DE7926189U1 - EXTRUDED HOLLOW BRICK - Google Patents

Description

The innovation relates to an extruded one Hollow brick with, staggered in an odd number Rows aligned perpendicular to the direction of heat transfer, delimited by longitudinal and transverse webs " Large chambers with a rectangular cross-section, the Large chamber, a length of at least 70 mm, preferably about 90 mm, and a ratio of width to Have a length of at least 1: 7, preferably 1:10, and the difference between the large chamber width and the longitudinal web width between 0 and I 4 I mm, preferably about j I j mm, and with sub-chambers that are essentially half the length of a Großkainmer on v / iron sen.

In AT-PS 276.706 theoretical considerations about clay bricks with the best possible insulation were already made employed. These considerations led to the Result that the total thermal conductivity of the brick m; .t decreasing air chamber widths and longitudinal web widths, as well as decreases with increasing air chamber lengths. However, since all three criteria are compression-related There are limits, the AT-PS 276.706 shows as a practicable solution air chambers with diamond-shaped Cross-sections in staggered rows, some of which run through in the small diamond axis additional crossbars divided si - ^. thereby giving rüe strength of the brick blank is increased during manufacture, but the thermal resistance is reduced.

The tile shown has an odd number of air chamber rows, with one as the outermost row

Row with similar chambers, next an offset row, etc. is arranged. It can be seen from AT-PS 27 6.705 that the The total thermal conductivity of the brick could be further reduced if the air chambers were in the Cross-section would be rectangular, v / o the longest possible flow of heat through the brick lattice Would have to cover a distance, but air chambers with a diamond-shaped cross-section must be created, otherwise the necessary strength cannot be achieved. It is evident that the overall

f the coefficient of thermal conductivity is reduced in the case of air chambers with a rectangular cross-section, but the extension of the path at half offset with an axis ratio of length to width of the air chamber of 4: 1 for a rectangular cross-section is 1.214 times that of the diamond-shaped cross-section, with a ratio of 7: 1 1.131 times

"~ and with a ratio of 10: 1 still that

1 j 055 times.

The experiment is also known from AT-PS 339.018 it has become necessary to build at least a few rows of rectangular air ducts into the diamond lattice; it was but so far not possible in terms of production technology, 'brick to manufacture by extrusion, which only have large chimneys with a rectangular cross-section, which meet the requirements mentioned at the beginning.

Surprisingly, a relatively simple trick has now succeeded in producing such bricks. On closer examination it was namely

found that the weak points of the horizontally pressed strand or the blank do not have the

entire cross-sectional area roughly evenly distributed

are what due to the even distribution of the |

Large chambers are imposed, but rather on two specific spatial and one temporal areas are concentrated, the rectification of which allows the manufacture of the desired bricks. The time range is | extends from the exit from the mouthpiece of the extruder either to the completion of the drying process Brick blanks or up to a rotation of the cut brick blanks by 90 °, so that the air chambers run vertically. The two local areas represent the sections of the two lateral edge webs of the horizontally pressed strand at the level of the lowermost air chamber of the first row. These edge web sections are on the one hand due to the dead weight of the strand and on the other hand due to their exposed Position directly on the contact surface on the conveyor base of the production plant is stressed to an extent that that the production of a large chamber with a height - or in cross-section with a length - accordingly did not allow the conditions mentioned at the beginning. The edge web sections only bulged laterally at best but generally break open completely, which of course destroys the lattice structure and the outer brick shape were.

The task of the innovation lies in the practical implementation of the theoretical calculation models, namely to create an extruded brick of the type mentioned.

According to the innovation, this is solved by the fact that every extreme Row, as known per se, begins at least at one end with a sub-chamber.

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It is known both for extruded bricks (DE-PS 817.950) and for concrete blocks that are manufactured in molds (AT-PSs 195.617, 309.759) to arrange partial chambers at the end of the outermost rows in half the length of the remaining chambers, but it was by no means foreseeable that this measure would make it possible. Bricks with large chambers - which correspond to the conditions mentioned at the beginning. Finally, the already mentioned AT-PS 339.18 also shows at the ends of the outermost rows partial chambers half the length of the triangular large chambers, but the other rectangular chambers are also only half the length.

The inventive arrangement of a sub-chamber at least at one end of the outermost rows is on the in the AT-PS 276.706 as "theoretically best designated design of the brick lattice with im Cross-section of large rectangular chambers nothing changed. The length of the heat flow paths remains the same, that specified minimum ratio of length to width can be far exceeded, and the absolute dimensions can be to be kept.

There are now two ways of distributing large cameras and part canoeing in the individual rows possible. the The first arrangement is to have a number of large chambers in each row and one at the end Form part chamber, due to the offset, the part chamber in a row on the first and in the . The following row appears at the second end, and because of the odd number of rows in the two outermost rows, the sub-chambers are arranged on the same side.

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The second possible arrangement sees so-called basic rows, with one basic row being one Retie with large chambers of equal length without partial chamber η is understood, and that staggered rows in front of which a sub-chamber is formed at each end.

If basic rows and staggered rows are formed, it is provided according to the innovation that in the sequence the rows, as known per se (ΠΞ-PS 817 950, AT-PS 309 759), the staggered rows on odd Numbers are falling.

For large chambers of this type, their length is inevitably based on the desired tile format. In The table below shows the possible arrangements for large chambers and partial chambers for two common ones Tile lengths (perpendicular to the direction of heat transfer) of 250 and 300 mm specified:

No. brick
length =
Strand height
mm line Kammerlcmgc- (Ί-subchamber) on Number and. thickness
the crossbars number of
Big came
mern 1. 250 1.
2. 33 (T) 73 73 33 (T).
73 73 73 5 X 7.6
4 X 7.75 3 2. 250 1.
2. 44 (T) 88 88
88 88 44 (T) 4 X 7.5
4 X 7.5 2 + 1/2 3. 250 1.
2. 52.5 (T) 113 52.5 (T)
113 113 4 X 8.0
3 X 8.0 2 4th 300 1.
2. 37.5 (T) 75 75 75
75 75 75 37.5 (T) 5 X 7.5
5 X 7.5 3 + 1/2 5. 300 1,
2. 41 (T) 90 90 41 (T)
90 90 90 5 X 7.6
4 X 7.5 3 6th 300 1: 53.8 (T) 107.5 107.5
107.5 107.5 53.8 (T) 4 X 7.8
4 X 7.8 2 + 1/2 7th 300 1.
2. 65 (T) 138 65 (T)
138 138 4 X 8.0
3 X 8.0 2

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The manufacture of the. Brick by horizontal Extrusion is therefore carried out by arranging a subchamber at the same ends of the outermost rows because in the two areas in which the weak points mentioned at the beginning occur, a. Crossbar. educated will. As mentioned, the side edge of a large chamber would serve as the lowest chamber of the outer rows | bulging as soon as the length of the chamber (or in Strand whose height) exceeds a certain amount, which, based on tests, is from 65 to 70 mm, depending on the sound quality. Due to the arrangement of the partial chamber on this Place a transverse web at a maximum height corresponding to this hatred from the bottom of the dog piece of the extruder generated, which connects the lateral edge web with the next longitudinal web and thus stabilizes it. the Seen from below, the second chamber of the outermost row of the strand is already so little loaded by its own weight, that she can represent a large ship. The others so the top chamber in the line can of course also be large chambers.

It is therefore possible to manufacture both the bricks that have large chambers and a sub-chamber in each row, "where the Partial chamber of the first row in the strand and due to the odd Number of the last row as the lowest, as well as those, the basic rows and offset Re ^^^ n with a Have partial chambers at each end, provided that the rows are staggered as first and last trained v / ground *

Subsequently, it has now been shown that the modernization of a brick enables the Teilkäininern to design at least the third to (n-2) th row open to the abutment surfaces, which has been the case with extruded bricks up to now was not feasible, although this was also done by the aforementioned in the case of concrete blocks that are produced in a mold AT-PSs 195.617 and 309.759 is described.

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The arrangement of the subchamber in accordance with the innovation in the outermost row as the lowest in the strand would even be • allow, also, this subchamber to the abutment surface of the To open the brick (towards the bottom or top surface of the mouthpiece of the extruder) and to produce the brick, but a relatively careful handling of the bricks would be necessary for the walling should not be taken for granted without further ado ►

The opening of the sub-chamber ^ of the third to (n-2) th Series makes it possible for the first time to apply the theory of optimal heat flow extension in extruded bricks to use the marginal area, which so far, as always restrictively mentioned in all publications, is could only extend to the middle area, since a continuous edge crossbar was unavoidable due to the manufacturing process was. Faira brick according to the innovation is the Tiärmefluß also continuously diverted over the longitudinal webs in the ranta zones.

The loss of heat flow path in bricks where the Partial chambers of the first and last row remain closed, can be neglected.

The innovation will now be described in more detail below with reference to the figures of the accompanying drawings, without going beyond this to be limited. Show it:

1-4 top views of four different exemplary embodiments from the brick according to the innovation.

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A first brick 20 according to the invention according to FIG. 1 has an uneven direction perpendicular to the direction of passage A. rad © number η of rows 5 with air chambers on »Each row 5 of this version consists of two in the transverse direction. Cut rectangular large chamber 1, with a width-length ratio of at least 1: 7 »where the length J - of the large chambers is at least 7) mm, and - - a sub-chamber 2 whose length is about half. Length of the f ■ large chamber 1 corresponds. The chambers 1, 2 are separated from one another by longitudinal webs 4, which extend in a straight line over the bricks - '"- length = strand height, ■ and by offset transverse webs 6.

The first and last row 5 ', and thus also all the others that fall on odd numbers in the sequence of rows 5, begin in the drawing below with a sub-chamber 2 ^! . As a result, a first transverse web 6 ¹ belonging to the normal brick lattice is formed at half the height of the first large chamber 1 of the second row 5. Di <-> FIG. 1 (and also FIG. 2) simultaneously also shows a view of the end piece of the extrusion press, so that each transverse web 6 * serves to strengthen the two weak points in the lower corner areas during extrusion. The known tile mentioned at the beginning has only large chambers in the outermost rows of chambers, with additional crossbars being inserted for reinforcement _; which lower the V / ä-L-ne on resistance. The provision of the sub-chamber 2 in the exposed lower corner area, which is also exposed to the greatest lateral load due to the inherent weight during extrusion, also creates a transverse web at this point, which reinforces the corner area. This transverse web 6 'is, however, a transverse web of the brick lattice and not an additional one. Furthermore, he strengthens the corner area surprisingly to an extent that the manufacture of the brick with large chambers 1 with rectangular

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Cross-section according to the theoretical calculation model is made possible. According to the embodiment of FIG. 1, the brick according to the innovation is per row two large chambers 1 and a partial chamber 2, which for an example brick length = strand height of 300 mm enables a large chamber length of 107.5 mm (tile no. 6 in the table).

The brick 20 according to FIG. 2 is provided with exclusively large chambers 1 on basic rows 5 and staggered rows 5 ″, which have two partial chambers 2 at the two ends of the row 6 'in the exposed corner area of the strand by the fact that the staggered rows 5 "in the sequence of rows 5 fall on odd numbers, i.e. the first row 5 ¹ , the third, the fifth, etc. up to the η-th and last row 5 ¹ staggered rows 5 ". With an example tile length of 300 nm, the large chambers 1 have a length of 90 mm (tile no. 5 in the table).

In FIGS. 3 and 4, the top view of two further exemplary embodiments of the innovation according to the invention is shown. Brick 20. Shown, with the same chamber lengths and arrangements as shown in Figs. In this embodiment, however, with the exception of the sub-chambers 2 'in the two outermost rows 5' 'all other sub-chambers open to the abutment surfaces 3, and therefore marked with 2 ". Also with these bricks there is the The prerequisite for thinking about their production by means of an extrusion process is that that in the lower corner areas of the strand, which correspond to the lower corner areas of the two bricks shown, each in the first and last row 5 'one

Partial chamber 2 · is formed with the associated reinforcement web 6 ¹ .

This design of the tile offers the particular advantage that the values described as ideal for chamber length, chamber width, longitudinal web width, etc. have so far only been valid for the central area of the tile, since the abutting surface 3, as also shown in FIGS. 1 and 2, was formed on a continuous edge transverse web, which could have slight projections and recesses or the like, but essentially represents a straight heat flow path in the direction of arrow A. The formation of the brick according to the invention with partial chambers 2 ″ open to the abutment surfaces j leads to an interrupted edge crosspiece, so that the heat flow path corresponds almost (Fig. 4) or completely (Fig. 3 whether n) to that in the middle of the brick therefore actually reaches the value that was calculated for the center of the brick. \

Claims (3)

1. Extruded hollow brick with an uneven number of staggered rows perpendicular to the direction of heat transfer aligned large chambers with rectangular ones, delimited by longitudinal and transverse webs Cross-section, with the large chambers one length • of at least 70 mm, preferably approx. 90 mm, and a ratio of width to length of at least 1: 7 »preferably 1:10, and the difference between the large chamber width and the longitudinal web width between 0 and J 4 | mm, preferably I 1 S mm, and with sub-chambers which are "essentially half the length of the large chamber, characterized in that each outermost row (5 ')> as is known, at least at one end with a sub-chamber (2 ¹ ) begins. 2. Hollow brick according to claim 1, wherein between each two Basic rows with only large chambers a staggered row of large chambers is arranged, which at each of its two ends has a sub-chamber, characterized in that in the order of the rows (5) As is known per se, the staggered rows (5 ") fall on odd numbers. 3. Hollow brick according to claim 1, characterized in that the sub-chambers (2 ") at least the third to (n-2) th row are open in a manner known per se to the abutment surfaces (3). 25 / sat