1. Introduction
Disrupted nutrient recycling is a serious problem for Europe and all over the world. Phosphorus (P) and nitrogen (N) are lost across environmental media during food production or are wasted instead of being used for plant nutrition [
1].
Phosphorus occurs in many minerals, of which apatite, Ca
5(F,Cl,OH) (PO
4)
3, is the most abundant and by far the most important group [
2]. Apatite, a group of phosphate minerals, has two major natural forms with concentrated P-content: mined mineral phosphate and biological origin animal bones. The term of phosphate rock (PR) refers to rock containing phosphate minerals, usually apatite, which can be commercially exploited, either directly or after processing, for commercial applications [
2]. Phosphate rocks of sedimentary origin typically have 30–35% phosphorus pentoxide (P
2O
5), whereas those of igneous origin contain marginally higher P
2O
5, typically 35–40% [
3].
Phosphate rocks by their geological and mineralogical nature contain a host of environmentally hazardous chemical elements such as cadmium (Cd), uranium (U), lead (Pb), mercury (Hg) and arsenic (As), among others.
Superphosphate fertilizers are particularly abundant in these hazardous elements and they contaminate the agricultural soils when used as fertilizer [
4].
U is an accompanying element of PR, particularly that of sedimentary origin. Depending on the geographical and biogenic origin, the uranium concentrations of PR may be as high as 150 mg kg
−1 in sedimentary and 220 mg kg
−1 in igneous PR [
5]. In Germany, the use of P-fertilizer from 1951 to 2011 has resulted in a cumulative application of approximately 14,000 t of U on agricultural land, corresponding to an average cumulative loading of 1 kg U per hectare [
6].
Reserves of PR used to make such fertilizers are finite, especially those ones with low Cd and U content, and concerns have been raised that they are in danger of exhaustion. Long term global food security requires the sustainable supply of P, a key resource for soil fertilization that cannot be substituted [
7]. Phosphate rock, which is the main fertilizer constituent, has been identified by the European Commission (EC) as a critical raw material in 2014 and upgraded in 2017 [
8].
The estimated yearly consumption of manufactured phosphorus mineral fertilizers in the European Union (EU) 27 member states (MS) was 1.11 Mt P in 2014 based on data provided by Fertiliser Europe [
9]. This is equivalent with 2.55 Mt/year mineral phosphorus fertilizer expressed in phosphorus pentoxide (P
2O
5).
For phosphate fertilizers, the EU is currently almost entirely dependent on import of PR mined outside of the EU (more than 90% of the phosphate rock used in the EU are imported, mainly from Morocco, Tunisia and Russia) [
10]. Concentration of phosphorus mines and gas fields outside the EU makes the EU fertilizing product industry and the European society dependent on, and vulnerable to, imports, high prices of raw materials and the political situation in supplying countries [
1]. Therefore, P recycling is one of the key priorities of the sustainable agricultural systems. Trends and developments on the global PR market are putting the EU’s security of supply of PR under increasing pressure [
11].
The environmental, economic, and social implications of food waste are of increasing public concern worldwide [
12]. The EU alone wastes 90 million tons of food every year or 180 kg per person. Much of this is food that is still suitable for human consumption [
7]. Losses from food processing mainly originate from the slaughtering of animals and the subsequent removal of P-rich waste materials (e.g., animal bones) from the biogeochemical P cycles. This loss flow equals 294 kt P year
−1 [
13]. The cattle, fish, and poultry industries are the largest sources of animal food industry waste [
14]. Animal-derived food waste contains rather high amounts of protein and cannot be disposed into the environment without proper treatment [
14].
According to the Eurostat databases, more than 51 million tons of carcass weight animals (bovine, poultries and pigs) are slaughtered every year in the EU 28 countries [
9]. According to Meeker and Hamilton [
15], approximately 49% of the live weight of cattle, 44% of the live weight of pigs, and 37% of the live weight of broilers are materials not consumed by humans. According to the European Fat Processors and Renderers Association (EFPRA), the proportion of each animal is not used for human consumption and rendered is the highest for bovine animals (42%), followed by pig (34%) and poultry (25%) [
16]. The European rendering industry (35 EFPRA members, 26 EU countries) processed more than 17 million t of raw materials in 2014, from which the category 3 processed products were 12 million t. EFPRA members process the majority of the total animal by-products in the EU and additionally a significant amount of material streams is produced by non-member organizations [
17]. The skeletal system can be up to 20% of the carcass weight, which mean that over 4 million tons of animal bone biomass re produced in the EU annually.
Biological apatite is an inorganic calcium phosphate salt. It is also a main inorganic component of biological hard tissues such as bones [
18]. The majority of P (85–88%) exists as bone P in the body of vertebrates [
19]. Animal bone by-product is characterized by very high P content compared to other animal waste. The P content of bovine and poultry bone is >10.5% on dry weight basis [
20,
21]. Other animal by-products have far lower phosphorus content than bone grist. For example, the phosphorus content of liquid pig manure, with 2–10% dry matter content, is 0.20–1.25% while the solid pig manure with 20–30% dry matter content has 1.6–5.08% P-content [
22].
Since 1870, the age of technological revolution, and through the 21st century, the carbon related technologies and products have been one of the most comprehensively researched sectors for energetic, steel industrial, activated carbon adsorbent, pharmaceutical, biotechnological and other applications. However, in the modern age, new environmental, climate protection and output product safety aspects require significantly improved and advanced pyrolysis technology performances to better protect the environment and human health. In this context, pyrolysis technology opens new technical, economic, environmental and legal opportunities for advanced production and use of safe Animal Bone Char (ABC) materials.
Pyrolysis (or carbonization process under true value reductive processing conditions) is the chemical decomposition of an organic substance by heating in the absence of oxygen. The process of pyrolysis transforms organic materials into three different components, i.e. solid, gas and liquid, in different proportions depending upon both the feedstock and the pyrolysis conditions used [
23].
The key objective of the pyrolysis process is to produce different types of carbon products. The organic carbon content of the pyrolyzed chars fluctuates between 5% and 95% of the dry mass, dependent on the feedstock and process temperature used. For instance, the carbon (C) content of pyrolyzed beech wood is around 85% while that of poultry manure is around 25% and that of bone is less than 10% [
24]. Different pyrolysis technology designs have highly variating quality performances to carbonize organic materials with different heat transfer efficiencies under reductive processing conditions, which is directly reflected in the remaining organic residual toxic content in the output char product, most importantly polycyclic aromatic hydrocarbons (PAHs).
Pyrolysis materials are different types of reductive processed stable carbon materials that are specifically made for different functional applications in designed quality, in which a chemically modified substance is produced from eligible input biomass materials via carbonization thermochemical treatment production process that fully meets the EU quality, safety, environmental and climate protection requirements. Biochar products are plant or animal bone biomass originating stable carbon pyrolysis materials with specific quality and safety parameters for explicit soil functional applications. The nutrient content of biochar mainly depends on the source: plant biochar is a high carbon composition soil improver with no or limited nutrient content, while ABC (Animal Bone Char) is a high phosphorus and calcium concentrated innovative organic fertilizer with high agronomic efficiency and low carbon content.
ABC is an innovative phosphorus natural fertilizer made of food grade (category 3) animal bones with concentrated >30% P2O5 content and specific quality for agronomical efficient organic and low input farming applications, also known as Bio-Phosphate.
Thus far, bone char has proven to be efficient in the remediation of heavy metal-contaminated soil and water [
25,
26] and to be suitable for agronomical applications. In previous studies, bone char (15% P, 28% Ca, 0.7% Mg) provided sufficient P and was also able to immobilize Cd in moderately contaminated soils [
27]. Meat and bone meal biochar showed potential for soil amendment, as liming agent, and for the remediation of Pb in contaminated waters [
28]. In highly Cd-contaminated soil with sufficient P supply, bone char could increase the yields of lettuce, wheat and potatoes, and at the same time decrease Cd contamination of potato [
29]. ABC is also suitable as a carrier for microorganisms, mainly P-solubilizing, acting as plant beneficial and biocontrol agents [
30,
31]. However, these studies used lab-scale pyrolysis processes, while an industrial scale pyrolysis system processing all types of category 3 and category 2 animal bones and converting them into ABC has only been recently developed.
Directive 2008/105/EC [
32] lists PAHs as identified priority hazardous substances and persistent organic pollutants which are generated from natural or anthropogenic processes, such as carbonization process. The occurrence of contaminants, such as polycyclic aromatic hydrocarbons (PAHs), Potential toxic elements (PTEs) in pyrolysis may derive either from contaminated feedstocks or from pyrolysis conditions which favor their production [
23]. Limits of these contaminants in biochar are under discussion and planned to enter into force in EU regulations and voluntary standards [
33]. It has been indicated that low temperatures are unable to remove micro pollutants that were originally present in contaminated feedstocks or created during the thermal process [
34,
35,
36]. During industrialized pyrolysis process, PAHs are the key target and performance indicator contaminants. Generally, it is considered that adequate pyrolysis methods allow a significant reduction of the PAHs contamination and that high PAHs levels indicate substandard production conditions [
37]. For example, if the process conditions do not separate solid residues and volatile tar components during cooling phases, a high PAHs content may eventually result [
38].
For slow-pyrolysis processes (at least 20 min reaction time), most of the weight loss in plant based pyrolysis materials derived from contaminated input materials occurs over the temperature range from 250 °C to 550 °C due to burning out of organics [
39,
40,
41], at least under laboratory conditions. At 500 °C, the pyrolysis reaction time to remove >90% of the organic micro pollutants was less than 5 min [
36]. However, animal bone based pyrolysis materials, due to their specific character, require far higher processing temperatures, up to 850 °C material core temperature and longer residence time, under true value industrial production conditions. In all types of pyrolysis materials, it is important to highlight, that there is a significant difference between the processing results from laboratory tests and from true value industrial and market competitive production conditions.
There is a substantial risk for the accumulation of non-volatile pollutants such as inorganic metals and metalloids in the pyrolysis materials as these mostly remain in the solid phase and become concentrated during the production process.
When pyrolysis material is irrevocably applied to open and complex soil ecological systems, there is also a direct interlink to subsurface water systems. Therefore, only qualified and safe biochar products can be applied to avoid both soil and water pollution. Currently, there is lack of harmonized quality and safety standards at European level for pyrolysis material products. However, the complex and strict criteria for safety and quality, functional application efficiency under open environmental and ecological conditions, are already unconditionally valid for all types of biochar products according to the Member State regulations. Nevertheless, since there is not yet a harmonized law on EU level, there are Member State differences. Industrial pyrolysis technology, pyrolysis material production and commercial applications, above 1 tons/year capacity, require Member State Authority permits that conform according to the European Union regulations. Less than 1 ton/year pyrolysis processing capacity is counted as research quantity.
The list of 16 polycyclic aromatic hydrocarbons (PAHs), issued by the U.S. Environmental Protection Agency (EPA) in 1976 with a view to use chemical analysis for assessing risks to human health from drinking water, has gained a tremendous role as a standardized set of compounds to be analyzed, especially in environmental studies [
42,
43]. Although not mandated by law in most countries, it appears that the list has attained the authority of a legal document and that the 16 priority PAHs compounds are routinely investigated in many environmental situations [
43].
The new scientific recognitions and developed analytical methods expanded the list to PAH19, which might be further expanded in the future. As an example, some Member State have required Authority accredited long termed agronomic efficiency tests and maximized potential organic contamination levels <1 mg kg
−1 for sum of 19 PAHs congeners for soil improvers since 2005, such as Hungary [
44], while other Member States do not perform agronomic efficiency testing for novel soil improver products and apply up to <6 mg kg
−1 for sum of US EPA 16 PAHs congeners. For example, the German Federal Soil Protection and Contaminated Sites Ordinance gives precautionary values for soil with low (≤8%) and high humus content (>8%) regarding the total content of 16 priority PAHs as defined by the Environmental Protection Agency of the United States (EPA 16 PAHs), namely 3 mg kg
−1 soil and 10 mg kg
−1, respectively [
33].
The Registration, Evaluation, Authorization and Restriction of Chemicals (REACH) is mandatory for all types of pyrolysis materials for import, manufacturing and placing on the market on its own or in preparation above 1 ton/year capacity, which is to be applied from 1 June 2018 in the EU. REACH is to be applied above 1 ton/year capacity for all types of pyrolysis material cases, i.e. all products that are thermochemically modified substances.
The conditions for access to the fertilizer market are only partially harmonized at EU level. The fragmentation of the non-harmonized part of the market is seriously hindering trade opportunities [
45]. Around 50% of the fertilizers currently on the market, however, are left out of the scope of the Regulation. This is true for a few inorganic fertilizers and for virtually all fertilizers produced from organic materials, such as animal or other agricultural by products, or recycled bio-waste from the food chain [
10].
Many Member States have detailed national rules and standards in place for such non-harmonized fertilizers, with environmental requirements, such as potential toxic elements (PTEs) contaminant limits, that do not apply to EC-fertilizers [
10]. The EU Member States have long regulated the agricultural use of soil improvers and organic fertilizers, such as ABC and other organic products. However, the regulations are different in each EU Member State, so the Mutual Recognition concept is difficult to be applied in practice. Therefore, the new EU Fertilizers Regulation revision under the Circular Economy incentive will soon, hopefully by 2019–2020, open full and EU wide law harmonization opportunity for many agricultural, food, and industrial by-products and organic material streams, including biochar as well as its formulated products.
The recent initiative on EU fertilizing products (COM (2016) 157 final) is expected to create a level playing field for all fertilizing products at EU level, thereby increase the industry’s opportunities to have access to the Internal Market while maintaining the national regulations in place for products limited to national markets, hence avoiding any market disruption [
45].
The improved and safe output pyrolysis material products enhance the environmental, ecological and economic sustainability of the food crop production, while reducing the negative footprint and contributing to climate change mitigation. Terra Humana Ltd. has been the science and technology coordinator and key technology designer for EU Commission co-financed biochar applied research projects since 2002, with prime specialization in ABC recovered bio-phosphate production full industrial engineering, economic field applications and market uptake evaluations. The core competence of Terra Humana Ltd. is zero emission pyrolysis and carbon refinery science and technology developments, objective driven to the added value recycling and recovery of phosphorus and other valuable nutrient materials [
46]. In this context, Terra Humana Ltd. is the EU and international knowledge center for ABC Bio-Phosphate matured research, science, technology and industrial engineering.
The recently closed EU project of Terra Humana Ltd. is REFERTIL (EU contract Number 289785 contracted in 2011,
www.refertil.info), the complex development works of which cover the fields of applied biochar, most importantly ABC, science, economical full scale industrialization and commercialization. REFERTIL is a biochar policy support specific project for conversion of biochar applied science into economical industrial practice, for which a comprehensive biochar law harmonization proposal has been reported to the Commission.
The objective of the present paper is to describe the Recycle–Reduce–Reuse (3R) zero emission pyrolysis technology designed for phosphorus recovery within the REFERTIL project as a case study for industrial scale production of animal bone char.
2. Materials and Methods
2.1. Origin of the Pyrolysis Materials
All ABC pyrolysis materials were processed by Terra Humana Ltd. Different pyrolysis treatment conditions (treatment temperature and residence time) were used in material treatability tests, considering different food grade animal bone meal and bone grist by-products with 400 kg/h (3200 tons/year) throughput capacity continuously operated 3R zero emission industrial pyrolysis equipment.
The origin of the category 3 food grade bone materials (cattle, chicken and big bones) was from the local animal by-product rendering and fat processing industrial factory. The rendering factory processes fresh raw material animal by-products from the meat and livestock industry into usable materials under heat treatment of 133 °C for 20 min at 3 bars of pressure and operating according to the EU animal by-product regulations 1069/2009 and 142/2011.
Different material core treatment temperatures (300, 450, 600 and 850 °C) were combined with different residence times (15, 20, 30, 40, 50 and 60 min) under industrial productive processing conditions. The temperature instruments were calibrated by accredited calibration laboratory, which is specialized for measuring temperature up to +1200 °C of different solid materials, liquids, gases and air under ISO 17025 standards. Standard Honeywell ceramic thermocouples were used with IP67 head for measurements up to +1200 °C.
Representative plant based pyrolysis material samples were received from the UK, Italy, France and Denmark and comparative tested for PAH16 and PAH19.
Table 1 shows the description of pyrolysis condition (treatment temperature (T), residence time (tres) and samples ID of different EU industrial reference plant based pyrolysis material samples which have been collected and analyzed.
Careful material specific consideration is needed for all analytical items, as well as which standards should be applied for investigation of the quality and safety of the pyrolysis materials, especially when open ecological soil applications are targeted. The Environmental Testing Laboratory of WESSLING Group is the first laboratory in Europe to have obtained accredited status for different analyses of the plant based and animal based pyrolysis materials. The accredited analysis of the different samples has been done by WESSLING Hungary Ltd. For sampling, EN-12079 standard was used, while, for sample pre-treatment, Method CEN/TC400—EN 16179:2012 was used.
2.2. Pyrolysis Material Yield
The yield of ABC was calculated as the proportion of the weight of pyrolysis product to the original material.
2.3. Determination of Total Carbon and Total Organic Carbon
Total Carbon was determined according to EN 13137:2001 standard, while the total organic carbon was measured according to EN 13039:2012 standard.
2.4. Determination of Total Nutrient Content of Pyrolysis Material
Total N was measured according to ISO 13878:1998-11 standard. Regarding sample preparation for determination of Total P, K, Ca, Mg, Na and S, the EN 13650:2002 standard was applied, with extraction of aqua regia soluble elements for sample preparation. Total P, K and S were measured by EPA Method 6010C (ICP-OES), while total Mg, Ca, Na were measured by EPA Method 6020A (ICP-MS).
2.5. Calculation of Nutrient Content of Pyrolysis Material Expressed in Oxide Form:
P2O5 (Phosphorus pentoxide) was calculated from the directly measured total P. The following chemical conversion factor was applied: P2O5 = Total P/0.436.
K2O was calculated from the directly measured total K. The following chemical conversion factor was applied: K2O = Total K/0.83.
MgO was calculated from the directly measured total Mg. The following chemical conversion factor was applied: MgO = Total Mg/0.603.
CaO was calculated from the directly measured total Ca. The following chemical conversion factor was applied: CaO = Total Ca/0.715.
SO3 was calculated from the directly measured total S. The following chemical conversion factor was applied: SO3 = Total S/0.4.
Na2O was calculated from the directly measured total Na. The following chemical conversion factor was applied: Na2O = Total Na/0.742.
2.6. Determination of Phosphorus Soluble in 2% Citric Acid
The EN 15920:2012 standard was used for sample preparation. The Phosphorus soluble in 2% citric acid was measured according to EPA Method 6010C (ICP-OES).
2.7. Determination of Organic Contaminants
PAH16 and PAH19 were measured according to CEN/TS 16181:2013 standard by gas chromatography (GC).
Regarding PCB7, the sum of PCB 28, 52, 101, 118, 138, 153, and 180 was measured according to EN 16167:2013 by gas chromatography with mass selective detection (GC-MS) and gas chromatography with electron-capture detection (GC-ECD).
PCDD/F were measured according to CEN/TS 16190:2012 by gas chromatography with high resolution mass selective detection (HR GC-MS).
2.8. Measurement of Potential Toxic Elements
Regarding Hg, sample preparation was done according to EN 13650:2002 and extraction of aqua regia soluble elements. Analysis was done with EPA Method 6020A using ICP-MS.
Cr (VI) was measured by CEN/TS 16318:2012. The determination was done by ion chromatography with spectrophotometric detection (method B).
As, Cd, Total Cr, Cu, Pb, Ni and Zn were measured according to EN 13650:2002 by extraction of aqua regia soluble elements and ICP-MS: EPA Method 6020A.
4. Discussion
For each type of pyrolysis (carbonization) processing technology, at full industrial production scale, the engineering design quality and efficiency performance is a critically important element. The pyrolysis technology design performance and quality will be reflected in all cases as a unique and recognized fingerprint in the output pyrolysis product quality and safety performance characteristics. In this context, the application of low quality pyrolysis production technology under market competitive production conditions result low quality and safety pyrolysis material output products with low market value, if any at all. Another important impact factor is the input material characteristics, which are also reflected in the output product characteristic.
The residence time is an important factor to maintain the economical industrial productivity during a short processing time, while it is also unconditionally important to assure equal quality for the processed carbon products. The Extended Producer Responsibility certification, the product quality and safety labeling documentation as of specified EU regulations, and Customer’s “right to know” information, are all important parts for the commercialization of biochar products.
All biological materials might have variations in their natural compositions and character, which is diverse by nature. The advanced carbonization processing must be able to fully compensate these variations and assure equal quality for the output ABC products. The animal by-product rendering pre-processing sterilization ofthe the input material animal bone by-products at 133 °C20min,3bars is upgraded into 3R carbonization final processing 850 °C20min safe performance. This system provides a safe and constant quality ABC product stream, while excluding any biological re- and trans-contamination risks at later agricultural applications, under any variating climatic and soil conditions.
The rendering industrial origin, food grade category 3 and industrial grade category 2 animal bone grist, is processed into ABC Bio-Phosphate. ABC is a macro-porous bio-based fertilizer, having as high as 92% pure calcium phosphate, 8% carbon content, and high nutrient density (30% P).
ABC provides multiple product functionalities in the organic and low input farming sectors, such as organic fertilizer (soil improver, growing medium and/or fertilizing product blends). The substitution of mineral phosphate import by recovered phosphorus is an important goal for European agriculture already in the short term, where ABC is a highly efficient and safe alternative in large extent in European industrial dimension. The fully safe ABC is used at low doses (100–600 kg/ha, on average 300 kg/ha) and in few cases when justified even up to 1000 kg/ha.
ABC bio-phosphate Phosphorus Fertilizer Replacement Value (PFRV) substitution potential in European dimension is estimated already at >5% (>125,000 t/year P) in short term (<2025) for all agricultural applications. The ABC PFRV for the organic farming and low input farming sectors, it is estimated at 100% in medium term (<2030). ABC overall European agriculture PFRV in the long term (>2030) is estimated at over >20% (>500,000 t/year P).
The REFERTIL consortium integrated the pyrolysis applied scientific and high maturity research, the industrial engineering, the legal and market competitive economical aspects and user demands from the horticultural sector. Harmonized and standardized analytical measurements have been developed for the determination of the physico-chemical properties, potential toxic element content and organic pollutants in all types of pyrolysis materials. A proposed quality and safety criterion system has also been set up which sets maximum inorganic and organic pollutant contents for safe application (
Table 10 and
Table 11).
The most important PTEs are Cd, Cr (Cr total and/or Cr(VI)), Cu, Zn, Hg, Ni, Pb and As, while the key organic parameters are polyclorinated dibenzodioxins and furans (PCDD/Fs), the sum of seven polychlorinated biphenyls (PCB7) and the sum of 16 US EPA priority PAHs (PAH16) congeners.
PCB7 is the sum of seven PCBs, PCB 28, 52, 101, 118, 138, 153 and 180. PAH16 is the sum of the following 16 US EPA congeners: naphthalene, acenaphthylene, acenaphthene, fluorene, phenanthrene, anthracene, fluoranthene, pyrene, benzo[a]anthracene, chrysene, benzo[b]fluoranthene, benzo[k]fluoranthene, benzo[a]pyrene, indeno[1,2,3-cd]pyrene, dibenzo[a,h]anthracene and benzo[ghi]perylene. PAH19, in addition to PAH16, includes 1-Methylnaphthalene, 2-Methylnaphthalene and Benzo[e]pyrene.
All proposed parameters are maximum allowable limits on EU level, which in justified environmental cases may be MS amended to lower limits. PAHs are key performance indicators, while PCDD/F and PCBs are not potential contamination risks. In some MS, 1 mg kg−1 for the sum of 19 PAHs congeners is permitted since 2005 as maximum limit for soil improvers. This low limit value requirement is already applied with special concern in environmentally sensitive regions. In general, 4 mg kg−1 PAH16 limit value is proposed. With various pyrolysis processing conditions, it has been verified that the technology critically influences the quality of the product.
Extended producers’ responsibility and liability for product safety are to be applied for all types of pyrolysis material cases.
Table 11 summarizes the proposed safety criteria for organic pollutants and
Table 12 for potential toxic elements by REFERTIL and the ongoing EU Fertilizers Regulation revision law harmonization.