Plan accurate concrete admixture dosing for every mix, pour, and truckload easily. Compare units, adjust for waste, and export results as reports instantly online.
| Scenario | Volume (m³) | Cement (kg/m³) | Basis | Rate | Batches | Estimated total (L) |
|---|---|---|---|---|---|---|
| Footing pour | 6.0 | 300 | mL/100kg | 350 | 2 | 6.30 |
| Slab pour | 12.5 | 320 | mL/100kg | 450 | 3 | 18.38 |
| Columns | 3.2 | 380 | L/m³ | 1.10 | 1 | 3.52 |
These examples are illustrative; always follow the product datasheet and project specification.
Rounding is applied after adjustments to match practical measuring resolution.
Admixtures are used to tailor slump retention, early strength, finishing behavior, and durability. Typical site goals include better placement, reduced rework, and consistent performance across trucks. Because performance depends on cement chemistry and water content, dosing should be tied to cement content and verified with trial batches.
Manufacturers publish dosage as mL per 100 kg cement, liters per cubic meter, or percent of cement mass. These formats are equivalent when the mix design is known. This calculator supports all three, plus automatic conversions between m³ and yd³ and between kg/m³ and lb/yd³ for cement content.
The most reliable dosing approach links directly to total cement in the pour. Total cement equals concrete volume multiplied by cement content. For example, a 12.5 m³ slab at 320 kg/m³ contains 4,000 kg of cement. At 450 mL/100 kg, the base requirement becomes 18.0 L before adjustments.
Many site controls track usage by liters, while procurement and safety data sheets often reference kilograms. Density converts between the two. A liquid product at 1.05 kg/L means 18.4 L corresponds to about 19.3 kg. For powder products, mass-based dosing is usually preferred, and volume outputs should be treated as secondary.
Small losses occur from pump priming, hose residue, container cling, and minor spills. A waste factor of 1–3% is common on busy pours, but project requirements differ. This tool applies waste after the base dosage to produce an adjusted total, helping teams order enough product while avoiding excessive overuse.
Hot weather can accelerate setting and increase water demand, while cold weather can slow hydration and finishing. If your specification defines a temperature multiplier, enable temperature adjustment and enter the factor (for example 1.10). The calculator also flags extreme site temperatures to prompt review of curing and set-control plans.
Field dosing must be repeatable for each truck. Dividing the total by the number of batches provides a per-batch target in liters and milliliters. Use the rounding option to match your measuring cylinder or dispenser resolution, then record batch targets, time, and operator notes for traceable quality control documentation.
Always follow the admixture datasheet limits, compatibility notes, and the project’s mix approval. Overdosing can cause delayed set, segregation, or strength variability. Use the warnings as prompts, not approvals. Confirm calibration of dispensers and verify slump and air content at start, mid-pour, and end.
Dosing by cement mass is usually more consistent because it tracks binder content. Dosing by volume can work for standardized mixes, but it can drift if cement content changes between mix designs.
Start with the mid-range rate for trial placement, then adjust within the approved range based on slump retention, finishing time, and strength results. Document the final approved rate for site use.
Density converts liters to kilograms and improves cost estimation. It also helps reconcile dispenser readings, delivery invoices, and inventory counts when the supplier reports mass but the site measures volume.
Calculate each product separately using its own dosage basis and density. Check compatibility guidance, sequencing, and total added liquid. Keep separate batch targets and labels to prevent mixing products unintentionally.
Not always, but it is practical. If dosing is done with closed, calibrated systems, waste may be near zero. For manual dosing and frequent container changes, 1–3% helps avoid shortages.
Yes, if the datasheet specifies it. The calculator converts percent dosing to liters using density. Verify whether the percent is by mass of product or active solids, and follow the datasheet wording.
Confirm dispenser calibration, mixing time, and uniform distribution. Monitor slump, air content, and temperature. If results drift, pause to verify the dosing rate, water additions, and admixture compatibility.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.