Aurora™ 1.0gpf

LCA results & interpretation Aurora™ One-Piece Toilet

Aurora™ 1.28gpf Aurora™ 1.0gpf EPD additional content

Scope and summary

Cradle to gate
Cradle to gate with options
Cradle to grave

Functional unit

One single flush toilet in an average residential environment without an electronic bidet seat. The expected service life (ESL) of a building is 75 years, and all use stage activity and impacts are accounted for in that full ESL period. The reference service life (RSL) of the toilet is 20 years, which is an industry-accepted average lifespan based on the economic lifespan of the product. The Aurora™ 1G toilet is a single flush toilet with a flush capacity of 1.0 gallons per flush.

Maintenance

Regular cleaning is assumed to use 1.69 fl oz (50mL) of a 1% sodium lauryl sulfate (SLS) solution twice per month over a 75 years. The use of 50mL over 24days/year for 75 years gives a total of 90L of solution. Therefore, 0.9kg of SLS plus 89.1kg of water were included in the model.

Repair and replacement

The trip lever handle, flapper seal, and fill valve seal are assumed to be replaced once during each 20-year RSL period as part of regular repairs, with replacement waste sent to landfill. At the end of its RSL, the residential toilet is assumed to be replaced. Therefore, an additional 2.75 products are included as replacements, with all life cycle modules considered, over the building's ESL of 75 years.

Manufacturing data

Reporting period: January 2025 – December 2025

Location: TOTO Vietnam manufacturing facility (TVN) in Hanoi, Vietnam

What’s causing the greatest impacts

All life cycle stages

The use stage dominates the results for all impact categories. The replacements module (B4) is highly dominant in all categories because of the necessity to consider an additional 2.75 products as replacements and operational water use. The production stage itself is slightly significant but does not dominate in any impact category. Additionally, the processes associated with dismantling the product and final waste treatment during the end-of-life stage do not have a significant impact.

Production stage [A1-A3]

Product manufacturing (A3) follows the impacts from raw material acquisition (A1), with insignificant impacts from raw material transportation (A2). Most of the impacts within A3 come from energy usage in the ceramic manufacturing operations.

Distribution and installation [A4-A5]

Distribution (A4) and installation (A5) are minor contributors to the total results. Transporting the finished product contributes to smog formation, with the majority of impacts arising from sea transport from Vietnam to the United States and subsequent road transport to end users.

Use [B1-B7]

Environmental impacts are driven by product replacement (B4) and operational water use (B7). The impacts of those 2.75 replacements account for 30%-65% of the total impacts. Operational water use is the leading contributor to three impact categories across the product life cycle: ozone depletion, carcinogenics, and global warming. It is also the second-largest contributor in the remaining impact categories. More than 98% of each of those comes from municipal sewage treatment of wastewater generated.

End-of-life stage [C1-C4]

The transportation to landfill and the disposal process dominate impacts in the end-of-life stage. Impacts associated with the end-of-life stage are minimal, accounting for less than 1% of total life cycle impacts.

Operational water use

The incoming municipal tap water does not require additional filtration. The amount of water used by the toilet depends on its flush rate. The 1.0gpf toilet consumes 1.0 gallons per flush and is assumed to be used 13 times per day over 75 years. This equates to 4,745 flushes per year and 355,875 flushes over the 75-year ESL, resulting in 355,875 gallons of water over its lifetime. An electricity factor of 0.00364 kWh per gallon (0.000961 kWh per liter) of water is used to represent energy for upstream municipal water collection, treatment, supply, and downstream management.

How we're making it greener

TOTO PeoplePlanetWater™ programs improving environmental performance

Dual-Max®, E-Max®, Tornado Flush™, 1G®, and EcoPower® reduce water consumption in the use phase
INTEGRAVITY SYSTEM™ optimizes cleaning power with less water
Energy efficiency programs optimize the firing process
Modular packing methods increase the fill rate of a trailer, cutting down on the number of trips needed
100% of post-industrial ceramic waste is recycled

See how we make it greener

LCA results

Life cycle stage	Production	Construction	USE	End of Life
Information modules: Included (X) \| Excluded (MND)* *Module D is not declared.	(X) A1 Raw materials	(X) A4 Transportation/ Delivery	(X) B1 Use	(X) C1 Deconstruction/ Demolition
	(X) A2 Transportation	(X) A5 Construction/ Installation	(X) B2 Maintenance	(X) C2 Transportation
	(X) A3 Manufacturing		(X) B3 Repair	(X) C3 Waste processing
			(X) B4 Replacement	(X) C4 Disposal
			(X) B5 Refurbishment
			(X) B6 Operational energy use
			(X) B7 Operational water use

SM Single Score

Learn about SM Single Score results

Impacts per functional unit	1.55E+01 mPts	1.94E+00 mPts	1.76E+02 mPts	8.21E-02 mPts
Materials or processes contributing >20% to total impacts of each life cycle stage	Ceramic parts production and energy used during manufacturing.	Transportation of the product to installation site or consumer and disposal of packaging.	Volume of water used during operation and the number of product replacements needed over the building's service life.	Transport to waste processing and disposal of material flows transported to a landfill.

Aurora™ 1.0gpf - TRACI v2.2 results per functional unit

Life cycle stage	Production	Construction	USE	End of Life

Ecological damage

Impact category	Unit
Global warming	kg CO₂ eqKilograms of Carbon Dioxide equivalent Global warming is an average increase in the temperature of the atmosphere near the Earth’s surface and in the troposphere, which can contribute to change in global climate patterns and is caused by the increase of the sources of greenhouse gases and decrease of the sinks due to deforestation and land use. GW leads to problems in human health, agriculture, forest, water source, and damage to species and biodiversity as well as coastal areas.	1.89E+02	1.37E+01	2.06E+03	1.15E+00
Ozone depletion	kg CFC-11 eq Kilograms of Trichlorofluoromethane equivalent Ozone depletion is the reduction of ozone in the stratosphere caused by the release of ozone depleting chemicals. Ozone depletion can increases ultraviolet B radiation to the earth which can adversely affect human health (skin cancer and cataracts and immune-system suppression) and other systems (marine life, agricultural crops, and other vegetation) and causes damage to human-built materials.	3.51E-06	1.11E-07	4.30E-05	1.53E-09
Acidification	kg SO₂ eq Kilograms of Sulfur Dioxide equivalent Acidification processes increase the acidity of water and soil systems and causes damage to lakes, streams, rivers, and various plants and animals, as well as building materials, paints, and other human-built structures.	9.31E-01	4.23E-01	1.02E+01	5.83E-03
Marine eutrophication	kg N eqKilograms of Nitrogen equivalent Marine eutrophication is the enrichment of an aquatic ecosystem with nutrients (nitrates and phosphates) that accelerate biological productivity (growth of algae and weeds) and an undesirable accumulation of algal biomass which impacts industry, agriculture, drinking, fishing, and recreation and causes death of fish and shellfish, toxicity to humans, marine mammals and livestock, and reduces biodiversity.	1.67E-01	1.19E-01	1.58E+00	1.41E-03
Freshwater eutrophication	kg P eq kilograms of phosphorus equivalents Freshwater eutrophication is the enrichment of an aquatic ecosystem with nutrients (phosphates) that accelerate biological productivity (growth of algae and weeds) and an undesirable accumulation of algal biomass.	4.16E-03	4.61E-05	4.59E-02	5.92E-06

Human health damage

Impact category	Unit
Smog	kg O₃ eqKilograms of Ozone equivalent Smog formation (photochemical oxidant formation) is the formation of ozone molecules in the troposphere by complex chemical reactions which are influenced by ambient concentrations of oxides of nitrogen (NOx), volatile organic compounds (VOCs), the mix of organic compounds (OCs), temperature, sunlight, and convective flows. Ozone concentrations in the Earth’s atmosphere above the natural trace amounts lead to detrimental impacts on human health and ecosystems.	1.95E+01	1.42E+01	1.84E+02	1.67E-01
Respiratory effects	kg PM_2.5 eqKilograms of Particulate Matter equivalent which are smaller than or equal to 2.5 micrometers in diameter Particulate matter concentrations have a strong influence on chronic and acute respiratory symptoms and mortality rates.	5.89E-02	5.31E-03	6.35E-01	3.07E-04

Additional environmental information

Impact category	Unit
Carcinogenics	CTU_h Comparative Toxic Units of Human cancerous toxicity Carcinogens have the potential to form cancers in humans.	3.06E-06	1.57E-07	4.06E-05	1.21E-08
Non-carcinogenics	CTU_h Comparative Toxic Units of Human non-cancerous toxicity Non-Carcinogens have the potential to causes non-cancerous adverse impacts to human health.	3.36E-05	1.47E-06	3.01E-04	9.86E-08
Ecotoxicity	CTU_e Comparative Toxic Units of Ecotoxicity Ecotoxicity causes negative impacts to ecological receptors and, indirectly, to human receptors through the impacts to the ecosystem.	1.64E+02	2.78E+01	1.40E+03	1.88E+00

References

LCA Background Report
Life cycle assessment (LCA) of TOTO Aurora toilets, 2026; TRACI v2.2, CML, and Cumulative Energy Demand (LHV) impact assessment methodologies; SimaPro Developer 10.3; ecoinvent v3.11, US-EI 2.2, and Industry data 2.0.

ISO 14025, “Sustainability in buildings and civil engineering works -- Core rules for environmental product declarations of construction products and services”

ISO 21930:2017, "Sustainability in Building Construction — Environmental Declaration of Building Products" serves as the core PCR along with Sustainable Minds Part A.

SM Part A: LCA calculation rules and report requirements, version 2023
August, 2023. PCR review conducted by the Sustainable Minds TAB, [email protected].

SM Part B: Residential toilets, v3.0
May, 2022. PCR review conducted by Jack Geibig, Chair (Ecoform) [email protected]; Hugues Imbeault-Tétreault, ing., M.Sc.A. (Groupe AGÉCO); Rebe Feraldi, LCACP, CLAR (Pacific Northwest National Laboratory).

Download PDF SM Transparency Report [EPD]™

SM Transparency Reports (TR) are ISO 14025 Type III environmental declarations (EPD) that enable purchasers and users to compare the potential environmental performance of products on a life cycle basis. They are designed to present information transparently to make the limitations of comparability more understandable. Environmental declarations of products that conform to the same PCR and include the same life cycle stages, but are made by different manufacturers, may not sufficiently align to support direct comparisons. They therefore cannot be used as comparative assertions unless the conditions as defined in ISO 14025 Section 6.7.2. ‘Requirements for Comparability’ are satisfied. In order to support comparative assertions, this EPD meets all comparability requirements stated in ISO 14025:2006. However, differences in certain assumptions, data quality, and variability between LCA data sets may still exist. Any EPD comparison must be carried out at the building level per ISO 21930 guidelines, use the same sub-category PCR where applicable, include all relevant information modules, be limited to EPDs applying a functional unit, and be based on equivalent scenarios with respect to the context of construction works. Some LCA impact categories and inventory items are still under development and can have high levels of uncertainty. To promote uniform guidance on the data collection, calculation, and reporting of results, the ACLCA methodology (ACLCA 2019) was used.

Rating systems

The intent is to reward project teams for selecting products from manufacturers who have verified life-cycle environmental performance.

LEED BD+C: New Construction | v4.1 - LEED v4.1

Building product disclosure and optimization

Environmental product declarations

Industry-wide (generic) EPD 1 product
Product-specific Type III EPD 1.5 products

LEED BD+C: New Construction | v.5 - LEED v5

MR Credit 4: Building Materials Resources Credit (BPSP)

Product-specific Type III EPD Multi-attribute score: 1

Green Globes for New Construction and Sustainable Interiors

Materials and resources

NC 3.5.1.2 Path B: Prescriptive Path for Building Core and Shell
NC 3.5.2.2 and SI 4.1.2 Path B: Prescriptive Path for Interior Fit-outs

BREEAM New Construction 2018

Mat 02 - Environmental impacts from construction products

Environmental Product Declarations (EPD)

Industry-average EPD .5 points
Multi-product specific EPD .75 points
Product-specific EPD 1 point