Systems and methods for identifying relay contact position within an appliance. In one embodiment, an appliance includes a first motor, a second motor, and a relay. The relay can be configured to be adjusted between at least a first position associated with a first circuit of the first motor and a second position associated with a second circuit of the second motor. The appliance can also include one or more control device(s) configured to identify the position of the relay within the appliance. For instance, the control device(s) can provide a test signal to the relay and detect an output signal that is based at least in part on the input signal. The output signal can be associated with the second circuit. The control device(s) can determine whether the relay is in the first position or the second position based at least in part on the output signal.

A fuse is at least partially located between a first load relay and a first charging relay, and an electric current detector is at least partially located between a second load relay and a second charging relay. The electric current detector is in contact with an insulating layer. As viewed from the side, the fuse is located below the electric current detector. The fuse is not in contact with the electric current detector.

A relay control apparatus and method is capable of retaining the operation state of a plurality of relays even when a processor is reset due to a system error. Therefore, the relay control apparatus and method has an advantage of preventing an accident caused by the reset of the processor since the operation state of a plurality of relays is maintained even when the processor is reset. In addition, if the operation state of the processor is a reset state even after a predetermined time passes, the operation state of the plurality of relays is changed to a turn-off state, and thus there is an advantage of preventing system resources and energy from being wasted.

A relay control apparatus and method is capable of retaining the operation state of a plurality of relays even when a processor is reset due to a system error. Therefore, the relay control apparatus and method has an advantage of preventing an accident caused by the reset of the processor since the operation state of a plurality of relays is maintained even when the processor is reset. In addition, if the operation state of the processor is a reset state even after a predetermined time passes, the operation state of the plurality of relays is changed to a turn-off state, and thus there is an advantage of preventing system resources and energy from being wasted.

A semiconductor relay module includes first to third semiconductor relays, first to third input terminals, first to third output terminals, and a first connection line. A first input circuit of the first semiconductor relay and a second input circuit of the second semiconductor relay are connected to the first and second input terminals. The first and second input circuits are connected in series. A third input circuit of the third semiconductor relay is connected to the first or second input terminal and the third input terminal. A first output circuit of the first semiconductor relay is connected to the first output terminal and the first connection line. A second output circuit of the second semiconductor relay is connected to the second output terminal and the first connection line. A third output circuit of the third semiconductor relay is connected to the third output terminal and the first connection line.

A semiconductor relay module includes first to third semiconductor relays, first to third input terminals, first to third output terminals, and a first connection line. A first input circuit of the first semiconductor relay and a second input circuit of the second semiconductor relay are connected to the first and second input terminals. The first and second input circuits are connected in series. A third input circuit of the third semiconductor relay is connected to the first or second input terminal and the third input terminal. A first output circuit of the first semiconductor relay is connected to the first output terminal and the first connection line. A second output circuit of the second semiconductor relay is connected to the second output terminal and the first connection line. A third output circuit of the third semiconductor relay is connected to the third output terminal and the first connection line.

A semiconductor relay module includes first to third semiconductor relays, first to third input terminals, first to third output terminals, a first connection line, and a first monitor terminal connected to the first connection line. A first input circuit of the first semiconductor relay and a second input circuit of the second semiconductor relay are connected to the first and second input terminals. A third input circuit of the third semiconductor relay is connected to the first or second input terminal and the third input terminal. A first output circuit of the first semiconductor relay is connected to the first output terminal and the first connection line. A second output circuit of the second semiconductor relay is connected to the second output terminal and the first connection line. A third output circuit of the third semiconductor relay is connected to the third output terminal and the first connection line.

A semiconductor relay module includes first to third semiconductor relays, first to third input terminals, first to third output terminals, a first connection line, and a first monitor terminal connected to the first connection line. A first input circuit of the first semiconductor relay and a second input circuit of the second semiconductor relay are connected to the first and second input terminals. A third input circuit of the third semiconductor relay is connected to the first or second input terminal and the third input terminal. A first output circuit of the first semiconductor relay is connected to the first output terminal and the first connection line. A second output circuit of the second semiconductor relay is connected to the second output terminal and the first connection line. A third output circuit of the third semiconductor relay is connected to the third output terminal and the first connection line.

The present invention relates to the field of electrical relays. In particular the invention relates to a bracket a relay and bracket combination which permits the relay to be mounted on a surface or panel in a plurality of angular rotational orientations. There is provided a relay and mounting bracket combination comprising a relay having a body with a terminal end portion provided with one or more electrical terminal connectors and a base end portion adapted for engagement with the bracket, wherein the bracket is provided with attachment features which facilitate the mounting of the bracket to an external object or surface when the bracket is engaged with the base end portion of the relay.

A semiconductor relay module includes first to third semiconductor relays, first to third input terminals, first to third output terminals, a first connection line, and a first monitor terminal connected to the first connection line. A first input circuit of the first semiconductor relay and a second input circuit of the second semiconductor relay are connected to the first and second input terminals. A third input circuit of the third semiconductor relay is connected to the first or second input terminal and the third input terminal. A first output circuit of the first semiconductor relay is connected to the first output terminal and the first connection line. A second output circuit of the second semiconductor relay is connected to the second output terminal and the first connection line. A third output circuit of the third semiconductor relay is connected to the third output terminal and the first connection line.