(Seed 🌱 + Organic Fertilizers 🌿 + Water 💧) × Time ⏳ = Healthy Organic Food 🍎🥦🌾 

Partnership Countries

A&V Consulting, LLC partners with diverse countries around the world to provide innovative and sustainable agricultural solutions to the U.S. market. Our international network includes collaboration with agricultural producers, distributors, and researchers who possess advanced technologies in the fields of biotechnology, organic farming, and crop protection.

Our partnership countries are as follows:

• Australia
• Brazil
• Canada
• China
• France
• Germany
• India
• Italy
• Japan
• Poland
• Russia
• South Africa
• Spain

Through these partnerships, we connect U.S. agricultural stakeholders with cutting-edge bio-products and biostimulants, driving agricultural sustainability and contributing to improved crop production.

Countries

The organic fertilizers and growth biostimulants market in the USA is expected to experience significant growth over the next 3-10 years, driven by rising consumer demand for organic products and increasing adoption of sustainable agricultural practices. By 2025, the market is projected to reach around $61.83 billion, and it is forecasted to continue expanding at a compound annual growth rate (CAGR) of approximately 10-12%. This growth will be fueled by increasing awareness of environmental sustainability, technological advancements in production, and government incentives supporting organic farming. The demand for organic fertilizers and biostimulants is projected to increase by 8-10% annually, with the market potentially surpassing $100 billion by 2030. Additionally, innovations in product quality and efficiency, such as bio-based and microbial fertilizers, are expected to contribute significantly to market expansion (Grand View Research, Market Research Future, Statista, Organic Trade Association, U.S. Department of Agriculture).

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The sources of this information include market research reports and projections from organizations such as Grand View Research, Market Research Future, and Statista, along with data from industry associations like the Organic Trade Association (OTA) and the U.S. Department of Agriculture (USDA

Manure Management Systems in US

Flush System

Flush Dairy Manure Management System with Sand Separation and Two-Stage Treatment

A flush dairy barn with a sand settling lane (to separate sand) and a weeping wall (to separate manure solids) maximizes nutrient use and protects the local water supply. See how brothers Mark and Andy Rodgers employ an elaborate cow cooling system and high-quality rations to maintain high milk production on their southeastern dairy farm. In addition, their small family farm has implemented the following practices in Hillcrest Farms Ic. Dearing, GA

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Mark Rogers said:

A flush dairy barn with a sand settling lane (to separate sand) and a weeping wall (to separate manure solids) maximizes nutrient use and protects the local water supply. See how brothers Mark and Andy Rodgers employ an elaborate cow cooling system and high-quality rations to maintain high milk production on their southeastern dairy farm. In addition, their small family farm has implemented the following practices: I need more details on how long flushed manure stays in one pond then removed to the second pond for how long before spreading to the field etc?

Below is a typical, field-proven timeline for a flush dairy barn system with sand settling lane + weeping wall + two-pond storage, like the one you described. Exact timing varies by herd size, climate, acreage, and nutrient-management plan, but these ranges are realistic for southeastern U.S. dairies.----------------------

1️⃣ Flush Barn → Sand Settling Lane

Purpose: Remove sand to protect pumps, pipes, and downstream treatment.

Time in system:

• Minutes to hours (continuous or batch flow)

What happens:

• Manure + flush water exits barns several times per day

• Velocity drops in the sand lane

• 80–90% of sand settles out

• Sand is typically recovered daily or every 1–3 days and reused after drying

👉 Sand is not stored long-term in liquid ponds.

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2️⃣ Primary Pond (or Weeping Wall Feed Basin)

Purpose: Capture coarse manure solids and reduce organic load

Typical retention time:

• 3–14 days

• Often designed as short-term hydraulic retention, not seasonal storage

What happens:

• Manure slurry flows to a weeping wall or solids basin

• Liquids pass through the wall

• Solids stack and dewater naturally

Solids removal frequency:

• Every 2–6 weeks (sometimes longer in dry weather)

Solids often:

• Stockpiled

• Composted

• Land-applied to forage fields

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3️⃣ Secondary Pond (Liquid Storage / Nutrient Pond)

Purpose: Store nutrient-rich liquid for controlled land application

Typical retention time:

• 30–180 days

• Many dairies design for 90–120 days minimum

• Some systems hold liquid 6–9 months to match crop demand

What happens:

• Liquids are more uniform and pumpable

• Nitrogen partially stabilizes (less odor, better application control)

• Pathogen levels decline over time

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4️⃣ Field Application (Irrigation or Injection)

Timing depends on:

• Crop type (corn silage, bermudagrass, rye, alfalfa)

• Soil moisture

• Nutrient Management Plan (NMP)

• Weather restrictions (especially in Florida & Southeast)

Common practice:

• Apply every 2–4 weeks during the growing season

Avoid spreading:

• On saturated soils

• Before heavy rain

• During restricted winter windows (if applicable)

Application methods:

• Low-pressure irrigation

• Traveling guns

• Subsurface injection (less common but increasing)

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5️⃣ Typical Overall Timeline (Simplified)

Stage

Typical Duration

Sand settling

Minutes–hours

Primary pond / weeping wall

3–14 days

Secondary liquid pond

1–6 months

Field application

Cyclical, crop-driven

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Challenges of Conventional Flush Dairy Manure Systems

Modular Proposal Section – A&V Consulting LLC

This section provides a unified, modular overview of the key operational, environmental, and strategic challenges associated with conventional flush dairy manure management systems. The structure allows the same technical content to be presented to producers, regulators, and investors with emphasis adjusted by audience.

Operational & Herd Health Challenges (Producer Perspective)

Flush systems with sand bedding are effective for manure movement, but over time they often create challenges related to odor, bedding hygiene, and cow health. As flush water is reused, it becomes more concentrated with organic matter and bacteria, leading to stronger odors and increased contamination of sand bedding. Wet, contaminated sand comes into direct contact with udders, teats, and reproductive areas, increasing the risk of mastitis, elevated somatic cell counts, and reproductive disorders.

Environmental & Biosecurity Considerations (Regulatory Perspective)

From an environmental standpoint, conventional flush systems rely heavily on recycled water and open storage lagoons. Repeated reuse increases nutrient and odor-causing compound concentrations, intensifying emissions during flushing and agitation. Open channels, sand lanes, and lagoons are exposed to birds, insects, and wildlife, limiting biosecurity and enabling continual pathogen circulation. Nutrient variability in storage ponds complicates nutrient management and increases long-term runoff and leaching risks.

Long-Term Risk & Scalability Limitations (Investor / ESG Perspective)

Conventional flush manure systems depend on dilution and storage rather than controlled treatment. Odor, pathogen levels, and nutrient concentrations are managed indirectly and remain highly variable, creating regulatory exposure and community-relations risk. Reliance on large open lagoons concentrates environmental liability and limits scalability, which increasingly conflicts with ESG and sustainability expectations.

Enclosed Fermentation as a Strategic Upgrade Path

Enclosed fermentation systems address these limitations by introducing controlled biological treatment. They significantly reduce odor emissions, lower pathogen loads, stabilize nutrients, and reduce reliance on open storage. Integrated with existing flush infrastructure, enclosed fermentation breaks the cycle of pathogen recirculation, improves bedding hygiene and biosecurity, and enables more predictable and higher-value fertilizer outputs—transforming manure management from disposal to resource recovery.

 Deep-Pit Manure System

Under-cage manure pit system in egg-layer facilities

Storage Tunnel / Deep-Pit Manure System — Detailed Description & Characteristics

1. Structural Configuration

A longitudinal storage tunnel (deep pit) runs continuously beneath the poultry house, typically extending the full length of the building. The pit is constructed of reinforced concrete (most common in modern facilities) or compacted earth with concrete sidewalls in older designs. Depth commonly ranges from 1.2 to 3.0 meters (4–10 feet), providing large volumetric capacity for manure accumulation.

The tunnel is accessed periodically through clean-out points at the ends or via side openings, allowing mechanical removal using loaders, scrapers, or conveyor systems.

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2. Manure Accumulation Dynamics

Manure drops directly from the cages by gravity and accumulates continuously in the pit. Retention time varies by operation and contractor availability, ranging from several days to multiple weeks or months.

During accumulation:

• Fresh manure layers continuously overlay older material.

• Lower layers become increasingly compacted under their own weight.

• Moisture stratification develops, with wetter, denser material at the bottom.

This creates a layered biological system rather than uniform storage.

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3. Moisture Characteristics

Manure in deep pits typically exhibits high moisture content, often in the range of 60–75%, depending on:

• Bird diet and water intake

• House ventilation rates

• Presence or absence of manure drying systems

Because the manure is not actively aerated or mixed, evaporative drying is limited, particularly in the lower pit layers. High moisture contributes directly to odor formation, ammonia volatilization, and biological instability.

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4. Anaerobic Conditions

As manure accumulates, oxygen penetration is limited to the surface layers only. Within a short period:

• Lower and compacted layers become anaerobic

• Oxygen diffusion is effectively zero below the top few centimeters

• Anaerobic microbial communities dominate

This environment promotes:

• Methanogenesis (methane production)

• Formation of reduced sulfur compounds (e.g., hydrogen sulfide)

• Incomplete organic matter stabilization

The pit therefore functions as a passive anaerobic reactor, though without process control.

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5. Heat Generation

Biological decomposition within the pit generates heat through microbial activity:

• Temperatures typically rise to 30–45°C (86–113°F) in active zones

• Heat is unevenly distributed due to lack of mixing

• Thermal stratification is common

Despite heat generation, temperatures are insufficient to achieve pathogen reduction or full stabilization, unlike controlled thermophilic systems.

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6. Gas Generation and Accumulation

Anaerobic degradation leads to continuous gas production, including:

• Ammonia (NH₃) — from nitrogen mineralization

• Methane (CH₄) — from anaerobic digestion

• Hydrogen sulfide (H₂S) — from sulfur-reducing bacteria

• Carbon dioxide (CO₂)

These gases:

• Accumulate within the pit

• Are intermittently released during ventilation cycles or clean-out

• Contribute to odor events, worker safety risks, and community complaints

Gas release is episodic and uncontrolled, often peaking during manure agitation or removal.

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7. Functional Classification

From an engineering and regulatory perspective, the deep-pit tunnel is best described as:

• A storage system, not a treatment system

• Passive, uncontrolled, and biologically unstable

• Designed to delay handling, not to reduce emissions or create value

While effective for separating manure from birds, the system does not address odor, emissions, nutrient stabilization, or downstream marketability.

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8. Relevance to Advanced Processing Systems

Because manure is already consolidated in a single below-house location, deep-pit systems are particularly compatible with downstream add-on technologies, such as enclosed fermentation or controlled treatment units, which can intercept manure after collection without altering bird housing or daily farm operations.

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Regulatory / Compliance Description (DEP / EPA)

1. Existing Manure Storage System — Regulatory Characterization

The facility utilizes a direct-drop deep-pit manure storage system located beneath the layer houses. Manure is deposited by gravity into a longitudinal below-house storage tunnel and is retained for variable periods prior to removal.

From an environmental compliance perspective, the system functions as a passive manure storage structure, not a treatment or stabilization process. Manure is stored in bulk under predominantly anaerobic conditions, with no active aeration, controlled mixing, or temperature management.

Key regulatory characteristics include:

• Extended retention time, allowing anaerobic decomposition

• Elevated moisture content (typically 60–75%)

• Generation of ammonia, methane, hydrogen sulfide, and odor-causing compounds

• Intermittent and uncontrolled gas release, particularly during ventilation cycles and clean-out events

The system is effective for separating manure from birds but does not reduce emissions, stabilize nutrients, or mitigate odor at the source. As such, it represents a potential point of environmental impact with respect to air quality, odor nuisance, and greenhouse gas emissions.

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2. Before / After Comparison

Deep-Pit Storage vs. Enclosed Fermentation (COMPO)

Regulatory Interpretation:

The enclosed fermentation system converts manure handling from a storage-based practice into a treatment-based process, significantly reducing emissions and improving environmental performance while producing a stabilized end product suitable for beneficial reuse.

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3. Emissions Avoidance & Environmental Credit Quantification

3.1. Baseline Assumptions (500,000 hens)

• Manure generated: 7–9 US tons/day

• Annual manure handled: 2,500–3,200 US tons/year

• Storage method: anaerobic deep pit

3.2 Estimated Emissions from Deep-Pit Storage (Typical Ranges)

• Methane (CH₄):~8–12 kg CH₄ / ton manure (as-handled)→ 20–38 metric tons CH₄/year→ 560–1,060 tCO₂e/year

• Ammonia (NH₃):20–40% of nitrogen volatilized→ Major contributor to odor, PM2.5 formation, and compliance risk

3.3 Emissions Reduction with Enclosed Fermentation (COMPO)

4. Based on controlled aerobic/thermophilic operation:

• Methane reduction: 70–90%→ 400–900 tCO₂e/year avoided

• Ammonia reduction: 60–80%→ Significant odor reduction and air quality improvement

• Secondary benefits:

     o Reduced runoff risk

     o Improved nutrient use efficiency

     o Enhanced compliance posture

5. Carbon / Environmental Credit Implications

Depending on program structure and verification pathway:

• Avoided emissions potential:~400–900 tCO₂e/year

• Indicative credit value:$15–30 / tCO₂e→ $6,000–27,000/year (conservative, program-dependent)

These values are indicative estimates suitable for pilot evaluation and screening and can be refined with site-specific data and third-party verification.

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Summary (Regulatory Framing)

The transition from deep-pit manure storage to enclosed fermentation represents a material improvement in environmental performance, shifting manure handling from passive storage to active treatment. This change measurably reduces greenhouse gas emissions, ammonia release, and odor while enabling beneficial reuse of nutrients, supporting both regulatory compliance and sustainability objectives.

The organic fertilizers and growth biostimulants market in Japan is experiencing significant growth, driven by a shift towards sustainable agricultural practices and a rising demand for organic food products. The biostimulants market is projected to grow at a compound annual growth rate (CAGR) of approximately 6.41% between 2025 and 2030, reaching an estimated value of $182.829 million by 2032.

Knowledge Sourcing

Similarly, the biofertilizers market is expected to expand from $94.72 million in 2023 to $232.65 million by 2032, reflecting a CAGR of 10.50% from 2024 to 2032.

Credence Research

Furthermore, the agricultural biologicals market is projected to grow at a CAGR of 13.5% from 2025 to 2033, increasing from $402.5 million in 2024 to $1,393.9 million by 2033.

Imarc Group

These trends underscore a robust and expanding market for organic fertilizers and biostimulants in Japan, driven by technological advancements and a growing commitment to sustainable agriculture.

SUCCESSFUL PROJECTS:

Poland is quickly becoming one of the most dynamic markets in Europe for organic fertilizers and biostimulant solutions. While only about 4–5% of Poland's agricultural land is certified organic, the real growth is coming from conventional farmers looking to improve soil structure, nutrient efficiency, and crop resilience. Rising fertilizer costs, soil degradation, and stronger EU environmental requirements are accelerating this shift.

Why Demand Is Increasing

Several forces are driving adoption:

• EU Common Agricultural Policy (CAP) eco-schemes reward practices that build soil health.

• Growers are seeking to reduce dependence on synthetic fertilizers without compromising yields.

• Increasing climate and soil stress is pushing interest in biological and natural solutions that support root strength, microbial activity, and nutrient uptake.

As a result, biostimulants and organic fertilizer products are no longer viewed as niche inputs—they are becoming strategic agronomic tools.

How Products Enter the Polish Market

There are two primary regulatory paths:

1. EU Fertilizing Products Regulation (2019/1009)

Products that meet the criteria can obtain CE marking, allowing seamless sales across the entire EU, including Poland.

2. Polish National Registration

For products not yet eligible for CE-marking, companies can register directly with the Ministry of Agriculture for use on the Polish market.

Choosing the correct route early helps prevent delays and reduces cost.

Companies Producing Organic Fertilizers and Biostimulants

     1. Intermag   https://intermag.pl

Italy is widely recognized for its advanced organic agriculture sector, strong regulatory framework, and innovation in biostimulant technologies. Here's why:

🌿 1. Pioneering Biostimulant Industry

• Italy is home to Valagro, Italpollina, and Hello Nature (formerly Italpollina Group) — all global leaders in biostimulant research and manufacturing.

• Italian companies were among the first to develop and commercialize plant-based amino acids, humic acids, seaweed extracts, and microbial biostimulants.

📈 2. Massive Organic Agriculture Sector

• Italy has one of the largest areas of organic farmland in Europe.

• According to FiBL and IFOAM, Italy consistently ranks in the top 5 countries worldwide for certified organic land and production.

🧪 3. Strong Research and Regulation

• Italian universities and institutes lead in agronomic research, especially on soil biology and organic matter regeneration.

• Italy was one of the early adopters of EU regulations around organic inputs and is active in shaping biostimulant legislation at the European level.

Companies Producing Organic Fertilizers and Biostimulants

1. Green Has Group   https://www.greenhasgroup.com

2. Italpollina   https://italpollina.com

3. Biolchim   https://www.biolchim.com

4. Agricola 2000   https://www.agricola2000.it

Over the next decade, France's market for organic fertilizers and growth biostimulants is anticipated to experience significant growth, mirroring broader European trends. The European organic fertilizers market is projected to expand at a compound annual growth rate (CAGR) of approximately 7.95%, increasing from USD 4.52 billion in 2025 to USD 6.62 billion by 2030.

Mordor Intelligence

Similarly, the European biostimulants market is expected to grow at a CAGR of around 8.00%, reaching an estimated value of USD 2.34 billion by 2030.

Knowledge Sourcing

While specific data for France is limited, these regional forecasts suggest a positive trajectory for the French market, driven by a growing emphasis on sustainable agricultural practices and environmental awareness.

Companies Producing Organic Fertilizers and Biostimulants

1. Agrauxine by Lesaffre   https://www.agrauxine.com 

2. Goëmar (Arysta/UPL Biostimulants)   https://www.upl-ltd.com 

3. Agronutrition (De Sangosse Group)   https://www.agronutrition.com 

4. Timac Agro   https://www.timacagro.com

Over the next decade, China's market for organic fertilizers and growth biostimulants is projected to experience substantial growth. The organic fertilizers market is anticipated to grow at a compound annual growth rate (CAGR) of 9.54%, increasing from USD 1.42 billion in 2023 to USD 2.94 billion by 2031.

Markets And Data

Similarly, the biostimulants market in China is expected to expand at a CAGR of 15.5%, reaching approximately USD 829.9 million by 2030.

PR Newswire

This growth is driven by a shift towards organic farming practices and a heightened focus on sustainable agriculture.

Over the next decade, Russia's market for organic fertilizers and growth biostimulants is expected to experience significant growth, driven by technological advancements and a shift towards sustainable agricultural practices. The Russian fertilizers market was valued at approximately USD 11.5 million in 2023 and is projected to reach USD 16.22 million by 2032, exhibiting a compound annual growth rate (CAGR) of 15.30% during this period.

Data Insights Market

This growth is primarily attributed to the increasing demand for hybrid seeds, which offer benefits such as improved yield, disease resistance, and resilience to climatic conditions. Government initiatives promoting sustainable agricultural practices and addressing food security concerns have further fueled market expansion. Additionally, in 2021, Russia produced nearly 101 million metric tons of organic fertilizers, indicating a strong domestic production capacity.

Statista

While specific data on biostimulants is limited, the global biostimulants market is projected to reach USD 7.6 billion by 2029, growing at a CAGR of 12.0% from 2024 to 2029.

Markets and Markets

Given these trends, Russia's market for organic fertilizers and biostimulants is poised for substantial growth in the coming years.

Over the next decade, Canada's market for organic fertilizers and growth biostimulants is projected to experience significant growth. The North American organic fertilizers market is expected to expand from approximately USD 2.89 billion in 2023 to USD 5.33 billion by 2032, reflecting a compound annual growth rate (CAGR) of 7.0% during this period.

Credence Research

Similarly, the North American biostimulants market is forecasted to grow from USD 940 million in 2024 to USD 2.76 billion by 2031, at a CAGR of 12.75%.

Verified Market Research

This growth is driven by increasing consumer awareness of organic products, government support for sustainable agriculture, and a rising demand for organic food.

TechSci Research

While specific data for Canada is limited, these regional trends suggest a positive trajectory for the Canadian market in the coming years.

Companies Producing Organic Fertilizers and Biostimulants

1. Acadian Plant Health   https://www.acadianplanthealth.com

The organic fertilizers and growth biostimulants market in Spain is expected to experience steady growth over the next 10 years. The global organic fertilizers market is projected to grow from USD 11.7 billion in 2021 to USD 25.5 billion by 2031, at a CAGR of 8.0%, with Spain following a similar upward trend due to increasing consumer demand for organic products and sustainable agricultural practices (marketresearchfuture.com). The Spanish market for biostimulants is also anticipated to expand significantly, driven by rising awareness of environmental sustainability and the shift toward eco-friendly farming practices. According to industry reports, the European biostimulants market is forecasted to grow at a CAGR of 13.1% from 2021 to 2026 (forte-consulting.com). Additionally, Spain's agricultural sector, which has a strong organic farming presence, will continue to drive the demand for organic fertilizers and biostimulants. The Spanish government's support for organic farming initiatives, combined with technological advancements in the sector, will further contribute to market expansion. 

Companies producing organic fertilizers and biostimulants

1. Futureco Bioscience   https://www.futurecobioscience.com

2. Seipasa   https://www.seipasa.com

3. Probelte   https://www.probelte.com

4. Bioiberica   https://www.bioiberica.com

5. Fertinagro Biotech   https://www.fertinagrobiotech.com

6. Daymsa   https://www.daymsa.com

SUCCESSFUL PROJECTS

At A&V Consulting LLC, we proudly partner with ININSA, a Spanish industry leader equipped with some of the most advanced technology for the production of greenhouses and their accessories. Together with ININSA's expert engineering and design team, we provide U.S. farmers and agri-businesses with customized, cutting-edge solutions that meet their specific structural and operational needs. ININSA is already working successfully with American growers, delivering eco-conscious, high-performance systems that boost productivity and resilience. Through this collaboration, we offer not only world-class greenhouse technology, but also personalized design, seamless project coordination, and ongoing technical support. Our partnership ensures U.S. customers gain access to proven European innovation while benefiting from local insight, efficient service, and long-term value.