A system includes at least one sensor and at least one controller. The at least one sensor is configured to generate a first weight signal corresponding to a first weight of a first lot of substrates, and a second weight signal corresponding to a second weight of a second lot of substrates. The at least one controller is coupled to the at least one sensor to receive the first weight signal and the second weight signal. The at least one controller is configured to convert a weight difference between the first weight and the second weight into a number of substrates each having a predetermined weight. The at least one controller is further configured to, based on the converted number of substrates, control a processing apparatus to rotate the first lot of substrates and the second lot of substrates simultaneously.

A system includes at least one sensor and at least one controller. The at least one sensor is configured to generate a first weight signal corresponding to a first weight of a first lot of substrates, and a second weight signal corresponding to a second weight of a second lot of substrates. The at least one controller is coupled to the at least one sensor to receive the first weight signal and the second weight signal. The at least one controller is configured to convert a weight difference between the first weight and the second weight into a number of substrates each having a predetermined weight. The at least one controller is further configured to, based on the converted number of substrates, control a processing apparatus to rotate the first lot of substrates and the second lot of substrates simultaneously.

A system includes at least one sensor and at least one controller. The at least one sensor is configured to generate a first weight signal corresponding to a first weight of a first lot of substrates, and a second weight signal corresponding to a second weight of a second lot of substrates. The at least one controller is coupled to the at least one sensor to receive the first weight signal and the second weight signal. The at least one controller is configured to, based on a weight difference between the first weight and the second weight, control a processing apparatus to rotate the first lot of substrates and the second lot of substrates simultaneously.

A system includes at least one sensor and at least one controller. The at least one sensor is configured to generate a first weight signal corresponding to a first weight of a first lot of substrates, and a second weight signal corresponding to a second weight of a second lot of substrates. The at least one controller is coupled to the at least one sensor to receive the first weight signal and the second weight signal. The at least one controller is configured to, based on a weight difference between the first weight and the second weight, control a processing apparatus to rotate the first lot of substrates and the second lot of substrates simultaneously.

Provided are non-exposure supplied fuel quantity testing device and method of a vehicle-mounted type, and more particularly, a device formed in a trunk of a vehicle without being exposed to test whether or not the ordered fuel quantity is supplied at the time of supplying fuel. Since the device is formed so as not to be exposed, it is disable to perform an artificial tampering of a lubricator, and since the device is mounted in the trunk, it is enable to measure whether or not the ordered fuel is supplied accurately at the same time as supplying fuel. The present invention relates to a testing method using the testing device.

A measuring instrument for thermogravimetrically determining the moisture content of a material, which includes a base (12), configured as a balance, with a base surface (22), and a hood (14) pivotably connected to the base. The hood has a weighing chamber lid (50), weighing chamber walls (52-56) and a heating element (44). The hood consists of an electronics module (36) that includes the heating element and an electronic power unit, and of a mechanical module (48) that includes the weighing chamber lid and all of the weighing chamber walls. The mechanical module (48) is rigidly and reversibly coupled to the electronics module so that the heating element, protrudes from a main body (42) of the electronics module and rises through a corresponding opening (58) in the rearward weighing chamber wall (56), with the main body being pivotably connected to the base and surrounding the electronic power unit.

A measuring instrument for thermogravimetrically determining the moisture content of a material, which includes a base (12), configured as a balance, with a base surface (22), and a hood (14) pivotably connected to the base. The hood has a weighing chamber lid (50), weighing chamber walls (52-56) and a heating element (44). The hood consists of an electronics module (36) that includes the heating element and an electronic power unit, and of a mechanical module (48) that includes the weighing chamber lid and all of the weighing chamber walls. The mechanical module (48) is rigidly and reversibly coupled to the electronics module so that the heating element, protrudes from a main body (42) of the electronics module and rises through a corresponding opening (58) in the rearward weighing chamber wall (56), with the main body being pivotably connected to the base and surrounding the electronic power unit.