US3252682A - Prefabricated concrete wall and roof form structure - Google Patents

Prefabricated concrete wall and roof form structure Download PDF

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US3252682A
US3252682A US50222A US5022260A US3252682A US 3252682 A US3252682 A US 3252682A US 50222 A US50222 A US 50222A US 5022260 A US5022260 A US 5022260A US 3252682 A US3252682 A US 3252682A
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concrete
wall
roof
section
sections
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Fabian F Soukup
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    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B1/00Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
    • E04B1/348Structures composed of units comprising at least considerable parts of two sides of a room, e.g. box-like or cell-like units closed or in skeleton form
    • E04B1/34815Elements not integrated in a skeleton
    • E04B1/34823Elements not integrated in a skeleton the supporting structure consisting of concrete
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B28WORKING CEMENT, CLAY, OR STONE
    • B28BSHAPING CLAY OR OTHER CERAMIC COMPOSITIONS; SHAPING SLAG; SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL, e.g. PLASTER
    • B28B7/00Moulds; Cores; Mandrels
    • B28B7/22Moulds for making units for prefabricated buildings, i.e. units each comprising an important section of at least two limiting planes of a room or space, e.g. cells; Moulds for making prefabricated stair units

Definitions

  • This invention relates to prefabricated concrete wall and roof forms. More particularly the present invention relates to structures of this character wherein the concrete units are reinforced by prestressed steel members.
  • prefabricated wall slabs or sections have been used widely for a number of years in building construction.
  • prefabricated wall slab or section is meant a wall slab or section made of concrete in a horizontal form and then tilted up, after removal of the form, to vertical position.
  • a three dimensional structure of this character that is, a structure which is not flat and which has a third dimension of large magnitude, is not easy to construct as one integral unit, and the structure is difficult to manipulate.
  • prestressing pretensioning and post-tensioning
  • Prestressing refers to the practice of applying tension to reinforcement members in concrete before a load is applied to the concrete. Prestressing can be carried out by pre-tensioning or by post-tensioning. In the former case (pre-tensioning) reinforcement cables or the like embedded in concrete are pulled or tensioned before the concrete has set and hardened. In the latter case (post-tensioning) the reinforcement cables or the like are pulled or tensioned after the concrete has set and hardened sufficiently to take compression, and it is accomplished by laying the cables in tubes which are embedded in the concrete, pulling the cables after the concrete has set and hardened, then filling the tubes with a concrete or grout mix and allowing it to harden. These are known techniques with which those skilled in the art are well acquainted.
  • FIGURE 1 is a perspective View of a form used in ac cordance with the invention to construct a concrete wall and roof unit.
  • FIGURE 2 is a transverse section taken through the form of FIGURE 1 shown filled with concrete.
  • FIGURE 3 is a perspective view of a filler strip employed with the form of FIGURE 1 to control the depth of the column and of the beam or rafter portions of the end product.
  • FIGURE 4 is a view in vertical midsection of the form of FIGURE 1 with concrete cast in place and with pretensioned reinforcement members also in place.
  • FIGURE 5 is a view similar to FIGURE 4 but wherein the reinforcement members are post-tensioned.
  • FIGURE 6 is a view in side elevation of a wall and roof unit constructed in accordance with the invention.
  • FIGURE 7 is a section taken along the line 77 of FIGURE 6.
  • FIGURE 8 is a view in end elevation of a building structure showing two wall and roof units (such as that shown in FIGURES 6 and 7) in erect, abutting relation.
  • FIGURE 9 is a perspective view of a modified type of form wherein the column and rafter elements of the wall and roof sections are intended to be on the exterior surface.
  • FIGURE 10 is a view in end elevation of a modified form of roof and wall unit in accordance with the invention.
  • a form is shown at 10 comprising a framework made up of base members 11, vertical members 13, and cross members 14.
  • the framework 11 may be of wood, steel, aluminum or any other desirable type of construction. It serves to support a form or mold surface 16 and side strips 17.
  • the form surface 16 is in two sections, 16a and 161), which adjoin one another at a peak 18 and which slope outwardly and downwardly therefrom to form an inverted V.
  • Each of the sections 16a and 16b is formed with a channel 19 which tapers in depth from the peak 18 to the bottom edge of the respective surface, so that the channel is deepest at the junction of the surface 16a or 16b and diminishes progressively in depth therefrom.
  • the form 10a is employed to produce a wall section and the form 10b is employed to produce a roof section.
  • Each form section 10a or 101) is channel-shaped in cross section as shown in FIGURE 2 and it tapers in cross section so that it is deeper near the center line.
  • a bulkhead 25 is provided.
  • the bulkhead 25 conforms to the cross sectional shape of the mold, it is movable to adjust the height of the wall section and the span of the roof section, and it is removable. It is held in place during use by any suitable means (not shown) such as wedges or nails.
  • a filler strip which is designated by the reference numeral 30 and which is tapered as shown.
  • a number of such filler strips are provided for each mold section 10a and 10b and each of them fits into its respective channel 19. Its purpose is to adjust the depth of the respective channel 19.
  • the filler strips 31 are of different thickness so that the channels 159 can be adjusted for a particular design. For example, if a shorter length of wall or a roof of shorter span is to be made, the channels 19 will be made shallower by selecting thicker filler strips.
  • the form 10 is there shown in vertical midsection.
  • the bulkheads 25 are shown in place.
  • steel cables 31 extending over the peak 18 and supported by members such as shown at 32 which serve to space the cables from the bottom of the form.
  • members such as shown at 32 which serve to space the cables from the bottom of the form.
  • Conventional steel reinforcement rods are shown at 31a which are not prestressed and which serve to provide strength for handling and compress-ion purposes.
  • the ends of the cables 31 are shown secured to anchor members 33.
  • Each cable will be pulled by a suitable means (not shown) such as jacks to apply a suitable tension and thereby prestress the cable. All inner surfaces of the form in contact with the concrete may be coated with a suitable release agent.
  • Concrete is then poured into the for-m starting at the bottom of each section 10a and ltlb adjacent the respective bulkhead 2S and progressing upwardly to the peak 18.
  • the concrete mix after having been poured, is screeded and leveled off flush with the side rails 17 and the bulkheads 25.
  • Two or more hooks 35 will be embedded :in the concrete before it hardens, such hooks being employed to hoist and manipulate the precast concrete unit when it is ready for removal from the form.
  • the concrete is allowed to set and harden sufiiciently to withstand the strain of lifting and removal from the form 10.
  • Suitable lift means such as a crane is used to hoist the concrete unit, employing the hook or hooks 35 to assist in this operation.
  • FIGURES 6 and 7 the resulting precast, prestressed, concrete roof and wall unit is there shown at 40. It is T-shaped in cross section as shown in FIGURE 7, comprising a body portion 41 and a column element 42a (or a rafter element 421)).
  • the body portion 41 as shown in FIGURE 6 comprises a wall section 41a and a roof section 41b. Shown in the wall section 41a are a door opening 43 and a window opening 44. Shown in the roof section 41b are roof openings 45 and 46, for example, for vents, pipes, chimneys, etc.
  • Openings such as those shown at 43, 44, 45 and 46 are very easily provided, whenever they are needed, by blocking off parts of the form 10 and then removing the blocking members after the concrete has hardened, thereby leaving openings such as those shown at 43, 44, 45 and 46 in FIGURE 5.
  • two roof and wall units 40 are there shown in erect position, each comprising a wall section 40:: and a roof section 40b. These are shown with the wall sections 40a upright and the roof sections 4011 abutting to form a peak.
  • roof sections 40b can be tied together at the peaks by any suitable means wellknown in the art and that the wall sections 40a can be seated upon and tied to a foundation by any suitable means (not shown). By repeating this operation a building of any desired length can be erected very rapidly.
  • the structural shape shown at 40 in FIGURES 6, 7 and 8 is advantageous. It provides both a wall section and a roof section. By using prestressed and pre-tensioned reinforcement members and by using the tapered column and rafter elements shown, a very strong structure is provided.
  • the forms shown are very advantageous because they facilitate casting the structures and they also facilitate storage and transport. For example, a large number of forms can be used and the concrete structures left on the forms and/or transported while still on the forms. Alternatively only one or a few forms can be employed.
  • the units 40 lend themselves to transportation by rail and by truck or highways.
  • a roof and wall unit 40 for a building having a fifty foot span can be laid on the bed of a truck or trailer and fall within the tolerance limits on height which are specified in many of the States.
  • the system is flexible because it offers a choice of making the units at a central plant and transporting the finished unit to the construction site, or making the units at the site. Also, the units are easily lifted, e.g., by a single crane.
  • FIGURE 4 illustrates how post-tensioning can be carried out in accordance with the invention.
  • the form 10 is the same as that shown in FIGURE 4, and similar parts are similarly numbered.
  • tubes 50 are supported in the form by any suitable means and reinforcement cables 31 are passed through these tubes.
  • reinforcement cables 31 are provided at 31a as in FIGURE 4.
  • Concrete is poured, screeded and levelled as described above in connection with FIGURE 4, and it is allowed to set and harden enough to resist compression. Then the steel cables 31 are tensioned.
  • This post-tensioning can be accomplished by fastening keeper members (not shown) to one end of each cable, and applying a jack to the other end of each cable, the jack reacting against the concrete structure. Then each tube 50 is filled with a grout or concrete mix, which is allowed to set and harden. Then the protruding ends of the cables are cut off.
  • the order of post-tensioning and filling the tubes 50 with grout or concrete may be reversed.
  • the tubes 50 can be filled with grout or concrete by forcing the wet mix into one end of each tube 50 until it comes out the other end.
  • a filler tube 51 may connect to each tube 4 50 at its peak and the met mix filled through this tube, which will be cut off after the tubes 50 have been filled.
  • This technique of post-tension ing is advantageous for on-site jobs, where units 40 are made at the construction site and where the extra equipment used in the pre-tensioning technique is not available. Thus, all that is needed is a means of anchoring the form 10 and cast unit 40, and a means such as a winch and pulleys, or a jack to post-tension the cables 31.
  • an inverted form is there shown which is generally designated by the reference number 55. It comprises two sections 10a and 10b as in the case of the form 10 shown in FIGURE 1. However, the sections 10a and 10b form a valley with its low point at 18.
  • the numeral 56 indicates generally a framework or support for this form which may be a solid block or a wooden or steel framework such as that shown in FIGURE 1, suitably modified.
  • Bulkheads, filler strips and blocking members will be employed as in the case of form 10 in FIGURE 1.
  • cables will be located within the form as described above in connection with FIGURE 4 or FIGURE 5 and will be preor post-tensioned cables.
  • Concrete will be poured commencing at the low point 18 and moving upwardly along each section 10a and 10b.
  • the concrete will be screeded, levelled, allowed to set and harden and then removed from the mold.
  • the resulting precast, prestressed concrete roof and wall unit Will be identical with that shown in FIGURES 6, 7 and 8 except that the column and rafter elements will be on the outside of the unit rather than on the inside.
  • FIGURE 10 an end elevational view of a prestressed, precast concrete unit 60 is there shown having a body portion 61 and a portion 62 constituting the column element of a wall section or the rafter element of a roof section.
  • the portion 62 is formed with a longitudinal passage 63.
  • This structure will be made in the same way as the structure 40 shown in FIGURES 6, 7 and 8 except that the channel 19 of the form 10 will have a suitable blocking member located within it to 'block out a portion of the channel, such blocking member being removable when the concrete has set and hardened. Alternatively if the blocking member is hollow, it may remain in the finished concrete structure.
  • the passageway 63 has the advantage that it lightens the Weight of the finished product. Also, these passageways serve as ducts to carry piping, for flow of a heating or cooling fluid and for other purposes.
  • a single form such as shown at 10 in FIGURE 1 can be adjusted for thicker and thinner slabs by adjusting the side walls 17, for shorter or longer slabs by adjusting the bulkheads 25 and for deeper or shallower ribs by selection of filler strips 30.
  • a form for producing a monolithic precast concrete structure comprising a pair of form sections
  • each of said sections including a bottom surface sufficiently wide to form a building wall or roof section, upright walls secured along the sides of said surface to confine fluid concrete to the desired thickness of side wall or roof section, and a unitary channel 5 6 member depending from and opening into said bOt- 7.
  • said sections diverge tom surface for formation of an integral reinforcing upwardly from said apex. column or beam, said sections being joined at adjacent ends with the References Cited y the Examiner bottom surfaces and the channels thereof disposed 5 UNITED STATES PATENTS at relatively fixed angles to each other and to the horizontal for formation of a continuous wall and roof section with integral column and beams.

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Description

F. F. SOUKUP May 24, 1966 PREFABRICATED CONCRETE WALL AND ROOF FORM STRUCTURE 4 Sheets-Sheet 1 Filed Aug. 17, 1960 INVENTOR FABIAN F. SOUKUP Ila-El ATTORNEY F. F. SOUKUP May 24, 1966 PREFABRICATED CONCRETE WALL AND ROOF FORM STRUCTURE 4 Sheets-Sheet 2 Filed Aug. 17, 1960 INVENTOR.
FABIAN F. SOUKUP ATTORNEY May 24, 1966 F. F. SOUKUP 3,252,682
PREFABRICATED CONCRETE WALL AND ROOF FORM STRUCTURE Filed Aug. 17, 1960 4 Sheets-Sheet 5 11" i-.j "11 l 400 I I E En INVENTOR.
FABIAN F. SOUKUP BY M ATTORNEY May 24, 1966 F. F. SOUKUP 3,252,682
PREFABRIGATED CONCRETE WALL AND ROOF FORM STRUCTURE Filed Aug. 17, 1960 4 Sheets-Sheet L INVENTOR.
FABIAN F. SOUKUP ATTORNEY United States Patent 3,252,682 PREFABRICATED CONCRETE WALL AND ROQF FORM STRUCTURE Fabian F. Soukup, Box 322, Healdsburg, Calif. Filed Aug. 17, 1960, Ser. No. 50,222 7 Claims. (Cl. 249158) This invention relates to prefabricated concrete wall and roof forms. More particularly the present invention relates to structures of this character wherein the concrete units are reinforced by prestressed steel members.
Prefabricated wall slabs or sections have been used widely for a number of years in building construction. By prefabricated wall slab or section is meant a wall slab or section made of concrete in a horizontal form and then tilted up, after removal of the form, to vertical position.
There is an advantage in applying such technique to wall and roof units but extension of the technique to include a roof section integral with a wall section is difficult. A three dimensional structure of this character, that is, a structure which is not flat and which has a third dimension of large magnitude, is not easy to construct as one integral unit, and the structure is difficult to manipulate.
It is another particular object of the invention to provide a facile, dependable means of prefabricating integral wall and roof units of concrete.
The above and other objects of the invention will be apparent from the ensuing description and the appended claims.
Inasmuch as the terms prestressing, pretensioning and post-tensioning are used herein, it is appropriate to define them.
Prestressing, as used herein, refers to the practice of applying tension to reinforcement members in concrete before a load is applied to the concrete. Prestressing can be carried out by pre-tensioning or by post-tensioning. In the former case (pre-tensioning) reinforcement cables or the like embedded in concrete are pulled or tensioned before the concrete has set and hardened. In the latter case (post-tensioning) the reinforcement cables or the like are pulled or tensioned after the concrete has set and hardened sufficiently to take compression, and it is accomplished by laying the cables in tubes which are embedded in the concrete, pulling the cables after the concrete has set and hardened, then filling the tubes with a concrete or grout mix and allowing it to harden. These are known techniques with which those skilled in the art are well acquainted.
Certain forms of the invention are illustrated by way of example in the accompanying drawings, in which:
FIGURE 1 is a perspective View of a form used in ac cordance with the invention to construct a concrete wall and roof unit.
FIGURE 2 is a transverse section taken through the form of FIGURE 1 shown filled with concrete.
FIGURE 3 is a perspective view of a filler strip employed with the form of FIGURE 1 to control the depth of the column and of the beam or rafter portions of the end product.
FIGURE 4 is a view in vertical midsection of the form of FIGURE 1 with concrete cast in place and with pretensioned reinforcement members also in place.
FIGURE 5 is a view similar to FIGURE 4 but wherein the reinforcement members are post-tensioned.
FIGURE 6 is a view in side elevation of a wall and roof unit constructed in accordance with the invention.
FIGURE 7 is a section taken along the line 77 of FIGURE 6.
FIGURE 8 is a view in end elevation of a building structure showing two wall and roof units (such as that shown in FIGURES 6 and 7) in erect, abutting relation.
3,252,682 Patented May 24, 1966 FIGURE 9 is a perspective view of a modified type of form wherein the column and rafter elements of the wall and roof sections are intended to be on the exterior surface.
FIGURE 10 is a view in end elevation of a modified form of roof and wall unit in accordance with the invention.
Referring now to the drawings and more particularly to FIGURE 1, a form is shown at 10 comprising a framework made up of base members 11, vertical members 13, and cross members 14. The framework 11 may be of wood, steel, aluminum or any other desirable type of construction. It serves to support a form or mold surface 16 and side strips 17. It will be seen that the form surface 16 is in two sections, 16a and 161), which adjoin one another at a peak 18 and which slope outwardly and downwardly therefrom to form an inverted V. Each of the sections 16a and 16b is formed with a channel 19 which tapers in depth from the peak 18 to the bottom edge of the respective surface, so that the channel is deepest at the junction of the surface 16a or 16b and diminishes progressively in depth therefrom.
In effect a double form 10a and 10b is thereby provided. The form 10a, as explained hereinafter, is employed to produce a wall section and the form 10b is employed to produce a roof section. Each form section 10a or 101) is channel-shaped in cross section as shown in FIGURE 2 and it tapers in cross section so that it is deeper near the center line. As there shown a bulkhead 25 is provided. The bulkhead 25 conforms to the cross sectional shape of the mold, it is movable to adjust the height of the wall section and the span of the roof section, and it is removable. It is held in place during use by any suitable means (not shown) such as wedges or nails. There is, of course, one bulkhead for each mold section 10a and 10b, and preferably an assortment of bulkheads is provided to conform to the carrying depth of the channels 19.
Referring to FIGURE 3 a filler strip is shown which is designated by the reference numeral 30 and which is tapered as shown. A number of such filler strips are provided for each mold section 10a and 10b and each of them fits into its respective channel 19. Its purpose is to adjust the depth of the respective channel 19. The filler strips 31 are of different thickness so that the channels 159 can be adjusted for a particular design. For example, if a shorter length of wall or a roof of shorter span is to be made, the channels 19 will be made shallower by selecting thicker filler strips.
Referring now to FIGURE 4, the form 10 is there shown in vertical midsection. The bulkheads 25 are shown in place. Also shown are steel cables 31 extending over the peak 18 and supported by members such as shown at 32 which serve to space the cables from the bottom of the form. (Conventional steel reinforcement rods are shown at 31a which are not prestressed and which serve to provide strength for handling and compress-ion purposes.) The ends of the cables 31 are shown secured to anchor members 33. Each cable will be pulled by a suitable means (not shown) such as jacks to apply a suitable tension and thereby prestress the cable. All inner surfaces of the form in contact with the concrete may be coated with a suitable release agent. Concrete is then poured into the for-m starting at the bottom of each section 10a and ltlb adjacent the respective bulkhead 2S and progressing upwardly to the peak 18. The concrete mix, after having been poured, is screeded and leveled off flush with the side rails 17 and the bulkheads 25. Two or more hooks 35 will be embedded :in the concrete before it hardens, such hooks being employed to hoist and manipulate the precast concrete unit when it is ready for removal from the form. The concrete is allowed to set and harden sufiiciently to withstand the strain of lifting and removal from the form 10. Suitable lift means (not shown) such as a crane is used to hoist the concrete unit, employing the hook or hooks 35 to assist in this operation.
Referring now to FIGURES 6 and 7, the resulting precast, prestressed, concrete roof and wall unit is there shown at 40. It is T-shaped in cross section as shown in FIGURE 7, comprising a body portion 41 and a column element 42a (or a rafter element 421)). The body portion 41 as shown in FIGURE 6 comprises a wall section 41a and a roof section 41b. Shown in the wall section 41a are a door opening 43 and a window opening 44. Shown in the roof section 41b are roof openings 45 and 46, for example, for vents, pipes, chimneys, etc. Openings such as those shown at 43, 44, 45 and 46 are very easily provided, whenever they are needed, by blocking off parts of the form 10 and then removing the blocking members after the concrete has hardened, thereby leaving openings such as those shown at 43, 44, 45 and 46 in FIGURE 5.
Referring to FIGURE 8, two roof and wall units 40 are there shown in erect position, each comprising a wall section 40:: and a roof section 40b. These are shown with the wall sections 40a upright and the roof sections 4011 abutting to form a peak.
It will be understood that the roof sections 40b can be tied together at the peaks by any suitable means wellknown in the art and that the wall sections 40a can be seated upon and tied to a foundation by any suitable means (not shown). By repeating this operation a building of any desired length can be erected very rapidly.
The structural shape shown at 40 in FIGURES 6, 7 and 8 is advantageous. It provides both a wall section and a roof section. By using prestressed and pre-tensioned reinforcement members and by using the tapered column and rafter elements shown, a very strong structure is provided. The forms shown are very advantageous because they facilitate casting the structures and they also facilitate storage and transport. For example, a large number of forms can be used and the concrete structures left on the forms and/or transported while still on the forms. Alternatively only one or a few forms can be employed.
Among other advantages the following may be mentioned: The units 40 lend themselves to transportation by rail and by truck or highways. For example, a roof and wall unit 40 for a building having a fifty foot span can be laid on the bed of a truck or trailer and fall within the tolerance limits on height which are specified in many of the States. The system is flexible because it offers a choice of making the units at a central plant and transporting the finished unit to the construction site, or making the units at the site. Also, the units are easily lifted, e.g., by a single crane.
The technique described with reference to FIGURE 4 comprises pre-tensioning the cables 31. FIGURE illustrates how post-tensioning can be carried out in accordance with the invention. The form 10 is the same as that shown in FIGURE 4, and similar parts are similarly numbered. However, tubes 50 are supported in the form by any suitable means and reinforcement cables 31 are passed through these tubes. (Conventional, non-prestressed steel rods are provided at 31a as in FIGURE 4.) Concrete is poured, screeded and levelled as described above in connection with FIGURE 4, and it is allowed to set and harden enough to resist compression. Then the steel cables 31 are tensioned. This post-tensioning can be accomplished by fastening keeper members (not shown) to one end of each cable, and applying a jack to the other end of each cable, the jack reacting against the concrete structure. Then each tube 50 is filled with a grout or concrete mix, which is allowed to set and harden. Then the protruding ends of the cables are cut off. The order of post-tensioning and filling the tubes 50 with grout or concrete may be reversed. The tubes 50 can be filled with grout or concrete by forcing the wet mix into one end of each tube 50 until it comes out the other end. Alternatively, a filler tube 51 may connect to each tube 4 50 at its peak and the met mix filled through this tube, which will be cut off after the tubes 50 have been filled.
This technique of post-tension ing is advantageous for on-site jobs, where units 40 are made at the construction site and where the extra equipment used in the pre-tensioning technique is not available. Thus, all that is needed is a means of anchoring the form 10 and cast unit 40, and a means such as a winch and pulleys, or a jack to post-tension the cables 31.
Referring now to FIGURE 9, an inverted form is there shown which is generally designated by the reference number 55. It comprises two sections 10a and 10b as in the case of the form 10 shown in FIGURE 1. However, the sections 10a and 10b form a valley with its low point at 18. The numeral 56 indicates generally a framework or support for this form which may be a solid block or a wooden or steel framework such as that shown in FIGURE 1, suitably modified.
Bulkheads, filler strips and blocking members will be employed as in the case of form 10 in FIGURE 1. Also, cables will be located within the form as described above in connection with FIGURE 4 or FIGURE 5 and will be preor post-tensioned cables. Concrete will be poured commencing at the low point 18 and moving upwardly along each section 10a and 10b. The concrete will be screeded, levelled, allowed to set and harden and then removed from the mold. The resulting precast, prestressed concrete roof and wall unit Will be identical with that shown in FIGURES 6, 7 and 8 except that the column and rafter elements will be on the outside of the unit rather than on the inside.
Referring now to FIGURE 10, an end elevational view of a prestressed, precast concrete unit 60 is there shown having a body portion 61 and a portion 62 constituting the column element of a wall section or the rafter element of a roof section. As will be seen, the portion 62 is formed with a longitudinal passage 63. This structure will be made in the same way as the structure 40 shown in FIGURES 6, 7 and 8 except that the channel 19 of the form 10 will have a suitable blocking member located within it to 'block out a portion of the channel, such blocking member being removable when the concrete has set and hardened. Alternatively if the blocking member is hollow, it may remain in the finished concrete structure. The passageway 63 has the advantage that it lightens the Weight of the finished product. Also, these passageways serve as ducts to carry piping, for flow of a heating or cooling fluid and for other purposes.
It will, therefore, be apparent that a novel and very useful structural shape has been provided consisting of an integral, precast and preferably prestressed concrete wall and roof section, and that a very novel and advantageous means of prefabricating such an article has been provided. The invention has been described in relation to wall and roof sections wherein the roof forms an obtuse angle with the wall. However, the invention can be applied to sections with a flat roof to the wall) and it can also be applied to inverted V-shaped structures wherein the sloping wall sections are formed which come together at an acute angle. The technique has desirable features of adjustability. For example, a single form such as shown at 10 in FIGURE 1 can be adjusted for thicker and thinner slabs by adjusting the side walls 17, for shorter or longer slabs by adjusting the bulkheads 25 and for deeper or shallower ribs by selection of filler strips 30.
I claim:
1. A form for producing a monolithic precast concrete structure comprising a pair of form sections,
each of said sections including a bottom surface sufficiently wide to form a building wall or roof section, upright walls secured along the sides of said surface to confine fluid concrete to the desired thickness of side wall or roof section, and a unitary channel 5 6 member depending from and opening into said bOt- 7. The form of claim 1 wherein said sections diverge tom surface for formation of an integral reinforcing upwardly from said apex. column or beam, said sections being joined at adjacent ends with the References Cited y the Examiner bottom surfaces and the channels thereof disposed 5 UNITED STATES PATENTS at relatively fixed angles to each other and to the horizontal for formation of a continuous wall and roof section with integral column and beams.
2. The form defined in claim 1 wherein the channel depending from the bottom surfaces of 10 each section is progressively deeper toward said adjacent ends.
3. In combination with the form defined in claim 1 spacer members insertable in said sections and adapted 2,031,899 2/1936 Mattes 25-1 2,280,832 4/1942 Ketcham.
2,294,528 9/ 1942 Wells.
2,393,055 1/1946 Negrin.
2,455,153 11/1948 Abeles.
2,750,646 6/1956 Reidenbach 251 2,786,349 3/1957 Golf.
2,897,688 8/1959 Graham.
3 041 702 7/ 1962 Schwab 2S154 to support metal reinforcement members along the 15 lengths of said Sections 3,055,146 9/1962 Lobato 25118 4. The form defined in claim 1 including FOREIGN PATENTS members insertable in said sections to blank out wall 652 483 10/1928 France or root openings. 2 1 47 5. The open form defined by claim 1 including 20 6 5 19952 2: 2: 2
21 bulkhead for each section which is removable from and insertable in its respective section at a selected SPENCER ()VERHOLSER, Primary Examiner,
dlstance from sa1d oint ad acent ends to conform JACOB L NACKENOFF MORRIS LEIBMAN ALEX ilegigaglgistgrltiis cross section of sa1d section at sa1d ANDER H. BRODMERKEL, Examiners.
2o 6. The form of claim 1 wherein said sections diverge R. B. MOFFITI, J. SHAPIRO, Assistant Examiners. downwardly from said apex.

Claims (1)

1. A FORM FOR PRODUCING A MONOLITHIC PRECAST CONCRETE STRUCTURE COMPRISING A PAIR OF FORM SECTIONS, EACH OF SAID SECTIONS INCLUDING A BOTTOM SURFACE SUFFICIENTLY WIDE TO FORM A BUILDING WALL OR ROOF SECTION, UPRIGHT WALLS SECURED ALONG THE SIDES OF SAID SURFACE TO CONFINE FLUID CONCRETE TO THE DESIRED THICKNESS OF SIDE WALL OR ROOF SECTION, AND A UNITARY CHANNEL MEMBER DEPENDING FROM AND OPENING INTO SAID BOTTOM SURFACE FOR FORMATION OF AN INTEGRAL REINFORCING COLUMN OR BEAM, SAID SECTIONS BEING JOINED AT ADJACENT ENDS WITH THE BOTTOM SURFACES AND THE CHANNELS THEREOF DISPOSED
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US20080149808A1 (en) * 2006-12-20 2008-06-26 Canadian Rockport Homes Ltd. Method and apparatus for producing concrete structures
US20100162651A1 (en) * 2008-12-31 2010-07-01 The Spancrete Group, Inc. Concrete roof panel

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FR652483A (en) * 1928-01-26 1929-03-08 T in reinforced concrete, contiguous, can be used for all floors
US2031899A (en) * 1934-09-17 1936-02-25 Decatur Brick Mfg Company Indenting and suamping machine for clay products, such as paving brick and the like
US2280832A (en) * 1940-01-02 1942-04-28 Alvin C Ketcham Building
US2294528A (en) * 1940-02-14 1942-09-01 Robert D Wells Composite structural element
US2393055A (en) * 1942-02-04 1946-01-15 Johannes Fredricus Ludovicus N Greenhouse structure
FR922815A (en) * 1946-01-07 1947-06-19 Entpr S Legros Raineteau & Cie Process for the economical and rapid construction of warehouses, warehouses or agricultural or industrial workshops entirely in reinforced concrete
US2455153A (en) * 1942-03-03 1948-11-30 Abeles Paul William Composite structural member
FR1006647A (en) * 1947-12-29 1952-04-25 Coloniale D Entpr S Et De Cons Improved method of construction by prefabricated elements, prefabricated elements used in the implementation of this process and constructions thus obtained
US2750646A (en) * 1952-03-27 1956-06-19 Gen Clay Products Company Ceramic column texturing machines
US2786349A (en) * 1951-01-16 1957-03-26 Coff Leo Prestressed concrete building
US2897688A (en) * 1955-09-12 1959-08-04 Graybill Ind Inc Hydraulic transmission mechanism
US3041702A (en) * 1957-10-15 1962-07-03 United States Steel Corp Method of making a prestressed reinforced concrete structure
US3055146A (en) * 1958-10-17 1962-09-25 Lobato Florentino Concrete stairway

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Publication number Priority date Publication date Assignee Title
FR652483A (en) * 1928-01-26 1929-03-08 T in reinforced concrete, contiguous, can be used for all floors
US2031899A (en) * 1934-09-17 1936-02-25 Decatur Brick Mfg Company Indenting and suamping machine for clay products, such as paving brick and the like
US2280832A (en) * 1940-01-02 1942-04-28 Alvin C Ketcham Building
US2294528A (en) * 1940-02-14 1942-09-01 Robert D Wells Composite structural element
US2393055A (en) * 1942-02-04 1946-01-15 Johannes Fredricus Ludovicus N Greenhouse structure
US2455153A (en) * 1942-03-03 1948-11-30 Abeles Paul William Composite structural member
FR922815A (en) * 1946-01-07 1947-06-19 Entpr S Legros Raineteau & Cie Process for the economical and rapid construction of warehouses, warehouses or agricultural or industrial workshops entirely in reinforced concrete
FR1006647A (en) * 1947-12-29 1952-04-25 Coloniale D Entpr S Et De Cons Improved method of construction by prefabricated elements, prefabricated elements used in the implementation of this process and constructions thus obtained
US2786349A (en) * 1951-01-16 1957-03-26 Coff Leo Prestressed concrete building
US2750646A (en) * 1952-03-27 1956-06-19 Gen Clay Products Company Ceramic column texturing machines
US2897688A (en) * 1955-09-12 1959-08-04 Graybill Ind Inc Hydraulic transmission mechanism
US3041702A (en) * 1957-10-15 1962-07-03 United States Steel Corp Method of making a prestressed reinforced concrete structure
US3055146A (en) * 1958-10-17 1962-09-25 Lobato Florentino Concrete stairway

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20080149808A1 (en) * 2006-12-20 2008-06-26 Canadian Rockport Homes Ltd. Method and apparatus for producing concrete structures
US20100162651A1 (en) * 2008-12-31 2010-07-01 The Spancrete Group, Inc. Concrete roof panel
US8763317B2 (en) * 2008-12-31 2014-07-01 The Spancrete Group, Inc. Concrete roof panel

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