WO2014207295A1 - Method for producing peat - Google Patents

Method for producing peat Download PDF

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Publication number
WO2014207295A1
WO2014207295A1 PCT/FI2013/051196 FI2013051196W WO2014207295A1 WO 2014207295 A1 WO2014207295 A1 WO 2014207295A1 FI 2013051196 W FI2013051196 W FI 2013051196W WO 2014207295 A1 WO2014207295 A1 WO 2014207295A1
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WO
WIPO (PCT)
Prior art keywords
peat
vegetation
pit
bog
production
Prior art date
Application number
PCT/FI2013/051196
Other languages
English (en)
French (fr)
Inventor
Kari Mutka
Original Assignee
Biodiili Oy
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Family has litigation
First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=52141148&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=WO2014207295(A1) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
Application filed by Biodiili Oy filed Critical Biodiili Oy
Priority to EP13888135.4A priority Critical patent/EP3014069B1/en
Publication of WO2014207295A1 publication Critical patent/WO2014207295A1/en

Links

Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21CMINING OR QUARRYING
    • E21C49/00Obtaining peat; Machines therefor
    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10FDRYING OR WORKING-UP OF PEAT
    • C10F5/00Drying or de-watering peat
    • C10F5/02Drying or de-watering peat in the field; Auxiliary means therefor

Definitions

  • the application relates to a method for producing peat and a method for working a peat bog.
  • Vapo Oy has developed a variety of methods! such as an asphalt production method (UTU) and a method based on a ' sub- soil drainage field (SUTU), in which it has been possible to significantly reduce environmental hazards; see also patent FI122902 (application- No: FI20106096).
  • UTU asphalt production method
  • SUTU sub- soil drainage field
  • FI122902 application- No: FI20106096
  • peat is transferred from areas with a shal- low layer of peat to production fields in such a way that a peat layer is formed and the deep parts of the bog are dried by means of drainage ditches.
  • the bog area is prepared by peat moving so that the shallow fringe areas form a peat-free, mainly vegetation covered protective zone around a peat production site.
  • the mainly vegetation covered pit according to the method surrounding the production field, the vegetation basin, acts as a part of a water treatment system and 'as a storage basin for flood water.
  • the mainly vegetation' covered pit formed around the production field having a thick layer of peat acts as a collector and binder of dust.
  • the vegetation covered pit can constitute a carbon sink.
  • a primarily vegetation covered, either star-shaped or ring-shaped pit may be formed around a deep, peat area.
  • the pit may be uniform, or the pit may con ⁇ - sist of basins connected to each other by connecting ditches.
  • the peat moving operation is carried out again, if necessary.
  • the surface area of the pit is increased in comparison with the production field, and the water treatment is enhanced.
  • water can be recirculated to the intermediate zones (the pit) in the upper part of the bog.
  • part of the water can be pumped to a runoff field, and part of the water can be recirculated to the intermediate zones (the pit) in the upper part of the bog.
  • the method makes it possible produce peat even in small bog areas and/or in bog areas with a shallow layer of peat.
  • the pit i.e. the vegetation basin, according to the method may comprise flooded dikes.
  • a service road is provided around the pit, i.e. the vegetation 5 basin.
  • willow trees are planted in the pit.
  • the shallow fringe areas of the bog 1 are prepared by moving the peat to. the production fields 3 by using an excavator in such a way that an almost totally peat-
  • the live ground vegetation from the bog is " returned to the harvested area 2 where it constitutes a live vegetation layer that binds carbon dioxide.
  • the peat free area can be called an intermediate zone, a pit, or a vegetation basin. If there is no vegetation, for example
  • the bog vegetation may comprise, for example, Sphagnum moss and/or Eriophorum vaginatum (hare's tail cottongrass).
  • the parts 4 (normally middle parts) of the bog which are deeper than 2 m are normally prepared and dried by means of drainage ditches 5.
  • the prepared bog has a star-like or ring-like shape where the centre part is a normal production field 4 and the fringe parts form a peat-free area 2 which is 30 primarily covered with vegetation. i " When the fringe parts of the production field become shallow, a peat moving operation is carried out again, wherein peat from the shallow part is transferred to the existing peat field and is levelled 6. The new area for peat mov-
  • the peat moving operation can be performed several times, if necessary, until the production field has reached its minimum size and the peat production is finished by conventional methods.
  • the intermediate zones i.e. the pits, replace conventional ditches on the fringe of the bog and act as storage basins for collecting flood water, if necessary, from which basins the water can be drained in a controlled manner to a water treatment system 7 and 8.
  • the peat production site is surrounded by a peripheral ditch, i.e. an isolation ditch.
  • the isolation ditch prevents water from the outside or the environment of the peat production site from flowing to the peat production field.
  • a peripheral ditch surrounds a protective zone surrounding the actual production field.
  • the protective zone prevents ⁇ the spreading of dust from the production field to the environment.
  • the vegetation basins presented here can be used to replace the protective zone in whole or in part.
  • the peat production site may also be provided with both a protective zone and a vegetation zone.
  • the vegetation basin makes it possi- ble to select and to utilize the vegetation in a versatile and efficient way, for example in comparison with the protective zone. With the vegetation basin, it is possible to effectively prevent the spreading of dust in the surrounding ditch.
  • the actual peat production is performed in the conventional way by means of normal production equipment.
  • Stack areas 0 and roads are built on the fringes of the production field in the conventional way.
  • a service road can be built between the peripheral ditch 1 of the bog area and the vegetation basin 2, to surround the peat production site.
  • the service roads can be built from the borrow material of the peripheral ditch 1.
  • the service road makes it possible to maintain the vegetation basin and, for example, to harvest willow from the area of the vegetation basin.
  • a water treatment system for the site is constructed by placing a pump station 7 at the lower fringe of the bog and by conveying the water from there to a runoff field 8. If necessary, chemicals can be applied to boost the treatment.
  • the intermediate zones or pits formed and primarily covered with veg- etation act as a first stage in water treatment by collecting dust, solids and nutrients.
  • the water treatment is intensified by circulating water to the upper parts of the bog, to the intermediate zones 9 covered with vegetation, wherein the vegetation in the pits is used as a purifying and filtering element.
  • the proportion of water circulated is higher and the efficiency of purification is better than in times of flooding. In times of little runoff, an almost closed circulation is achieved.
  • a closed circulation of water can be achieved. This is particularly important for binding dust and nutrients during the production.
  • the content of impurities in 1 water is the highest during the production period.
  • the functionality of the water treatment system is significantly improved, because flood waters can be collected in the space (pits) formed in the intermediate zones and conveyed from there in a controlled manner through the treatment system.
  • the most significant weakness of present treatment systems is uncontrolled runoff fluctuation, which causes problems in the dosage of chemicals as well as in the planning of the capacity of the treatment systems.
  • the water treatment capacity is liable to being exceeded during flooding. For example, the amount of water in the runoff field and a chemical dosing unit may temporarily exceed their receiving and/or treating capacity.
  • the vegetation surface in the intermediate zones (pits) acts as a runoff field as such, effectively collecting fines, humus and nutrients.
  • the circulation of water substantially improves the efficiency of water treatment.
  • the method is cost-effective as the preparations for the production are not significantly more expensive than normal preparations, because peat moving by an excavator is efficient.
  • the costs for the preparation of the deep areas fall within the normal range.
  • the costs for the peat production itself are normal, because conventional methods and equipment are used in the production.
  • the vegetation basin formed provides a habitat for wetland plants, insects and birds even during the peat production period, from the beginning of the production.
  • peat is transferred from shallow peat areas 2 by an excavator to production fields 3 in such a way that a two to three fold peat layer is pro- vided, depending on the thickness of the peat layer of the bog.
  • the peat layer can also be thinner. The thickness of the peat layer will depend on the quantity of peat and on the extent of the surface area on which it is spread.
  • the pit 2 surrounding the production field is a uniform area.
  • the pit 2 can be a uniform annular area around the production field 4.
  • the pit can be a uniform area or it can comprise single basins.
  • the pit can form a star-shaped area around the production field.
  • the pit can consist of fields extending towards the production field.
  • the pit can contain non-uniform areas.
  • the strips of the pit can constitute single basins.
  • the pit can comprise several single basins linked to each other to facilitate water circulation.
  • the basins are connected to each other by means of, for example, ditches. In the area of the pit, water is circulated either naturally within the uniform area, or via ditches connecting the single basins. >
  • the shallow fringe part of the bog 1 constitutes a vegetation basin 2.
  • Said vegetation basin 2 stores flood waters and enables controlled water treatment.
  • the vegetation in the vegetation basin evaporates water, binds nutrients and peat dust, and acts as a runoff field.
  • the bog vegetation in the vegetation basin binds carbon dioxide from the air.
  • the vegetation basin acts as a carbon sink from the second year on at the latest, throughout the production period. In this way, the surface area 4 of the production field 4 * that generates carbon dioxide in the air is reduced.
  • the vegetation in the vegetation basin 2 can contain, for example, Sphag- num moss, Eriophorum vaginatum, and/or willow.
  • Eriophorum vaginatum (cottongrass) is found even in harsh environments, and it collects and binds nutrients well.
  • the vegetation basin it is possible to grow e.g. willow as an energy crop already during the peat production. As an energy crop, the willow evaporates water and binds nutrients in an efficient way. The willow evaporates even 500 mm during a growing season. For its part, the crop will intensify the treatment of waters.
  • useful biofuel can be produced from the willow as an energy crop.
  • Willow planted or transplanted in the vegetation basin can form a bush-like fence around the production field. The willow fence will efficiently prevent the spreading of dust from the production field, for example compared with lower vegetation.
  • Service roads can be built between the ditch 1 that surrounds the bog area, and the vegetation basin 2.
  • the service roads are useful in the cultivation of the vegetation and enable, for example, the harvesting of willow.
  • the production field is frozen and has load-bearing capacity.
  • the load-bearing capacity of the ice crust on the vegetation basin will depend on the ambient conditions.
  • the service roads in the vegetation basin make it possible to maintain the vegetation basin irrespective of the ambient conditions.
  • the service roads can be built by utilizing borrow material from the area. Earth does not need to be brought from elsewhere but the service roads can be made of material from the bog itself.
  • flooded dikes are provided at the bottom of the vegetation basin 2 surrounding the production field 4.
  • the flooded dikes make water run more slowly from the production field 4 to the vegetation zone 2.
  • the flooded dikes water is stored more evenly throughout the area of the vegetation basin 2. Runoff water can be guided forward in a controlled manner.
  • the water can be pumped 7 to a runoff field 8.
  • Water can be recirculated to the upper, drier areas 9 of the vegetation basin!
  • the vegetation in the pit 2 filters and purifies water.
  • the water purification can be intensified by circulating water from the wet, deeper parts of the vegetation zone to its drier, shallower parts 9.
  • the flooded dikes make it possible to circulate water in a controlled manner.
  • Heavy precipitation whose depth may be even e.g. 50 mm, loads the water treatment system as the amount of water is suddenly increased.
  • there is bulk peat on the production field that is washed away with the water and causes additional loading in the water treatment system.
  • a downpour may have caused runoff of unwanted material all the way to the waterways.
  • At the time of spring flooding there is no bulk peat on the production field, but nutrients and humus in the bog area constitute a load on the water treatment.
  • the water circulation may constitute a closed circulation during a dry period, for example in the summer. Water is circulated when the surface of ground- water is below a given maximum level. If the maximum level is exceeded, part of the water is conveyed to a water treatment system 8 outside the area. During a dry period, some or a major part of the waters can be evaporated off ⁇ winter, or when -the ground is frozen, the amount of runoff is small. In times of frost, runoff is cleaner, so that water treatment is less loaded/ Thus, the water under the ice crust of the vegetation basin can be pumped off. In this way, the capacity of the vegetation basin is increased. The pumped-off basin can receive eventual floodwaters in the spring. Draining the vegetation basin will increase the capacity of the vegetation basin to receive greater amounts of water and prevent adverse environmental impacts and/or loads in the subsequent steps of water treatment. Preferably, the amount of water in the pit can be regulated by means of a pump.
  • the flooded dikes in the vegetation basin By means of the flooded dikes in the vegetation basin, it is possible to control impurities in water during the dry and wet seasons.
  • a dry season for example in the summer when the water amount is relatively small, the nutrient content in water is relatively higher than in a wet season, for example during flooding, when the water amount is larger.
  • water can be circulated, aiming at an internal circulation, wherein water is not drained out of the bog area 1 of the peat production site, for example to a runoff field 8. If the amount of water is exceeds that which can be internally circulated in the bog area 1 of the peat production site, it is necessary to drain some of the water to the runoff field 8.
  • the circulated water drained to the runoff field is cleaner than water pumped directly to the runoff field.
  • water is circulated in the sys- tern. In this way, the efficiency of purification is increased.
  • runoff peaks can be controlled better. Said methods enable effective treatment and purification of waters. Thanks to the simple implementation, the implementation costs remain low.
  • the 5 area can have the shape of, for example, a square.
  • the average depth of the peat layer in the peat production field to be examined is 3 meters.
  • the area is surrounded by a vegetation basin having a width of 20 meters.
  • the average depth of peat to be removed from the area of the vegetation basin is about 1.5 meters.
  • the amount of peat to be moved is about 120,000 m 3 .
  • a precipitation of 50 mm (50,000 m 3 ) in a production field of 100 hectares can be stored in a vegetation basin surrounding the production field and having a width of 20 m and a capacity of 80,000 m 3 .
  • the capacity or maximum degree of filling of the vegetation basin is thus about 2/3 of its volume.
  • the vegetation basin will bind part of the dust and humus contained in
  • the vegetation basin will collect part of the airborne dust. As the vegetation basin binds dust, less dust is carried to the ditches bordering the bog area and to the nearby areas.
  • the basin is used both as a runoff field and as a settling basin.
  • the implementation contains equipment for, for example, moving peat mass from the fringe areas to the production field, for spreading the peat on the production field, and for pumping water.
  • the equipment may comprise known devices which are in use, such as equipment for pumping water and/or an excavator for moving and spreading masses of peat.
  • effi- 5 cient techniques can be used in the production.
  • the method can be implemented by equipment of prior art. In the method, it is possible to utilize
  • shallow fringe areas of wetlands can be utilized by turning 0 them into a vegetation basin.
  • peat extracted from a vegetation basin is first lifted to form a fresh peat layer on top of an existing peat layer in the production field in the middle part of the bog area.
  • Capillary water rise is discontinued between said existing and fresh peat layers. This improves the conditions for drying of the peat.
  • the weather dependence of the 5 fringe areas is decreased.
  • the transfer of peat can repeated several times.
  • peat mass can be lifted from the fringe areas onto the production field.
  • the ground surface is about 2 to 2.5 meters lower than the ground surface in the production field.
  • the production fields can become shallower by 7 to 14 cm per year, for example about 10 cm per year.
  • peat can be moved from the fringe area to the production fields in the centre.
  • the transfer of peat is repeated at intervals of about 4 to 5 years.
  • Peat 6 from the shallower area is moved to an existing peat field in the central part of the production field. In this way, the surface area of the vegetation area will increase and the surface area of the production field will decrease, respectively.
  • the peat mass in the production field will increase and the area will be higher than before the transfer.
  • peat transfer from the shallower fringe area of the production field can be repeated several times.
  • Said methods have a positive effect on the environmental impacts of peat production. Dust possibly spread from the bog can be bound in a more effective way, whereby dust emissions are reduced. Carbon dioxide emissions are reduced. Biodiversity is increased.
  • Environmental restoration is accelerated, as the restoration process begins on the fringe of the bog already at the beginning of the production. The restoration area will expand towards the centre of the area as the production proceeds. Runoff waters and entrained nutrients are utilized in the restoration. In this way, wetlands are formed, which are useful for e.g. waterfowl and waders.
  • the water balance of the bog area will be restored faster. When the water balance is restored and the water level remains high, the vegetation will start to form peat. In other words, the peatland will begin to function as a real bog.
  • the pit i.e. ' the vegetation basin around the site, acts as a fire protection basin.
  • the vegetation basin will prevent a possible fire from spreading out- side the peat production site. Because the pit surrounding the peat production site contains water, water is available on all sides of the peat production site, and no separate fire water basins will be needed.
  • peat is transferred from shallow peat areas by an excavator to production fields 3 in such a way that a two to three fold peat layer is provided, depending on the thickness of the peat layer of the bog. Live bog vegetation from the location of the peat layer to be transferred is returned to its original location, whereby a carbon-binding vegetation zone is provided.
  • the deep parts of the bog are dried in the normal way by means of drainage ditches 5.
  • the bog area 1 is prepared by peat moving in such a way that shallow (typically shallower than 2 m) fringe areas form a peat-free protective zone 2 around the peat production site, primarily covered by vegetation and acting as storage basins for flood water and as a part of the water treatment system for the site.
  • a star-shaped or ring-shaped pit 2 primarily covered with vegetation is formed around the deep peat area 4.
  • the peat moving is performed again 6, if necessary, wherein the surface area of the pit increases in comparison with the production field, and the water treatment is enhanced.
  • the actual peat production can be implemented by means of normal production equipment in a cost-efficient way.
  • the pit 2 formed, surrounding the production field and mainly covered by vegetation, acts as a part of the water treatment system and as a storage basin for flood water.
  • part of the water is pumped from the pump station 7 at the lowermost point of the bog to the runoff field 8, and part of the water is recirculated to the intermediate zones 9 in the upper part of the bog (to the pit).
  • the mainly vegetation-covered pit 2 formed around the area with a thick layer of peat acts as a collector and binder of dust.
  • the pits covered with vegetation can be used to reduce greenhouse gas emissions from the site, the pits constituting a carbon sink, and to reduce emissions caused by residual peat by means of more economical utilization of the peat.
  • the restoration of the bog after the peat production can be performed quickly by means of pits 2, or the area can also be prepared for agricultural or forestry use.
  • the peat production can be implemented in an efficient, economical and environmentally friendly way, even in bog areas which are small or have a shallow layer of peat.
  • Obvious modifications can be made in the above described methods and examples without deviating from the scope of protection.
  • Features according to the methods and examples can be combined, omitted and/or replaced with others.

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  • Engineering & Computer Science (AREA)
  • Mining & Mineral Resources (AREA)
  • Chemical & Material Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • Geochemistry & Mineralogy (AREA)
  • Geology (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Organic Chemistry (AREA)
  • Cultivation Of Plants (AREA)
  • Treating Waste Gases (AREA)
PCT/FI2013/051196 2013-06-24 2013-12-20 Method for producing peat WO2014207295A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP13888135.4A EP3014069B1 (en) 2013-06-24 2013-12-20 Method for producing peat

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
FI20130179A FI125378B (sv) 2013-06-24 2013-06-24 Förfarande för producering av bränn- och växttorv
FI20130179 2013-06-24

Publications (1)

Publication Number Publication Date
WO2014207295A1 true WO2014207295A1 (en) 2014-12-31

Family

ID=52141148

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/FI2013/051196 WO2014207295A1 (en) 2013-06-24 2013-12-20 Method for producing peat

Country Status (3)

Country Link
EP (1) EP3014069B1 (sv)
FI (1) FI125378B (sv)
WO (1) WO2014207295A1 (sv)

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
SU688629A1 (ru) * 1977-07-05 1979-09-30 Всесоюзный Научно-Исследовательский Институт Торфяной Промышленности Вниитп Способ полевой сушки резного торфа
WO2010084250A1 (en) * 2009-01-23 2010-07-29 Vapo Oy Method and drying field for fuel peat production
EP2444471A2 (en) * 2010-10-22 2012-04-25 Vapo Oy Method for producing peat

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
SU688629A1 (ru) * 1977-07-05 1979-09-30 Всесоюзный Научно-Исследовательский Институт Торфяной Промышленности Вниитп Способ полевой сушки резного торфа
WO2010084250A1 (en) * 2009-01-23 2010-07-29 Vapo Oy Method and drying field for fuel peat production
EP2444471A2 (en) * 2010-10-22 2012-04-25 Vapo Oy Method for producing peat

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
ROCHEFORT, L. ET AL.: "Restoration of degraded boreal peatlands", BOREAL PEATLAND ECOSYSTEMS, vol. 188, 2006, PAGES 389, 397-399, 405-408 AND 410-411;, XP008181013 *

Also Published As

Publication number Publication date
EP3014069B1 (en) 2018-09-05
EP3014069A4 (en) 2017-04-12
FI20130179A (sv) 2014-12-25
FI125378B (sv) 2015-09-15
EP3014069A1 (en) 2016-05-04

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