US604708A - Child s building-blocks - Google Patents

Description

I (110 Model.) 2 SheetsSheet 1.

(LS. BURTON. GHILDS BUILDING BLOCKS.

No. 604,708. Patented May 24, 1898,. v 129.1. I O O O o (No Model.) v 2 Sheets-SheetZ. G. S. BURTON. GHILDS BUILDING BLOCKS.

No. 604,103. Pajtented May", 24. 1898.

I UNITED, STATES fatnnr F Fr,cE."-

CHARLES S. BURTON, OF OAK PARK, ILLINOIS.

CHILDS BUlLDlNG-BLOCKS.

SPECIFICATION forming part of Letters Patent No. 604,708, dated May 24, 1898. Application filed May 27, 1896- Serial No. 593,245. (No model citizen of the United States, residingv at Oalr Park, countyof Cook, and State of Illinois,

have inventedcertain new and useful Improvements in 'Ghildrens Building- Blocks, which are fully set forth in the following specification, reference being had to the accompanying drawings, forming a part thereof.

In the drawings,.Figure 1 is a perspective of aform of rectangular building-block adapted for use with my invention. Fig. 2 is a similar block of a size which would be formed by dividing the block shown in Fig. l transversely at the middle point of its length. Dotted lines on both these figures indicate fractional or divisional elements correspondin g to which other blocks of the set are made. Fig. 3 is a front elevation of a partial arch formed of blocks adapted to be adjustable in respect to the spread or radius of the arch. Fig. 4 is a section through three of the blocks shown in Fig. 3, illustrating the variations in adjustment from that which produces a straight shaft to that which produces the most convex arch. Fig. 5 represents a group of arches formed by means of a special form of block which is represented in them all and is adapted by various combinations with fectangular blocks to prod uce arches of an y. span or radius. Fig. 6 is a detail elevation showing a modification in respect to means for securing together blocks of the form shown in Fig. 5 in the construction of arches therewith. Fig. 7 is a section of a cornice made up of the several molding elements, showing the manner of assembling and securing such elements. Fig. 8 is a typical plan of the molding elements, the edge pattern being that of the upper element of Fig. 7. Fig. 9 is a plan of the shortest length of the molding element provided for piecing out. Fig. 10 is a group of cornice molding-blocks broken away back of their molded edges, said blocks be ing of the general type which are combined in Fig. 7, butincluding other forms.- Fig.11 is a front elevation of the gable end of a building designed to show a form of block adapted for'that specific purpose. Fig. 12 is a similar view showing blocks of the same shape arranged to produce a gable for a roof of a different pit-ch.

For wall building I provide blocks of the customary rectangular forms, each dimension 7 being a multiple of a selected unit of measure, the cube of which I term the unit cube, the full-sized block being'of the usual proportions of building bricks-that is, the.

breadth twice the thickness and the length twice the breadth-and equivalent-t0 eight unit cubes. Such a block (indicated by the letter A) is shown in Fig. 1. Other blocks of this series may be respectively half, quarter,

and eighth of the block A, produced by di-"- the length of the block A, such a block being .,.7, shown in Fig. 3 and indicated by the letter.

(J, and other blocks being produced by'dividing these again transversely toeither dimen sion. The entire series would include simple cubes and any form which might be produced without reentrant angles by assembling such cubes. Such rectangular blockshave the customary forms and proportions in buildingblocks, and in specifying them'l': have not-described anything'peculiar to myinventio'n;

For the purpose of securing such blocks in anyrelation in which they will most natua rally be assembled in building walls, rectarr gular columns, stairs, &c., Imake these blocks with sockets in their several faces adapted-its] receive keys, preferably in the form of ronnd .pins, whereby the contiguous blocks'ma'y be:

detachably joined. The sockets are distrib p uted over the several faces, so that suclr'zag socket is found on every face, which isprovided, with sockets at a distance fromeach edge equal to half the dimension of the unit cube and at distances apart equal to said di-- mension. As illustrated, the sockets are in the form of pin-holes located at the center of each square corresponding to the face of the unit cube into which the face of the block can be divided. The rule for the location of the pin-holes may be otherwise expressed thus:

that their distance apart is the greatest common divisor of the three dimensionsof the block and their distance from the ed gesis half that greatest common divisor. least dimension of the block is seven-eighths Thus if the- I of an inch, which is the customary size, these adapt them also to be secured by sockets or pin-holes a; will be located in rows seven-sixteenths of an inch from every edge of every face and at intervals of seven-eighths of an inch in such rows. For greater variety of arrangement in assembling such blocks the pin-holes 'may be made seven-sixteenths of an inch-that is, half the unit of measure-apart in the rows, as well as at that distance from the edges, respectively; but the utility of these additional pin-holes is comparatively slight. These pin-holes may be of as little depth as considered necessary to cause the pins M, intended to be inserted in them to join the blocks together, to obtain sufficient held.

In practice with blocks of the dimensions above stated I have made the pin-holes threequarters of an inch deep, which in case of the least dimension makes the holes from opposite faces meet and become one hole, the block being penetrated. There is certain utility in this construction in binding the building together with tie-rods, as hereinafter explained.

For the purpose of cornice-moldings I provide elemental forms T T T T T T T T, &c. ,adapted to be used individually and separately, but also adapted to be combined to produce any desired edge outline, the principle being similar to that involved in formation-of columns from the elemental forms of rotation, In orderto adapt these elemental molding-forms to be combined and secured together in all the combinations which may be required in building up cornices and to the pins to the other building-blocks of the set wherever they maybe applied, I make these moldingblocks T with pin-holes 25, located, so far as the distance from the ends and distance apartin the length of the molding-blocks is concerned, precisely according to the rule governing the form of the pin holes in the rectangular blocks-that is to say, at a distance from the end one-half the unit of measure or greatest common divisor of the dimensions of the rectangular blocks and a distance apart equal to that unit of measure or greatest common divisor; but I make the molding-blocks with both lateral edges molded, but with the mold ing pattern reversed, as seen in Fig. 7, (the reversion of the pattern obviously is of no effeet in the case of half-round forms, whether concave or convex,) and,considering the mold as comprising a body portion and an edge portion, the body portion being the rectangular portion which would be left after cutting ed by planes at right angles to the face the entire molded portion and the edge portion consisting of that which would be cut off by such plane, I locate the pin-holes at a distance from one edge equal to one-fourth of the unit of measure and at a distance from the other edge equal to one-half such unit. This one-fourth of the unit of measure, for convenience, I term the unit of measure of molding or unit of thickness," because, as will he understood from inspection of Fig. 7, the simple elemental forms of molding which most conveniently be employed arein three thicknessesfirst being the full thickness of the standard rectangular block-that is, having the unit of measure of said block for such thicknessand the second half and the third onefourth of that thickness. All three thicknesses are shown in Fig, 7 with. differentlymolded edges. It will be understood upon inspection of these forms that in combining these elements they will retreat or advance from any fixed line in steps corresponding to the thickness and that these steps therefore will be multiples of the quarter-thickness, which may therefore be taken as the unit of measure or adjustment in combinations of the moldings. The width of the body therefore of the moldings is the unit of measure or side of the unit cube of the system plus threefourths of that unit. In order to make it possible to combine these moldings in every required relation or order, I provide, inaddition to the pin-holes located as already described, holes midway between each transverse pair of holes, so that there are in the molding-blocks transverse rows of holes, containing three in each row, the rows being distant from the ends half the unit of measure and from each other once that unit. A little inspection will make it apparent, that by using one edge or the other of the molding every possible combination and arrangement of these molding elements can be made and coinciding pin-holes found at which they may be secured.

For the purpose of constructing arches of different spans by means of blocks of the same type by difierent combinations of such blocks I provide the wedge-shaped block V of small angle, which is an aliquot part of' one hundred and eighty degrees, and preferably an aliquot part of ninety degrees, so that a certain number of suchblocks, assembled by their oblique faces, constitute a span of one hundred and eighty degrees. .I have represented, for example, these blocks V as having an angle of fifteen degrees, so that twelve blocks make one hundred and eighty degrees span. The smallest arch that can be formed with them evidently is made by combining them without other blocks. For a larger span they may be alternated with parallel-sided blocks V of the least dimension found in the set-as, for example, the unit of thickness of the moldings or onefourth the unit of measure. the smallest arch shown is produced. For larger arches-more of the blocks V or thicker So combined blocks, as V 011V, (which is the unit eube,)

may be interposed between the wedge-shaped blocks V to any extent, producing thereby an arch of any desired span, since whenever twelve of the wedge-shaped blocks have been introduced one hundred and will have been covered.

' I have shown two methods of'securing the eighty degrees coef'zos blocks inn such ana rcl i togetiter,the simplest is preferablycontinuous throughout theen= tire arch, being made of copper or other comparatively soft wire, which has nevertheless I sufficient stilfness when bent to holdthe'arch' inform. Another method, and in sOme respects superior, is shown, the oblique faces-0t the wedges and the parallel faces of the in terposed blo'cksbeing provided with trans-' verse furrows '0, adapted to-receive a wooden key 11 Preferably thefurrow is dovetailed and the key a' double dovetail inform. The parallelrsided blocks V V V 850,, which are adapted to be used in such arch building, are

also adapted for the ordinary combinations =with the other rectangular blocks.

I have shown another form of adjustable arch, which, however, is adapted for purely ornamental purposes and'not calculated to sustain weight as an arch. This form of arch consists of an assemblage of pieces cut from a cylinder by planes oblique to the axis, mak-Q J ing cylindrical segments symmetrical about a plane transverse to the axis. Pin-holes being bored to the center of each block-face at right'angles to that block-face it'will be seen that a succession of such segments may be assembled so as to form either a perfect cylinder or an arch of any curvature up to the maximum, which will depend upon the angle of divergence of the oblique faces and the length of the segment at the shortest side.

These cylindrical segments are indicated by the letter X, the pin-holes in them by the letter w, and the pins by the letter X since they are the same as will be used in other connections-as, for example, those shown in Fig. -10. i In the drawings two of the segments at the right hand are assembled so as to produce a cylinder, while the one at the left hand is placed in relation to the next one in position to produce the greatest curvature.

In making gables for slopingroofs it has been customary in building-blocks to make right-angledtriangular blocks of the form produced by dividing diagonally the standard oblong block of the system, twice as long as its width, and by similarly dividing the square block, which is half that oblong. This gives triangular blocks whose slant side is not commensurate with the other two's'ides'-that is, has no simple divisor common to the other sides. Thisform thereforecannotbe employed whereroof-boards are,;tof be applied to such slant sides and securedyby pins in socketswhich are spacedaccording to the law which obtains in the remainder of the system. To;

meet this requirement, I make gable-blocks U in right-angled triangular form,whose sides are respectively three, four, and five times the unit of measure and which may be arranged to support roofs of diiferent pitch, and for Gothic roofs I make right-angled. triangular blocks U, whose sides are respectively five,

twelve, and thirteen times the unit of meas ure. thickness of the standard wall-blocks and with sockets spaced asin the standard blocks.

-:I claim- I q 1 In child?sbuilding-blocks, moldingstrips of different thicknesses, which are mul- -=tiples of a'selectedunit of thickn'ess,,having at-opposite edges similarly-molded face porqtious,correspondingiin extent to the thick-' mess, the body portion intermediate said face portions having pin-holes in three longitudin-al rows, .one outer row being distant'from the lateral" boundary of the body once the unit of thickness, the other outer row being distant from the other lateral boundary twice said unit, and the middle row being dist-ant from the outer rows twice said unit of thickness.

2. In childs building-blockgin combination with blocks whose dimensions are all multiples of a selected unit of measure, and which have pin-holes in their faces distant from each other once said unit and from the edges respectively of the blocks half such unit; molding-strips of different thicknesses which are all multiples of a unit of thickness which is an aliquot part of said unit'of' measure, said molding-strips having at opposite edges similarly-molded face portions corresponding in extent to the thickness, the body portion intermediatesaid face portions having pin-holes in three longitudinal rows, one outer row being distant from the lateral boundary of the body once the unit of thick- Roof-boards U may be made of half the ness, the other outer row being distant from the other lateral boundary-twice said unit, and the middle row being distant from the outer rows twice said unit of thickness.

3. In childs building-blocks, inicombination with rectangular blocks whose dimensions are all multiples of a selected unit of measure, and which have sockets in their several faces distant from their edges respec- IIO tively halt the unit of measure and from each 7 other once such unit; right-angle triangular gable-blocks whose three'sides are all multiples of the unit of measure, and whose edges at said three sides are provided with sockets at the middle point of each such unit into which said-edges can be divided.

4. In childsbuilding-blocks, in combination with rectangular blocks whose. dimensions are all multiples of a unit of measure, and which have socketsin their several faces ,distant from the edges respectively half the -unitof measure and fronreach other once such unit, right-,angle-triangular gable-blocks whose sides are respectively three, four and five times the unit of measure and whose edges are provided with sockets at the middle point of each such unitv into which said edges can be divided.

5. In building-blocks for arch construction,

wedges of small angle which is an aliquot part of one hundred and eighty degrees, in combination with blocks having their two opposite faces parallel, said wedges having their oblique faces and said other blocks having their opposite parallel faces provided with sockets adapted to "receive connecting de vices, whereby the parallel-face blocks in dif ferent numbers or dimensions may be interposed and secured between the wedges to form arches of different span and radius.

6. In bu ildin g-bloeks for arch construct-ion, wedges of small angle which is an aliquot part of ninety degrees, in combination with blocks 'having their two opposite faces parallel, said wedges having their oblique faces and said other blocks having their opposite parallel faces provided with furrows at corresponding positions, and keys adapted to enter said corresponding furrows to unite the edges to the parallel-faced blocks at their said parallel faces.

7. In building-blocks for arch construction, wedges of small angle which is an aliquot part of ninety degrees, in combination with blocks having their two opposite faces parallel, said wedges having their oblique faces and said other blocks having their opposite parallel facesprovided with dovetailed furrows at corresponding positions and do'ubledovetail keys adapted to enter said corresponding furrows to unite the edges to the.parallel-faceitj'bloeks at said parallel faces.

8. In childs building-bloc'ks for await-e arch construction, blocks which are cylin' drical segments with equal oblique bases, pro

vided with sockets at the center*o.f..;s-uch' oblique bases and entering the block at right angle to such bases respectively,and pins adapted to enter such sockets, whereby the span and radius of an arch formed by a series of such oblique cylindrical segments may be varied at will. 7 r I 9. In childs building-blocks, keystone blocks for arch building comprising two pieces hinged together at one edge and having each a row of perforations; a staple adapted to have one leg inserted in a pin-hole ofeach block, whereby the spread of the blocks from their hinge edge may be varied by the selection of the perforations used for the staples:

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