuate the cylinder so as to maintain said clamping jaws closed, said control valve being effective in a first position to actuate the cylinder so as to effect jaw-closing movements, in a second position to close off said cylinder and allow said pressure accumulator to
  • a support a bricksupporting and clamping drum mounted on said support for rotation about a horizontal axis, a motor drivingly connected to the drum for rotating the latter, a plurality of brick-clamping cradles mounted on the periphery of the drum and movable through a loading station, a centering station, a grinding station and a discharge station in the order named, a pair of brick-clamping jaws associated with each cradle and movable between closed brick-clamping and open brick-releasing positions, fluid pressure means effective to cause closing movements of the jaws as the associated cradles move through the loading station and to cause opening movements of the jaws as the associated cradles move through the discharge station, a pair of centering shoes on opposite sides of the drum at the centering station and movable toward and away from each other in unison between retracted inoperative and advanced operative positions and effective, when in their operative position to engage the side faces of a brick passing through the centering station to align the same with
  • valve actuator is yieldingly biased to a position wherein said centering shoes are in their inoperative retracted position, and wherein said control cams on the drum are in the form of trip fingers for momentarily engaging the actuator in passing.
  • control valve operatively connected to the source of, fluid tering shoes are retracted and in a second position to move the rocker arms to positions wherein said centering shoes are advanced, a valve actuator for controlling the positions of said valve, and a series of control cams mounted on the drum, movable bodily with the drum, and engageable with said valve actuator in succession to cause advance movement of the centering shoes during movement of the cradles through the centering station.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Ceramic Engineering (AREA)
  • Inorganic Chemistry (AREA)
  • Mining & Mineral Resources (AREA)
  • Grinding Of Cylindrical And Plane Surfaces (AREA)
  • Devices For Post-Treatments, Processing, Supply, Discharge, And Other Processes (AREA)
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US346339A 1964-02-20 1964-02-20 Apparatus for grinding bricks or the like Expired - Lifetime US3292310A (en)

Priority Applications (11)

Application Number Priority Date Filing Date Title
US346339A US3292310A (en) 1964-02-20 1964-02-20 Apparatus for grinding bricks or the like
FR4726A FR1433414A (fr) 1964-02-20 1965-02-08 Machine à rectifier les briques
CH172065A CH427548A (fr) 1964-02-20 1965-02-09 Machine à rectifier les briques
BE659451D BE659451A (es) 1964-02-20 1965-02-09
AT128065A AT258752B (de) 1964-02-20 1965-02-12 Ziegelschleifvorrichtung
GB6748/65A GB1067604A (en) 1964-02-20 1965-02-17 Improvements relating to apparatus for grinding bricks
DE1965I0027523 DE1502456A1 (de) 1964-02-20 1965-02-17 Vorrichtung zum Schleifen von Ziegeln od.dgl.
NO156815A NO119899B (es) 1964-02-20 1965-02-17
DK88465AA DK108956C (da) 1964-02-20 1965-02-19 Murstensslibeapparat.
NL6502089A NL6502089A (es) 1964-02-20 1965-02-19
ES309951A ES309951A1 (es) 1964-02-20 1965-02-20 Instalacion para rectificar ladrillos y similares.

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US346339A US3292310A (en) 1964-02-20 1964-02-20 Apparatus for grinding bricks or the like

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US3292310A true US3292310A (en) 1966-12-20

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AT (1) AT258752B (es)
BE (1) BE659451A (es)
CH (1) CH427548A (es)
DE (1) DE1502456A1 (es)
DK (1) DK108956C (es)
ES (1) ES309951A1 (es)
FR (1) FR1433414A (es)
GB (1) GB1067604A (es)
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Cited By (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3410259A (en) * 1965-09-14 1968-11-12 Skirvin Walter Brick cleaning device
US4121387A (en) * 1975-03-12 1978-10-24 Badische Maschinenfabrik G.M.B.H. Blasting machine
US4256078A (en) * 1979-11-13 1981-03-17 The R. T. French Co. Brick finishing machine
US4660539A (en) * 1985-06-04 1987-04-28 Battaglia Gino C Method and apparatus for cutting and polishing marble slabs
NL9001552A (nl) * 1990-07-06 1992-02-03 Staal En Machinebouw Aberson B Inrichting voor het transport van baksteenvormen.
US5115599A (en) * 1989-08-26 1992-05-26 Keuro Maschinenbau Gmbh & Co. Kg Apparatus for removal of workpiece elements, particularly bolt, rod or disk-shaped elements, from a cutting apparatus
US20030079586A1 (en) * 2001-10-25 2003-05-01 John Zukley Brick recycling method and apparatus
US6736127B2 (en) * 2002-01-31 2004-05-18 Joseph M. Steckling Inline pitching system
EP1570935A1 (en) * 2004-03-05 2005-09-07 VAN AELST, Filip Method and device for sawing slices of natural stone
US20060037267A1 (en) * 2004-08-05 2006-02-23 Taylor Charles D Jr Simulated granite
CN104290000A (zh) * 2014-09-26 2015-01-21 浙江海洋学院 一种汽车加油口盖板修整机
CN107443353A (zh) * 2016-05-30 2017-12-08 洛阳海特智能科技有限公司 一种砌墙机器人及其工作方法
CN109605206A (zh) * 2018-12-29 2019-04-12 慈兴集团有限公司 一种外径定位的轴承内圈超精研装置以及方法
US10301121B1 (en) * 2017-07-20 2019-05-28 Amazon Technologies, Inc. System having a carousel of buckets configured to induct inventory items into packaging
CN110524253A (zh) * 2019-08-23 2019-12-03 宝鸡保德利电气设备有限责任公司 高铁接触网铝合金零部件自动化打磨设备
CN112045519A (zh) * 2020-07-31 2020-12-08 山东高强紧固件有限公司 一种螺栓螺纹处理设备
CN112658902A (zh) * 2021-01-25 2021-04-16 漆桂龙 一种新能源汽车加工用减振器表面打磨装置
CN113120592A (zh) * 2021-04-19 2021-07-16 仪征海天铝业有限公司 一种翅片管回收装置
CN113319667A (zh) * 2021-05-27 2021-08-31 诸暨市金科弹簧科技有限公司 一种弹簧端面磨床
CN118683910A (zh) * 2024-08-23 2024-09-24 四川省怀德建设工程有限公司 一种建筑施工用物料输送装置

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AT400828B (de) * 1993-12-30 1996-03-25 Kamas Maschinen Und Stahlbau G Verfahren und anlage zur herstellung keramischer ziegel mit hoher massgenauigkeit
DE4436148C1 (de) * 1994-10-11 1996-07-04 Keller Gmbh Verfahren und Vorrichtung zum seitlichen Planieren von Ziegelformlingen und/oder Ziegeln
DE19601723A1 (de) * 1996-01-18 1997-07-24 Klinkerwerk Hagemeister Gmbh & Pflaster- oder Verblendstein und Verfahren zum Herstellen eines solchen Steines
WO2018009981A1 (en) 2016-07-15 2018-01-18 Fastbrick Ip Pty Ltd Brick/block laying machine incorporated in a vehicle
US10865578B2 (en) 2016-07-15 2020-12-15 Fastbrick Ip Pty Ltd Boom for material transport
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CN108422574A (zh) * 2018-05-11 2018-08-21 广西钟山县天顺石材有限公司 一种板材切割的定位装置
CN111113239A (zh) * 2020-01-08 2020-05-08 佛山瑞萨纳建材有限公司 一种抛光机
CN113333611B (zh) * 2021-06-19 2022-09-23 芜湖常瑞汽车部件有限公司 一种汽车部件生产线输送流转装置
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US1166647A (en) * 1907-11-05 1916-01-04 Huntley Mfg Company Corn-husking machine.
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Cited By (23)

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Publication number Priority date Publication date Assignee Title
US3410259A (en) * 1965-09-14 1968-11-12 Skirvin Walter Brick cleaning device
US4121387A (en) * 1975-03-12 1978-10-24 Badische Maschinenfabrik G.M.B.H. Blasting machine
US4256078A (en) * 1979-11-13 1981-03-17 The R. T. French Co. Brick finishing machine
US4660539A (en) * 1985-06-04 1987-04-28 Battaglia Gino C Method and apparatus for cutting and polishing marble slabs
US5115599A (en) * 1989-08-26 1992-05-26 Keuro Maschinenbau Gmbh & Co. Kg Apparatus for removal of workpiece elements, particularly bolt, rod or disk-shaped elements, from a cutting apparatus
NL9001552A (nl) * 1990-07-06 1992-02-03 Staal En Machinebouw Aberson B Inrichting voor het transport van baksteenvormen.
US20030079586A1 (en) * 2001-10-25 2003-05-01 John Zukley Brick recycling method and apparatus
US6736127B2 (en) * 2002-01-31 2004-05-18 Joseph M. Steckling Inline pitching system
BE1016281A3 (nl) * 2004-03-05 2006-07-04 Aelst Filip Van Werkwijze en inrichting voor het in schijven zagen van blokken natuursteen.
EP1570935A1 (en) * 2004-03-05 2005-09-07 VAN AELST, Filip Method and device for sawing slices of natural stone
US20060037267A1 (en) * 2004-08-05 2006-02-23 Taylor Charles D Jr Simulated granite
CN104290000A (zh) * 2014-09-26 2015-01-21 浙江海洋学院 一种汽车加油口盖板修整机
CN107443353A (zh) * 2016-05-30 2017-12-08 洛阳海特智能科技有限公司 一种砌墙机器人及其工作方法
US10301121B1 (en) * 2017-07-20 2019-05-28 Amazon Technologies, Inc. System having a carousel of buckets configured to induct inventory items into packaging
CN109605206A (zh) * 2018-12-29 2019-04-12 慈兴集团有限公司 一种外径定位的轴承内圈超精研装置以及方法
CN110524253A (zh) * 2019-08-23 2019-12-03 宝鸡保德利电气设备有限责任公司 高铁接触网铝合金零部件自动化打磨设备
CN110524253B (zh) * 2019-08-23 2024-05-10 宝鸡保德利电气设备有限责任公司 高铁接触网铝合金零部件自动化打磨设备
CN112045519A (zh) * 2020-07-31 2020-12-08 山东高强紧固件有限公司 一种螺栓螺纹处理设备
CN112658902A (zh) * 2021-01-25 2021-04-16 漆桂龙 一种新能源汽车加工用减振器表面打磨装置
CN112658902B (zh) * 2021-01-25 2023-06-23 广东顺德川崎汽车零部件有限公司 一种新能源汽车加工用减振器表面打磨装置
CN113120592A (zh) * 2021-04-19 2021-07-16 仪征海天铝业有限公司 一种翅片管回收装置
CN113319667A (zh) * 2021-05-27 2021-08-31 诸暨市金科弹簧科技有限公司 一种弹簧端面磨床
CN118683910A (zh) * 2024-08-23 2024-09-24 四川省怀德建设工程有限公司 一种建筑施工用物料输送装置

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Publication number Publication date
GB1067604A (en) 1967-05-03
DE1502456A1 (de) 1969-04-10
ES309951A1 (es) 1965-11-16
NL6502089A (es) 1965-08-23
DK108956C (da) 1968-02-26
BE659451A (es) 1965-08-09
CH427548A (fr) 1966-12-31
AT258752B (de) 1967-12-11
NO119899B (es) 1970-07-20
FR1433414A (fr) 1966-04-01

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