Abstract: A sensor device includes a housing having a hole allowing substances to pass from an exterior of the housing to an interior of the housing, and a printed circuit board having a humidity sensor and at least one electronic component. The sensor device also includes a tube comprising a waterproof material, wherein a first end of the tube surrounds the humidity sensor, wherein a first seal is formed by between the first end of the tube and the printed circuit board, wherein a second end of the tube is located proximate the hole. The sensor device also includes a waterproof, breathable material layer disposed between the second end of the tube and the hole, wherein a second seal is formed between the material layer and the housing, wherein a third seal is formed between the material layer and the second end of the tube. The hole and the material layer allow water vapor to pass from the exterior to the humidity sensor.
Abstract: A plurality of sensor devices are placed at a plurality of locations at which concrete is to be poured, wherein each sensor device is adapted to measure humidity. For example, the plurality of sensors may be placed at selected locations within a form at a construction site associated with a construction project. Concrete is poured at the plurality of locations. Data representing humidity measurements is received from the plurality of sensor devices. For each of the plurality of sensor devices, a respective spike in humidity and a respective time associated with the spike in humidity are determined, thereby determining a plurality of spikes in humidity and a plurality of corresponding times. A build rate is determined for the construction project based on the plurality of spikes in humidity and a plurality of corresponding times.
Abstract: A system includes at least one sensing device located within a structure being built as part of a construction project. The sensing device obtains measurements relating to a first characteristic of concrete of the structure and transmits the data wirelessly. The system also includes a memory, and a processor adapted to receive the data from the sensing devices, determine a second characteristic of the concrete based on the data, and generate a schedule of activities based on the second characteristic. The schedule may be a project schedule specifying tasks associated with the construction project. The processor is also adapted to cause at least one activity to be performed based on the schedule of activities.
Abstract: A sensing device includes a concave side adapted to conform to a curvature of an outer side of a standard concrete test cylinder, a temperature sensor, and a humidity sensor. In one embodiment, the sensing device includes a capillary needle disposed on the concave side. The capillary needle comprises a humidity sensor. The sensing device is attached to the side of a concrete test cylinder, temperature and humidity measurements are obtained by the sensing device, and a prediction of maturity and strength of the concrete is generated based on the temperature and humidity measurements.
Abstract: A system includes at least one sensing device located within a structure being built as part of a construction project. The sensing device obtains measurements relating to a first characteristic of concrete of the structure and transmits the data wirelessly. The system also includes a memory, and a processor adapted to receive the data from the sensing devices, determine a second characteristic of the concrete based on the data, and generate a schedule of activities based on the second characteristic. The schedule may be a project schedule specifying tasks associated with the construction project. The processor is also adapted to cause at least one activity to be performed based on the schedule of activities.
Abstract: A sensing device includes a concave side adapted to conform to a curvature of an outer side of a standard concrete test cylinder, a temperature sensor, and a humidity sensor. In one embodiment, the sensing device includes a capillary needle disposed on the concave side. The capillary needle comprises a humidity sensor. The sensing device is attached to the side of a concrete test cylinder, temperature and humidity measurements are obtained by the sensing device, and a prediction of maturity and strength of the concrete is generated based on the temperature and humidity measurements.
Abstract: A mobile calorimeter includes a container comprising one or more walls defining a cavity. The container is adapted to hold a concrete mixture within the cavity. The mobile calorimeter also includes one or more heat flow sensors adapted to detect a heat flow generated by the concrete mixture. The heat flow sensors may include a thermoelectric device, a Peltier plate, or a macro fiber composite (MFC) sensor. The one or more heat flow sensors may be attached to the one or more walls, or may be embedded within the one or more walls. Data relating to a heat flow is obtained by the heat flow sensors, and is used to generate a prediction of a characteristic or performance of the concrete mixture.
Abstract: A system includes a sensor device having a sensor adapted to generate measurement data relating to a characteristic of a concrete mixture, a transmitter adapted to transmit a first signal based on the measurement data, and a conductive wire forming a coil having a plurality of loops around the sensor device and a wire antenna. The coil is adapted to generate an electric current in response to the first signal. The antenna is adapted to transmit a second signal based on the electric current. The system is embedded in a concrete mixture and a portion of the antenna is exposed above the surface of the concrete mixture. A current is induced in the coil due to electromagnetic induction. A second signal is transmitted via the wire antenna. The second signal is received and transmitted to a processor. The processor may analyze and/or store the signal.
Abstract: A plurality of sensing devices are inserted into a concrete mixture to be used at a construction site. The concrete mixture is poured to form one or more structural elements, wherein one or more sensing devices are embedded in the concrete of each structural element. Data relating to a first characteristic of the concrete in each structural element is received from the sensing devices. For each structural element, a second characteristic of the concrete of the associated structural element is determined, based on the first characteristic. A map showing the one or more structural elements is generated. For each of the one or more structural elements, a respective graphical indicator indicating the second characteristic associated with the respective structural element is displayed on the map. The map is displayed on a user device.
Abstract: A system includes at least one sensing device located within a structure being built as part of a construction project. The sensing device obtains measurements relating to a first characteristic of concrete of the structure and transmits the data wirelessly. The system also includes a memory, and a processor adapted to receive the data from the sensing devices, determine a second characteristic of the concrete based on the data, and generate a schedule of activities based on the second characteristic. The schedule may be a project schedule specifying tasks associated with the construction project. The processor is also adapted to cause at least one activity to be performed based on the schedule of activities.
Abstract: A mobile calorimeter includes a container comprising one or more walls defining a cavity. The container is adapted to hold a concrete mixture within the cavity. The mobile calorimeter also includes one or more heat flow sensors adapted to detect a heat flow generated by the concrete mixture. The heat flow sensors may include a thermoelectric device, a Peltier plate, or a macro fiber composite (MFC) sensor. The one or more heat flow sensors may be attached to the one or more walls, or may be embedded within the one or more walls. Data relating to a heat flow is obtained by the heat flow sensors, and is used to generate a prediction of a characteristic or performance of the concrete mixture.
Abstract: A sensing device includes a concave side adapted to conform to a curvature of an outer side of a standard concrete test cylinder, a temperature sensor, and a humidity sensor. In one embodiment, the sensing device includes a capillary needle disposed on the concave side. The capillary needle comprises a humidity sensor. The sensing device is attached to the side of a concrete test cylinder, temperature and humidity measurements are obtained by the sensing device, and a prediction of maturity and strength of the concrete is generated based on the temperature and humidity measurements.
Abstract: A device includes a cylinder having a cavity adapted to hold a concrete test cylinder, an accelerometer adapted to detect motion data, and a second sensor adapted to obtain measurements of a characteristic of the concrete during a predetermined time period. For example, the second sensor may be a temperature sensor. The device also includes a processor adapted to receive motion data from the accelerometer, determine that the device has moved during the predetermined time period, based on the motion data, and determine that the measurements obtained by the second sensor are invalid, based on the determination that the concrete test cylinder has been moved during the predetermined time period.
Abstract: A measuring device is embedded in a section of concrete at a location at a construction site, the measuring device being adapted to obtain a measurement of a first characteristic of the section of concrete and transmit the measurement via wireless transmission. The first characteristic may include temperature, humidity, conductivity, impedance, salinity, etc. A local wireless gateway receives the measurement data and transmits the data to a processor. Alternatively, an airborne drone flying above the construction site receives the measurement data and transmits the data to the processor. The processor generates a predicted second characteristic of the section of concrete based on the measurement data. For example, the second characteristic may include strength, slump, age, maturity, etc., of the concrete.
Abstract: A sensor device includes a housing having a hole allowing substances to pass from an exterior of the housing to an interior of the housing, and a printed circuit board having a humidity sensor and at least one electronic component. The sensor device also includes a tube comprising a waterproof material, wherein a first end of the tube surrounds the humidity sensor, wherein a first seal is formed by between the first end of the tube and the printed circuit board, wherein a second end of the tube is located proximate the hole. The sensor device also includes a waterproof, breathable material layer disposed between the second end of the tube and the hole, wherein a second seal is formed between the material layer and the housing, wherein a third seal is formed between the material layer and the second end of the tube. The hole and the material layer allow water vapor to pass from the exterior to the humidity sensor.
Abstract: A smart cap system includes a cap adapted to fit on a concrete test cylinder, the cap including one or more internal surfaces, and one or more sensors disposed in or on the one or more internal surfaces of the cap, the one or more sensors being adapted to obtain a measurement of a characteristic of a concrete mixture disposed in the test cylinder. The cap may be adapted to fit on one of a 4×8-inch cylinder and a 6×12-inch cylinder. The one or more sensors may include one of a temperature sensor, a humidity sensor, a chronometer, a heat flow sensor, a motion sensor, a pH sensor, a location detector, a GPS sensor, an accelerometer, a triangulation sensor, a thermoelectric heat flow sensor, a salinity sensor, a macro fiber composite (MFC) sensor, and a capillary sensor.
Abstract: For each of a plurality of production facilities, a series of operations is performed. For each of a plurality of batches of a concrete mixture produced at the respective production facility based on a formulation, a first difference between a measured quantity of cementitious and a first quantity specified in the formulation is determined. A first standard deviation is determined based on the first differences. For each of the plurality of batches, a second difference between a measured quantity of water and a second quantity specified in the formulation is determined. A second standard deviation is determined based on the second differences. A first benchmark is selected from among the first standard deviations, and a second benchmark is selected from among the second standard deviations. An amount by which costs may be reduced by improving production at the production facility to meet the first and second benchmarks is determined.
Abstract: First cost information relating to a first cost of production of a first concrete mixture, and second cost information relating to a second cost of production of a second concrete mixture, are received from a plurality of production facilities that produce concrete mixtures. First quality information relating to a first concrete mixture is received from a first construction site. Second quality information relating to the second concrete mixture is received from a second construction site. A map displaying a region containing the first construction site and the second construction site is displayed on a display device. The first cost information and the first quality information are presented in a graphical format and are overlaid over the map proximate the first construction site, and the second cost information and the second quality information are overlaid over the map proximate the second construction site.
Abstract: Information relating to a change made to a concrete mixture in a concrete mixer truck is obtained. An expected value of a selected characteristic of the concrete mixture is determined based on the change. A representation of the expected value is displayed on a processing device located in a cab of the concrete mixer truck. In one embodiment, the mixture comprises a concrete mixture. The change may comprise an addition of water to the mixture.
Abstract: A mobile calorimeter includes a container comprising one or more walls defining a cavity. The container is adapted to hold a concrete mixture within the cavity. The mobile calorimeter also includes one or more heat flow sensors adapted to detect a heat flow generated by the concrete mixture. The heat flow sensors may include a thermoelectric device, a Peltier plate, or a macro fiber composite (MFC) sensor. The one or more heat flow sensors may be attached to the one or more walls, or may be embedded within the one or more walls. Data relating to a heat flow is obtained by the heat flow sensors, and is used to generate a prediction of a characteristic or performance of the concrete mixture.