Compact modular electrical load management system

The invention claimed is: 1. A load management system for a circuit breaker panel, the system comprising: a load management unit adapted to be supported within a wiring trough of the circuit breaker panel adjacent to a row of circuit breakers, the load management unit including a first circuit path comprising: an input for coupling to a first circuit breaker in the row of circuit breakers within the wiring trough of the circuit breaker panel; an output for coupling to loads outside the circuit breaker panel, the output comprising an angled connector having two connectors arranged at an angle from each other to reduce a wire bending radius of wires coupled to the connectors; and a disconnect switch coupled between the input and the output, the disconnect switch also coupled to receive a control signal to control the switch to disconnect the input from the output. 2. The system of claim 1 wherein the load management unit further comprises a current sensor coupled between the input and the output, the current sensor having a current sensor output providing signals representative of current flow between the input and the output. 3. The system of claim 1 further comprising one or more additional circuit paths for coupling to one or more additional circuit breakers within the circuit breaker panel. 4. The system of claim 1 further comprising multiple additional load management units supported within the circuit breaker panel. 5. The system of claim 4 further comprising a head unit adapted to be supported within the circuit breaker panel for controlling the load management unit disconnect switches. 6. The system of claim 5 wherein the head unit controls the load management unit disconnect switches based on at least one of sensed voltage and frequency levels to avoid an impending overload condition. 7. The system of claim 5 wherein the head unit controls the load management unit disconnect switches in response to a battery becoming a primary source of power for the loads. 8. The system of claim 7 wherein the head unit disconnect switches based on predefined priority for loads in response to the battery becoming the primary source of power for the loads. 9. The system of claim 5 wherein the load management units are coupled to the head unit in a serial daisy chain manner. 10. The system of claim 1 wherein the two connectors are arranged at approximately 90-degree angles from each other to reduce the curvature of coupled wiring within the circuit breaker panel to one or more loads. 11. The system of claim 1 further comprising a base mount for coupling to an inside back of the circuit breaker panel, the mount having tabs extending away from the inside back of the circuit breaker panel to couple to the load management unit, wherein tabs support the load management unit an adjustable distance from the inside back of the circuit breaker panel. 12. The system of claim 1 wherein the load management unit further comprises: a current sensor coupled between the input and the output, the current sensor having a current sensor output providing signals representative of current flow between the input and the output; and control circuitry coupled to receive the current sensor output signals and coupled to control the disconnect switch responsive to the current sensor output signals. 13. A modular load management system comprising: a head unit having an antenna, processor, communication module coupled to the antenna, and a first node connector of the head unit, wherein the unit is configured to connect to and within a circuit breaker panel; a first load management unit adapted to be supported within a wiring trough of the circuit breaker panel adjacent to a row of circuit breakers, the first load management unit including a first circuit path comprising: a first input for coupling to a first circuit breaker in the row of circuit breakers within the wiring trough of the circuit breaker panel; a first output for coupling to a first load outside the circuit breaker panel, the first output comprising an angled connector having two connectors arranged at an angle from each other to reduce a wire bending radius of wires coupled to the connectors; and a first disconnect switch coupled between the first input and the first output, the first disconnect switch coupled to receive a first control signal via the first circuit path coupled to one of the node connectors of the head unit to control the switch to disconnect the input from the output. 14. The system of claim 13 further comprising: a second load management unit adapted to be supported within the wiring trough of the circuit breaker panel adjacent to the row of circuit breakers, the second load management unit including a second circuit path comprising: a second input for coupling to a second circuit breaker in the row of circuit breakers within the trough of the circuit breaker panel; a second output for coupling to a second load outside the circuit breaker panel; and a second disconnect switch coupled between the input and the output, the disconnect switch and also coupled to receive a control signal via the first circuit path coupled to the first node connector of the head unit to control the second switch to disconnect the second input from the second output. 15. The system of claim 14 wherein the first and second load management units are daisy chained together via the first circuit path. 16. The system of claim 15 wherein the head unit comprises a second node connector located on a opposite side of the head unit from the first node connector, wherein the head unit is configured for mounting at an end of two columns of circuit breakers in the circuit breaker panel and wherein the second node is configured to daisy chain connect further load management units coupled to circuit breaker of a column different from the column containing the first circuit breaker. 17. The system of claim 13 wherein the first load management unit further comprises: a current sensor coupled between the input and the output, the current sensor having a current sensor output providing signals representative of current flow between the input and the output; and control circuitry coupled to receive the current sensor output signals and coupled to control the disconnect switch responsive to the current sensor output signals. 18. The system of claim 17 wherein the current sensor is configured to provide data representative of current draw to the head unit, wherein the head unit is configured to communicate the data to a remote device for display of current related information to a user, and wherein the remote device is configured to facilitate a user activating the first switch to connect or disconnect the load management unit from providing current from the first circuit breaker. 19. A load management system for a circuit breaker panel, the system comprising: a load management unit adapted to be supported inside the circuit breaker panel within a wiring trough of the circuit breaker panel adjacent to a row of circuit breakers and on a same surface as the circuit breakers, the load management unit including a first circuit path comprising: an input for coupling to a first circuit breaker in the row of circuit breakers within the wiring trough of the circuit breaker panel; an output for coupling to loads outside the circuit breaker panel; and a disconnect switch coupled between the input and the output, the disconnect switch also coupled to receive a control signal to control the switch to disconnect the inp