A gravimetric measuring device (10, 10′, 10″, 10′″) includes a balance base body (12) and a top unit (14, 14′, 14″, 14′″), wherein the balance base body (12) has a balance base body wall (20), to which the top unit (14, 14′, 14″, 14′″) can be reversibly fixed, and a weighing system with a load receptor (22) passing through the balance base body wall (20) and the top unit (14, 14′, 14″, 14′″). A plurality of optical, magnetic, tactile, radio, thermal, electrical and/or electronic interfaces (201) coupled to a balance electronics are arranged on the balance base body wall (20), at least one of which interfaces is connected to a corresponding interface of the top unit (14, 14′, 14″, 14′″) to form an optical, magnetic, tactile, radio, thermal, electrical or electronic connection between the top unit (14, 14′, 14″, 14′″) and the balance electronics.

An electronic balance includes a balance unit having a measuring pan surrounded by a space enclosed within a windshield having a door, and a rear-section casing formed by plates and containing a motor unit which includes a motor and a driving element connected with the rotation shaft of the motor. When the motor unit is fixed within the rear-section casing, the driving element protrudes through a driving-element hole in one of the plates to the outside of the rear-section casing and engages with a driven element fixed to the door so that the door can be opened and closed by the motor. When the motor must be replaced, the motor unit including the motor and the driving element in an integrated form can be entirely and easily replaced with a new motor unit.

A gravimetric measuring device includes a weighing chamber with a vertical weighing chamber wall, which is formed as a support structure (14) with cover modules (28) detachably fixed thereto on the weighing chamber side, each cover module (28) having, on its weighing chamber side, a module front wall (30) covering the support structure (14) at least partially. The cover modules (28) have locking cantilevers (38) directed towards the support structure such that the locking cantilevers (38) are provided with vertically directed through-openings (40) which are aligned with corresponding through-openings (20, 22) of the support structure (14). The cover modules (28) are locked to the support structure (14) with locking rods (42) which pass through the mutually aligned through-openings (40; 20, 22) of the cover modules (28) and the support structure (14).

Embodiments of the present application provide a weighing device that comprises a weighing unit for weighing wafers, a support structure placed on the weighing unit, at least two support platforms disposed on the support structure and each having a bearing surface for supporting peripheral regions of the wafers, and a driving part for driving the support platforms to move on the support structure, so as to adapt the at least two support platforms to bear the differently sized wafers. Since a wafer contacts merely several support platforms, cleanness of the wafer is better maintained during the weighing process; at the same time, the support platforms are enabled to stably bear differently sized wafers through adjustment of movements of the support platforms on the support structure.

[Object] To provide an electronic balance configured to uses a non-contact sensor to perform a predetermined operation, in which a greater number of operations than the number of non-contact sensors can be performed.

[Means for solving problem] An electronic balance (1) includes: a non-contact sensor (31; 32) configured to detect an object; a state identifier (306) configured to identify a time pattern of a detection signal of the non-contact sensor (31; 32) as one of a plurality of previously defined time patterns; and an operation controller (30; 303; 304; 305) configured to control an operation of a predetermined section of the electronic balance (1) related to the time pattern identified by the state identifier.

A windshield for a balance which has a door that can be automatically opened and closed or half opened and half closed is provided. The windshield includes doors to which air cylinders are joined as driving means, sensors for monitoring movements of the doors, pressure sensors configured to monitor a pressure of air to be supplied to the air cylinders of the driving means, and a control unit configured to stop an air supply to the air cylinders when a pressure of air monitored by the pressure sensor exceeds a predetermined value. Stoppers are disposed on movement paths of the doors to block movement, and when air pressure inside the air cylinder increases to the predetermined value due to contact with the stopper, the door stops. The door can be freely fully opened and half-opened according to the position of the stopper.

Provided is a windshield for a balance, for which opening and closing doors of the windshield are smoothly moved without wobbling, dust or the like is unlikely to accumulate on the part of guide rails that guide the opening and closing doors, and cleaning is easy. Upper portions of the pair of opening and closing doors of the windshield are respectively suspended by upper frames provided along respective side portions of an upper surface door, and the opening and closing doors are reciprocated by air cylinders by being guided by guide rails each formed of a horizontal portion and a vertical portion. On the respective horizontal portions, projections that restrict lower ends of the respective opening and closing doors from being displaced in separating directions from the vertical portions are provided along movement paths of the respective opening and closing doors.

Provided is a balance with a windshield having a door to be smoothly opened and closed either manually or automatically. Provided is an electronic balance with a windshield including a balance main body including a weighing mechanism connected to a weighing pan, a windshield having doors capable of opening and closing by sliding, and configured to form a weighing chamber by covering the weighing pan, and actuators configured to open and close the doors, wherein the actuator includes a double-acting type air cylinder having two ports serving as air intake ports, an air pump-to be connected to the two ports, two valves respectively interposed between the air pump and the two ports and configured to make the ports communicate with and shut off from the atmosphere, and a control device configured to control the two valves-to make the two ports communicate with the atmosphere when the air pump is stopped. Without a special mechanism, switching between automatic opening and closing and manual opening and closing can be made, and in either automatic or manual opening and closing, the doors of the windshield are smoothly opened and closed.

An electronic balance includes: a non-contact sensor including a substrate, a light-emitting element and a light-receiving element, in which the light-emitting element is fixed to a surface of the substrate so as to be directed at a target sensing space, and the light-receiving element is fixed to the surface of the substrate, apart from the light-emitting element, so as to be directed at the target sensing space; and an operation controller configured to control an operation of a predetermined section of the electronic balance according to a detection signal from the non-contact sensor.

A windshield for a balance is provided, and the windshield to be attached to a balance to define a weighing chamber, includes openable and closable doors constituting portions of the weighing chamber, opening and closing mechanisms configured to open and close the doors, sensors configured to detect movement of the doors, and a control unit configured to command the opening and closing mechanism to open and close the door when a movement of the door from a stationary state is detected by the sensors. When an operator slightly moves the door from a stationary state to open or close the door, the sensor detects this, and the door is automatically opened or closed.