US3755521A - Method of making brick panels - Google Patents

Method of making brick panels Download PDF

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US3755521A
US3755521A US00753500A US3755521DA US3755521A US 3755521 A US3755521 A US 3755521A US 00753500 A US00753500 A US 00753500A US 3755521D A US3755521D A US 3755521DA US 3755521 A US3755521 A US 3755521A
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concrete
track
brick
bricks
head plate
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US00753500A
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J Young
G Whitney
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    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04CSTRUCTURAL ELEMENTS; BUILDING MATERIALS
    • E04C2/00Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels
    • E04C2/02Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by specified materials
    • E04C2/04Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by specified materials of concrete or other stone-like material; of asbestos cement; of cement and other mineral fibres
    • E04C2/041Building elements of relatively thin form for the construction of parts of buildings, e.g. sheet materials, slabs, or panels characterised by specified materials of concrete or other stone-like material; of asbestos cement; of cement and other mineral fibres composed of a number of smaller elements, e.g. bricks, also combined with a slab of hardenable material
    • E04C2/042Apparatus for handling the smaller elements or the hardenable material; bricklaying machines for prefabricated panels
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B28WORKING CEMENT, CLAY, OR STONE
    • B28BSHAPING CLAY OR OTHER CERAMIC COMPOSITIONS; SHAPING SLAG; SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL, e.g. PLASTER
    • B28B19/00Machines or methods for applying the material to surfaces to form a permanent layer thereon
    • B28B19/0053Machines or methods for applying the material to surfaces to form a permanent layer thereon to tiles, bricks or the like

Definitions

  • a method of manufacturing a brick panel includes the steps of forming a bed of concrete, arranging the bricks in a plurality of rows, moving the rows of bricks over the exposed surface of the bed of material, sequentially depositing the rows of bricks in the bed of concrete, and sequentially partially embedding the rows of bricks in the surface of the concrete, as by vibratory blows.
  • the present invention relates to a method for making masonry or concrete structures, particularly faced wall structures.
  • the object of the present invention to provide a method providing a precast panel with a surface having the appearance of laid brick.
  • the present invention provides a method for embedding or implanting objects, such as rows of bricks; in the exposed surface of a'bed of cementitious material, such as wet concrete, so as to provide, upon curing of the concrete, a panel with a surface having the appear ance of laid brick.
  • the bed of material is formedin aforrn or other receptacle.
  • a surfacing machine, movable along the form is positioned over the form.
  • the machine includes a frame having .a support means mounted inside an endless'belt or track having a plurality of track sections for receiving the rowsof brick.
  • the track iscarried by the support means for movement in an orbital path with respect to the frame.
  • the support means positionsa portion of the track adjacent the exposed surface of the bed of material from which portion the bricks maybe deposited in the surface.
  • a driving means mounted'on the frame,ifmo vesj'the frame along the form and moves the track in its orbital path to add new, brick laden track sections to the portion of the track adjacent the exposed surface of the concrete and remove the empty sections from that portion, so that the deposition of rows of brick continues as the machine moves along the form.
  • a means to assist the embedment of the brick in the surface of the material, such as a vibrating means, may be provided on the frame.
  • the method of forming a panel with embedded objects in the surface thereof commences with the forming of the bed of material in the form. If desired, collapsible cores may be inserted in the material to reduce the weight of the complete panel. The material is struck off in the form to provide the exposed surface.
  • a plurality of objects are then deposited on the surface of the material and embedded therein, as by operation of the surfacing machine.
  • the spaces between the embedded objects may be filled with mortar and the material cured to form the completed panel.
  • FIG. 1 is a perspective view of a surfacing apparatus
  • FIG. 2 is a longitudinal cross sectional view of the apparatus of FIG. 1 showing the deposition of the objects in the exposed surface of the material;
  • FIG. 3 is a lateral cross sectional view of the apparatus of FIG. 1 taken along the line 33 of FIG. 2;
  • FIG. 4 is a partial, lateral cross sectional view of the surfacing apparatus, similar to FIG. 3, but showing the embedment of the objects in the surface of the material;
  • FIG. 5 is a detailed, partial, lateral cross sectional view showing a means for coupling the surfacing machine to the material form;
  • FIG. 6 is a partial longitudinal cross sectional view showing the details of the endless track of the surfacing machine and the rotary support means therefor;
  • FIG. 7 is a partial perspective view of the means for embedding the objects in the exposed surface of the material
  • FIG. 8 is a somewhat schematic and diagrammatic view of the means for embedding the objects in the exposed surface of the material and of a control system therefor;
  • FIG. 9 is a detailed view of a track section forming a portion of the endless track of the surfacing machine.
  • FIG. 10 is a perspecive view of a portion of the means for embedding the objects in the surface of the material.
  • FIG. 11 is a perspective view of a completed panel of cementitious material having a plurality of objects embedded in an exposed surface thereof, such as may be provided by the method of the present invention
  • FIG. 12 is a perspective view of a retaining means incorporated in the surfacing machinev for retaining the objects in the endless track until deposition in the material.
  • FIGk 1' shows a panel? which may be formed by the method or the present invention-
  • the panel includes a substratum of "concrete C or otherceihentitous material on an exposed surface of which is embedded a' plurality of objects, suchas -br'icks -B.”
  • Panel"P may' contain brackets BR for attaching the panel to the steel framework of the building.
  • the bricks B are embedded in the concrete C in a pattern such" that the exposed surface of th'e finished panel resembles laid brick having a desired 1 bond configuration, such as stretcher, header, common, or English bond. In all such bond patterns, the bricks are generally positioned in aplurality of horizontal rows, termed courses.
  • FIG. 11 show's',forsimplicity, a bond configuration in which the bricks are arranged in a plurality of vertical rows, termed stacks.
  • any of the generally available types of brick such as common brick, pressed brick, or glazed brick, may be used in panel P.
  • the drawing accompanying the specification shows, in an exemplary manner, pressed brick having a plurality of holes extendinng therethrough parallel to the finished faces of the brick.
  • the concrete form The apparatus includes a surfacing machine 20 coupled to, or mounted on a form 22, as shown in FIG. 1.
  • Form 22 may be an elongated or longitudinally extending U- shaped trough having a bottom plate 24 and a pair of laterally spaced parallel vertical sidewalls 26 and 28.
  • the ends of form 22 may be closed by bulkhead 29 which are adjustably positioned along the length of form 22 to provide a finished panel P of the desired length.
  • a plurality of collapsible cores 30 extend down the length of form 22 and through the bulkheads. As shown in FIG. 3, each of the cores 30 includes a bottom plate 32 and a top plate 34 having curved longitudinal edges extending toward each other. Top plate 34 and bottom plate 32 may be retained for limited movement toward and away from each other by slotted straps 33 linked by bolts 35, as shown in FIG. 3.
  • the core also includes side plates 36 and 38 which are positioned to abut the top and bottom plates near their edges.
  • the position of side plates 36 and 38 is adjustable by turnbuckle 40 or other means.
  • the plates comprising cores 30 are generally constructed from a heavy material, such as iron or steel, to offset any tendency of the cores to float as concrete is poured into form 22 and around cores 30.
  • mp plate 34 and botton plate 32 are forced apart to the. limits ofv braces 33 to form a rigid structure around which concrete may be poured.
  • top and bottom plates 34 and 32 By moving side plates 36 and 38 inwardly, away from the curved edges of top and bottom plates 34 and 32 the latter plates may be moved toward each other to collapse the core andallow its removal from. the hardened concrete in form 22.
  • the holes in the panel -P formed by cores 30 lighten the-panel and permitelectric wires,-
  • the upper surfaces of parallel, vertical sidewalls 26 and '28 of form 22 contain a plurality of projections 42 spaced along the length of the Wall which are used to couple the surfacing machine 20 to the form to form the surfacing apparatus. As shown in FIG. 5, each of these projections may comprise a bolt 44 or other means attached to the form. As hereinafter described, projections 42 serve to position surfacing machine 20 with respect to "the exposed surface of the wet concrete C in form 22.
  • the surfacing machine 20 includes a frame, portions of which are, mounted inside an endless belt or track which moves in an orbital path with respect to the frame. Means are provided for mounting the frame on the form and over the bed of material, as by an engagement of a portion of the track with projections 42 on the form.
  • the entire surfacing machine 20 moves forward in an longitudinal path along the form while, at the same time, the track moves in an orbital path with respect to the frame, resulting in a laying down of additional portions of the endless track on the form at the front of the machine and a picking up of corresponding portions off the form at the rear of the machine, in the manner of a tracked vehicle. It is important to the understanding of the apparatus of the present invention to realize that, while the machine moves forward along the form as described above, the portion of the track engaging the form remains stationary with respect to the form in the position in which it is laid down, until it is picked up. The machine, and particularly the frame portions thereof, thus move forward with respect to the portion of the track in engagement with the form, or conversely, this portion of the track moves rearwardly with respect to the frame.
  • Frame 50 constructed of steel channel members.
  • Frame 50 may be generally rectangular in shape having a pair of longitudinal members 52 and 54 lying parallel to, and adjacent, vertical sidewalls 26 and 28 of form 22, a forward lateral member 56, and a rear lateral member 58 connecting the lognitudinal members.
  • a pair of laterally extending axles 60 and 62 are journalled at longitudinally spaced positions on longitudinal members 52 and 54 by bushings 64 and 66 and 68 and 70. See FIGS. 1 and 2.
  • Each of the axles supports a rotary support means in the form of a drum or plurality of separate discs. The latter configuration is shown in FIGS 1, 2 and 3, wherein each axle has a disc aflixed thereto, adjacent the bushing.
  • Axle 60 supports discs 72 and 74 while axle 62 supports discs 76 and 78.
  • the periphery of the discs may be covered with rubber belt 80 or other non-slip material, as shown in FIG. 6.
  • An endless track or belt 82 is rotatably mounted on discs 72 and 74 and 76 and 78 so that the discs are on the inside or within track 82.
  • the longitudinal spacing of axles 60 and 62, and the discs supported thereby, causes track 82 to assume a generally oval or elliptical shape, as shown in FIG. 2, having forward and rear portions abutting the discs and a lower flattened portion extending between the two sets of discs adjacent the exposed surface of the concrete C in concrete form 22.
  • the track 82 may also have an upper flattened portion extending bet-ween the tops of the two sets of discs parallel to the lower flattened portion.
  • Track 82 is comprised of a plurality of hinged track sections 84 shown in detail in FIG. 9 and in longitudinal cross section i FIG. 6.
  • Track section 84 includes a lattice having 'a plurality of compartments 85, sized to receive bricks B.
  • the lattice of each track section may include a compartment for one or more courses or rows of bricks B in the finished panel P, the track section shown in FIG. 9 having suflicient compartments for three courses of bricks, six bricks wide.
  • the strip like members forming the compartments 85 of track section 84 also serve to separate adjacent bricks and thus form the bed joints and head jointsin the completed panel.
  • the longitudinal. dimension of the compartments 85 and track sections 84 is that parallel to longitudinal frame members 52 and 54 and the lateral dimension runs parallel to forward and rear lateral frame members-56 and 58.
  • Each track section 84 includes an end plate 86 at either side thereof having an outwardly extending flange 88, the outer portion of which engages discs 72 and 74 and 76 and 78 so as to mount track 82 on the discs.
  • the end plates are joined by marginal lateral members 90 and 92, termed half bed joint dividers which may be welded, bolted, or otherwise secured to end plates 86.
  • the half bed joint divided 92 which is nearest forward lateral frame member 56 when the track section is in the lower flattened portion of track 82, is shorter in height than the half bed joint divider 90 which is nearest rear lateral frame member 56, so as to prevent tipping or cocking of the brick embedded in concrete C as the track section moves from the lowerportion of track'82 to the rear portion thereof.
  • End plates 86 are also joined by a plurality of full bed joint dividers 94 which extend laterally between the end plates intermediate the half bed joint dividers.
  • the half bed joint dividers are joined by a plurality of longitudinal head joint plates 96 which extend between the half bed joint dividers 90 and 92 intermediate end plates 86 to form the lattice of the track section.
  • the interception of the full bed joint dividers 94 and the head joint plates 96 may be effected by cutting away half of each member and joining the members in the manner of an egg crate divider, or by other means.
  • a plurality of pins 266 are aflixed to flange 88 on one side of track section 84 and extend outwardly therefrom.
  • One such pin located in the center of the compartment, is provided for each row or course of compartments 85 of track section 84 so that in the track section shown in FIG. 9, three pins are provided on each flange. These pins are used to control the operation of surfacing machine 20.
  • half'bed joint divider 90, full bed joint dividers 94 and head joint plates 96 depends on the size of brick B used in the construction of panel P and the position of the lower flattened portion with respect to the exposed surface of wet concrete and may be equal, greater, or less than, the height of brick B.
  • the bricks may be deposited in the concrete in any desired manner so that the surface of the finished panel resembles a desired bond configuration. It will be appreciated that as the bond of the brick B is not needed for the structural integrity of panel P, numerous artistic or decorative patterns, not normally available in brick construction, may be provided.
  • Track sections 84 are linked together at either side by hinges 98, shown in detail in FIG. 6, to form track 82.
  • Hinge plates 100 forming the hinges are attached to the inner edges of end plates 86, which may be recessed to receive the hinge plates.
  • a hinge pin 102 is inserted through hinge plates 100.
  • the hinge plates 100 are formed so that the center of hinge pin 102 is in alignment with, or positioned slightly below, the bottom of end plates 86 as shown in FIG. 6.
  • eachtrack section 84 contains a depression or hole 89in the flange 88 that engages projections 42 on the upper edges of vertical sidewalls 26 and .28 to form 22 when the track section is located in the lower flattened portion of the track, as shown in FIG. 5.
  • the holes 89 in adjacent track sections 84 and projections 42 are spaced equal distances apart for this purpose.
  • the discs, such as disc 78, rest on flanges 88 so as to support frame 50 and the remainder of surfacing machine 20.
  • the discs may rest on flanges 88 directly over holes 89 and projections 42 so as to eliminate any bending moment on the flange, as shown in FIG.. 5.
  • the engagement of projections 42 in holes 89 serves to accurately locate surfacing machine 20 in the desired vertical and horizontal-position with respect to form 22 and the exposed surface of the concrete lying therein.
  • the weight of surfacing machine 20 is transferred to projections 42 by the abutment of discs 72 through 78 on flanges 88, as shown in FIGS. 3 and 5.
  • a pair of casters one of which is indicated by the numeral 169 in FIG. 1, and bearing on the upper edge of sidewall 26, may be provided on transverse member 58 to lessen the weight of surfacing machine 20 applied to the track sections by discs 76 and 78, so as to assist the track sections 84 in turning up and around discs 72 and 74.
  • Casters 171 may be provided at the front of surfacing machine 20 for the same purpose.
  • the engagement of projections 42 in hole 89 also aids in the movement of surfacing machine 20 along form 22 in a manner hereinafter described.
  • a retaining means includes a plate 104 lying beneath the upper flattened portion of track 82 to prevent the brick from falling through the compartments of track sections 84.
  • Plate 104 is mounted on frame 52 by supports 106 fastened to the frame. The plate extends arcuately downward at the forward end of surfacing machine 20 to approximately the horizontal radii of discs 72 and 74 so as to prevent the bricks from falling through the track sections until they have attained a vertical position.
  • the retaining means of surfacing machine 20 also keeps the bricks from falling out of the track sections after they have moved passed the horizontal radii of discs 72 and 74.
  • the means includes a plurality of spring plates mounted in rows in thefront of brick laying machine 20, as seen most clearly in FIG. 2.
  • One plate is provided for each stack of bricks in the track 82.
  • the plates may be formed from steel or other like resilient or spring-like material.
  • the upper row of plates 108 engages the bricks as they assume the vertical position and presses them against the arcuate portion of plate 104.
  • the middle row of plates 110 retains the bricks in track section 84 as they turn under discs 72 and 74 and the lower row of plates 112 retains the brick in a track section until they are deposited in the concrete in form 22.
  • the upper, middle, and lower rows of plates are secured to shafts 114 which are rigidly mounted in the frame 52 by supports 116, 118, and 120.
  • each of the retaining means may be of either construction, as desired.
  • retaining means 112 may be formed as a single plate 1121 as shown in. FIG. 12, having a plurality of longitudinal extending bars 101 aflixed thereto.
  • the bars 101 are positioned on plate 1121 so as to lie in vertical alignment with head joint dividers 96 as the track sections pass over the plate.
  • One end of a leaf spring 103 is at- 7 tached to either 'sideof bars; 101 so thatthe other ends of thetwo leaf springs .103. attachedto the same-bar 101 are laterally displaced an equidistant amount from bar 101.
  • the two-leaf. springs' attached to the'same bars form a generally .V. shaped configuration.
  • a single leaf spring 105' is attached to either longitudinal edge'of plate 1121.
  • the leaf springs'103 and 105 serve'to insure that the bricks Bare laterally centered in compartments 85 asthey aredeposited on the-wet surface of theconcrete C thereby insuring that the'head joints between the bricks in the panel are equal in size.
  • The: use of a retainingplate 1121 is particularly advantageous if thelateraldimensions of the bricks are 'lessthan the lateral dimensions-of compartments 85.: v v As the tracksections 84 turn under discs 72 and 74, the bricks fall partially out of compartments 85 and rest on the forward-portionof'plate 1121.
  • retaining means such as a plurality of belts having portions thereof abuting the track sections may be used in place of the plate 104 and plates 108, 110, and 112.
  • Surfacing machine 20 is driven by a drive means attached to forward lateral member 56.
  • the drive means is mounted on plate 122 affixed to member 56 and having frames 124 and 126 for supporting the various pillow blocks and journals of the drive means.
  • An electric motor 128 is mounted on plate 122 having a gear box coupled to the output shaft thereof.
  • the output shaft of gear box 130 drives jack shaft 132 through pulleys 134 and 136 and belt 138.
  • Jack shaft 132 rotates drive shaft 140 through sprockets 142 and 144 and chain 146.
  • Sprockets 148 and 150 are mounted on the ends of drive shaft 140 to drive axle 60 through chains 162 and 164 and sprockets 166 and 168.
  • axle 60 rotates discs 72 and 74 causing those discs to move forward within track 82.
  • This forward movement causes the track sections 84 near forward lateral frame member 56 in the front of the upper flattened portion of track 82 to turn down and under discs 72 and 74 to form part of the lower flattened portion of track 82 and to be positioned so that holes 89 engage projections 42 on form- 22.
  • Thesevtrack sections remain stationary with respect to form 22, positioned horizontally and vertically on the forms by projections 42, as surfacing machine 20 passes forward over them.
  • the track sections become adjacent rear lateral frame member 58, they are raised up and around. discs. 7-6 and 78 and returned to the upper flattened portion.
  • Surfacing machine 20 may move forward onform22 at a speed of approximately 30 inches per minute.
  • the casters 171 or some other element of surfacing machine 20 engaging concrete form 22, may be driven by the drive means to propel the machine along the form. 1
  • a vibrating means is included in brick laying machine 20 for embedding the bricks B in a layer of concrete C in form 22 by vibrating them into the surface.
  • the elements of the vibratingmeans are shown in FIGS. 2, 3, 4, 7- and 10.
  • Apneumatic system for controlling the operation of the vibrating means' is shown in FIG. 8.
  • the vibrating means is designed for insertion into the compartments of track sections 84 to push the bricks out of the track sections 84 of track 82 and embed them in the surface of the concrete.
  • the vibrating means includes a vibrator head plate 170 which extends across substantially thewidth of the track 82.
  • the vibrator head plate is located abovethe lower flattened portion of track 82.
  • the upper surface-of vibrator head plate 170 contains a pair of L-shaped metal bars 172 and 174 which extend beyond either end of the plate.
  • the L-shaped portions 176 and 178 of bars 172 and 174 extend vertically of plate 170-and mount the vibrator head plate 170 on frame 50 for vertical movement with respect to the frame and the lower flattened portion of track 82, as hereinafter .described.
  • Vibrator head plate 170 contains a vibrator 180 which may be mounted on anadditional set of bars 182. Bars 172, 174, and 182 serve to stilfen vibrator head plate 170 against the vibrations generated by vibrator 180. While vibrator 180 may be of any common type, an electric solenoid, solid impact type is presently preferred. Such a vibrator consists of a slug of soft iron 184 (see FIG. 3) positioned inside an electric coil '186. The magnetic field created by the coil when energized with alternating current raises the soft iron slug up and then drives it downwardly into the vibrator head plate.
  • a plurality of probers 188 are aflixed to the bottom of vibrator head plate 170 so as to be simultaneously insertable into four adjacent rows of compartments of track sections 84 when vibrator head plate is lowered.
  • the probers 188 drive the brick out of the track sections and embed the bricks.
  • B in concrete C by means of the vibrations generated by vibrator 180, as shown in FIG. 4.
  • Such probers may comprise channel members having a length and width slightly less than the length and width of the compartments of track section 84.
  • One prober is provided for each compartment in the four rows, as shown in FIGS. 2 and 3, so that twenty-four probers are provided on vibrator head plate 170.
  • the probers are arranged in four rows identified by the numerals 188a, 188b, 1880, and 188d, as shown in FIG. 7, and are positioned on vibrator head plate 170 so as to be centered in the compartments of track sections 84 when vibrator head plate 170 is lowered.
  • Probers 18811 are located nearest forward lateral frame member 56 and the forward end of surfacing machine 20.
  • the probers may be affixed to the bottom of vibrator head plate 170 as by welding.
  • the depth of the probers from the bottom of the head plate to the end of the channel members may be slightly greater than the height of the bed joint dividers 94 and head joint plates 96 of track sections 84 so that when the probers 188 are inserted all the way into the compartment 85 of track sections 84, and vibrator head plate 170 rests on the upper surface of the track sections 84 in the lower flattened portion of track 82, the bottom of the channel member is slightly below the lower edges of the bed dividers and head joint plates.
  • the depth of the probers may be made greater if desired, and as this dimension of the probers determines the amount by which the brick will be embedded in the concrete, it must be coordinated with the height of the projections 42 and the elevation of the concrete C in concrete form 22.
  • Vibrator head plate 170 is mounted on frame 50 for both vertical and horizontal movement with respect thereto.
  • the track sections in the lower flattened portion of track 82 moves rearwardly with respect to frame 50 so that vibrator head plate 170 will also move rearwardly with respect to frame 50 when probers 188 are inserted in the compartments of track sections 84.
  • vibrator head plate 170 must :be raised so that probers 188 are removed from the compartments of track sections 84, returned to a forward position, and then lowered so that the probers 188 are inserted into a different set of compartments 85 of the track sections 84. The vibrating head plate 170 is then moved rearwardly by the movement of frame 50 again.
  • a stationary side plate 190 may be affixed to the inside of longitudinal members 52 and 54 intermediate axles 60 and 62, as shown in FIG. 7.
  • the plates are fastened to the frame members by means of bolts 191 which are inserted through the plates at slots 194 on either vertical edge of the plates and tightened. Slots 194 permit limited horizontal movement of side plates 190 with respect to frame members -2 and 54, so that the position of vibrator head plate 170 may be adjusted, as hereinafter described.
  • Stationary side plates 190 contain upper and lower pairs of rollers 196 and 198, rotatably mounted thereon.
  • Sliding side plates 200 have parallel rods extending from the upper and lower edges thereof to engage rollers 196 and 198 so that sliding side plates 200 may be reciprocally moved in a longitudinal direction along stationary side plates 190 and longitudinal frame members 52 and 54.
  • a pair of vertical vibrator head plate guides 202 are fastened to sliding side plates 200, as by bolts 204 so that the L portions of bars 172 and 174 of vibrator head plate 170 fit between the guides for vertical movement with respect to sliding side plate 200.
  • An elevating shaft bracket 206 is afiixed to the inner surface of vibrating head plate guides 202 for movement with sliding side plate 200 and to enclose the guide path for the L portions of bars 172 and 174. Elevating shaft bracket 206 includes notch 207 which allows vibrator head plate 170 to be raised.
  • Pillow blocks 208 mounted on the upper surfaces of elevating shaft brackets 206, journal elevator shaft 210 which extends laterally across frame 50 parallel to axles 60 and 62.
  • Elevator shaft 210 contains a pair of pulleys 212 to which one end of chains 214 are afiixed. The other end of chains 214 are fixed to vibrating head plate 170 so that by rocking or partially rotating elevator shaft 210, vibrating head plate 170 may be raised or lowered.
  • Such partial rotation of shaft 210 may be provided by a rack and pinion mechanism, the pinion 216 of which is mounted on one end of shaft 210 and the rack 218 of which may be affixed to the end of piston 220 of air cylinder 222 fastened to flange 209 of elevating shaft bracket 206.
  • rack 218 By pneumatically extending piston 220 and by retracting piston 220 by means of spring 221, rack 218 is moved, pinion 216 rotated, and vibrating head plate 170 raised and lowered.
  • a guide roller 224 may be provided to assist the movement of rack 218.
  • Rearward horizontal movement of vibrator head plate 170 is provided by inserting probers 188 in the compartments '85 of track sections 84 so that the vibrator head plate is carried rearwardly by the rearward movement of the track sections with respect to frame 50.
  • By pneumatically extending piston rods 230 and 232 sliding head plate 200 may be moved forward with respect to frame 50.
  • Such forward movement may terminate at stop 233 mounted on frame 50 against which vibrator head plate is held by the extended piston rods 230 and 233.
  • the amount of such forward movement may be slightly greater than the longitudinal dimension of the compartments in track section 84.
  • Piston rods 230 and 232 may be retracted and moved out of abutment with sliding side plates 200 by springs 231 and 232.
  • Air cylinder 222 which raises and lowers vibrator head plate 170, and air cylinders 226 and 228, which move vibrating head plate 170 forward, are energized and controlled by the pneumatic system shown in FIG. 8.
  • the air system is powered by a source of compressed air, such as compressor234.
  • Compressor 234- supplies compressed air in pipe 236 to T connector 238 which, in turn, provides the compressed air to air lines 240 and 241.
  • Air line 240 is connected to valve 242 which is operated by a sensing means 244, mounted on frame 54 and which is responsive to the position of vibrator head plate 170 with respect to frame 50.
  • sensing means 244 may be mounted on frame member 54 so as to engage elevating shaft bracket 206 when the elevating shaft bracket and sliding side plate 200 have moved to a rearward position along frame member 54.
  • valve 242 When sensing means 244 is actuated, valve 242 is Opened to allow air to enter air line 246 having check valve 248 interposed therein. The connection of sensing means 244 to valve 242 is indicated by the dotted line. The air in air line 246 operates air cylinder 222 to raise vibrator head plate 170 by means of rack 218 and pinion 216. Exhaust valve 250 is closed during this operation, as indicated in FIG. 8.
  • Air line 241 is connected to three-way valve 252 having an exhaust outlet 254 and a pressure outlet 256.
  • the pressure outlet 256 is connected to air lines 258 and 260 which supply air cylinders 226 and 228.
  • a sensing means 262 is positioned on elevating shaft bracket 206 so as to be actuated by striking vibrator head plate 170 as the latter is raised by air cylinder 222.
  • the actuation of sensing means 262 energizes air valve 252 to supply air from air line 241 to pressure outlet 256, as by rotating valve 252.
  • the air pressure in pressure outlet 256 and air lines 258 and 260 operates air cylinders 226 and 228 to extend pistons 230 and 232 and move sliding side plates 200 and vibrator head plate 170 forward aggainst stop 233.
  • the position of stationary side plates 190 on frame member 52 and 54 may be adjusted by means of slots 194 to insure that vibrator head plate 170 is held firmly against stop 233 by the extended pistons 230 and 232.
  • sensing means 244, closing valve 242 and retaining piston 220 of air cylinder 222 in the extended position This retains vibrator head plate 170 in the raised position.
  • a sensing means 264 is mounted on frame member 52 so as to be actutable by striking one of pins 266 extending from flange 88 of track section end plate 86.
  • the sensing means is mounted on the frame member so as to be actuatable when the probers 188 are centered over the compartments in track sections 84 in the lower flattened portion of track 82.
  • the actuation of sensing means 264 opens exhaust valve 250 to de-energize air cylinder 222 and retract piston 220 by means of spring 221.
  • the retraction of piston 220 moves rack 218 to lower vibrator head plate and reinserts probers 188 into the compartments of track section 84. Compensation may be provided, in the positioning of sensing means 264, for the continuous movement of track section 84 with respect to frame 50, and particularly for that increment of movement occurring during the time the vibrator head plate 170 is being lowered.
  • sensing means 262 and valve 252 are de-actuated, de-energizing air cylinders 226 and 228, retracting the pistons 230 and 232 away from sliding side plates 200 by means of springs 269 and 271.
  • the air in cylinders 226 and 228 is exhausted through valve 252 from pressure outlet 256 to exhaust outlet 254. Sliding side plates 200 are not affected by the retraction of pistons 230 and 232 because of the lack of any coupling between the members.
  • Vibrator head plate 170 and sliding side plates 200 are moved rearwardly with respect to frame 50 of brick laying machine 20, along with the track sections 84 in which probers 188 are inserted so as to again actuate 1 1 sensing 'means 244 when the vibrator head plate attains a rearwardposition, to repeat the operating cycle again.
  • the path of movement of vibrator head plate170', with respect'to frame 50 which carries it, is rectangular in that the vibrtaor head plate is initially moved rearwardly along withtrack sections 84, then moved upwardly by air cylinder 222, then forward by air cylinders 226 and 228 to a position hereinafter termed the raised, forward position and finally downwardly by air cylinder 222.
  • the mount of the forward and rearward movement of vibrator head plate 170 is equal to thelongitudinal dimension of the compartment 85 of track sections 84 so that the vibrator head plate is advanced one row or course of compartments 85 with each operating cycle.
  • the sensing means and air valves may be electrically operated devices, as for example, electrical limit switches and solenoid operated air valves or may be mechanically operated,.or linked.
  • the surfacing machine shown in the attached drawing employs pressed brick split in half so as to utilize two finished surfaces of the brick thereby reducing the cost of the brick required for the panel.
  • the brick may be split by a masonry saw, or other means, along the center line of the brick and a diameter of the holes in the brick.
  • the split bricks B are placed in the compartments 85 of the track sections 84 in the upper flattened portion of track 82 at a first station along the orbital path of the track, with the finished surfaces lying on retaining means 104 and the split surfaces exposed, as shown in FIG. 1.
  • Motor 128 is then energized to commence the operation of surfacing machine 20. Vibrator 180 may also be energized at this time. Motor 128 rotates axle 60 and discs 72 and 74 through the machine drive means. Rotation of axle 60 moves frame 50 forward with respect to track 82 so as to place additional track sections 84 on projections 42 at the front edge of the machine while removing track sections from projections 42 at the rear of the machine. Surfacing machine 20 moves along the vertical side walls 26 and 28 of form 22 by the engagement of projections 42 in holes 89 in flanges 88 of track section end plates 86.
  • the track sections 84 in the upper flattened portion of track 82 containing the split brick B are moved toward the forward end of surfacing machine 20 and drawn downwardly and around discs 72 and 74.
  • the bricks b are retained in the track sections by spring plates 108.
  • the bricks B are retained in the track sections by spring plates 110 and 112.
  • the bricks B in the track sections reach the end of spring plates 112, they fall onto the exposed surface of the concrete C, a row at a time, so as to rest thereon while still being partially retained within the track section 84 forming the lower flattened portion of track 82.
  • This point may hereinafter be termed the second station along the orbital path of track 82.
  • the retention of the bricks in track sections 84 serves to position the rows or courses of brick against displacement along the surface of the concrete C in accordance with the dimensions of the bed joint dividers and head joint plates of the track sections 84.
  • the track sections 84 do not move with respect to form 22 because of the engagement of holes 89 on projections 42.
  • the first row, or course, of bricks B eventually reaches a position in which the bricks are directly under the first row of probers 188a when vibrator head plate 170 is in the raised, forward position. This may occur when five to six courses of bricks B have been deposited on the surface of concrete C.
  • sensing means 264 strikes one of pins 266, actuating the sensing means and de-energizing air cylinder 222 to lower the vibrator head plate 170, so that the first row of prob ers 188a descends to strike the first course of brick B.
  • the vibrations generated by vibrator 180 in probers 188a and the weight of head plate 170 embeds the first course of brick into the surface of the concrete.
  • the surfacing machine continues to move forward along form 22-to deposit additional courses of bricks b on the exposed surface of concrete C.
  • the track sections 84 forming the lower flattened portion of track 82 continue to move rearwardly with respect to frame 50 of the machine.
  • Vibrator head plate 170 is carried rearwardly with respect to frame 50' by track sections 84 due to the engagement of probers 188a in the compartments of track sections 84.
  • elevator shaft bracket 206 actuates sensing means 244 to energize air cylinder 222 and raise vibrator head plate 170.
  • Probers 188a disengage the first course of brick B on the surface of concrete C.
  • sensing means 262 When vibrator head plate 170 has been raised, sensing means 262 is actuated to cause air cylinders 226 and 228 to move the vibrator head plate 170 forward a distance equal to the longitudinal dimension of the compartments 85 so that the vibrator head plate 170 is returned to the forward, raised position.
  • the vibrator head plate 170 is thus moved forward with respect to the courses of brick B lying on the surface of concrete C in form 22 to place the first row of probers 188a over the second course of brick B.
  • sensing means 264 When the vibrating plate 170 is positioned so that the probers are again centered over the compartments 85 of track section 84, sensing means 264 is actuated by another of pins 266 to de-energize air cylinder 222 and lower vibrator head plate 170. Due to the forward movement of vibrator head plate 170 the first row of probers 188a now descends to strike the second course of brick B to vibrate that course into the surface of the concrete.
  • the second row of probers 18811 on the vibrator head plate 170 descends onto the first course of brick so as to revibrate it into the surface of the concrete and to prevent those bricks from rising as the second row of brick is vibrated into the concrete.
  • the surface of the concrete has a tendency to rise due to the displacement of the concrete by the bricks.
  • the first row has a tendency to rise along with the concrete. The revibration of the first course of brick by the second row of probers 188b counteracts this tendency.
  • Additional forward movement of surfacing machine 20 again repeats the above operating cycle so that the first row of probers 188a engages the fourth course of brick on the surface of the concrete C when vibrator head plate 170 is lowered.
  • the second, third, and fourth rows of probers 188b, 1880, and 188d revibrates the third, second and first courses of brick to retain them in their embedded positions.
  • the second third, and fourth rows of probers188b, 188C, and 188d revibrate the fourth,- third, and second courses of brick B.
  • the first course of brick B is no longer revibrated, that course, and the surface of the concrete surrounding it, beingsufficiently far removed from the point where the fifth row of brick is being embedded in the surface of the concrete as to beunaffected by such embedment, and having been securely positioned in the surface of the concrete byfour successive applications of the probers 188 of vibrator headplate 170.
  • the bricks In the case of a panel P utilizing split pressed brick B havingsemi-circular depressions along the split surface, the bricks must be embedded in the exposed surface of the concrete to an extent such that the semi-circulardepressions are completely below the surface of the concrete so as to prevent waterfrom accumulating-in the depressions and causing freeze damage. In a typical instance, such bricks B will be embedded onehalf inch in concrete C.
  • each course of brick deposited on the surface of the concrete is subjected to thesame treatment as described above, that is, it is initially vibrated into position by vibrator head plate 170 and the first row of probers 188a and then retained in that position by three re-applications of the probers 188 of vibrator head plate 170.
  • the courses of brick undergo a decreasing vertical displacement with each successive vibration to arrive at their final position at the end of four operatingcyclesof vibrator head plate 170.
  • the track section is pivoted up and away by discs 76 and 78.
  • Collapsible cores 30 are inserted through bulkheads 29 and into concrete form 22 so as to lie parallel with vertical side walls 26 and 28.
  • Turnbuckles 40 are adjusted to extend side plates 36 and 38 and expand cores 30.
  • Reinforcing rods or prestressing strands and the like may be inserted in form 22, if desired, as may brackets BR.
  • Form 22 is then filled with the cementitious material, such as concrete C.
  • the material must be of a consistency such that it is thin enough to allow the brick to be embedded therein by the vibrations generated by vibrator 180 and the weight of vibrator head plate 170, yet firm enough to support and prevent displacement of the bricks once they have been embedded in the desired position.
  • concrete having a consistency such that it forms a four inch slump is most desirable.
  • the term slump is utilized in the art as a measure of concrete consistency. A frustum of wet concrete twelve inches high, six inches in diameter at the bottom, and two inches in diameter at the top is formed and the amount by which the height of the frustum falls is measured.
  • slump This distance, measured in inches, is termed the slump.
  • a concrete frustum of four inch slump falls four inches in height.
  • wet concrete having a two to three inch slump is commonly used in the manufacture of precast, prestressed bridge girders while concrete having a five inch slump is used in ordinary concrete work and for concrete cast directly in place at the job site.
  • the amount 14 of slump in wet concrete is determined by its ingredients. For example, large quantities of fine aggregates, such as sand, decrease the slump whereas large quantities of coarse aggregate increase the slump. The greater the amount of water in the wet concrete, the greater the slump.
  • Concrete C having the desired slump is poured into form 22 and struck off to the desired elevation.
  • the elevation at which the concrete is struck must be correlated to the height of projections 42 and the depth of probers 188 so that surfacing machine 20 is positioned the correct distance above the exposed surface of the concrete in the form and the bricks are embedded in the concrete the desired amount.
  • the depression of the brick into the surface of the concrete causes a corresponding rise in the level of the concrete surface, it is essential that the concrete in the form be accurately struck off at the desired level.
  • courses of brick B are deposited on the exposed surface and embedded therein, as by the operation of surfacing machine 20 in the above described manner.
  • surfacing machine 20 may be placed aside for the remainder of the manufacturing process.
  • a conventional brick motar is mixed, as from portland cement, lime, and sand. A small amount of water is added so that the resulting mortar is very dry. Sufficient water is added to the mortar so that it barely forms, and remains in, a ball when compressed by hand.
  • the mortar M so formulated is then shoveled over the entire surface of the completed panel, after which the surface is scraped to remove the excess mortar from the courses of bricks and insert it in the joints between the bricks.
  • the surface of the bricks may be swept to further clean the exposed faces of the bricks.
  • a mortar frame which may comprise a track section 84, having a half bed joint dividers replaced with full bed joint dividers, is then placed over the panel so that the bed joint dividers and head joint plates lie in the bed and head joints of the bricks in the panel.
  • a vibrator which may be similar to vibrator 180, is applied to the mortar frame to vibrate or tamp the mortar down to the proper elevation. The mortar frame and vibrator are moved about the panel so that each bed joint and head joint in the panel is tamped, after which the mortar frame and vibrator may be removed.
  • additional mortar may be applied to the joints so as to make them flush with the surface of the brick.
  • the joints may also be tooled to form a concave, weather, V or other desired joint, either by hand tools, or by shaping the bottom of the head joint dividers and head joint plates to the desired configuration.
  • the panel After the joints have been mortared, the panel is covered wtih a waterproof material and partially cured by the application of heat.
  • a heated fluid such as steam may be inserted in the cores 30 to initiate the curing of the concrete adjacent the cores.
  • the cores 30 are then collapsed and removed from the form and panel and the panel removed from the form.
  • the panel is then fully cured by the reapplication of heat.
  • step of conveying the rows is further defined as conveying the rows of objects in a manner such that the rows enter the path of movement of the track at the first station one row at a time and wherein the step of sequentially partially discharging the objects is further defined as sequentially partially discharging the objects one row at a time and depositing the row on the exposed material surface.
  • step of sequentially ejecting the objects is further defined as applying vibratory blows to the objects to drive them out of the compartments and into the exposed surface of the bed of material.
  • step of sequentially ejecting the deposited objects is further defined as applying vibratory blows to a given row of objects to drive it into the exposed surface While simultaneously reapplying vibratory blows to an adjacent, previously deposited row of objects to prevent its displacement upon the embedment of said given row.
  • step of moving the rows of objects is further defined as moving the rows of objects in a semi-orbital path from the first station to the second station.
  • step of forming the bed of material is further defined as providing a form having internal dimensions correspondingto'the desired dimensions of said finished panel and pouring the material into said form;
  • the methodof claim 9 including the steps of distributing the mortar over the exposed surface of the bed of material and the partially embedded objects, scraping the mortar off the surface of the partially embedded objects into the 'spaces therebetween, tamping the mortar into the spaces and allowing the mortar to harden.
  • the method of claim10 including the step of tooling'the mortar after insertion in the spaces to give the spaces the appearance of mortared joints.

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Abstract

A method of manufacturing a brick panel includes the steps of forming a bed of concrete, arranging the bricks in a plurality of rows, moving the rows of bricks over the exposed surface of the bed of material, sequentially depositing the rows of bricks in the bed of concrete, and sequentially partially embedding the rows of bricks in the surface of the concrete, as by vibratory blows.

Description

Aug. 28, 1973 J. M. YOUNG TAL 3,755,521
METHOD OF MAKING BRICK PANELS Original Filed Aug. 19, 1968 4 Sheets-Sheet l Aug. 28, 1973 J. M. YOUNG EI'AL METHOD OF MAKING BRICK PANELS 4 Sheets-Sheet 2 Original Filed Aug. 19, 1968 Aug. 28, 1973 J, YOUNG ETAL METHOD OF MAKING BRICK PANELS 4 Sheets-Shet 3 Original Filed Aug. 19, 1968 Aug. 28, 1973 J. M. YOUNG ETAL METHOD OF MAKING BRICK PANELS 4 Sheets-Sheet 4 Original Filed Aug. 19, 1968 United States Patent 3,755,521 METHOD OF MAKING BRICK PANELS James M. Young, 3402 W. Wells St. 53208, and George 0. Whitney, Milwaukee, Wis. (868 Bayway Blvd., Apt.
M-312, Clearwater, Fla. 33515) Original application Aug. 19, 1968, Ser. No. 753,500. Divided and this application Mar. 25, 1971, Ser. No. 128,123
Int. Cl. B28b 1 08, 1/16 US. Cl. 264-69 11 Claims ABSTRACT OF THE DISCLOSURE A method of manufacturing a brick panel includes the steps of forming a bed of concrete, arranging the bricks in a plurality of rows, moving the rows of bricks over the exposed surface of the bed of material, sequentially depositing the rows of bricks in the bed of concrete, and sequentially partially embedding the rows of bricks in the surface of the concrete, as by vibratory blows.
This is a divisional application of Ser. No. 753,500, filed Aug. 19, 1968.
BACKGROUND OF THE INVENTIONFIELD OF THE INVENTION The present invention relates to a method for making masonry or concrete structures, particularly faced wall structures.
BACKGROUND OF THE INVENTION- DESCRIPTION OF THE PRIOR ART Recent trends in building construction techniques have favored the construction of buildings from steel framing which may be pre-cut or prefabricated on a mass production basis and then assembled or erected at the individual job site. The walls of such buildings comprise sheets or panels of metal or other materials attached to the steel framework. Such panels have been formed from pre-cast concrete or other cementitious materials so that the finished steel frame building is similar, in appearance, to one constructed by conventional methods. By contouring the forms in which the panels are cast, panels having an outer surface resembling, or simulating, ordinary building materials used in walls, such as stucco, may be provided.
It has long been desired to provide such panels or walls with an outer surface resembling laid brick. While the concrete form may be contoured to resemble brick, the distinctive color of brick has required either that the concrete be colored in some manner or that the finished panel be painted. The first of these approaches fails to provide the economy desired of precast panel construction, while the second is lacking in durability.
SUMMARY OF THE PRESENT INVENTION It is, therefore, the object of the present invention to provide a method providing a precast panel with a surface having the appearance of laid brick.
The present invention provides a method for embedding or implanting objects, such as rows of bricks; in the exposed surface of a'bed of cementitious material, such as wet concrete, so as to provide, upon curing of the concrete, a panel with a surface having the appear ance of laid brick.
The bed of material is formedin aforrn or other receptacle. A surfacing machine, movable along the form is positioned over the form. The machine includes a frame having .a support means mounted inside an endless'belt or track having a plurality of track sections for receiving the rowsof brick. The track iscarried by the support means for movement in an orbital path with respect to the frame. The support means positionsa portion of the track adjacent the exposed surface of the bed of material from which portion the bricks maybe deposited in the surface. I h v w .1 f A driving means, mounted'on the frame,ifmo vesj'the frame along the form and moves the track in its orbital path to add new, brick laden track sections to the portion of the track adjacent the exposed surface of the concrete and remove the empty sections from that portion, so that the deposition of rows of brick continues as the machine moves along the form. A means to assist the embedment of the brick in the surface of the material, such as a vibrating means, may be provided on the frame.
It is a further object of the present invention to provide a method for making such a panel which utilizes actual brick, thereby lending authenticity and durability to the panel surface.
It is yet another object of the present invention to provide a method for making such panels rapidly and with low labor cost.
It is a still further object of the present invention to provide a method for making such panels which may utilize split brick, thereby using both faces of the brick and substantially reducing material costs. a
The method of forming a panel with embedded objects in the surface thereof commences with the forming of the bed of material in the form. If desired, collapsible cores may be inserted in the material to reduce the weight of the complete panel. The material is struck off in the form to provide the exposed surface.
A plurality of objects are then deposited on the surface of the material and embedded therein, as by operation of the surfacing machine. The spaces between the embedded objects may be filled with mortar and the material cured to form the completed panel.
BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a perspective view of a surfacing apparatus;
FIG. 2 is a longitudinal cross sectional view of the apparatus of FIG. 1 showing the deposition of the objects in the exposed surface of the material;
FIG. 3 is a lateral cross sectional view of the apparatus of FIG. 1 taken along the line 33 of FIG. 2;
FIG. 4 is a partial, lateral cross sectional view of the surfacing apparatus, similar to FIG. 3, but showing the embedment of the objects in the surface of the material;
FIG. 5 is a detailed, partial, lateral cross sectional view showing a means for coupling the surfacing machine to the material form;
FIG. 6 is a partial longitudinal cross sectional view showing the details of the endless track of the surfacing machine and the rotary support means therefor;
FIG. 7 is a partial perspective view of the means for embedding the objects in the exposed surface of the material;
FIG. 8 is a somewhat schematic and diagrammatic view of the means for embedding the objects in the exposed surface of the material and of a control system therefor;
FIG. 9 is a detailed view of a track section forming a portion of the endless track of the surfacing machine;
FIG. 10 is a perspecive view of a portion of the means for embedding the objects in the surface of the material.
FIG. 11 is a perspective view of a completed panel of cementitious material having a plurality of objects embedded in an exposed surface thereof, such as may be provided by the method of the present invention; and I FIG. 12 is a perspective view of a retaining means incorporated in the surfacing machinev for retaining the objects in the endless track until deposition in the material.
FIGk 1' "shows a panel? which may be formed by the method or the present invention- The panel includes a substratum of "concrete C or otherceihentitous material on an exposed surface of which is embedded a' plurality of objects, suchas -br'icks -B."Panel"P may' contain brackets BR for attaching the panel to the steel framework of the building. The bricks B are embedded in the concrete C in a pattern such" that the exposed surface of th'e finished panel resembles laid brick having a desired 1 bond configuration, such as stretcher, header, common, or English bond. In all such bond patterns, the bricks are generally positioned in aplurality of horizontal rows, termed courses. The bricks forming any given course are separated by head joints'and adjacent courses of brick are separated by bed joints. The joints may be filled with mor-tar 'M so as' to give the surface of the panel the appearance of conventionally laid brick. FIG. 11 show's',forsimplicity, a bond configuration in which the bricks are arranged in a plurality of vertical rows, termed stacks.
Any of the generally available types of brick, such as common brick, pressed brick, or glazed brick, may be used in panel P. The drawing accompanying the specification shows, in an exemplary manner, pressed brick having a plurality of holes extendinng therethrough parallel to the finished faces of the brick.
The concrete form The apparatus includes a surfacing machine 20 coupled to, or mounted on a form 22, as shown in FIG. 1. Form 22 may be an elongated or longitudinally extending U- shaped trough having a bottom plate 24 and a pair of laterally spaced parallel vertical sidewalls 26 and 28. The ends of form 22 may be closed by bulkhead 29 which are adjustably positioned along the length of form 22 to provide a finished panel P of the desired length.
A plurality of collapsible cores 30 extend down the length of form 22 and through the bulkheads. As shown in FIG. 3, each of the cores 30 includes a bottom plate 32 and a top plate 34 having curved longitudinal edges extending toward each other. Top plate 34 and bottom plate 32 may be retained for limited movement toward and away from each other by slotted straps 33 linked by bolts 35, as shown in FIG. 3.
The core also includes side plates 36 and 38 which are positioned to abut the top and bottom plates near their edges. The position of side plates 36 and 38 is adjustable by turnbuckle 40 or other means.
The plates comprising cores 30 are generally constructed from a heavy material, such as iron or steel, to offset any tendency of the cores to float as concrete is poured into form 22 and around cores 30.
With side plate 36 and 38 extended, as shown in FIG. 3;mp plate 34 and botton plate 32 are forced apart to the. limits ofv braces 33 to form a rigid structure around which concrete may be poured.
By moving side plates 36 and 38 inwardly, away from the curved edges of top and bottom plates 34 and 32 the latter plates may be moved toward each other to collapse the core andallow its removal from. the hardened concrete in form 22. The holes in the panel -P formed by cores 30 lighten the-panel and permitelectric wires,-
piping, and other services to be inserted through the panels and the walls formed therefrom.
The upper surfaces of parallel, vertical sidewalls 26 and '28 of form 22 contain a plurality of projections 42 spaced along the length of the Wall which are used to couple the surfacing machine 20 to the form to form the surfacing apparatus. As shown in FIG. 5, each of these projections may comprise a bolt 44 or other means attached to the form. As hereinafter described, projections 42 serve to position surfacing machine 20 with respect to "the exposed surface of the wet concrete C in form 22.
The surfacing machine l 'As noted in the summary, thesurfacing machine 20 includes a frame, portions of which are, mounted inside an endless belt or track which moves in an orbital path with respect to the frame. Means are provided for mounting the frame on the form and over the bed of material, as by an engagement of a portion of the track with projections 42 on the form.
During the deposition of brick in the surface of the material in form 22, the entire surfacing machine 20 moves forward in an longitudinal path along the form while, at the same time, the track moves in an orbital path with respect to the frame, resulting in a laying down of additional portions of the endless track on the form at the front of the machine and a picking up of corresponding portions off the form at the rear of the machine, in the manner of a tracked vehicle. It is important to the understanding of the apparatus of the present invention to realize that, while the machine moves forward along the form as described above, the portion of the track engaging the form remains stationary with respect to the form in the position in which it is laid down, until it is picked up. The machine, and particularly the frame portions thereof, thus move forward with respect to the portion of the track in engagement with the form, or conversely, this portion of the track moves rearwardly with respect to the frame.
Turning now to the details of surfacing machine 20, the machine includes a main frame 50 constructed of steel channel members. Frame 50 may be generally rectangular in shape having a pair of longitudinal members 52 and 54 lying parallel to, and adjacent, vertical sidewalls 26 and 28 of form 22, a forward lateral member 56, and a rear lateral member 58 connecting the lognitudinal members.
A pair of laterally extending axles 60 and 62 are journalled at longitudinally spaced positions on longitudinal members 52 and 54 by bushings 64 and 66 and 68 and 70. See FIGS. 1 and 2. Each of the axles supports a rotary support means in the form of a drum or plurality of separate discs. The latter configuration is shown in FIGS 1, 2 and 3, wherein each axle has a disc aflixed thereto, adjacent the bushing. Axle 60 supports discs 72 and 74 while axle 62 supports discs 76 and 78. The periphery of the discs may be covered with rubber belt 80 or other non-slip material, as shown in FIG. 6.
An endless track or belt 82 is rotatably mounted on discs 72 and 74 and 76 and 78 so that the discs are on the inside or within track 82. The longitudinal spacing of axles 60 and 62, and the discs supported thereby, causes track 82 to assume a generally oval or elliptical shape, as shown in FIG. 2, having forward and rear portions abutting the discs and a lower flattened portion extending between the two sets of discs adjacent the exposed surface of the concrete C in concrete form 22. The track 82 may also have an upper flattened portion extending bet-ween the tops of the two sets of discs parallel to the lower flattened portion. Track 82 is comprised of a plurality of hinged track sections 84 shown in detail in FIG. 9 and in longitudinal cross section i FIG. 6.
Track section 84 includes a lattice having 'a plurality of compartments 85, sized to receive bricks B. The lattice of each track section may include a compartment for one or more courses or rows of bricks B in the finished panel P, the track section shown in FIG. 9 having suflicient compartments for three courses of bricks, six bricks wide. The strip like members forming the compartments 85 of track section 84 also serve to separate adjacent bricks and thus form the bed joints and head jointsin the completed panel. In the following description, the longitudinal. dimension of the compartments 85 and track sections 84 is that parallel to longitudinal frame members 52 and 54 and the lateral dimension runs parallel to forward and rear lateral frame members-56 and 58.
Each track section 84 includes an end plate 86 at either side thereof having an outwardly extending flange 88, the outer portion of which engages discs 72 and 74 and 76 and 78 so as to mount track 82 on the discs. The end plates are joined by marginal lateral members 90 and 92, termed half bed joint dividers which may be welded, bolted, or otherwise secured to end plates 86. The half bed joint divided 92 which is nearest forward lateral frame member 56 when the track section is in the lower flattened portion of track 82, is shorter in height than the half bed joint divider 90 which is nearest rear lateral frame member 56, so as to prevent tipping or cocking of the brick embedded in concrete C as the track section moves from the lowerportion of track'82 to the rear portion thereof.
End plates 86 are also joined by a plurality of full bed joint dividers 94 which extend laterally between the end plates intermediate the half bed joint dividers. The half bed joint dividers are joined by a plurality of longitudinal head joint plates 96 which extend between the half bed joint dividers 90 and 92 intermediate end plates 86 to form the lattice of the track section. The interception of the full bed joint dividers 94 and the head joint plates 96 may be effected by cutting away half of each member and joining the members in the manner of an egg crate divider, or by other means. A plurality of pins 266 are aflixed to flange 88 on one side of track section 84 and extend outwardly therefrom. One such pin, located in the center of the compartment, is provided for each row or course of compartments 85 of track section 84 so that in the track section shown in FIG. 9, three pins are provided on each flange. These pins are used to control the operation of surfacing machine 20.
The height of half'bed joint divider 90, full bed joint dividers 94 and head joint plates 96 depends on the size of brick B used in the construction of panel P and the position of the lower flattened portion with respect to the exposed surface of wet concrete and may be equal, greater, or less than, the height of brick B.
By altering the configuration of the compartments 85 formed by the bed dividers and head joint plates, the bricks may be deposited in the concrete in any desired manner so that the surface of the finished panel resembles a desired bond configuration. It will be appreciated that as the bond of the brick B is not needed for the structural integrity of panel P, numerous artistic or decorative patterns, not normally available in brick construction, may be provided.
Track sections 84 are linked together at either side by hinges 98, shown in detail in FIG. 6, to form track 82. Hinge plates 100 forming the hinges are attached to the inner edges of end plates 86, which may be recessed to receive the hinge plates. A hinge pin 102 is inserted through hinge plates 100. The hinge plates 100 are formed so that the center of hinge pin 102 is in alignment with, or positioned slightly below, the bottom of end plates 86 as shown in FIG. 6.
Also as shown in FIG. 6, only a small gap exists between the flange 88 of two adjacent track sections 84 when the sections are in alignment, as for example, when the track sections are positioned in the upper or lower flattened portions of track 82. A similarly small gap exists between half bed joint divider 92 of one track section and the half bed joint divider 90 of the succeeding track section. The half bed joint dividers may be constructed of thin material so that the thickness of the two half bed joint dividers, plus the gap between them 6 equals the thickness of a full .lbed jointdivided 94, there by causing all of the bed. joints of the finished panel to be equal in thickness. I I 1 Track 82 also serves to couple surfacing machine 20 to form 22. The end plates 86 of eachtrack section 84 contain a depression or hole 89in the flange 88 that engages projections 42 on the upper edges of vertical sidewalls 26 and .28 to form 22 when the track section is located in the lower flattened portion of the track, as shown in FIG. 5. The holes 89 in adjacent track sections 84 and projections 42 are spaced equal distances apart for this purpose. The discs, such as disc 78, rest on flanges 88 so as to support frame 50 and the remainder of surfacing machine 20. The discs may rest on flanges 88 directly over holes 89 and projections 42 so as to eliminate any bending moment on the flange, as shown in FIG.. 5. The engagement of projections 42 in holes 89 serves to accurately locate surfacing machine 20 in the desired vertical and horizontal-position with respect to form 22 and the exposed surface of the concrete lying therein. The weight of surfacing machine 20 is transferred to projections 42 by the abutment of discs 72 through 78 on flanges 88, as shown in FIGS. 3 and 5. A pair of casters, one of which is indicated by the numeral 169 in FIG. 1, and bearing on the upper edge of sidewall 26, may be provided on transverse member 58 to lessen the weight of surfacing machine 20 applied to the track sections by discs 76 and 78, so as to assist the track sections 84 in turning up and around discs 72 and 74. Casters 171 may be provided at the front of surfacing machine 20 for the same purpose. The engagement of projections 42 in hole 89 also aids in the movement of surfacing machine 20 along form 22 in a manner hereinafter described.
The bricks are retained in track sections 84 until deposited in the concrete in form 22 by a retaining means. Such means includes a plate 104 lying beneath the upper flattened portion of track 82 to prevent the brick from falling through the compartments of track sections 84. Plate 104 is mounted on frame 52 by supports 106 fastened to the frame. The plate extends arcuately downward at the forward end of surfacing machine 20 to approximately the horizontal radii of discs 72 and 74 so as to prevent the bricks from falling through the track sections until they have attained a vertical position.
The retaining means of surfacing machine 20 also keeps the bricks from falling out of the track sections after they have moved passed the horizontal radii of discs 72 and 74. For this purpose, the means includes a plurality of spring plates mounted in rows in thefront of brick laying machine 20, as seen most clearly in FIG. 2. One plate is provided for each stack of bricks in the track 82. The plates may be formed from steel or other like resilient or spring-like material. The upper row of plates 108 engages the bricks as they assume the vertical position and presses them against the arcuate portion of plate 104. The middle row of plates 110 retains the bricks in track section 84 as they turn under discs 72 and 74 and the lower row of plates 112 retains the brick in a track section until they are deposited in the concrete in form 22.
The upper, middle, and lower rows of plates are secured to shafts 114 which are rigidly mounted in the frame 52 by supports 116, 118, and 120.
While the figures show retaining means 104 as a single plate and retaining means 108, 110 and 112 as a plurality of plates, each of the retaining means may be of either construction, as desired.
Thus retaining means 112 may be formed as a single plate 1121 as shown in. FIG. 12, having a plurality of longitudinal extending bars 101 aflixed thereto. The bars 101 are positioned on plate 1121 so as to lie in vertical alignment with head joint dividers 96 as the track sections pass over the plate. One end of a leaf spring 103 is at- 7 tached to either 'sideof bars; 101 so thatthe other ends of thetwo leaf springs .103. attachedto the same-bar 101 are laterally displaced an equidistant amount from bar 101. The two-leaf. springs' attached to the'same bars form a generally .V. shaped configuration. A single leaf spring 105' is attached to either longitudinal edge'of plate 1121. The leaf springs'103 and 105 serve'to insure that the bricks Bare laterally centered in compartments 85 asthey aredeposited on the-wet surface of theconcrete C thereby insuring that the'head joints between the bricks in the panel are equal in size. The: use of a retainingplate 1121 is particularly advantageous if thelateraldimensions of the bricks are 'lessthan the lateral dimensions-of compartments 85.: v v As the tracksections 84 turn under discs 72 and 74, the bricks fall partially out of compartments 85 and rest on the forward-portionof'plate 1121. As the bricks move rearwardly along plate, 1:121 ,2the.bricks.pass between the leaf springs 103 and: 105, flexing springs 103 toward each other and springs 105 toward the edges of. plate 1121. The flexure; of the springs provides oppositely applied lateral ,forces on each brick: in the course passing between the springs, which. forces centerthe bricks in the compartments of the track section so that they are deposited on the concrete with equal lateral spacing and head joints between them.
Other retaining means, such as a plurality of belts having portions thereof abuting the track sections may be used in place of the plate 104 and plates 108, 110, and 112.
Surfacing machine 20 is driven by a drive means attached to forward lateral member 56. The drive means is mounted on plate 122 affixed to member 56 and having frames 124 and 126 for supporting the various pillow blocks and journals of the drive means.
An electric motor 128 is mounted on plate 122 having a gear box coupled to the output shaft thereof. The output shaft of gear box 130 drives jack shaft 132 through pulleys 134 and 136 and belt 138. Jack shaft 132, in turn, rotates drive shaft 140 through sprockets 142 and 144 and chain 146. Sprockets 148 and 150 are mounted on the ends of drive shaft 140 to drive axle 60 through chains 162 and 164 and sprockets 166 and 168.
The rotation of axle 60 rotates discs 72 and 74 causing those discs to move forward within track 82. This forward movement causes the track sections 84 near forward lateral frame member 56 in the front of the upper flattened portion of track 82 to turn down and under discs 72 and 74 to form part of the lower flattened portion of track 82 and to be positioned so that holes 89 engage projections 42 on form- 22. Thesevtrack sections remain stationary with respect to form 22, positioned horizontally and vertically on the forms by projections 42, as surfacing machine 20 passes forward over them. As the track sections become adjacent rear lateral frame member 58, they are raised up and around. discs. 7-6 and 78 and returned to the upper flattened portion. Surfacing machine 20 may move forward onform22 at a speed of approximately 30 inches per minute.
If desired, the casters 171 or some other element of surfacing machine 20 engaging concrete form 22, may be driven by the drive means to propel the machine along the form. 1
. A vibrating means is included in brick laying machine 20 for embedding the bricks B in a layer of concrete C in form 22 by vibrating them into the surface. The elements of the vibratingmeans are shown in FIGS. 2, 3, 4, 7- and 10. Apneumatic system for controlling the operation of the vibrating means'is shown in FIG. 8.
The vibrating means is designed for insertion into the compartments of track sections 84 to push the bricks out of the track sections 84 of track 82 and embed them in the surface of the concrete. For this purpose, the vibrating means includes a vibrator head plate 170 which extends across substantially thewidth of the track 82. The
vibrator head plate is located abovethe lower flattened portion of track 82. The upper surface-of vibrator head plate 170 contains a pair of L-shaped metal bars 172 and 174 which extend beyond either end of the plate. The L-shaped portions 176 and 178 of bars 172 and 174 extend vertically of plate 170-and mount the vibrator head plate 170 on frame 50 for vertical movement with respect to the frame and the lower flattened portion of track 82, as hereinafter .described.
i Vibrator head plate 170 contains a vibrator 180 which may be mounted on anadditional set of bars 182. Bars 172, 174, and 182 serve to stilfen vibrator head plate 170 against the vibrations generated by vibrator 180. While vibrator 180 may be of any common type, an electric solenoid, solid impact type is presently preferred. Such a vibrator consists of a slug of soft iron 184 (see FIG. 3) positioned inside an electric coil '186. The magnetic field created by the coil when energized with alternating current raises the soft iron slug up and then drives it downwardly into the vibrator head plate. It has been found that the type of vibrator that simply raises the slug and allows it to descend of its own weight provides vibrations insuflicient in magnitude for use in the present brick laying machine because of the stiffness of the concrete in which the bricks are embedded. The rotating type of vibrator employing an eccentrically loaded shaft or other rotating means has a tendency to cause lateral and longitudinal oscillations in the vibrating means so that it moves over the surface of the brick rather than driving the brick directly downward into the concrete.
A plurality of probers 188 are aflixed to the bottom of vibrator head plate 170 so as to be simultaneously insertable into four adjacent rows of compartments of track sections 84 when vibrator head plate is lowered. The probers 188 drive the brick out of the track sections and embed the bricks. B in concrete C by means of the vibrations generated by vibrator 180, as shown in FIG. 4. Such probers may comprise channel members having a length and width slightly less than the length and width of the compartments of track section 84. One prober is provided for each compartment in the four rows, as shown in FIGS. 2 and 3, so that twenty-four probers are provided on vibrator head plate 170. The probers are arranged in four rows identified by the numerals 188a, 188b, 1880, and 188d, as shown in FIG. 7, and are positioned on vibrator head plate 170 so as to be centered in the compartments of track sections 84 when vibrator head plate 170 is lowered. Probers 18811 are located nearest forward lateral frame member 56 and the forward end of surfacing machine 20. The probers may be affixed to the bottom of vibrator head plate 170 as by welding. The depth of the probers from the bottom of the head plate to the end of the channel members may be slightly greater than the height of the bed joint dividers 94 and head joint plates 96 of track sections 84 so that when the probers 188 are inserted all the way into the compartment 85 of track sections 84, and vibrator head plate 170 rests on the upper surface of the track sections 84 in the lower flattened portion of track 82, the bottom of the channel member is slightly below the lower edges of the bed dividers and head joint plates. The depth of the probers may be made greater if desired, and as this dimension of the probers determines the amount by which the brick will be embedded in the concrete, it must be coordinated with the height of the projections 42 and the elevation of the concrete C in concrete form 22.
Vibrator head plate 170 is mounted on frame 50 for both vertical and horizontal movement with respect thereto. As noted above, the track sections in the lower flattened portion of track 82 moves rearwardly with respect to frame 50 so that vibrator head plate 170 will also move rearwardly with respect to frame 50 when probers 188 are inserted in the compartments of track sections 84. To maintain continuous operation of surfacing machine 20, vibrator head plate 170 must :be raised so that probers 188 are removed from the compartments of track sections 84, returned to a forward position, and then lowered so that the probers 188 are inserted into a different set of compartments 85 of the track sections 84. The vibrating head plate 170 is then moved rearwardly by the movement of frame 50 again.
To provide the necessary vertical and horizontal movement to vibrator head plate 170, a stationary side plate 190 may be affixed to the inside of longitudinal members 52 and 54 intermediate axles 60 and 62, as shown in FIG. 7. The plates are fastened to the frame members by means of bolts 191 which are inserted through the plates at slots 194 on either vertical edge of the plates and tightened. Slots 194 permit limited horizontal movement of side plates 190 with respect to frame members -2 and 54, so that the position of vibrator head plate 170 may be adjusted, as hereinafter described.
Stationary side plates 190 contain upper and lower pairs of rollers 196 and 198, rotatably mounted thereon. Sliding side plates 200 have parallel rods extending from the upper and lower edges thereof to engage rollers 196 and 198 so that sliding side plates 200 may be reciprocally moved in a longitudinal direction along stationary side plates 190 and longitudinal frame members 52 and 54.
A pair of vertical vibrator head plate guides 202 are fastened to sliding side plates 200, as by bolts 204 so that the L portions of bars 172 and 174 of vibrator head plate 170 fit between the guides for vertical movement with respect to sliding side plate 200. An elevating shaft bracket 206 is afiixed to the inner surface of vibrating head plate guides 202 for movement with sliding side plate 200 and to enclose the guide path for the L portions of bars 172 and 174. Elevating shaft bracket 206 includes notch 207 which allows vibrator head plate 170 to be raised.
Pillow blocks 208, mounted on the upper surfaces of elevating shaft brackets 206, journal elevator shaft 210 which extends laterally across frame 50 parallel to axles 60 and 62. Elevator shaft 210 contains a pair of pulleys 212 to which one end of chains 214 are afiixed. The other end of chains 214 are fixed to vibrating head plate 170 so that by rocking or partially rotating elevator shaft 210, vibrating head plate 170 may be raised or lowered.
Such partial rotation of shaft 210 may be provided by a rack and pinion mechanism, the pinion 216 of which is mounted on one end of shaft 210 and the rack 218 of which may be affixed to the end of piston 220 of air cylinder 222 fastened to flange 209 of elevating shaft bracket 206. By pneumatically extending piston 220 and by retracting piston 220 by means of spring 221, rack 218 is moved, pinion 216 rotated, and vibrating head plate 170 raised and lowered. A guide roller 224 may be provided to assist the movement of rack 218.
Rearward horizontal movement of vibrator head plate 170 is provided by inserting probers 188 in the compartments '85 of track sections 84 so that the vibrator head plate is carried rearwardly by the rearward movement of the track sections with respect to frame 50. Forward horizontal movement of vibrator head plate 170, when it is in the raised position, so that probers 188 are removed from compartments 85, is provided by air cylinders 226 and 228 mounted on the inside of frame members 52 and 54 and having extensible piston rods 230 and 232, the ends of which bear on sliding side plates 200. By pneumatically extending piston rods 230 and 232, sliding head plate 200 may be moved forward with respect to frame 50. Such forward movement may terminate at stop 233 mounted on frame 50 against which vibrator head plate is held by the extended piston rods 230 and 233. The amount of such forward movement may be slightly greater than the longitudinal dimension of the compartments in track section 84. Piston rods 230 and 232 may be retracted and moved out of abutment with sliding side plates 200 by springs 231 and 232.
Air cylinder 222, which raises and lowers vibrator head plate 170, and air cylinders 226 and 228, which move vibrating head plate 170 forward, are energized and controlled by the pneumatic system shown in FIG. 8. The air system is powered by a source of compressed air, such as compressor234. Compressor 234- supplies compressed air in pipe 236 to T connector 238 which, in turn, provides the compressed air to air lines 240 and 241.
Air line 240 is connected to valve 242 which is operated by a sensing means 244, mounted on frame 54 and which is responsive to the position of vibrator head plate 170 with respect to frame 50. Specifically, sensing means 244 may be mounted on frame member 54 so as to engage elevating shaft bracket 206 when the elevating shaft bracket and sliding side plate 200 have moved to a rearward position along frame member 54.
When sensing means 244 is actuated, valve 242 is Opened to allow air to enter air line 246 having check valve 248 interposed therein. The connection of sensing means 244 to valve 242 is indicated by the dotted line. The air in air line 246 operates air cylinder 222 to raise vibrator head plate 170 by means of rack 218 and pinion 216. Exhaust valve 250 is closed during this operation, as indicated in FIG. 8.
Air line 241 is connected to three-way valve 252 having an exhaust outlet 254 and a pressure outlet 256. The pressure outlet 256 is connected to air lines 258 and 260 which supply air cylinders 226 and 228.
A sensing means 262 is positioned on elevating shaft bracket 206 so as to be actuated by striking vibrator head plate 170 as the latter is raised by air cylinder 222. The actuation of sensing means 262 energizes air valve 252 to supply air from air line 241 to pressure outlet 256, as by rotating valve 252. The air pressure in pressure outlet 256 and air lines 258 and 260 operates air cylinders 226 and 228 to extend pistons 230 and 232 and move sliding side plates 200 and vibrator head plate 170 forward aggainst stop 233. The position of stationary side plates 190 on frame member 52 and 54 may be adjusted by means of slots 194 to insure that vibrator head plate 170 is held firmly against stop 233 by the extended pistons 230 and 232.
The forward movement of sliding side plates 200 and vibrating head plate 170 de-actuates sensing means 244, closing valve 242 and retaining piston 220 of air cylinder 222 in the extended position. This retains vibrator head plate 170 in the raised position.
A sensing means 264 is mounted on frame member 52 so as to be actutable by striking one of pins 266 extending from flange 88 of track section end plate 86. The sensing means is mounted on the frame member so as to be actuatable when the probers 188 are centered over the compartments in track sections 84 in the lower flattened portion of track 82. The actuation of sensing means 264 opens exhaust valve 250 to de-energize air cylinder 222 and retract piston 220 by means of spring 221. The retraction of piston 220 moves rack 218 to lower vibrator head plate and reinserts probers 188 into the compartments of track section 84. Compensation may be provided, in the positioning of sensing means 264, for the continuous movement of track section 84 with respect to frame 50, and particularly for that increment of movement occurring during the time the vibrator head plate 170 is being lowered.
As vibrator head plate 170 is lowered, sensing means 262 and valve 252 are de-actuated, de-energizing air cylinders 226 and 228, retracting the pistons 230 and 232 away from sliding side plates 200 by means of springs 269 and 271. The air in cylinders 226 and 228 is exhausted through valve 252 from pressure outlet 256 to exhaust outlet 254. Sliding side plates 200 are not affected by the retraction of pistons 230 and 232 because of the lack of any coupling between the members.
Vibrator head plate 170 and sliding side plates 200 are moved rearwardly with respect to frame 50 of brick laying machine 20, along with the track sections 84 in which probers 188 are inserted so as to again actuate 1 1 sensing 'means 244 when the vibrator head plate attains a rearwardposition, to repeat the operating cycle again.
It will be appreciated that the path of movement of vibrator head plate170', with respect'to frame 50 which carries it, is rectangular in that the vibrtaor head plate is initially moved rearwardly along withtrack sections 84, then moved upwardly by air cylinder 222, then forward by air cylinders 226 and 228 to a position hereinafter termed the raised, forward position and finally downwardly by air cylinder 222. The mount of the forward and rearward movement of vibrator head plate 170 is equal to thelongitudinal dimension of the compartment 85 of track sections 84 so that the vibrator head plate is advanced one row or course of compartments 85 with each operating cycle.
The sensing means and air valves may be electrically operated devices, as for example, electrical limit switches and solenoid operated air valves or may be mechanically operated,.or linked.
OPERATION OF THE SURFACING MACHINE The surfacing machine shown in the attached drawing employs pressed brick split in half so as to utilize two finished surfaces of the brick thereby reducing the cost of the brick required for the panel. The brick may be split by a masonry saw, or other means, along the center line of the brick and a diameter of the holes in the brick. The split bricks B are placed in the compartments 85 of the track sections 84 in the upper flattened portion of track 82 at a first station along the orbital path of the track, with the finished surfaces lying on retaining means 104 and the split surfaces exposed, as shown in FIG. 1.
Motor 128 is then energized to commence the operation of surfacing machine 20. Vibrator 180 may also be energized at this time. Motor 128 rotates axle 60 and discs 72 and 74 through the machine drive means. Rotation of axle 60 moves frame 50 forward with respect to track 82 so as to place additional track sections 84 on projections 42 at the front edge of the machine while removing track sections from projections 42 at the rear of the machine. Surfacing machine 20 moves along the vertical side walls 26 and 28 of form 22 by the engagement of projections 42 in holes 89 in flanges 88 of track section end plates 86.
The track sections 84 in the upper flattened portion of track 82 containing the split brick B are moved toward the forward end of surfacing machine 20 and drawn downwardly and around discs 72 and 74. As the track sections 84 attain a vertical position across the front of surfacing machine 20, the bricks b are retained in the track sections by spring plates 108. When the track sections move under discs 72 and 74, the bricks B are retained in the track sections by spring plates 110 and 112.
As the bricks B in the track sections reach the end of spring plates 112, they fall onto the exposed surface of the concrete C, a row at a time, so as to rest thereon while still being partially retained within the track section 84 forming the lower flattened portion of track 82. This point may hereinafter be termed the second station along the orbital path of track 82. The retention of the bricks in track sections 84 serves to position the rows or courses of brick against displacement along the surface of the concrete C in accordance with the dimensions of the bed joint dividers and head joint plates of the track sections 84. The track sections 84 do not move with respect to form 22 because of the engagement of holes 89 on projections 42.
As surfacing machine 20 continues to move forward, along form 22, the courses of brick deposited on the surface of the concrete C move rearwardly with respect to the machine. The first row, or course, of bricks B eventually reaches a position in which the bricks are directly under the first row of probers 188a when vibrator head plate 170 is in the raised, forward position. This may occur when five to six courses of bricks B have been deposited on the surface of concrete C. At this point, sensing means 264 strikes one of pins 266, actuating the sensing means and de-energizing air cylinder 222 to lower the vibrator head plate 170, so that the first row of prob ers 188a descends to strike the first course of brick B. The vibrations generated by vibrator 180 in probers 188a and the weight of head plate 170 embeds the first course of brick into the surface of the concrete.
The surfacing machine continues to move forward along form 22-to deposit additional courses of bricks b on the exposed surface of concrete C. The track sections 84 forming the lower flattened portion of track 82 continue to move rearwardly with respect to frame 50 of the machine. Vibrator head plate 170 is carried rearwardly with respect to frame 50' by track sections 84 due to the engagement of probers 188a in the compartments of track sections 84. When vibrator head has moved rearwardly a distance equal to the longitudinal dimension of the compartments of track section 84, elevator shaft bracket 206 actuates sensing means 244 to energize air cylinder 222 and raise vibrator head plate 170. Probers 188a disengage the first course of brick B on the surface of concrete C. When vibrator head plate 170 has been raised, sensing means 262 is actuated to cause air cylinders 226 and 228 to move the vibrator head plate 170 forward a distance equal to the longitudinal dimension of the compartments 85 so that the vibrator head plate 170 is returned to the forward, raised position. The vibrator head plate 170 is thus moved forward with respect to the courses of brick B lying on the surface of concrete C in form 22 to place the first row of probers 188a over the second course of brick B. When the vibrating plate 170 is positioned so that the probers are again centered over the compartments 85 of track section 84, sensing means 264 is actuated by another of pins 266 to de-energize air cylinder 222 and lower vibrator head plate 170. Due to the forward movement of vibrator head plate 170 the first row of probers 188a now descends to strike the second course of brick B to vibrate that course into the surface of the concrete.
The second row of probers 18811 on the vibrator head plate 170 descends onto the first course of brick so as to revibrate it into the surface of the concrete and to prevent those bricks from rising as the second row of brick is vibrated into the concrete. It will be appreciated that as the courses of brick are embedded in the exposed surface of the concrete, the surface of the concrete has a tendency to rise due to the displacement of the concrete by the bricks. Thus, as the second row of bricks is embedded in the concrete, the first row has a tendency to rise along with the concrete. The revibration of the first course of brick by the second row of probers 188b counteracts this tendency.
Further movement of surfacing machine 20 repeats the above operating cycle of the vibrating means so that during the third operating cycle the first row of probers 188a of the vibrator head plate 170 descends to strike the third course of brick B lying on the surface of the concrete C in concrete form 22. The second row of probers 18811 revibrates the second course of brick B while the third row of probers 188a again revibrates the first course of brick to restore it to its initial position as the third course of brick is embedded in the concrete.
Additional forward movement of surfacing machine 20 again repeats the above operating cycle so that the first row of probers 188a engages the fourth course of brick on the surface of the concrete C when vibrator head plate 170 is lowered. The second, third, and fourth rows of probers 188b, 1880, and 188d, revibrates the third, second and first courses of brick to retain them in their embedded positions.
At the beginning of the fifth operating cycle of the vibrating means of the machine, when the first row of probers 188a engages the fifth course of brick, the second third, and fourth rows of probers188b, 188C, and 188d revibrate the fourth,- third, and second courses of brick B. The first course of brick B is no longer revibrated, that course, and the surface of the concrete surrounding it, beingsufficiently far removed from the point where the fifth row of brick is being embedded in the surface of the concrete as to beunaffected by such embedment, and having been securely positioned in the surface of the concrete byfour successive applications of the probers 188 of vibrator headplate 170. In the case of a panel P utilizing split pressed brick B havingsemi-circular depressions along the split surface, the bricks must be embedded in the exposed surface of the concrete to an extent such that the semi-circulardepressions are completely below the surface of the concrete so as to prevent waterfrom accumulating-in the depressions and causing freeze damage. In a typical instance, such bricks B will be embedded onehalf inch in concrete C. vAssurfacing machine 20 moves along form 22, each course of brick deposited on the surface of the concrete is subjected to thesame treatment as described above, that is, it is initially vibrated into position by vibrator head plate 170 and the first row of probers 188a and then retained in that position by three re-applications of the probers 188 of vibrator head plate 170. The courses of brick undergo a decreasing vertical displacement with each successive vibration to arrive at their final position at the end of four operatingcyclesof vibrator head plate 170. As a course of brick and the track section '84 which formerly carried it approach the rear of bricklaying machine 20, the track section is pivoted up and away by discs 76 and 78. The shortened height of half bed joint dividers 92 and the location of hinge pin 102iin alignment with the upper surface of end plates 88 of the track section 84 allows the track section to so pivotwithout tipping the course of brickdirectlybelow the third or rear row of compartments in the track section. Track sections 84 then return to the upper flattened portion of track 82 to be reloaded with additional quantities of split brick B. t V t I THE METHOD The manufacture of a panel P in accordance with the present invention is initiated by moving surfacing machine 20 to a rearward position along form 22. The bulkheads 29 are inserted in form 22, spaced apart by a distance equal in length to the desired length of the finished panel. Collapsible cores 30 are inserted through bulkheads 29 and into concrete form 22 so as to lie parallel with vertical side walls 26 and 28. Turnbuckles 40 are adjusted to extend side plates 36 and 38 and expand cores 30. Reinforcing rods or prestressing strands and the like may be inserted in form 22, if desired, as may brackets BR.
Form 22 is then filled with the cementitious material, such as concrete C. The material must be of a consistency such that it is thin enough to allow the brick to be embedded therein by the vibrations generated by vibrator 180 and the weight of vibrator head plate 170, yet firm enough to support and prevent displacement of the bricks once they have been embedded in the desired position. In this regard and using concrete as a specific example, it has been found that concrete having a consistency such that it forms a four inch slump is most desirable. The term slump is utilized in the art as a measure of concrete consistency. A frustum of wet concrete twelve inches high, six inches in diameter at the bottom, and two inches in diameter at the top is formed and the amount by which the height of the frustum falls is measured. This distance, measured in inches, is termed the slump. A concrete frustum of four inch slump falls four inches in height. By way of comparison, wet concrete having a two to three inch slump is commonly used in the manufacture of precast, prestressed bridge girders while concrete having a five inch slump is used in ordinary concrete work and for concrete cast directly in place at the job site. The amount 14 of slump in wet concrete is determined by its ingredients. For example, large quantities of fine aggregates, such as sand, decrease the slump whereas large quantities of coarse aggregate increase the slump. The greater the amount of water in the wet concrete, the greater the slump.
Concrete C having the desired slump is poured into form 22 and struck off to the desired elevation. The elevation at which the concrete is struck must be correlated to the height of projections 42 and the depth of probers 188 so that surfacing machine 20 is positioned the correct distance above the exposed surface of the concrete in the form and the bricks are embedded in the concrete the desired amount. As the depression of the brick into the surface of the concrete causes a corresponding rise in the level of the concrete surface, it is essential that the concrete in the form be accurately struck off at the desired level.
After the concrete C is struck off in form 22, the courses of brick B are deposited on the exposed surface and embedded therein, as by the operation of surfacing machine 20 in the above described manner. When courses of bricks have been deposited along the entire length of concrete C in form 22, surfacing machine 20 may be placed aside for the remainder of the manufacturing process.
It is generally desirable to complete panel P by inserting mortar M between bricks B so as to give the completed panel the look of a conventionally laid brick wall and to seal the surface of the panel. The insertion of this mortar may be done in many ways, the following method being, at present, considered preferred.
A conventional brick motar is mixed, as from portland cement, lime, and sand. A small amount of water is added so that the resulting mortar is very dry. Sufficient water is added to the mortar so that it barely forms, and remains in, a ball when compressed by hand.
The mortar M so formulated is then shoveled over the entire surface of the completed panel, after which the surface is scraped to remove the excess mortar from the courses of bricks and insert it in the joints between the bricks. The surface of the bricks may be swept to further clean the exposed faces of the bricks.
A mortar frame, which may comprise a track section 84, having a half bed joint dividers replaced with full bed joint dividers, is then placed over the panel so that the bed joint dividers and head joint plates lie in the bed and head joints of the bricks in the panel. A vibrator, which may be similar to vibrator 180, is applied to the mortar frame to vibrate or tamp the mortar down to the proper elevation. The mortar frame and vibrator are moved about the panel so that each bed joint and head joint in the panel is tamped, after which the mortar frame and vibrator may be removed.
If desired, additional mortar may be applied to the joints so as to make them flush with the surface of the brick. The joints may also be tooled to form a concave, weather, V or other desired joint, either by hand tools, or by shaping the bottom of the head joint dividers and head joint plates to the desired configuration.
After the joints have been mortared, the panel is covered wtih a waterproof material and partially cured by the application of heat. A heated fluid such as steam may be inserted in the cores 30 to initiate the curing of the concrete adjacent the cores. The cores 30 are then collapsed and removed from the form and panel and the panel removed from the form. The panel is then fully cured by the reapplication of heat.
We claim:
1. A method for manufacturing a panel having a plurality of brick-like objects arranged in a predetermined, ordered pattern of rows, the objects being embedded in an exposed surface of cementitious material capable of supporting the objects, said method comprising the steps of:
forming a confined bed of cementitious material having an exposed surface;
placing the objects in a compartmented endless track in a plurality of successive traverse rows having the predetermined, ordered pattern at a first station removed from the exposed surface of the bed of material; conveying the rows of objects in the track in seriatim between the first station and a second station wherein the rows are located over the exposed surface by orbitally moving the track; sequentially partially discharging the rows of objects from the compartments of the track at the second station to deposit them on the exposed material surface while retaining them in the predetermined pattern against displacement along the exposed surface;
sequentially completely ejecting the deposited objects from the compartment and partially embedding them in the surface of the material; and
allowing the material to harden.
2. The method of claim 1 wherein the step of conveying the rows is further defined as conveying the rows of objects in a manner such that the rows enter the path of movement of the track at the first station one row at a time and wherein the step of sequentially partially discharging the objects is further defined as sequentially partially discharging the objects one row at a time and depositing the row on the exposed material surface.
3. The method of claim 1 wherein the step of sequentially ejecting the objects is further defined as applying vibratory blows to the objects to drive them out of the compartments and into the exposed surface of the bed of material.
4. The method of claim 3 wherein the step of sequentially ejecting the deposited objects is further defined as applying vibratory blows to a given row of objects to drive it into the exposed surface While simultaneously reapplying vibratory blows to an adjacent, previously deposited row of objects to prevent its displacement upon the embedment of said given row.
5. The method of claim 1 wherein the step of moving the rows of objects is further defined as moving the rows of objects in a semi-orbital path from the first station to the second station.
6. The method of claim 1 wherein the step of forming the bed of material is further defined as providing a form having internal dimensions correspondingto'the desired dimensions of said finished panel and pouring the material into said form; T
7. The method of claim 6 wherein said material is concrete and wherein the step of forming the concrete is further defined as including the step of compounding'a concrete mixture having approximately a 4" slump and forming a bed thereof. 9 p v 1 8. The method of claim 1 wherein said objects "are bricks and including-the step of splitting the brick prior to placing the bricks in the track. t
9. The method of claim 1 wherein the pattern of rows includes spaces between the objects and said method-includes the step of inserting mortar in-the spaces between the partially embeddedobjects.
10. The methodof claim 9 including the steps of distributing the mortar over the exposed surface of the bed of material and the partially embedded objects, scraping the mortar off the surface of the partially embedded objects into the 'spaces therebetween, tamping the mortar into the spaces and allowing the mortar to harden. 11. The method of claim10 including the step of tooling'the mortar after insertion in the spaces to give the spaces the appearance of mortared joints.
References Cited UNITED STATES PATEN S 3,629,384 12/1971 Elgenstierna 264 261 3,469,000 9/1969 Smith 264-69 X 3,359,354 12/1967 Johnson 26435 X 2,296,453 9/1942 Satfert 264-256X 857,581 6/1907 Boyle 264-314 3,012,901 12/1961 Reese 264-70X 3,203,069 8/1965 Wogulis er al. 26 4-261 x I OTHER REFERENCES Frost et ah: Modern Practical Brickworkj Batsford,
London (1956), pp. -55, 59, 276 and 277 relied on.
ROBERT F. WHITE, Primary Examiner w. E. HOAG, Assistant Examiner
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0182567A2 (en) * 1984-11-10 1986-05-28 Plasmor Insulation Limited Wall cladding
BE1012599A4 (en) * 1997-05-21 2001-01-09 Moors Jan Fixing technique for strips of bricks onto concrete panels
US6869553B1 (en) * 2002-07-12 2005-03-22 John D. Gentile Method for forming a precast brick riser
WO2015001169A1 (en) * 2013-07-04 2015-01-08 Nwg Tools Oy Tile assembling apparatus
US10676926B2 (en) * 2016-05-18 2020-06-09 Acquies Holding B.V. Device and method for adhering brick slips to a panel

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0182567A2 (en) * 1984-11-10 1986-05-28 Plasmor Insulation Limited Wall cladding
EP0182567A3 (en) * 1984-11-10 1987-08-05 Plasmor Insulation Limited Wall cladding
BE1012599A4 (en) * 1997-05-21 2001-01-09 Moors Jan Fixing technique for strips of bricks onto concrete panels
US6869553B1 (en) * 2002-07-12 2005-03-22 John D. Gentile Method for forming a precast brick riser
WO2015001169A1 (en) * 2013-07-04 2015-01-08 Nwg Tools Oy Tile assembling apparatus
US10676926B2 (en) * 2016-05-18 2020-06-09 Acquies Holding B.V. Device and method for adhering brick slips to a panel

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