A connection arrangement for releasably securing a vibratory apparatus onto a screening apparatus, wherein the vibratory apparatus includes a first vibratory mechanism and a second vibratory mechanism capable of introducing vibration. The connection arrangement includes at least one support plate having at least one indentation and a side plate having at least two indentations. The at least one support plate and the side plate are attachable to the screening apparatus and cooperate with each other to form, in terms of the indentations, respective enclosures for holding the first vibratory mechanism and the second vibratory mechanism.

A connection arrangement for releasably securing a vibratory apparatus onto a screening apparatus, wherein the vibratory apparatus includes a first vibratory mechanism and a second vibratory mechanism capable of introducing vibration. The connection arrangement includes at least one support plate having at least one indentation and a side plate having at least two indentations. The at least one support plate and the side plate are attachable to the screening apparatus and cooperate with each other to form, in terms of the indentations, respective enclosures for holding the first vibratory mechanism and the second vibratory mechanism.

A vibrator separator system has a vibrator separator position and a vibratory basket, a screen assembly positioned in the vibratory separator, and a vibration amplifier coupled to the vibratory separator. The vibratory basket has sides arranged in spaced relation to each other. The vibratory separator has at least one motor affixed thereto. The screen assembly extends between an inlet end and a discharge end of the vibratory basket. The motor is cooperative with the screen assembly so as to impart a vibration frequency to the screen assembly. The vibration amplifier is positioned beneath the screen assembly. The vibration amplifier is cooperative with the screen assembly so as to exert a force against a portion of an underside of the screen assembly.

A vibrator separator system has a vibrator separator position and a vibratory basket, a screen assembly positioned in the vibratory separator, and a vibration amplifier coupled to the vibratory separator. The vibratory basket has sides arranged in spaced relation to each other. The vibratory separator has at least one motor affixed thereto. The screen assembly extends between an inlet end and a discharge end of the vibratory basket. The motor is cooperative with the screen assembly so as to impart a vibration frequency to the screen assembly. The vibration amplifier is positioned beneath the screen assembly. The vibration amplifier is cooperative with the screen assembly so as to exert a force against a portion of an underside of the screen assembly.

A vibratory screen assembly includes a rigid frame having a pair of parallel side members that are spaced apart such that a space is provided between them. A tappet assembly extending horizontally across the space between the side members includes a horizontal member having opposing ends secured to the frame. A screen placed over the tappet assembly provides a screening medium having a mesh size. A vibrator motor is located at each of the opposing ends of the horizontal member to form a cooperative pair of vibrator motors that induce vibrations in the horizontal member and in the screen. As the screen vibrates, aggregate material that is smaller than the mesh size passes through the screening medium and aggregate material that is larger than the mesh size does not pass through the screening medium.

A shot peening efficiency system for separating reusable abrasive media from non-reusable media includes a housing having an opening configured to receive an abrasive media inlet valve; and a separator assembly disposed within the housing, the separator assembly comprising at least one mesh screen and at least one vibratory motor. The housing includes a main channel having a first channel for reusable abrasive media and a second channel for non-reusable abrasive media. The separator assembly is configured to separate reusable abrasive media from non-reusable abrasive media by passing the reusable abrasive media via the first channel and by passing the non-reusable abrasive media via the second channel. The first channel terminates at a reusable abrasive media outlet valve connected to at least one first abrasive media hopper; the second channel terminates at an abrasive media discard outlet valve connected to at least one second abrasive media hopper.

A shot peening efficiency system for separating reusable abrasive media from non-reusable media includes a housing having an opening configured to receive an abrasive media inlet valve; and a separator assembly disposed within the housing, the separator assembly comprising at least one mesh screen and at least one vibratory motor. The housing includes a main channel having a first channel for reusable abrasive media and a second channel for non-reusable abrasive media. The separator assembly is configured to separate reusable abrasive media from non-reusable abrasive media by passing the reusable abrasive media via the first channel and by passing the non-reusable abrasive media via the second channel. The first channel terminates at a reusable abrasive media outlet valve connected to at least one first abrasive media hopper; the second channel terminates at an abrasive media discard outlet valve connected to at least one second abrasive media hopper.

An electrode material containing active material powder is prepared. Dry classification of the electrode material is performed by a classifier. An electrode is manufactured by using the electrode material subjected to the dry classification. The classifier includes a mesh screen, a blade, and a motor. Breakage of the mesh screen is detected by monitoring either or both of an operation sound of the classifier and torque of the motor. The electrode material contained in the classifier will no longer be used for manufacturing of the electrode when breakage of the mesh screen is detected.

An electrode material containing active material powder is prepared. Dry classification of the electrode material is performed by a classifier. An electrode is manufactured by using the electrode material subjected to the dry classification. The classifier includes a mesh screen, a blade, and a motor. Breakage of the mesh screen is detected by monitoring either or both of an operation sound of the classifier and torque of the motor. The electrode material contained in the classifier will no longer be used for manufacturing of the electrode when breakage of the mesh screen is detected.

A vibrating screen feed conveying apparatus for conveying and separating sticky “moisture laden bulk solids” which are sticky and wet flowing onto a vibrating screening feeder and into a hopper. The apparatus includes a bed on which material is conveyed, a longitudinal counterbalance supported on a plurality of isolation springs, a plurality of inclined drive springs extending between the bed and the longitudinal counterbalance, and a plurality of stabilizers for controlling movement of the drive springs along their central axes. A plurality of vibratory motors, each having rotatable eccentric weights are attached to the rear end of the longitudinal counterbalance. The eccentric weights rotate in phase with one another to vibrate the bed at a vibration frequency.