US3618886A

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Publication number: US3618886A
Application number: US843037A
Authority: US
Inventors: Phillip Graham
Original assignee: Individual
Current assignee: Individual
Priority date: 1969-07-18
Filing date: 1969-07-18
Publication date: 1971-11-09
Anticipated expiration: 1988-11-09

Abstract

This invention pertains to a low cost adjustable form that can be adjusted for forming various types of two-way curved, precast, reinforced thin shell cementitious and plastic panels for small spanned building shells having uniform scalloplike, corrugated shells like the shells shown in my U.S. Pat. No. 3,154,888 and to the method of making the same. The form can be adjusted so as to mold different original types of panels, that differ by having different curvature, and/or different size. The form has a base with an adjustable template frame. A thin reinforced base coating is mounted within the template frame. An elastic edge form that is like a gasket, is secured to the template frame with metallic fasteners. The elastic edge form molds a keying groove in the panel edging. The fasteners position reinforcing and clevis connectors that are attached to the reinforcing, to allow like panels to be easily joined with pins at erection, even during inclement weather, the keying grooves allowing the panels to be keyed together with grout when the weather is suitable.

Description

United States Patent 72] Inventor Phillip Graham 2825 Glenmore Ave., Pittsburgh, Pa. 15216 [21] Appl. No. 843,037 [22] Filed July 18, 1969 [45] Patented Nov. 9, 1971 Continuation-impart of application Ser. No. 802,348, Feb. 26, 1969, now abandoned Continuation-impart of application Ser. No. 540,314, Apr. 5, 1966, now Patent No. 3,467,354.

[54] ADJUSTABLE PANEL FORM FOR THINSHELLS 13 Claims, 43 Drawing Figs.

[52] U.S. Cl 249/13, 249/155, 249/210 [51] Int.Cl B28b 7/02,B28b 7/22 [50] Field of Search 249/13, 209,210,159, 160,112, 155;25/l2l R, 121 M, 131 P Primary Examiner-Robert D, Baldwin Attorney-William J. Ruano ABSTRACT: This invention pertains to a low cost adjustable form that can be adjusted for forming various types of twoway curved, precast, reinforced thin shell cementitious and plastic panels for small spanned building shells having uniform scalloplike, corrugated shells like the shells shown in my U.S. Pat. No. 3,154,888 and to the method of making the same. The form can be adjusted so as to mold different original types of panels, that differ by having different curvature, and/or different size. The form has a base with an adjustable template frame. A thin reinforced base coating is mounted within the template frame. An elastic edge form that is like a gasket, is secured to the template frame with metallic fasteners. The elastic edge form molds a keying groove in the panel edging. The fasteners position reinforcing and clevis connectors that are attached to the reinforcing, to allow like panels to be easily joined with pins at erection even during inclement weather, the keying grooves allowing the panels to be keyed together with grout when the weather is suitable.

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This invention relates to improvements in adjustable panel form for molding thin shell cementitious and plastic panels. The fonn can be adjusted to mold two-way curved panels of selective longitudinal curvature and panels that are straight longitudinally and curved transversely, which can be readily interlocked or bonded together to obtain an integral building shell.

This invention particularly refers to a highly efficient and nearly foolproof, low cost, adjustable form that has an adjustable base and an elastic edge form that allows quick and accurate molding of various shapes and sizes of small curved precast, reinforced thin shell concrete panels, and to the method of making the same. In general,'the form is reusable to allow many types of original panels to be molded, thus eliminating the need to make numerous costly forms that could not economically be altered to allow for different curvatures. Thus the form eliminates the great fault that has prevented much usage of thin shell precast panel construction for small spanned buildings.

My copending application Ser. No. 540,314 and my U.S. Pat. Nos. 3,161,938; 3,224,726 and 3,245,647 describe limited simplified form means, and my U.S. Pat. Nos. 3,154,888 and 2,971,237, describe various shapes of panels that can be formed with the adjustable form, and how such panels can be used to build houses and other types of shelters; in addition, these patents list my numerous related patents that supplement the adjustable form means in building shelters.

The invention allows semiskilled labor to setup the form with parts of the form being selectively adjusted so as to mold two-way curved panels of selective longitudinal and transverse curvature, or straight panels with transverse curvature and in which the form includes fastener means to allow accurate positioning of reinforcing connectors along the edges of the panels so that like panels can be quickly and securely joined with pins at erection.

The adjustable form has improvements over the form combinations described in my copending application Ser. No. 540,314, and in my earlier applications and patents. The improved form includes an original base that is made up of components that can be selectively adjusted so as to mold a panel having different curvature. These improvements greatly reduce the cost of an original base over the mass base of cementitious materials described in my older applications. The adjustable form can be dismantled to make it compact for ease in handling and for low cost storage and shipping. In addition, the adjustable form that is assembled could be moved readily, as it would not be as heavy as the old form having a mass base.

The adjustable form could be used repeatedly in differently curved setups, for two-way curved panels and in transversely curved panels that are straight in length, without materially deteriorating. When the form has outlived its usefulness, most of its parts could be disposed of at little cost.

The form having the old mass base would require much skill to make the base and the old base would require the use of a great amount of material.

The form having the old mass base could not be used to mold panels that differed in longitudinal curvature, or transverse curvature; the form having the old base is heavy, bulky, and thus costly to store and to ship, in addition, the mass base would be difficult to dispose of after it has served its purpose.

There is need for a low cost form for molding small thin shell precast panels, since in such thin shell construction, a small amount of low cost building material is shaped to force it to work at optimum efficiency. Engineers throughout the world think that small thin shells would be ideal for low cost dwellings, if a means to reduce the form costs is developed, as the cost of conventional forms for molding small precast thin shell panels is prohibitive. There is need for such thin shell type of construction to allow unskilled labor to construct extremely low cost, strong, durable, fireproof buildings, particularly in rural areas and undeveloped areas.

An object of my invention is to provide an adjustable form for molding curved thin shell cementitious and plastic panels. The form having adjusting means to allow it to be selectively curved longitudinally and transversely so it can be used to mold two-way curved panels and adjusting means to straighten it in length, so as to mold straight panels having transverse curvature, adjusting means to selectively size the panels to be cast, an elastic strip portion that molds a grooved panel edging and adjustable template means to position reinforcing connectors around a panel edging, so that like panels can be easily and securely joined at erection.

Other objects of my invention will become apparent from the following description taken with the accompanying drawings wherein:

FIG. 1 is an elevational view showing an adjustable form that is set up to mold a thin two-way curved reinforced concrete panel;

FIG. 2 is a plan view taken along line 2-2 of FIG. 1;

FIG. 3 is a sectional view taken along line 3-3 of FIG. 1;

FIG. 4 is an elevational view taken along line 4-4 of FIG. 1;

FIG. 5 is an elevational view that is similar to FIG. 1, but it shows the form adjusted to mold a differently shaped panel that is partially straight in length;

FIG. 6 is an elevational view that is similar to FIG. 1, but it shows the form adjusted to mold a panel that is oppositely curved longitudinally to the panel shown in FIG. 1;

FIG. 7 is an elevational view that is similar to FIG. 1, but it shows the form adjusted to mold a panel having different longitudinal curvature along opposite side edges;

FIG. 8 is a sectional view taken along line 8-8 of FIG. 7;

FIG. 9 is an elevational view that is similar to FIG. 1, but it shows the form adjusted to mold a curved panel that is tapered in length;

FIG. 10 is a plan view taken along line 10-10 of FIG. 9; FIG. 11 is a sectional view taken along line 11-11 of FIG.

FIG. 12 is an elevational view taken along line 12-12 of FIG. 9;

FIG. 12a is a sectional view similar to FIG. 3, but it has wavelike curvature;

FIG. 13 is an enlarged, fragmentary plan view taken along line 13-13 ofFIG. 1;

FIG. 14 is a fragmentary, elevational view taken along line 14-14 of FIG. 13;

FIG. 15 is a fragmentary, sectional view taken along line 15-15 of FIG. 13;

FIG. 16 is a fragmentary, elevational view taken along line 16-16 ofFIG. 14;

FIG. 17 is a fragmentary, elevational view taken along line 17-17 ofFIG.14;

FIG. 18 is a fragmentary, sectional view taken along line 18-18 ofFIG. 14;

FIG. 19 is a perspective view showing a depressor for depressing a backing sheet;

FIG. 20 is a fragmentary, elevational view showing a depressor clamped to a rib;

FIG. 21 is an enlarged, fragmentary, sectional view taken along line 21-21 ofFIG. 13;

FIG. 22 is an enlarged, fragmentary, sectional view taken along line 22-22 of FIG. 13;

FIG. 23 is a fragmentary, sectional view taken along line 23-23 ofFIG. 22;

FIG. 24 is a fragmentary, elevational view taken along line 24-24 of FIG. 22;

FIG. 25 is a fragmentary view taken along line 25-25 of FIG. 22;

FIG. 26 is an enlarged, fragmentary, sectional view taken along line 2626 of FIG. 13;

FIG. 27 is an elevational view showing details of a stiffener plate to backup an elastic edge form;

FIG. 28 is an enlarged, fragmentary, sectional view taken along line 28-28 of FIG. 13;

FIG. 29 is a fragmentary view taken along line 29-29 of FIG. 28;

FIG. 30 is a fragmentary, elevational view similar to FIG. 22, but it has an upper template frame;

FIG. 31 is an elevational view taken along line 31-31 of FIG. 26;

FIG. 32 is an elevational view showing some possible adjustments of a fastener;

FIG. 33 is an elevational view similar to FIG. 22 but it has a top form portion to mold the top of a building panel;

FIG. 34 is an elevational view similar to FIG. 26 but it has a top form portion to mold the top of a building panel;

FIG. 35 is an elevational view showing a screed for transversely spanning the top of the form or the top of a building panel being cast upon it;

FIG. 36 is an elevational view showing a more complex screed for shaping a tapered curved surfacelike that of the form setup shown in FIG. 9;

FIG. 37 is a fragmentary, elevational view similar to FIG. 22 but it shows fasteners being positioned by the connectors of an existing panel;

FIG. 38 is an elevational view showing a fastener adjusted for the usage shown in FIG. 37;

FIG. 39 is a fragmentary, elevational view similar to FIG. 22, but it shows a panel edging being molded and joined to an existing panel;

FIG. 40 is a sectional view taken through a multiple corrugated shell portion;

FIG. 41 is a typical sectional view taken through a longitudinal joint formed by the joining of two transversely bowed panels that are molded with the form;

FIG. 42 is a fragmentary, sectional view similar to FIG. 21, but showing a modification having sheeting above fairing.

Referring to the drawings, FIGS., 1-4 show an adjustable form F that is adjusted to mold a rectangular two-way curved reinforced precast thin shellconcrete panel 1, that has a lower surface with concave longitudinal and transverse curvatures. The form F is substantially symmetrical about its longitudinal and transverse axii. After a form F is no longer needed to mold apanel 1, it can be readily adjusted so as to mold a panel having different curvature from that ofpanel 1. Although the transverse curvature of the form can be adjusted to change it, I anticipate that a standardize transverse curvature would in general be used. Adjustments for changing curvatures will be described further on.

As an example, the form F is shown being used to mold apanel 1 having a transverse chord of 4 feet and a length of about 8 feet. Such a panel allows for ease in handling and shipping. The form F can be adjusted to mold narrower panels, by making adjustments that are similar to the adjustments that are made to narrow a panel as shown in FIGS. 11 and 12.

Forms may obviously be made that differ greatly in size from this example, to allow much different sized panels to be molded. Thepanel 1 is like the panel described in my copending application Ser. No. 540,314. My U.S. Pat. Nos. 3,245,647, 3,224,726 and 3,161,938, describe forms and panels in great detail, which are like the present form and panels, except for the improvements described in later disclosures.

FIG. 5 shows the form F adjusted to mold aconcrete panel 2 that has the same transverse curvature aspanel 1, but the longitudinal shape of the lower surface curvature is partially concave and partially straight. Apanel 2 and the like can be used as a portion of a building shell that has vertical sides and an arched roof.

FIG. 6 shows the form F adjusted to mold aconcrete panel 3 that has the same transverse curvature aspanel 1, but the longitudinal shape of the lower surface curvature is convex. Apanel 3 can be used as a portion of an arched building shell that has corrugations with transverse concave curvature facing upwardly.

FIG. 7 shows the form F adjusted to mold aconcrete panel 4 that is likepanel 1, except that the side edges of thepanel 4 are curved differently from each other. Apanel 4 and the like can be used to partially close an end portion of a building shell by a step.

FIGS. 9-12 show the form F adjusted to mold aconcrete panel 5 that has the same type of transverse and longitudinal curvature aspanel 1, except that thepanel 5 is tapered in length so that it can be used as part of a corrugated hemisphere.

The form F can be used to mold a panel that has a wavelike transverse curvature, like thepanel 22, that is shown in FIG. 12a. The setups of the form F as shown in FIGS. 1-12a, are examples of some of the many possible setups that can be made. Some of the other possible setups that can be made (not shown), include setups for molding useful and novel panels that are: transversely curved and straight in length; partially convex and partially concave in longitudinal or transverse curvature, spirally curved longitudinally and twisted longitudinally.

After the panels 1-5, and 22, have cured, they may be raised a distance of a panel thickness, so they can be used temporarily as form portions to mold the top surfaces of identical panels to be cast. This type of setup will be described in detail further on.

As shown in FIGS. 1-8, and 13-32, the form F includes a template frame T1, to which spaced curved ribs R are connected. Apliable sheet 6, that would preferably be elastic, overlays the ribs R in the area confined by the frame T1.Longitudinal fairings 7 overlay thesheet 6 and are held in place by notches in the ribs R. Metallic wire would be highly suitable asfairings 7, as it is low in cost and it is usually available. Slightly resilient plastic wire or rod may be used asfairings 7, particularly when noncorrosive fairing is needed where humid climatic conditions are prevalent. When metallic or plastic fairings are not available, thin narrow strips of wood may be used as fairings.

Spacedwire fasteners 8 are mounted on the frame T1. An elastic or flexible edge form strip orgasket 9 is mounted on the frame T1 adjacent to thefasteners 8. Theelastic form 9 shapes the edge of thepanel 1, so as to provide a groove in the panel edging, that will allow like panels to be keyed together with grout at erection. Abase coating 10 is placed and molded to shape over thesheet 6. Cementitious material or plastic are suitable for making abase coating 10. The coating embeds thefairings 7.Fasteners 8 support and

position reinforcing connectors

11 and 12 for the panel.Connectors 11 are clevises andconnectors 12 are eyes. Aconnector clevis 11 on a panel is pin connected to aconnector eye 12 on an adjacent panel at erection, as shown in FIG. 41. The

connectors

11 and 12 are fastened to aperimetrical reinforcing strand 13 in the panel I. The apertures of the

connectors

11 and 12 face towards the faces ofthe panels.

A cementitious coating may be made of plaster or a weak concrete aggregate. A screed such as the screed S shown in FIG. 35, may be used to accurately shape the top of thebase coating 10. Thefairings 7 act as reinforcing for thecoating 10, thereby allowing the coating to be thin.Depressor wires 14, shown in FIGS. 19 and 20, depress thesheet 6 at the ribs R to cause thecoating 10 to be of adequate thickness, particularly where it is adjacent to the ribs.

A template frame Tl includes a pair of curved longitudinal template bars and a pair of curved transverse template bars 16, that are attached to each other. The template bars have holes to allow the bars to be fastened together and to allow ribs R,fasteners 8, and accessories to be connected to them.

After a setup of the form F, such as the setup shown in FIG. 1, has served its purpose bymolding panels 1, thecoating 10 is broken and stripped from the fairing and other portions of the form F. When thecoating 10 is made of plaster or the like, the broken plaster can be used as a filler, along with some fresh plaster, to make a coating for molding a different shaped panel. When thecoating 10 is strong concrete, thefairings 7 and the like, may be discarded rather than to spend time in cleaning concrete from their surfaces.Fairings 7 may be coated with oil or the like, to prevent thecoating 10 from adhering to them. After the removal of thecoating 10, thebars 15 are bent differently to change their longitudinal curvature, so as to mold a needed panel with such a different longitudinal curvature. The template bars 15 and 16 are fastened together as shown in FIGS. 28 and 29, with anangle iron 17. Theangle 17 is connected to apivotal block 18 with abolt 19. A bolt 20 fastens ablock 18 to thebar 16. Twobolts 21 fasten eachangle 17 to abar 15.

Eachangle 17 can be unbolted from an end position on thebar 15 and be rebolted to an intermediate position on thebar 15, when a shorter panel is to be cast. The end portions of thebars 15 have their inner edges beveled to allow thebars 16 to project past thebars 15. When the form F is to be used to mold panels that are shorter than thepanel 1, thebars 15 would be beveled at intermediate portions where thebars 16 would be adjacent. When such intermediate beveled portions are not being used, a beveled filler strip (not shown) would be cemented or be welded to fill in the beveled portions.

Each rib. R has an upwardly bowed-shaped rib-bar 23. The upper edge ofeachbar 23 has substantially the same curvature as the transverse curvature of the upper surface of thecoating 10. The curvature may be a standardized curvature that would be suitable for wide usage.

I assume that the form would in general be used with a standardized transverse curvature. For the purpose of illustration, the rib-bars 23 are illustrated as being large in depth as would be most suitable for a standardized curvature. When rib-bars 23 are to be adjustably changed in curvature, the rib-bars 23 would be smaller in depth so they could be rebent more readily. Thebars 16 along with the rib-bars 23, would be curved differently when panels of different transverse curvature are required. As shown in FIGS. 3, l6 and 22, each end of each rib-bar 23 is fastened to aclevis 24 with aclevis pin 24a. Eachclevis 24 is fastened to atemplate bar 15 with abolt 25. Anut 24b on theclevis pin 24a is tightened to squeeze the prongs of theclevis 24 against the rib-bar 23, so the connection cannot pivot.

When it is preferable not to have holes in the rib-bars 23, for thepin 24a, the hole in the clevis prong that is adjacent to the head of thepin 24a is threaded so the cleviscan act as a C- shaped clamp. The end of thepin 24a may have a small sharp point that can penetrate a soft rib-bar 23, so asto restrain the rib-bar 23 from moving out of position. The use of theclevis 24 as a C-shaped clamp, would be suitable when the rib-bars 23 are made of relatively soft materials such as wood, plastic, aluminum and mild steel. Such clamping would be suitable for setups such as the setup shown in FIGS. 9-l2, for molding a curved tapered panel.

'I'ic wires 26 may be used across the chord to tie the ends of each rib-bar 23 together to prevent the curvature of the rib from flattening to an extent under a load. Each tie made ofwires 26 may have a turnbuckle 27 to allow the effective lengthof the tie to be changed, to shorten or lengthen the chord, so as to change the curvature of the rib-bar 23.Tie wires 26 may bev changed in length without a turnbuckle, by cutting and welding the wires.Tie wires 26 and a rib-bar 23 form a tied arch arrangement to make optimum use of materials in them.

A modified rib with a permanent curvature (not shown) may be made with a deeper stronger member than thebar 23, so thattie wires 26 would not be needed.

Tie wires 26 and a turnbuckle 27 may be used to restrain atemplate bar 16 from flattening, and the turnbuckle may be adjusted to change the chord and thus the curvature of abar 16.

Modified template bars and ribs (not shown) may be held in position and be fastened together with temporary tack welds or the like, rather than be bolted, to provide a strong, low cost unit. 1 Designs of small shells that are to be made with such precast panels as panels l-5 and the like, would likely have combinations of various true arcs having constant radii, to allow drafting and fabricating costs to be kept low, as true arcs, their chords and middle ordinates are easily calculated, by a person, with a knowledge of high school mathematics, with the aid of such a book of mathematical tables as SMOLEYS SEG- MENTAL FUNCTIONS.

Fabricating equipment such as sets of rolls that are used in structural steel fabricating work can be readily adjusted so as to uniformly curve a bar, but they cannot be adjusted to curve a bar to nonuniform curvature.

Bars l5, l6 and 23, that are made of mild steel, can readily be bent to an irregular curvature with a press that bends a short portion of a bar at a time. Mild steel bars 15 can be curved laterally to setup a form F for molding a panel that is curved laterally.

In general, the parts for the form F can be made of different types of materials to suit conditions, including the types of material readily available, and the cost of readily available material, the type of labor and the type of equipment available to use in making the form, use of materials that would be best suited for use in a climate where it is to be used, such as using noncorrosive materials where highly corrosive climatic conditions are prevalent. For the purpose of illustration, the template frame T1 and the ribs are shown as being made of steel.

Template bars 15 and I6, and rib-bars 23, may be made of materials such as metal, plastic or wood. Steel would be highly suitable, particularly when a small quantity of these parts are needed.

The

bars

15, 16 and 23 may be readily made with mild steel, as it can easily be, bent with conventional sets of rolls or the like, that are used in steel fabricating shops.

Thebars 15, in general, would be made of bendable material such as metal, wood or plastic, which can be formed to different curvatures that are required for molding panels with different longitudinal curvature. When thebars 15 are made of thick mild steel, they can be rebent by a press that may be similar to a manual press that is used to bend pipe. When preferred,

mild steel bars

15 and 16 may be made with various stock sized curvatures, which allows a set of bars to be removed and a set with a different curvature to be positioned in their place, rather than to spend time in repetitious bending operations. Such stock bar use would be equivalent to bars that must be frequently changed by bending. Mild steel bars 15, 16, and 23, may have conventional welded-type stud bolts (not shown), welded to them, instead of spaced holes, to provide a ready means for permanently or temporarily fastening bars l5, l6, and 23, andfasteners 8. The w'elded stud bolts could easily be removed, and they would not weaken the bars.

When large quantities ofbars 16 and rib-bars 23 are to be made with a fixed curvature, they may be molded of strong stiff plastic.

When all of the template bars and 16 are made of steel, they may be temporarily joined by welding to form a strong template frame T1. When the adjustable form is to be strong and light in weight to allow the form to be shipped and handled at a low cost, the template bars 15 and 16, and the rib bars 23 may be made of aluminum, that has a protective coat- When preferred, thelongitudinal bars 15 may be made of wood, preferably strong resilient wood which can be bent readily. Eachbar 15 is bowed and tied withtie wires 30 and aturnbuckle 27, across the chord of the bow. Theturnbuckle 27 is rotated to change the chord length.Eyebolts 31 or the like may be used to anchor the ends of thetie wires 30. Theeyebolts 31 may be skewed as shown, to offset thewires 30 from thebars 15. A pair of additional ties made ofwires 32 withturnbuckles 27 may be tied across each half of the bowed curvature of eachbar 15 to allow changing the curvature and to prevent thebar 15 from deforming objectionably. The curvatures ofresilient bars 15 can be changed by rotating theturnbuckles 27, so as to shorten or lengthen the effective lengths of

wires

30 and 32, thereby shortening or lengthening the chords of thebars 15.

Tie wires are low in cost and easily cut and welded to vary their length. Turnbuckles may be omitted when wires are cut and welded to accurately change the length of a tie.

A lightweight chain with an open end link to act as a hook, and a turnbuckle, may be used in general in place of tie wires and turnbuckles for the form F. Chains allow adjustment in link lengths. Chains are more costly than wire. The chains would act similar to the chain shown in FIG. 15.

A nonwarping and noncorrosivelongitudinal template bar 15 may be made of resilient plastic that is reinforced with fiber glass, it would be strong and resilient, like a plastic bow that is used in modern archery.

Bars 16 may be made likebars 15. When bars 16 are to be used only in connection with panels having a single standardized transverse curvature, they may be made strong so they would be nonbendable.

Wood and

plastic bars

15 and 16, may be conventional threaded inserts to allow machine screws and bolts to be securely attached to them.

As shown in FIGS. 22 and 26, the template bars 15 and 16 have tapped holes spaced along their centers, to whichbolts 33 are engaged.Fasteners 8 are attached to the template bars with thebolts 33. Thebolts 33 have slotted ends and nuts, to allowfasteners 8 to be attached or be removed by engaging or disengaging nuts, without removing the bolts.Pointed dowels 34 are attached to thefasteners 8, and engaged to plain holes in the template bars. Eachdowel 34 has a narrow raised bandlike portion that bears against a template bar and against thefastener 8. Thedowels 34 restrain thefasteners 8 from pivoting. Thedowels 34 may be permanently attached to thefasteners 8. Twodowels 34 can independently engage one hole in template T3 and the like, as shown in FIGS. 33 and 34, so a dowel can be removed without disturbing the other dowel in the hole.

Fasteners 8 may be tack welded to the template bars 15 and 16, instead ofusingbolts 33 and dowels 34.

Center spacer chains 36 may be used to help hold the upper portions of the rib-bars 23 and the template bars 16 in true aligned positions. The positions would be radial for curved setups. Each rib-bar 23 has aU-shaped plate 37 fastened to its center. Eachbar 16 has aplate 38 fastened to its center. Thechains 36 are rigged through the holes formed by theplates 37. Thechains 36 are anchored to the center rib R that is at substantially the center of the form F, with aneyebolt 39 and aneyenut 40 that engage the hole formed by aplate 37. The outer ends of thechains 36 are anchored to hook-bolts 41 that are fastened to theplates 38. Nuts on the hook-bolts 41 can be rotated to slightly adjust the position of thebars 16. As shown in FIG. 21, aspring clip 44 engages achain 36 and aribbar 23 to restrain a rib R from sagging laterally. The center rib R is anchored to a fixed position by diagonally positioned lateral ties made ofwires 45 andturnbuckles 27. Theturnbuckles 27 can be rotated to make adjustments. The ties may be made of light chain instead ofwire 45, to allow major adjustments of the effective lengths of the ties.Wires 45 can be spliced or be cut to allow major adjustments in lengths. Thewires 45 are attached to thecorner eyebolts 31 and to theeyebolt 39 andeyenut 40, to allow the form F to be trued-up and be maintained in a true position. Theclips 44 are removed and thechains 36 are selectively engaged to thehookbolts 41 when the form F is readjusted for molding a panel of a different longitudinal curvature.

The form F may haveadjustable supports 48 engaged to thebars 15, to support the template frame T1 to prevent it from deflecting, particularly when it is molding a concrete panel. The supports 48 can act as legs, as shown in FIG. 1. The supports 48 bear on blocks ofwood 49 or the like. Theblocks 49 may bear onsoil 50 or the like. The supports 48 are accessories that are differently positioned to suit different arrangements, as shown in FIGS. 1 and 5-8.

The form F may be supported from above with an overhead monorail or the like. Chains and hooks (not shown) would engage the fourend eyebolts 31, thus eliminating the need forsupports 48 that act as legs.

Thesheet 6 may be made of various materials, including rubberlike plastic, nylon, woven fiber glass, cotton or the like. Anelastic sheet 6 would be most suitable, as it could stretch and be taut. Anelastic sheet 6 would allow acementitious coating 10 to be easily stripped from it, when a form F is being made ready for molding a differently shaped panel. Asheet 6 would be low in cost, thus it could be replaced at small cost if it is torn when removing acoating 10 from its surface. The edges of thesheet 6 may be fastened to the

bars

15 and 16, with an adhesive.

The rib-bars 23 have spaced notches into whichlongitudinal fairings 7 are rigged. Thefairings 7 would depress thesheet 6 into the notches. A highlyelastic sheet 6 could stretch readily to allow it to be pressed into notches in the rib-bar 23 when thefairings 7 are pressed into the notches. Thefairings 7 may be made of slightly resilient steel, so they can curve from rib to rib and thus maintain a constant curvature. The ends of thefairings 7 project througheyelets 51 that are fastened to thebars 16. Thefairings 7 may be long enough to fair the longest possible setup of form F. The ends offairings 7 that are made of wire, may be bent downwardly so they cannot be accidentally pulled while thecoating 10 is curing.

Curved transverse rib-fairings 52 may be placed below or above thelongitudinal fairings 7. A rib-fairing 52 acts as both a rib and a fairing. The ends of the rib-fairings 52 may engage holes in thebars 15, as shown in FIG. 18. The ends ofribfairings 52 can be bent slightly to allow thebars 15 or theribfairings 52 to be skewed, as shown in FIGS. 8 and 11. When the form F is to be used many times for a given setup, theribfairings 52 may be fastened to some of thefairings 7 with soft conventional tying wire (not shown), or they may be fastened with temporary welds, or the like.

A form F may have additional rib-fairings 52 spaced close to each other, eliminating the use offairings 7. The center of each rib-fairing 52 may be held in an aligned radial position by fastening it to thesheet 6 with an adhesive.

Metallic wire would be most suitable in general for ribfairings S2. A rib-fairing 52 is like afairing 7, plastic wire or wooden strips may be used if preferred to suit climatic or economic conditions. Plastic wire and wooden strips may be fastened with adhesives. Heavy rib-fairings 52 may be used as the sole rib means, eliminating the need for ribs R. Wire ribfairings 52 would be lower in cost, but weaker than ribs R.

Each rib-fairing 52 may be crimped to form notches for thefairings 7, as shown in FIG. 18. The crimped notches may be narrower than the thickness of afairing 7, so that afairing 7 can be forced into a notch, thereby making a tight engagement that would tend to prevent a rib-fairing 52 from slipping and sagging laterally out of alignment. When rib-fairings 52 are not crimped and they are used as the sole rib means, the

fairings 7 may be tied to rib-fairings 52 with conventional tie wires or welds.

Afairing 7 that is near the center of the form F, may be tied tightly or be temporarily welded to each rib-fairing 52 and tobars 16, so it acts as a center spacer strand means to align the rib-fairings 52 in radial positions and to restrain theribfairings 52 from slipping and sagging laterally.

When a coating is placed over thesheet 6, the

fairings

7 and 52 act as embedded reinforcing and prevent objectionable cracking.

As shown in FIG. 42, theelastic sheet 6 may be placed above the

fairings

7 and 52, then thecoating 10 can be applied to the top of thesheet 6. The

fairings

7 and 52 support such acoating 10, but they are not embedded in it, thus such acoating 10 is weaker, but the coating can be removed easily after it thepanel 1 will have unobjectionable slightly flattened portions on its curvature.

When plastic andfiber glass coating 10 is preferred, ratherthan acementitious coating 10, the coating may be made much thinner. Such a thin plastic coating would weigh less and be less likely to be broken if the form F is moved. Athin coating 10 that is made of plastic and chopped fiber glass may be sprayed onto thesheet 6 and the

fairings

7 and 52, so as to mold it to true curvatures, thus eliminating the use of a screed S for shaping the coating l0.

A strongthin coating 10 may be made, when a pliable sheet of netlike ormeshlike fabric 55 that is similar to mosquito screening or netting is used. The sheet offabric 55 is stretched to cover the space inside the frame T1 and it covers the

fairings

7 and 52. A fragment of thesheet fabric 55 is shown in FIG. 2. The sheet fabric55 may have its strands at right angles to each other and such fabric may be positioned so the fabric strands are at an angle to the bars and 16, to allow the fabric to be stretched to a two-way curvature.Fabric 55 may be made with strands of metal, plastic, fiber glass or the like. Thesheet fabric 55 may be expanded metal lath mesh that is similar to wire fabric. When thesheet fabric 55 is used, the

.sheet 6 may be omitted. Thefabric 55 may be used with either a plastic or acementitious coating 10.

A form F may have acoating 10 that is reinforced by closely spaced

fairings

7 and 52, that are embedded in it, thesheet 6 orsheet 55 being omitted. Thecoating 10 can be applied to the fairings like a stiff plaster is applied to lath.

A screed S, as shown in FIG. 35, can be used to shape the top surface of thecoating 10, and the tops of thecurved panels 14 and the like. The screed S has abeam 58 which has a lower edge curved like the transverse curvature that is required for the top of thepanel 1 and the like. Each end of thebeam 58 has an end plate '59 bolted to it. Eachend plate 59 has acontact plate 60 bolted to it. Theend plates 59 engage the outer edges of thebars 15.Plates 60 engage the tops of thebars 15.End plates 59 are slotted to allow thecontact plates 60 to be adjusted so thebeam 58 can shape thecoating 10 or be adjusted so thebeam 58 can shape thepanel 1. The screed S is pressured downwardly and laterally to shape thecoating 10 of thepanel 1. The screed S can be kept in a vertical position when shaping of apanel 1 to cause the panel to have a uniform vertical thickness.

A screed S2 shown in FIG. 36, can be used to shape the top surface of thecoating 10 and'the top of the curvedtapered panel 5 that are shown in FIGS. 9-12. Screed S2 can also be used to shape the tops of thecoatings 10 and the tops of the panels l-4 that are shown in FIGS. 1-8. The screed S2 is more complex and thus it would be more costly than screed S, therefore, when a screed S is available, a screed S2 would only be needed whenpanels 5 and the like are to be cast. The screed S2 can be used to shape a wider and a narrower panel thanpanel 1.

The screed S2 has two slotted L-shapedbeams 63 that are pin connected and slidably engaged to each other. Two upwardly bowed slottedbars 64 are pin connected and slidably engaged to each other. Eachbar 64 is pivotally engaged to abeam 63, with apin 65. Two handles 66 are attached to thebeams 63. Each handle 66 has aplate 67 attached to it. Theplates 67 ride on thebars 15, when the handles '66 are forced against the edges of thebars 15. The screed S2 is gripped by the twohandles 66 and it is pushed laterally along the template frame Tl, while pressuring it downwardly and inwardly so thehandles 66 and theplates 67 bear against thebars 15.

When acementitious coating 10 is used and it has cured, it may be coated with water resistant substance, such as silicone waterproofing or plastic. Any type ofcoating 10 may be coated with a conventional liquid nonadhering mixture, to prevent thecoating 10 from adhering to the concrete in the panel that is cast upon it.

When a panel likepanel 1 is to be tapered in thickness, tapered wood strips 70 or the like may be attached to the top surface of the template frame T1, to cause the screed S or S2 to rise to thicken a portion of the panel being cast. A short taperedstrip 70 is shown in FIG. 1.

Theadjustable fasteners 8 are attached in spaced relationship with each other on the top of the template frame TI. Thefasteners 8 back up theelastic edge form 9. FIGS. 22, 23, 24 and 32 are elevational views that show details of afastener 8. The top and bottom of eachfastener 8 are alike. Eachfastener 8 has apin portion 8a. FIGS. 22 and 26 each show afastener 8 and adjacent portions of the form F, along with a portion of apanel 1, to which anorifice plate 72 and a reinforcingconnector 11 are coupled. Theplate 72 is a portion of a spacer and backup strand B. FIGS-23 and 24 show details of portions of the strand B, which haswires 73.

A restrainingspring wire clip 74 restrains theplate 72 and theconnector 11 from uncoupling from thepin 8a, before thepanel 1 is cast. Eachconnector 11 is coupled to a reinforcingstrand 13 in thepanel 1. My US. Pat. No. 3,224,726, fully describes a fastener that is like afastener 8. My US Pat. No. 3,245,647, fully describes a restraining spring wire clip and spacer strand that are like theclip 74 and strand B. My US. Pat. Nos. 3,161,938 and 2,97l,237 fully describe an elastic edge form thatis like theelastic form 9. My copending application Ser.No. 540,314 describes an improved reinforcing connector and improved panel reinforcing that are like theconnector 11 and reinforcing 13.

All of thefasteners 8 have theirpin portions 8a positioned parallel to each other, to allow acurved panel 1 to be lifted off the form F, without disturbing the form. Thefasteners 8 are made with pliable wire, so they can be bent, including twisting, to suit the curvatures of the form F. FIG. 32 shows in phantom outlines, some of the positions into which portions of the fastener can be bent to adjust them. Large pliers or an adjustable jig (not shown) may be used to bend thefasteners 8 to adjust them.

The

connectors

11 and 12 are twisted slightly after the panel is removed from the form F, so that connectors will align with connectors to which they are to be coupled with pins at erection.

The pin spacer or backup strand B has spacedorifice plates 72 that are connected withwires 73. Theplates 72 engage the spacedpins 8a. The strand B engages an offset 9a on theelastic edge form 9, as shown in FIG. 24, to restrain theform 9 from bulging outwardly when it is pressured by fresh concrete and to restrain the lower portion of theform 9 from expanding upwardly. Thewires 72 may have resilient coiled portions, as shown in FIG. 24, to make them taut, even when the spacing of thepin portions 8a change, when the longitudinal curvature is changed. The strand B may have uncoiled portions (not shown), connecting theorifice plates 72 for use withfasteners 8 on

bars

15 or 16 that have a constant curvature, so the strand B can help to keep thefasteners 8 properly spaced and aligned. The strand B is not needed to hold down theform 9, when a template frame T2, as shown in FIG. 30, is used to depress theform 9. Theedge form 9 has spaced slits that are notched to allow it to be forced down over the

connectors

11 and 12.

Apanel 1 would preferably have clevis reinforcingconnectors 11 embedded along one side edge and one end edge, andeye connectors 12 embedded along the other side edge and the other end edge.

Modified panels may haveconnectors 12 along all four side edges. Such a modification would be weaker, but easier to erect.

The

connectors

11 and 12 are connected to the reinforcing 13 that is embedded and positioned around the perimeter of thepanel 1. Thepanel 1 has reinforcingfabric 75, such as rectangular wire fabric or expanded metal fabric, that is placed with its strands positioned diagonally with respect to the side edges of thepanel 1, to allow thefabric 75 to be stretched to the curvature of the panel. Thefabric 75 is fastened to theperimeter wire 13, to provide continuity to the reinforcing. Thefabric 75 is supported onchairs 78.Chairs 78 may be positioned on the coating above the rib-bars 23, like thechair 78 is positioned, as shown in FIG. 21. Thepanel 1 may have longitudinal reinforcingstrands 79 stretched from end to

end connectors l

1 and 12. Thestrands 79 may be made of wire or fiber glass. Thestrands 79 provide strong reinforcing, where the panel would tend to deform from bending stresses.

After the reinforcing 75 and 79 are positioned, concrete is placed on top of thecoating 10 and it is smoothed and accurately shaped with the screed S. Theelastic edge form 9 has an offset 9b to mold a keyinggroove 10 in the panel edging. FIG. 41 shows how thegrooves 10 and the

connectors

11 and 12, that are molded and positioned by the form F, can coact when like panels 1d and l f are joined at erection to form a scalloplike corrugated shell portion like the arrangement shown in FIG. 40.

As shown in FIG. 41, the

connectors

11 and 12 can be coupled with apin 80 to allow like panels 1d and If to be easily and quickly erected, and the grooves it allowgrout 81 to be inserted later, to lock the panels 1d and 1f together. Eachpin 80 may have a hole through its head, to allow a reinforcingwire 82 to be rigged through the hole. Thewire 82 along with the adjacent reinforcing strands l3, reinforce the V-shaped joint. Thepin 80 may have its shank split and bent so the pin is self-locking. Since there would likely be low stresses in the transverse reinforcing of panels, evenloose pins 80 and

limber connectors

11 and 12 are feasible, as thegrout 81 would prevent theconnectors 1 1 and 12 from bending under a load.

The form F would be useful to mold small thin shell panels that do not have the

connectors

11 and 12.

The upper portion of theelastic form 9, as shown in FIG. 26, would tend to bend outwardly when the fresh concrete of thepanel 1 is pressured against it, tending to cause some of the adjacent concrete to spill over.Stiff backup sheets 84 such as that shown in FIG. 27 may be positioned between theform 9 and the main upright portions of thefasteners 8, to restrain theform 9 from bulging outwardly. Slots insheets 84 allow the sheets to be slipped over the pin offsets of thefasteners 8. A more effective but more costly means to confine the concrete is to provide a second template frame T2 above and in spaced relationship with the template T1, as shown in FIG. 30. A template frame T2 is like a template frame T1. The template frame T2 would depress or holddown the top of theelastic form 9 and help to keep thefasteners 8 in alignment. When a template frame T2 is omitted, a screed S or S2 can depress the top of theelastic edge 9 in shaping the top of thepanel 1. A screed S or S2 can be adjusted to allow it to bear on either a template frame T1 or the frame T2.

The setup for molding apanel 2, as shown in FIG. 5, has the straight portion of eachbar 15 restrained from sagging by trussing thewires 32 with asupport 48. When additional stiffness is needed, a strong straightstiff bar 86 may be fastened to the bottom or top of the outer portion of the straight portion of thebar 15. A small fragment of thebar 86 is shown in FIG.

5. Portions of the template frame T1 that are straight, may have stiff wood strips (not shown) in place ofelastic strip portions 9.

The setup for molding apanel 3, as shown in FIG. 6, has the

longitudinal tie wires

30 and 32 rigged to eyebars 31 that are above thebars 15. If the

tie wires

30 and 32 are rigged to eyebars 31 that are below thebars 15, there would be a tendency for the pull on the wires to change the degree of curvature of the ends of thebars 15. If thelower eyebars 31 are extremely short, the

tie wires

30 and 32 can be rigged to them without causing objectionable bending of the ends of thebars 15, thus eliminating the need for theupper eyebolts 31.Supports 48 are fastened to the end portions ofbars 15.

The setup for molding apanel 4, as shown in FIGS. 7 and 8, has the opposing template bars 15 differently curved longitudinally. The connections to thebars 15 are loosened and adjusted to allow the ribs R and thebars 16 to be skewed.

When the form F is to be setup to mold a taperedpanel 5, as shown in FIGS. 9-12, the connections tobars 15 are loosened and adjusted to allow thebars 15 to be skewed laterally and vertically, to allow the longitudinal curvature to be a true radius. The effective lengths of the ribs R and bars 16 are shortened by loosening, adjusting and reconnecting them to suit the shape required for molding apanel 5. Thebars 23 and bars 16 may have spaced intermediate holes to allow thebolts 24a and the bolts 20 to be connected to them at intermediate points. The pin-bolts 24a are retracted and engaged to other spaced holes in the rib-bars 23, or they are clamped to thebars 23 to allow the effective length of each rib R to be shortened. Thebolts 25 are loosened to allow thebars 15 to be skewed with the ribs R. The bolts 20 are removed frombars 16 and inserted in other spaced holes in thebars 16 to shorten the effective length of thebar 16 on the narrow end of the setup. After thebars 15 are positioned, the bolts are tightened so the parts cannot disengage or pivot. The holes in eachangle iron 17 forbolts 21 are oversized and slotted to allow theangle 17 to be skewed in its relationship to thebar 15 to which it is connected. When theangle 17 is correctly adjusted, washers on thebolts 21 are welded temporarily to theangle 17.

Theclevises 24 may be clamped to intermediate portions ofbars 23 when thebars 23 are not provided with intermediate holes. Eachbar 23 may be gripped by the end of thebolt 24a to allow clamping action. Transverse rib-fairings 52 may be shortened by being cut and welded. When preferred, particularly for tapering and narrowing of a setup, any or all of the connections that are made of steel that are shown bolted, may be temporarily welded. Afairing 7 that is made of steel, that is adjacent to an edge and terminates at an intermediate portion of the edge can be bent downwardly after it engages the last rib R that has a notch to support it.

The setup for molding apanel 22, shown in FIG. 12a, would have wave-shaped rib-bars 23a. Atypical bar 23, as shown in FIG. 3, that is made of mild steel, can be cut transversely at its center, one of its parts can be turned over and rotated one hundred and eighty degrees and then the parts can be welded together, to form abar 23a. Mild steel bars 16 can be formed to the wave-shaped curvature, like thebar 23a is formed.Ribfairings 52 could readily be rebent to the wave-like curvature.Strands 79 andfasteners 8 are positioned at the high and low portions of the wave. The screed S would have a modifiedbeam 58, that is shaped to the wavelike curvature, so the top of thecoating 10 and the top of thepanel 22 can be readily shaped. Apanel 22 and the like, would be suitable for extremely small arched spans and for partitions.

When the contemplated usage of the form F indicates there will be need to adjust and use the form to mold a different type of panel while the previous type of panel is still to be produced, a setup may be used that will provide an additional form means, so most of the parts of the adjustable form F can be released for other usage. The setup would include a template frame T2 as shown in FIG. 30. After thepanel 1 has cured, the nuts that hold thefasteners 8 to the template frame T1, are removed from thebolts 33, then thepanel 1, with template frame T2,elastic form 9 and thefasteners 8 attached to it, are removed from the template frame Tl, so thepanel 1 and the attached form parts can be used as a base portion of a form for moldingadditional panels 1 upon it. Thefasteners 8 can spring slightly to allow removal.Additional fasteners 8 and an additionalelastic form 9, are mounted on the template frame T2, so as to allow thepanel 1 and the form parts to be used as a form. Another template frame may be fastened to the tops of theupper fasteners 8, thereby forming a setup that is similar in appearance to the upper portions of the setup shown in FIGS. 33 and 34. After thepanel 1 and the form parts are no longer needed to mold a panel like thepanel 1, thepanel 1 can be used as a building panel- As shown in FIGS. 33 and 34, thepanel 1 with the frame T2,form 9 andfasteners 8 attached to it may be raised to a position that is a panel thickness higher than thecoating 10. The nuts are removed from thebolts 33 that hold thefasteners 8 to the template T1, to allow the template T2 and the attached members to be removed.

Additional fasteners 8 and anadditional form 9 are mounted on the frame T1, and a template frame T3 is positioned between the frame T1 and the frame T2, and it is fastened to the lower and to the upper sets offasteners 8. With this setup, the underside of thepanel 1 molds the top of a panel la that is cast below it, thus eliminating the need to use a screed S to shape the top of the panel la. The fresh concrete for the panel la, can be inserted through a valve (not shown) in theform 9 or through an access hole in the panel 1 (not shown). My U.S. Pat. No. 2,971,237 fully describes such a valve and access hole for inserting the concrete. A panel that is tapered in thickness (not shown), that is similar to panel la, may also be made when a panel capping is used. The height of some of thefasteners 8 being adjusted so they gradually increase so as to vary the distance between the template frames T1 and T3.

The form F may have a stack of panels likepanel 1 molded one above another on top of it, similar in appearance to the panels In and 1 that are shown in FIGS. 33 and 34. Stacking allows a panel to cure thoroughly before moving it. Stacking conserves space in curing and storage yards. A cured stack of panels with template frames, forms 9 andfasteners 8, but without the form F, would act as a strong unit,, that could be handled as a unit with a crane, with little danger of damaging the panels during handling or shipping.

As shown in FIG. 37, form F may be used along with an existing panel 1h to mold apanel 1 and accurately space thefasteners 8 so they match theconnectors 12 in the existing panel 1h to which they will be joined during erection. The fastener pins 80 are coupled to theconnectors 12 in the existing panel 1h. Theconnectors 12 are twisted slightly to allow them to seat on thefasteners 8. Thefasteners 8 are tack welded or otherwise fastened to the bar that supports the adjacent side of the panel 1h. The upper portion of eachfastener 8 is bent or cutoff to clear thepanel 1. The panel 1h is notched to allowfasteners 8 to be positioned. Theconnector 12 is coupled to thefastener pin 8a. Thefastener 8 is bent as shown in FIG. 38 to allow theconnector 12 to extend to thefastener pin 80. The screed S may be used to shape the top of thepanel 1. The

contact plate

8,7 is fastened to thebeam 58, after removing theadjacent end plate 59 and thecontact plate 60. Thecontact plate 87 bears, and is movable against the existing panel 1h. Eachfastener 8 aligns the engaging

connectors

11 and 12, so that apin 80, shown in FIG. 41, can be inserted to lock the connectors together at erection.

FIG. 39 shows how the form F is used along with an existingpanel 1/: to mold a panel 1m to it, to form a large panel having a plurality of corrugations, such as thepanel 88 shown in FIG. 40. The

connectors

11 and 12 are joined with apin 80. A reinforcingwire 82 may be rigged through holes in the heads ofpins 80. The screed S is used to shape the top of the panel 1m. Theelastic form 9 is omitted, where the panels 1k and 1m are joined.

Thepanel 88 shown in FIG. 40, has panel corrugations 88a, 88b and 880. Each of these panel corrugations may be poured separately by using any of the form means shown in FIGS. 22, 37 or 39.

I assume that in large scale usage of the form F, that labor with the higher skill would setup the forms, less skilled labor would place the reinforcing, still less skilled labor would place the concrete and use a screed to shape it.

While I have illustrated and described several embodiments of my invention, it will be understood that these are by way of illustration only, and that various changes and modifications may be made within the contemplation of my invention and within the scope of the following claims.

Iclaim:

1. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means, attaching means fastening together said end bar means and said side bar means, said end bar means being at least partially curved in length, said side bar means including longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means including tie means that extend across the chord of the bow of each of said side bar means, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, elastic strip means mounted on at least a portion of the periphery of said template frame, a plurality of spaced fastener means mounted on and attached to at least a portion of the periphery of said template frame outwardly from said strip means, said fastener means engaging and confining said strip means, said strip means having an eflective height substantially equal to the thickness of said building panel to be cast, said strip means having a protruding portion substantially centrally of the height of said strip means and facing inwardly for molding a keying groove in the edging of said building panel, said strip means adapted to confine fresh aggregate of said building panel deposited within its confines, connector means adapted to be spaced along its said edging, said strip means having spaced transverse holes through an intermediate portion of its height adjacent to said fastener means, said connector means having end portions extending through said transverse holes, said fastener means adapted for anchoring and positioning said end portions, whereby two way curved building panels having different curvatures can be made readily.

2. A from as recited inclaim 1, wherein said curvature of said end bar means is a single bow and wherein said end bar means includes selective transverse curving means to allow said end bar means to be selectively curved in lengths, whereby building panels having different transverse curvatures can be readily made.

3. A form as recited inclaim 1, wherein said side bar means includes spaced side engaging means and wherein said attaching means engaging at least one of said end bar means includes detachable means, so at least said one end bar means can be selectively positioned and be attached to intermediate positions along said side bar means, whereby said building panel can be made in a selective length.

4. A form as recited inclaim 1, wherein said end bar means includes spaced end engaging means and wherein said attaching means engaging at least one of said side bar means includes detachable means, so at least said one side bar means can, be selectively positioned and be attached to intermediate positions along said end bar means, whereby said building panel can be varied in width.

5. A form as recited inclaim 1, wherein said attaching means include pivotal fastening means, whereby said side bar means can be skewed, and whereby the side edges of said building panel can be skewed.

6. A form as recited inclaim 1, together with longitudinal fairing means mounted in spaced relationship to each other and engaging said rib means, said longitudinal fairing means spanning the space between said end bar means, whereby the underside of said building panel can be molded with a uniform fair curvature.

7. A form as recited inclaim 1, together with cap means mounted in spaced relationship above said sheet, said cap means having substantially the same curvature as said sheet, said cap means covering space where said building panel is to be cast, whereby said cap means can mold the top surface of said building panel.

8. A form as recited inclaim 3, wherein said end bar means includes spaced end engaging means and wherein said attaching means engaging at least one of said side bar means includes detachable means, so at least said one side bar means can be selectively positioned and be attached to intermediate positions along said end bar means, whereby said building panel can be varied in width and length.

9. A form as recited inclaim 3, together with longitudinal fairing means mounted in spaced relationship to each other and engaging said rib means, said longitudinal fairing means spanning the space between said end bar means, whereby the underside of said building panel can be molded with a uniform fair curvature.

10. A form as recited inclaim 4, wherein said attaching means includes pivotal fastening means, whereby said side bar means can be skewed, and whereby the side edges of said building can be skewed.

11. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means that are fastened together, said end bar means being at least partially curved in length, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, said curvature of said end bar means being a single bow, said side bar means includes longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means includes tie means that extend across the chord of the bow of each of said side bar means, said end bar means includes selec tively transverse curving means to allow said end bar means to be selectively curved in length, whereby building panels having different longitudinal and transverse curvatures can be readily made.

12. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means that are fastened together, said end bar means being at least partially curved in length, said form having transverse wire rib-fairing means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said transverse wire rib-fairing means being at least partially curved in length, a pliable sheet engaged with said transverse wire rib-fairing means and covering the opening formed by said template frame and being engaged with said side bar means and said end bar means, said curvature of said end bar means being a single bow, said side bar means including longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means including tie means that extend across the chord of the bow of each of said side bar means, whereby said building panel can have a fair transverse curvature.

13. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means that are fastened together with attaching means, said end bar means being at least partially curved in length, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, said curvature of said end bar means being a single bow, said side bar means including longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means including tie means that extend across the chord of the bow of each of said side bar means, said attaching means including pivotal fastening means, whereby said side bar means can be skewed to skew the edges of said building panel.

Claims

1. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means, attaching means fastening together said end bar means and said side bar means, said end bar means being at least partially curved in length, said side bar means including longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means including tie means that extend across the chord of the bow of each of said side bar means, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, elastic strip means mounted on at least a portion of the periphery of said template frame, a plurality of spaced fastener means mounted on and attached to at least a portion of the periphery of said template frame outwardly from said strip means, said fastener means engaging and confining said strip means, said strip means having an effective height substantially equal to the thickness of said building panel to be cast, said strip means having a protruding portion substantially centrally of the height of said strip means and facing inwardly for molding a keying groove in the edging of said building panel, said strip means adapted to confine fresh aggregate of said building panel deposited within its confines, connector means adapted to be spaced along its said edging, said strip means having spaced transverse holes through an intermediate portion of its height adjacent to said fastener means, said connector means having end portions extending through said transverse holes, said fastener means adapted for anchoring and positioning said end portions, whereby two way curved building panels having different curvatures can be made readily.

2. A from as recited in claim 1, wherein said curvature of said end bar means is a single bow and wherein said end bar means includes selective transverse curving means to allow said end bar means to be selectively curved in lengths, whereby building panels having different transverse curvatures can be readily made.

3. A form as recited in claim 1, wherein said side bar means includes spaced side engaging means and wherein said attaching mEans engaging at least one of said end bar means includes detachable means, so at least said one end bar means can be selectively positioned and be attached to intermediate positions along said side bar means, whereby said building panel can be made in a selective length.

4. A form as recited in claim 1, wherein said end bar means includes spaced end engaging means and wherein said attaching means engaging at least one of said side bar means includes detachable means, so at least said one side bar means can be selectively positioned and be attached to intermediate positions along said end bar means, whereby said building panel can be varied in width.

5. A form as recited in claim 1, wherein said attaching means include pivotal fastening means, whereby said side bar means can be skewed, and whereby the side edges of said building panel can be skewed.

6. A form as recited in claim 1, together with longitudinal fairing means mounted in spaced relationship to each other and engaging said rib means, said longitudinal fairing means spanning the space between said end bar means, whereby the underside of said building panel can be molded with a uniform fair curvature.

7. A form as recited in claim 1, together with cap means mounted in spaced relationship above said sheet, said cap means having substantially the same curvature as said sheet, said cap means covering space where said building panel is to be cast, whereby said cap means can mold the top surface of said building panel.

8. A form as recited in claim 3, wherein said end bar means includes spaced end engaging means and wherein said attaching means engaging at least one of said side bar means includes detachable means, so at least said one side bar means can be selectively positioned and be attached to intermediate positions along said end bar means, whereby said building panel can be varied in width and length.

9. A form as recited in claim 3, together with longitudinal fairing means mounted in spaced relationship to each other and engaging said rib means, said longitudinal fairing means spanning the space between said end bar means, whereby the underside of said building panel can be molded with a uniform fair curvature.

10. A form as recited in claim 4, wherein said attaching means includes pivotal fastening means, whereby said side bar means can be skewed, and whereby the side edges of said building can be skewed.

11. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means that are fastened together, said end bar means being at least partially curved in length, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, said curvature of said end bar means being a single bow, said side bar means includes longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means includes tie means that extend across the chord of the bow of each of said side bar means, said end bar means includes selectively transverse curving means to allow said end bar means to be selectively curved in length, whereby building panels having different longitudinal and transverse curvatures can be readily made.

13. A form for molding a thin, curved building panel, said form including a template frame having oppositely disposed end bar means and oppositely disposed side bar means that are fastened together with attaching means, said end bar means being at least partially curved in length, said form having rib means mounted in spaced relationship on said side bar means and spanning the space between said side bar means, said rib means being at least partially curved in length, a pliable sheet engaged with said rib means and covering the opening formed by said template frame, said curvature of said end bar means being a single bow, said side bar means including longitudinal curving means to allow said side bar means to be selectively bowed at least partially in length, said longitudinal curving means including tie means that extend across the chord of the bow of each of said side bar means, said attaching means including pivotal fastening means, whereby said side bar means can be skewed to skew the edges of said building panel.