4a

Table 4a: Quarterly sales   of sand and gravel (thousand tonnes), Great Britain [note 1]
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Source: DBT
Year Quarter Seasonally adjusted sand and   gravel [note 2, 3] Sand for building Sand for concreting Gravel for concreting and other   uses Sand and gravel for coating Sand, gravel and hoggin for fill Total sand and gravel of which Marine-dredged
2011 Q1 14,702 1,572 5,665 [c] [c] [c] 14,150 2,746
2011 Q2 14,610 1,579 6,127 5,291 [c] [c] 14,831 2,923
2011 Q3 13,831 1,533 6,085 5,160 [c] [c] 14,684 2,937
2011 Q4 13,919 1,357 5,612 4,719 [c] [c] 13,397 2,563
2012 Q1 14,503 1,481 5,635 5,039 [c] [c] 13,894 2,675
2012 Q2 14,183 1,712 5,608 5,633 [c] [c] 14,474 2,609
2012 Q3 14,278 1,778 5,612 6,259 [c] [c] 15,192 2,749
2012 Q4 15,009 1,528 5,139 6,146 [c] [c] 14,412 2,287
2013 Q1 13,913 1,380 4,854 5,107 [c] [c] 12,957 2,260
2013 Q2 12,964 1,570 4,665 4,908 [c] [c] 13,662 2,681
2013 Q3 13,041 1,545 5,007 4,760 322 2,264 13,898 2,914
2013 Q4 12,672 1,227 4,510 4,115 [c] [c] 12,074 2,634
2014 Q1 12,456 1,379 4,221 4,393 394 1,533 11,919 2,447
2014 Q2 13,132 1,472 4,744 5,627 302 1,379 13,524 3,296
2014 Q3 13,450 1,593 5,456 5,511 387 1,388 14,334 3,138
2014 Q4 13,392 1,359 4,796 4,825 333 1,340 12,653 2,832
2015 Q1 13,405 1,352 4,722 4,643 283 1,598 12,599 2,905
2015 Q2 13,589 1,626 5,539 5,170 413 1,617 14,364 3,150
2015 Q3 12,427 1,465 5,140 4,841 386 1,464 13,297 3,003
2015 Q4 13,300 1,371 5,128 4,661 330 971 12,461 2,679
2016 Q1 14,130 1,406 5,213 4,893 349 1,167 13,027 2,593
2016 Q2 14,099 1,796 5,775 5,587 600 1,408 15,165 3,116
2016 Q3 14,354 1,661 6,042 5,912 449 1,312 15,376 3,245
2016 Q4 14,431 1,449 5,392 5,043 393 1,169 13,446 2,816
2017 Q1 15,567 1,478 5,978 5,867 354 1,101 14,778 2,982
2017 Q2 15,133 1,703 6,515 6,345 390 950 15,903 4,045
2017 Q3 14,553 1,666 6,376 6,397 413 828 15,679 3,520
2017 Q4 15,073 1,462 5,763 5,429 341 969 13,965 3,117
2018 Q1 13,568 1,366 5,043 4,741 387 876 12,414 2,608
2018 Q2 14,502 1,782 6,276 6,190 393 1,041 15,681 3,140
2018 Q3 15,589 1,691 6,393 7,176 527 935 16,721 3,121
2018 Q4 14,605 1,533 5,617 5,089 369 840 13,448 2,730
2019 Q1 14,568 1,657 5,454 5,435 371 781 13,699 2,895
2019 Q2 14,733 2,043 5,863 6,252 390 1,077 15,619 3,154
2019 Q3 14,531 1,910 6,224 6,118 384 1,040 15,677 3,008
2019 Q4 14,661 1,493 5,502 5,225 349 930 13,498 2,753
2020 Q1 13,566 1,486 4,980 5,115 337 897 12,815 2,612
2020 Q2 9,899 1,235 3,993 4,397 244 707 10,575 2,318
2020 Q3 13,743 1,604 5,914 6,007 337 988 14,850 3,101
2020 Q4 12,775 1,182 4,709 4,666 353 831 11,742 2,365
2021 Q1 13,358 1,341 5,018 4,991 254 776 12,381 2,220
2021 Q2 13,440 1,614 5,782 5,936 324 937 14,593 2,683
2021 Q3 13,150 1,551 5,683 5,577 262 1,101 14,174 2,955
2021 Q4 13,819 1,383 5,188 4,878 273 896 12,619 2,235
2022 Q1 14,019 1,459 5,419 5,088 259 1,058 13,283 2,497
2022 Q2 13,589 1,604 6,136 5,373 328 991 14,431 2,778
2022 Q3 13,169 1,563 5,776 5,546 266 902 14,055 3,060
2022 Q4 12,692 1,219 4,568 4,550 227 933 11,497 2,498
2023 Q1 12,380 1,409 4,700 4,609 184 906 11,807 2,778
2023 Q2 11,868 1,482 5,168 5,089 214 915 12,868 2,995
2023 Q3 10,891 1,283 4,604 4,658 239 807 11,590 2,357
2023 Q4 10,428 969 3,673 3,613 210 839 9,303 1,973
2024 Q1 10,592 1,070 4,033 3,833 183 773 9,893 2,364

A conventional slate roof consists of thin slates, hung over wooden laths. Slates are hung in place by wooden pegs through a hole at the top of each slate.[2] The peg stops the slate slipping downwards, the weight of the slates above it hold the slate down. Later roofs replaced the peg by an iron nail driven into the lath, but the nail is always primarily a hook and it is the weight of the slates above that hold the roof covering down onto the frame. Lead nails were also used, long enough to be bent over the laths from the inside. In time these developed into strips cut from lead sheet.

Such roofs are common and are particularly well known in Wales, where the high quality slate from North Wales was exported worldwide. As the slate was of high quality it could be split very thinly by skilled artisans and so gave a lightweight roof covering that was still strong and long-lasting against harsh weather. Where local slate was used instead, this was of lower quality than Snowdonia slate and so the roof design may have been less successful. In particular, lower quality slate must be cut to thicker, heavier slates to retain adequate strength, so giving a roof of much greater weight.

Failure in slate roofs

The primary means of failure in a slate roof is when individual slates lose their peg attachment and begin to slide out of place. This can open up small gaps above each slate.

A secondary mode of failure is when the slates themselves begin to break up. The lower parts of a slate may break loose, giving a gap below a slate. Commonly the small and stressed area above the nail hole may fail, allowing the slate to slip as before. In the worst cases, a slate may simply break in half and be lost altogether.

A common repair to slate roofs is to apply ‘torching’, a mortar fillet underneath the slates, attaching them to the battens.[1][3] This may applied as either a repair, to hold slipping slates, or pre-emptively on construction.

Where slates are particularly heavy, the roof may begin to split apart along the roof line. This usually follows rot developing and weakening the internal timbers, often as a result of poor ventilation within the roofspace.

Grouted roofs
Where a roof has begun to fail overall, it may be ‘grouted’ to extend its working life. This is not a spot repair, but an overall treatment applied to the entire roof. A thin wash of mortar or render is applied across the roof. This fills the gaps between slates and also covers the slates’ surface. Grouting has two obvious visual effects: the distinct edges of the slates blur into a monolithic roof panel and also, as the grout is a pale white, paler than other building materials visible, the roof becomes much more prominent.[4][5]

Grouting is seen predominately along the western seaboard of the UK, particularly in Pembrokeshire in South West Wales and to a lesser extent the Isle of Anglesey, Cornwall and Devon. It has also been used, primarily as a sealant, on porous stone slates such as the Permian sandstones of Dumfriesshire.[1]

Grouting developed as a repair technique. A roof might have been grouted several times in its lifetime, each time the coating becoming thicker and more rounded. Eventually the weight of these extra render coats becomes too much for the structure of the roof and the roof may fail irreparably by splitting apart at the ridge.

A partial form of grouting was also practiced, where an external lime mortar grouting was applied, but only on the spaces between slates. This was used for larger slates and may have been applied to cottages that were re-roofed from thatch to slate.[6]

Pembrokeshire grouted roofs

Grouted roofs are most distinctive in Pembrokeshire and are considered to form part of the vernacular architecture of the county.

Pembrokeshire slate is often of poor quality compared to North Wales slate, thus requires thicker, heavier slates. These heavy slates also needed to be set on a mortar bed beneath, and grouted above.[7]

A feature of the Pembrokeshire style of roof are a number of prominent vertical ridges on the outside of the roof.[8] These are caused by barbed wire being stretched over the roof before grouting. The wire can be firmly attached to the structure and the barbs on the wire act as a mechanical key to retain the grout in place. Over time and repeated re-grouting, the wires are lost beneath ridges that build up. Barbed wire was used because it was conveniently available to remote farming communities and performed well. It was not manufactured until the 1870s and so this style of roof is newer than the first use of grouting, even with cement. William[7] describes the used of barbed wire as being a twentieth century development, and derived from the earlier ‘roped thatch’ technique, where a roof of thatched straw or reed would be retained by straw ropes over it.[9]