Louis Dreyfus Company Kenya Limited (Louis Dreyfus Company – LDC) — LDC Mombasa T160 Pre-Feasibility
Louis Dreyfus Company Kenya Limited (Louis Dreyfus Company – LDC) — LDC Mombasa T160 Pre-Feasibility
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Project AI Research Agent
Project Story
This confidential pre-feasibility report examines integrating Climatenza T160 parabolic trough collectors into the existing hot-water network at LDC Mombasa (Shimanzi, KPA Gate 12). The recommended configuration uses a pressurised buffer tank, a plate heat exchanger (HX-201) and solar skid to preheat the boiler return header (approx. 110°C → toward 120°C supply), with the existing Thermax SMW2000 boiler providing trim heat to maintain supply setpoints. The analysis uses a 3,550 m² candidate site (effective aperture ~1,420 m²), 258 T160 collectors and assumes an annual DNI placeholder of 1,750 kWh/m²·y.
Pre-feasibility outputs indicate a design-point useful power of ~805 kWth and an annual useful solar heat of ~4,787 GJ/year (approx. 78.9% solar fraction vs 2025 baseline useful heat), displacing ~135 t HFO/year and avoiding ~382 tCO2/year. Key engineering deliverables identified for FEED include bankable DNI data, hourly load profiles, detailed tie-in and structural assessments, water chemistry, a detailed HX and stagnation/transient analysis, and a CAPEX quotation for 258 collectors, skid, HX, buffer tank, piping, instrumentation and installation.
The report emphasises measured M&V boundaries (process-side heat metering), conservative boiler-trim integration, coastal soiling/corrosion risk mitigation, and staged next steps (bankable meteorology, hourly heat demand, tie-in survey, FEED) to convert the opportunity into a bankable lighthouse project.
Verified Impact Data Card
Louis Dreyfus Company Kenya Limited (Louis Dreyfus Company – LDC) — LDC Mombasa T160 Pre-Feasibility
This project's impact data is structured for Scope 3 Category 15 (Investments) reporting. Verified emissions reductions can be attributed to investor portfolios under the GHG Protocol Corporate Value Chain standard.
CSRD alignment under ESRS E1 (Climate Change) is in preparation and will be available once the EU taxonomy technical screening criteria are finalised for this project category.
Decentralised physical infrastructure network integration
will provide real-time MRV telemetry for this project.
Ask about this project's carbon methodology, Scope 3 reporting, DePIN integration, or emissions data.
What is this card?
The Verified Impact Data Card summarises the key environmental and assurance metrics for this project. Data is pulled live from VCS assessments and on-chain commitments.
How to read the data
- Emissions Reduction — Estimated annual CO2e avoided or removed, derived from the project's VCS methodology and baseline scenario.
- Overall Score — Composite VCS readiness score (0–100%) covering additionality, permanence, leakage, and MRV quality.
- REC % — Alignment with Renewable Energy Certificate issuance criteria.
- EEC % — Alignment with Energy Efficiency Certificate criteria.
- Phase — Current stage in the project development lifecycle.
- DePIN Integrity — Data integrity score from decentralised sensor network (uptime, calibration, completeness).
Glossary
- VCS — Verified Carbon Standard (Verra), a leading carbon credit certification programme.
- tCO2e/yr — Tonnes of carbon dioxide equivalent per year.
- VVB — Validation/Verification Body, the independent auditor that reviews project claims.
- Evidence Tier — Classification of supporting evidence quality (e.g. Tier 1 = measured data, Tier 3 = default factors).
- Commitment Hash — Cryptographic hash of the assessment data committed to blockchain for tamper-proof audit trail.
- DePIN — Decentralised Physical Infrastructure Network, providing real-time sensor-based MRV data.
- Scope 3 Cat. 15 — GHG Protocol category covering financed emissions from investments.
- CSRD / ESRS E1 — EU Corporate Sustainability Reporting Directive, climate change disclosure standard.
- MRV — Measurement, Reporting, and Verification.
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Credits Simulator
Project Credits Simulator v1.5.0
REC Assumptions
Financial Projections
Investor Inputs (REC)
Per-Year Valuation — Today vs Forecast
Voluntary: REC (Med-Low)
Voluntary: EEC / Removal (Med-High)
Compliance: EU ETS
REC Projects & SDG Synergies
- SDG 7: More renewables displacing fossil power.
- SDG 13: Verified reductions, market signal for clean power.
- SDG 11: Cleaner air & resilient grids.
EEC Assumptions
Financial Projections
Investor Inputs (EEC)
Per-Year Valuation — Today vs Forecast
Voluntary: EEC / Removal (Med-High)
Compliance: EU ETS
EEC Projects & SDG Synergies
- SDG 9: Industrial modernisation, AI/dMRV.
- SDG 12: Resource efficiency & demand-side abatement.
- SDG 7: "First fuel" energy efficiency.
CCUS Assumptions VM0049 · Industrial CCS
Pricing: bilateral offtake $30–80/t · 45Q floor $60–85/t (US) · no liquid spot market
Financial Projections
Investor Inputs (CCUS)
Per-Year Valuation — Today vs Forecast
CCUS / Industrial CCS (VM0049)
Compliance: EU ETS
CCUS Projects & SDG Synergies
- SDG 9: Industrial innovation — point-source capture at cement, steel, refining facilities.
- SDG 13: Hard-to-abate sector decarbonisation; permanent geological storage.
- SDG 11: Cleaner industrial zones, reduced local air pollutants alongside CO₂.
VM0049 (Verra, June 2024): modular CCS methodology covering geological storage, CO₂ utilisation, and transport pathways. 45Q tax credit provides a $60–85/t USD policy floor in the US.
Thermal Energy Storage Assumptions AMS-II.C · AMS-III.AE · ACM0014 (adj.)
Pricing: $6–9/t standard · $10–14/t IoT-verified · $14–18+/t DePIN data-anchored · TenzaHeat/Climatenza integrated stack
Financial Projections
Investor Inputs (TES)
Per-Year Valuation — Today vs Forecast
Thermal Energy Storage Credits
Voluntary: REC (Med-Low)
Thermal Energy Storage & SDG Synergies
- SDG 7: Affordable & Clean Energy — storing surplus renewable heat makes clean thermal energy dispatchable.
- SDG 9: Industry & Innovation — core to industrial-heat decarbonisation (cement, chemical, food processing).
- SDG 12: Responsible Consumption — reduces fossil-fuel boiler runtime through load-shifting.
AMS-II.C · AMS-III.AE · ACM0014 (adj.): metered charge/discharge cycles, round-trip efficiency, displaced fossil-fuel baseline. TES is a natural fit for TenzaHeat + Climatenza solar-thermal stacks — DePIN-native temperature, flow, and dispatch telemetry anchor the verifiability premium.
- 💧 Water Benefit Certificates (WBCs) — adjacent certificate class: Gold Standard water restoration / access / quality projects.
- ♨ Methane / Waste-to-Energy — 28–84× CO₂e multiplier; ACM0001 · AMS-III.H · AMS-III.D; DePIN gas-flow verification.
Battery / Grid Storage Assumptions Verra draft storage · CDM grid EF (emerging)
Pricing: $5–8/t standard · $8–11/t IoT-verified · $11–15+/t DePIN data-anchored · SOC + dispatch-timing telemetry required
Financial Projections
Investor Inputs (Battery)
Per-Year Valuation — Today vs Forecast
Battery / Grid Storage Credits
Voluntary: REC (Med-Low)
Battery / Grid Storage & SDG Synergies
- SDG 7: Affordable & Clean Energy — unlocks higher renewable grid penetration by time-shifting surplus generation.
- SDG 9: Industry & Innovation — emerging storage methodology; DePIN dispatch-timing telemetry solves peaker-avoidance attribution.
- SDG 12: Responsible Consumption — avoids marginal fossil-peaker dispatch; reduces curtailment of renewables.
- SDG 13: Climate Action — direct hourly attribution of avoided grid emissions.
Verra draft storage methodologies and CDM grid emission factor frameworks: baseline = hourly marginal emission factor; monitoring = per-cycle MWh in / out + SOC + round-trip efficiency. Emerging methodology scarcity + MRV-intensive verification justify the tier premium for DePIN-monitored projects.
- 💧 Water Benefit Certificates (WBCs) — adjacent certificate class.
- ♨ Methane / Waste-to-Energy — 28–84× CO₂e multiplier; DePIN gas-flow verification.
India Carbon Credit Trading Scheme CCTS · phased-live · first session mid-2026
India's Carbon Credit Trading Scheme (CCTS) is the country's new domestic compliance carbon market, operated under a three-body structure: MoEFCC notifies sector intensity targets (via the Environment Protection Act 1986), BEE administers the scheme + issues Carbon Credit Certificates (CCCs) + operates the registry, and CERC regulates trading on accredited power exchanges. The scheme covers 9 sectors, ~740 obligated entities, and ~700 Mt CO₂e — roughly 16% of India's emissions.
Covered sectors
Aluminium · Cement · Chlor-alkali · Paper & Pulp · Petrochemical · Petroleum Refinery · Textile (Iron & Steel and Fertiliser — notification status as of April 2026 unconfirmed). Power generation is NOT in Phase 1 — a notable gap.
Trading venues & settlement
Order-book trading on IEX / HPX / PXIL (all CERC-accredited). MCX is NOT accredited. Settlement in INR. Indicative price band ~₹800–1,200/t (no gazetted floor/ceiling yet). First trading session expected mid-2026.
Sources: ICAP ETS Map · BEE notifications (Oct 2025 / Jan 2026) · CERC accredited-venues list · IETA India CCTS Business Brief (July 2025).
CCC vs CCC-V vs EScert — what each is, who issues, who trades
Indian project developers have three routes. Which one fits depends on whether the host entity is CCTS-obligated, whether the buyer needs international claim credibility, and how much legacy-PAT exposure sits on the balance sheet.
CCC — Compliance INDIC
- Issued by: BEE against sector intensity target
- Traded on: IEX · HPX · PXIL (INR)
- Eligible: CCTS-obligated entity outperforming target
- Foreign claim value: ❌ Not without Article 6 corresponding adjustment
CCC-V — Voluntary LIVE
- Issued by: BEE voluntary mechanism (launched March 2025)
- Methodologies: 8 at v1 release
- Eligible: Non-obligated Indian project developers
- Alternative to: Verra / Gold Standard international voluntary
EScert — Legacy LEGACY
- Scheme: PAT (2012–2024), winding down
- Throughput: 1.5M of 3.8M ESCerts Cycle I traded (poor)
- Migration: Surplus convertible to CCC at a to-be-gazetted ratio
- Owner action: Track surplus for the conversion opportunity
A project cannot issue BOTH a VCU (international voluntary) AND a CCC (Indian compliance) from the same tCO₂e reduction — buyer-side claims would clash. When a host is CCTS-obligated, the tCO₂e must be attributed to either the compliance ledger or the voluntary ledger. TenzaOne's Scope 3 Export flags this automatically via its doubleCountingRisk field.
Quick Revenue Estimator today's-price only · no IRR/NPV yet
Today's-price projection only. Full IRR/NPV forecasting waits on post-launch price discovery. For richer per-project modelling today, use the REC / EEC / CCUS / TES / Battery tabs.
Estimated revenue
CCC fallback price is indicative pending first trading session (mid-2026). Admin can override via wp option update tenza_feed_price_ccc X. When the admin override is set, terminal + MID + this simulator all pick up the new value on next page load.
India CCTS & SDG Synergies
- SDG 13: Climate Action — domestic compliance cap mobilises ~700 Mt CO₂e of industrial abatement against sector intensity targets.
- SDG 9: Industry, Innovation & Infrastructure — 9 hard-to-abate sectors (cement / aluminium / chlor-alkali / petchem / steel / textile / refinery) directly incentivised to decarbonise.
- SDG 11: Sustainable Cities — supports cleaner industrial clusters and PM/NOx co-reductions alongside CO₂.
- SDG 7: (CCC-V track) — voluntary mechanism adds domestic route for clean-energy projects below compliance threshold.
TenzaOne positioning: dMRV is ACV-Agency-compatible and registry-complementary, NEVER a registry replacement. DePIN telemetry supplies underlying M&V evidence; ACV Agencies verify and sign; BEE issues. The blockchain anchor adds auditable provenance the ACV process can optionally cite. CCTS explicitly encourages dMRV as best practice even though it does not mandate it.
- Project to Credits — India CCTS tab → (full flow + CCTS-vs-VCM developer Q&A)
- Carbon Markets widget — India CCTS deep dive →
- DePIN stack → (how TenzaOne dMRV integrates)
Feeds & Endpoints
Primary endpoint: /wp-json/tenza/v1/prices (Auto tries relative; falls back to https://tenza.one/wp-json/tenza/v1/prices).
Project data: /wp-json/wp/v2/tenza_project (loads meta: emissions, funding, scores, stage, tech type).
Venues: ICE (EUA), CME (GEO / N-GEO), EEX (GO); I-REC registry (regional indications); EEC modeled.
FX: ECB euro reference (cached daily).
Methodology
Forecast outlook: Conservative/Base/Optimistic scale the 2035 multiplier path and apply a sale-realisation haircut; small discount-rate nudge reflects risk.
REC pricing: V-REC/GO/I-REC converted to selected units (MWh or tCO₂e-eq via EF) and currency; tier factor applies to REC/EEC classes.
Financials: All internal calculations in the selected currency. Annual net flow = (credit revenue × (1−haircut) + optional savings) − O&M. KPIs: IRR (Newton-Raphson), NPV and discounted payback at your rate.
Currency handling: Capex, O&M and savings are all in the selected currency. Credit prices are converted from their native currency via ECB rates.
Standards & Registries
Primary standards: Verra (VCS) & Gold Standard. Tool is Verra-first but surfaces Gold Standard context where relevant.
Market intel: See AlliedOffsets (market/registry analytics) and Gold Standard Dashboard for reference data and methodologies.
Demo Data
When LIVE is unavailable or Demo is selected, seeded baselines are used for tickers and trends so charts never render blank. Badges above clearly show DEMO.
Project selector fetches live data from the WordPress REST API. If the API is unreachable, the selector is hidden and manual inputs remain fully functional.
VCS Readiness Assessment
Summary
The pre-feasibility package provides a strong, engineering-led technical basis for a T160 solar-thermal retrofit at LDC Mombasa with explicit baseline fuel audit, collector sizing, yield/sensitivity analysis and a clear M&V boundary. However, the documents lack multiple VCS-critical elements (methodology/version mapping, formal additionality, safeguards/stakeholder evidence and several quantification/monitoring procedural specifics), preventing immediate VCS validation-ready status.
Scores
Checklist
Section 1: Project Details 53%
| Item | Status | PDD | Notes |
|---|---|---|---|
| Project Start Date | ✗ | 1.11 | Evidence is missing. |
| Crediting Period Duration | ✗ | 1.12 | Evidence is missing. |
| Crediting Period Type | ✗ | 1.12 | Evidence is missing. |
| Other Certifications | ✗ | 1.16 | Evidence is missing. |
| Participation in Other GHG Programs | ✗ | 1.17 | Evidence is missing. |
| Host Country | ● | 1.5 | Evidence is weak or non-specific. |
| GPS Coordinates | ✗ | 1.5 | Evidence is missing. |
| Project Proponent Contact | ✗ | 1.8 | Evidence is missing. |
Section 2: Safeguards & Stakeholder Engagement 20%
| Item | Status | PDD | Notes |
|---|---|---|---|
| Stakeholder Feedback Summary | ✗ | 2.1 | Evidence is missing. |
| Grievance Redress Mechanism | ✗ | 2.2 | Evidence is missing. |
| Respect for Human Rights & Equity | ✗ | 2.4 | Evidence is missing. |
| Worker and Labour Rights | ✗ | 2.4 | Evidence is missing. |
| Free, Prior, Informed Consent (FPIC) | ✗ | 2.4 | Evidence is missing. |
| Community Health and Safety | ✗ | 2.4 | Evidence is missing. |
| Cultural Heritage Protection | ✗ | 2.4 | Evidence is missing. |
| Gender Equality Considerations | ✗ | 2.4 | Evidence is missing. |
| Indigenous Peoples Rights | ✗ | 2.4 | Evidence is missing. |
| Biodiversity Impact | ✗ | 2.4 | Evidence is missing. |
| Water Resource Impact | ✗ | 2.4 | Evidence is missing. |
| Consultation Dates / Timeline | ✗ | 2.1 | Evidence is missing. |
| Participant Demographics | ✗ | 2.1 | Evidence is missing. |
| Written Grievance Records | ✗ | 2.2 | Evidence is missing. |
| Biodiversity Baseline Assessment | ✗ | 2.4 | Evidence is missing. |
| Stakeholder Feedback Integration Evidence | ✗ | 2.1 | Evidence is missing. |
Section 3: Methodology Application 43%
| Item | Status | PDD | Notes |
|---|---|---|---|
| Methodology Version | ✗ | 3.1 | Evidence is missing. |
| Methodology Applicability Check | ✗ | 3.2 | Evidence is missing. |
| Regulatory Surplus | ✗ | 3.5.1 | Evidence is missing. |
| Additionality Justification Type | ✗ | 3.5.2 | Evidence is missing. |
| Common Practice Analysis | ✗ | 3.5.2 | Evidence is missing. |
| IRR without Carbon Revenue | ✗ | 3.5.2 | Evidence is missing. |
| IRR with Carbon Revenue | ✗ | 3.5.2 | Evidence is missing. |
| LCOH/LCOE | ✗ | 3.5.2 | Evidence is missing. |
| Methodology Conformity Mapping | ✗ | 3.2 | Evidence is missing. |
| Financial Hurdle Rate | ✗ | 3.5.2 | Evidence is missing. |
| Market Conditions Analysis | ✗ | 3.5.2 | Evidence is missing. |
| Regulatory Baseline Check | ✗ | 3.5.1 | Evidence is missing. |
Section 4: GHG Quantification 5%
| Item | Status | PDD | Notes |
|---|---|---|---|
| Baseline Emissions (tCO2e/yr) | ● | 4.2 | Evidence is weak or non-specific. |
| Baseline Emissions Approach | ✗ | 4.2 | Evidence is missing. |
| Project Emissions (tCO2e/yr) | ✗ | 4.3 | Evidence is missing. |
| Project Emissions Approach | ✗ | 4.3 | Evidence is missing. |
| Leakage Emissions (tCO2e/yr) | ✗ | 4.4 | Evidence is missing. |
| Leakage Assessment | ✗ | 4.4 | Evidence is missing. |
| Net GHG Emission Reductions | ● | 4.5 | Evidence is weak or non-specific. |
| Emission Factors & Data Sources | ✗ | 4.2 | Evidence is missing. |
| Calculation Spreadsheet/Tool | ✗ | 4.1 | Evidence is missing. |
| Uncertainty Assessment | ✗ | 4.6 | Evidence is missing. |
| Ex-Ante Data Parameters | ✗ | Table in 4.2/4.3 | Evidence is missing. |
| Ex-Post Monitored Parameters | ✗ | Table in 5.1 | Evidence is missing. |
| GWP Values Source | ✗ | 4.1 | Evidence is missing. |
| Baseline Fuel Consumption | ✗ | 4.2 | Evidence is missing. |
| Project Fuel Consumption | ✗ | 4.3 | Evidence is missing. |
| Energy Production / Savings | ✗ | 4.2 | Evidence is missing. |
| Operating Hours / Capacity Factor | ✗ | 4.2 | Evidence is missing. |
| Grid Emission Factor (Regional) | ✗ | 4.2 | Evidence is missing. |
| Multi-GHG Breakdown (CO2/CH4/N2O) | ✗ | 4.1 | Evidence is missing. |
| Uncertainty Quantification Method | ✗ | 4.6 | Evidence is missing. |
Section 5: Monitoring Plan 52%
| Item | Status | PDD | Notes |
|---|---|---|---|
| Equipment Accuracy | ✗ | 5.1 | Evidence is missing. |
| Equipment Make / Model | ✗ | 5.1 | Evidence is missing. |
| Equipment Serial Numbers | ✗ | 5.1 | Evidence is missing. |
| Equipment Installation Date | ✗ | 5.1 | Evidence is missing. |
| Calibration Certificate Location | ✗ | 5.2 | Evidence is missing. |
| Data Logger / Historian System | ✗ | 5.3 | Evidence is missing. |
| Data Archival Retention Period | ✗ | 5.3 | Evidence is missing. |
| Named Monitoring Responsible Party | ✗ | 5.4 | Evidence is missing. |
| Non-Compliant Data Procedure | ✗ | 5.2 | Evidence is missing. |
Methodology
- VCS Methodology
- AMS-II.C
- Version
- Not found in document
- Project Type
- Solar thermal industrial process heat integration (T160 parabolic troughs) — return-header preheat + pressurised buffer tank; boiler trim configuration
- Capacity
- Peak design thermal output: 805 kWth (design-point, DNI = 900 W/m²); Installed aperture area ~1,419 m² (258 T160 collectors, 5.5 m² each); Annual useful solar heat ~4,787 GJ/year (~1,330 MWhth/year)
- Baseline Scenario
- Baseline: HFO-fired hot-water system using an existing Thermax SMW2000 boiler supplying the site hot-water network (network supply ≈120°C, return ≈110°C). Baseline year 2025 fuel consumption = 179,054 L HFO (170.9 t), fuel energy input = 6,892 GJ/y, useful heat delivered (boiler eff. 88%) = 6,065 GJ/y. Baseline CO2 (2025) = 484.5 tCO2/y (derived from HFO monthly fuel log and Intertek ROA).
Ghg
Monitoring
Dedicated M&V-grade heat metering on the process side of the heat exchanger (Q = ṁ·Cp·ΔT) combined with continuous SCADA/PLC data-logging and a historian/cloud dashboard to record solar-loop and process-side sensors (irradiance, temperatures, pressures, flows, tank levels) for performance, availability and fuel-displacement reconciliation.
Action Plan
- Collect and document information for Project Start Date
- Collect and document information for Crediting Period Duration
- Collect and document information for Crediting Period Type
- Collect and document information for Other Certifications
- Calculate emissions using methodology-specified equations and credible emission factors
