A viscous liquid supply apparatus includes a storage tank (10) that stores viscous liquid, and a pump (14) that supplies the viscous liquid stored in the storage tank to a use point, wherein the viscous liquid supply apparatus is configured with a viscometer (20) that measures a viscosity of the viscous liquid stored in the storage tank, and a replenishment device (30) that supplies replenishment liquid to the storage tank based on the viscosity measured with the viscometer. The viscometer (20) is a rotary type viscometer that has a rotor (23) in a cylindrical shape wherein the rotor is immersed in the viscous liquid and rotates therein, and the rotor is configured with a stirring blade that agitates the viscous liquid inside the storage tank (10).

A viscous liquid supply apparatus includes a storage tank (10) that stores viscous liquid, and a pump (14) that supplies the viscous liquid stored in the storage tank to a use point, wherein the viscous liquid supply apparatus is configured with a viscometer (20) that measures a viscosity of the viscous liquid stored in the storage tank, and a replenishment device (30) that supplies replenishment liquid to the storage tank based on the viscosity measured with the viscometer. The viscometer (20) is a rotary type viscometer that has a rotor (23) in a cylindrical shape wherein the rotor is immersed in the viscous liquid and rotates therein, and the rotor is configured with a stirring blade that agitates the viscous liquid inside the storage tank (10).

Systems and methods for measuring the viscosity of a fluid may comprise a rotor cup having an inner chamber; a first bob rotatably disposed within a first region of the inner chamber; and a second bob rotatably disposed within a second region of the inner chamber, wherein the second bob rotates relative to the first bob based on a difference in viscosity of fluid in the first region and the second region.

Systems and methods for measuring the viscosity of a fluid may comprise a rotor cup having an inner chamber; a first bob rotatably disposed within a first region of the inner chamber; and a second bob rotatably disposed within a second region of the inner chamber, wherein the second bob rotates relative to the first bob based on a difference in viscosity of fluid in the first region and the second region.

A system for measuring the viscosity of a fluid comprises a rotor cup; a bob disposed within the rotor cup and having shaft rotatably coupled to the rotor cup; a bearing connecting the shaft of the bob to the rotor cup; a magnetic coupling comprising a first magnetic element connected to the shaft of the bob and a second magnetic element disposed outside the rotor cup adjacent to the first magnetic element; and an inertial measurement unit disposed adjacent to the second magnetic element which is capable of sensing rotation of the magnetic coupling.

A system for measuring the viscosity of a fluid comprises a rotor cup; a bob disposed within the rotor cup and having shaft rotatably coupled to the rotor cup; a bearing connecting the shaft of the bob to the rotor cup; a magnetic coupling comprising a first magnetic element connected to the shaft of the bob and a second magnetic element disposed outside the rotor cup adjacent to the first magnetic element; and an inertial measurement unit disposed adjacent to the second magnetic element which is capable of sensing rotation of the magnetic coupling.

A mixer (1) having a measuring device (5) for determining a torque which can be applied using a mixing device drive (3) of the mixer to a medium to be mixed. The mixing device drive (3) is mounted to pivot within the housing (2) of the mixer (1) and is supported at least indirectly against at least one rotational direction of its two rotational directions. With the aid of the measuring device (5), a reaction force of this at least one support can be detected and from this, the torque applied by the mixing device drive can be determined.

There is provided a method of detecting a change of a state of a liquid comprising the steps of: •providing a liquid detection medium (12) comprising a liquid and having a plurality of anisotropic magnetic particles suspended therein; •applying a modulated magnetic field across at least a portion of the liquid detection medium (12), wherein the magnetic field induces an alignment of the magnetic particles; •introducing electromagnetic radiation (22) into the liquid detection medium (12); •detecting a variable which is modulated by the applied magnetic field, wherein the variable is associated with the interaction of the electromagnetic radiation (22) with the magnetic particles and wherein the change in the state of the liquid causes a variation in the detected variable; and •correlating the variation in the detected variable with the change in the state of the liquid.

There is provided a method of detecting a change of a state of a liquid comprising the steps of: •providing a liquid detection medium (12) comprising a liquid and having a plurality of anisotropic magnetic particles suspended therein; •applying a modulated magnetic field across at least a portion of the liquid detection medium (12), wherein the magnetic field induces an alignment of the magnetic particles; •introducing electromagnetic radiation (22) into the liquid detection medium (12); •detecting a variable which is modulated by the applied magnetic field, wherein the variable is associated with the interaction of the electromagnetic radiation (22) with the magnetic particles and wherein the change in the state of the liquid causes a variation in the detected variable; and •correlating the variation in the detected variable with the change in the state of the liquid.

A gel-time detection apparatus includes a carrier, a stirring device, and an image-capturing device. The gel-time detection apparatus uses the carrier to liquefied powder to be detected, uses the stirring device to stir the liquefied powder and sense the torque of stirring the liquefied powder, and uses the image-capturing device to capture images of the liquefied powder, so as to determine a gel time according to a determination criterion relevant to the torque and the images. A gel-time detection method includes liquefying powder to be detected, stirring the powder, sensing the torque of stirring the liquefied powder, capturing images of the liquefied powder, and then determining a gel time according to a determination criterion relevant to the torque and the images. The determination criterion may include a torque predetermined threshold and an area-shrinkage-rate predetermined threshold.