초록 ▼

Method and system for controlling and monitoring the quality of concrete based on the concrete's maturity. Various embodiments of the present invention are discussed. First, Enhanced Maturity involves a maturity calibration method to account for the water-to-cementitious-materials ratio, air content

Method and system for controlling and monitoring the quality of concrete based on the concrete's maturity. Various embodiments of the present invention are discussed. First, Enhanced Maturity involves a maturity calibration method to account for the water-to-cementitious-materials ratio, air content, and gross unit weight of the concrete. Second, Moisture-Loss Maturity is a method for determining the appropriate time to terminate moisture-loss protection of concrete and concrete structures. Third, Improved Maturity is a method and system for determining the strength of curing concrete using improved maturity calculations. Fourth, SPC Maturity is a method that beneficially couples maturity measurements and calculations with Statistical Process Control (SPC) methods to enable rapid recognition of changes to the concrete mix and/or incompatibilities between the various components of the concrete mix. Fifth, Loggers, Readers, and Software represent the preferred embodiment for automating and simplifying the implementations of the aforementioned methods.

대표청구항 ▼

What is claimed is: 1. A logger capable of being positioned on or within a concrete mass, comprising: one or more temperature sensors to measure physical properties of the concrete mass and to generate sensor data associated with the temperature of the concrete mass; a memory device that receives a

What is claimed is: 1. A logger capable of being positioned on or within a concrete mass, comprising: one or more temperature sensors to measure physical properties of the concrete mass and to generate sensor data associated with the temperature of the concrete mass; a memory device that receives and stores strength-maturity correlation data formed by varying the proportions of water-to-cementitious ratio, air content, and maturity data in a plurality of calibration batches and then obtaining strength measurements while breaking the calibration batches and also receiving and storing the relative proportions of water, cement, and air content; a microprocessor which accesses the strength-maturity correlation data and receives the sensor data and calculates maturity data and mechanical strength data based on the strength-maturity correlation data and the relative proportions of the water, cement, and air content; and an encasement enclosing the memory device and microprocessor. 2. The logger of claim 1, further comprising one or more sensors that generate data by measuring moisture of the concrete mass. 3. The logger of claim 1, further comprising one or more sensors that generate data by measuring the relative humidity of the concrete mass. 4. The logger of claim 1, further comprising one or more sensors that generate data by measuring the electrical conductivity of the concrete mass. 5. The logger of claim 1, further comprising one or more sensors that generate data by measuring pH of the concrete mass. 6. The logger of claim 1, further comprising one or more ion selective sensors. 7. The logger of claim 1, further comprising one or more thermal-conductivity sensors. 8. The logger of claim 1, further comprising one or more oxidation-reduction potential sensors. 9. The logger of claim 1, further comprising one or more acoustic velocity sensors. 10. The logger of claim 1, wherein the one or more temperature sensors are thermistors. 11. The logger of claim 1, wherein the encasement is formed from an elastic material. 12. The logger of claim 1, wherein the encasement is formed from an elastomeric material. 13. The logger of claim 1, wherein the encasement is formed from a hardened material. 14. The logger of claim 13, wherein the hardened material is epoxy resin. 15. The logger of claim 13, wherein the hardened material is polyester resin. 16. The logger of claim 1, wherein the calibration batches are further comprised of low water/low air content, high water/low air content, low water/high air content, high water/high air content, and medium water/medium air content. 17. The logger of claim 1, wherein the logger is powered by a battery source.