Aspects of the present disclosure generally relate to systems and methods related to providing and managing utility power sources. More specifically, the present disclosure relates to an automatic transfer switch to transfer power between two separate power systems.
Automatic transfer switches (ATS) are typically used to transfer power between two different power systems. For example, an ATS may be employed to switch between power provided by a utility and power provided by a generator. The ATS provides a means for a user to effectively manage power consumption at a premises by providing the option of switching between the two (or more) power systems. However, such automatic transfer switches typically provide some protection against potentially dangerous situations, such as “back-feeding” of power at the switch location.
To prevent “back-feeding” of power, which may be dangerous to service personnel or others, the automatic transfer switches are commonly of the “open-transition” or “break before make” type. In this type of switch, the connection to one source is opened before the connection to the other source is closed. This type of switch typically employs a mechanical construction or an interlock that makes it physically impossible to provide a connection between the two sources.
The most typical switch employed in this scenario is a multi-pole bi-stable switch. Such a switch is inherently incapable of interconnecting the two power sources. One disadvantage of such a switch is its size and cost. Strong springs are usually employed to provide the force necessary to maintain contact closure pressure required during large fault currents that may occur in electrical distribution systems. If the large currents associated with these faults cause the contacts to part, destructive arcing will occur. These strong springs require large forces to force the switch toggle mechanism over-center, thereby requiring the use of large, expensive electromechanical solenoids to drive the mechanism. Another disadvantage that increases the size and therefore cost is that the contacts used by the different power sources must be physically separated sufficiently to prevent the arcing that may occur at contact opening from extending from one power source contact to the other. Minimizing this arc length requires rapid contact opening which again implies large forces required for movement.
It is with these and other issues in mind, among others, that various aspects of the present disclosure were conceived and developed.
Aspects of the present disclosure involve systems, methods, and the like, for an automatic transfer switch (ATS) of a power system. The ATS allows for switching between two or more power systems while preventing back-feeding of the power systems. Rather than utilizing typically high-cost switches, the ATS described herein utilizes multiple magnetic latching relays. To provide the safety features of the ATS, a “safety board” or “safety circuit” and “control board” or “control circuit” may be implemented with the magnetic latching relays to control the actions of the latching relays and provide the switching function of the ATS. In one particular embodiment, the safety board comprises one or more electromechanical relays positioned between the controlling electronics of the control board and the magnetic latching relays. In one embodiment, the safety board is a separate physical entity from the ATS control board and is mounted within the ATS enclosure. In another embodiment, the safety board circuits are incorporated into the control board circuitry. As explained in more detail below, the safety board design contains measures to ensure it still functions if one of the disconnect switches is not connected, if one of the connections to a first load phase, a second load phase or neutral is lost and if the main control board is not connected. In this manner, the safety board circuitry is single fault tolerant to provide safety features of the ATS.
In addition, a “safety board” (or “safety board circuit” or “safety circuit”) is in electrical communication with the utility latching relay 102 and the generator latching relay 104. As described in more detail below with reference to
An “ATS control board”, “control board” or “control circuit” 108 may also be in electrical communication with the safety board 106. In general, the control board 108 provides one or more control signals to the safety board 106 and/or the latching relays 102, 104 to control the operation of the ATS 100. Such control signals are described in more detail below. To provide the control signals for the ATS, the control board 108 may include any number of electronic components that form a circuit to provide said signals. In one embodiment, the control board 108 includes one or more processors and one or more memory components that store instructions that, when processed by the one or more processors, provide the control signals to the ATS 100. The components of the control board 108 are described in more detail below with reference to
One or more busbars 110 or other energized components of the ATS 100 may also be connected to or otherwise associated with the safety board 106. The electrical connections of the one or more busbars 110 provide state information of the ATS 100 to the safety board 106 (and control board 108 in some implementations) for use by the boards in determining the state of the ATS. For example, the safety board 106 may determine that a particular busbar 110 is energized by at least one of the power sources and may utilize that information during the switching between the power sources to prevent a dangerous situation at the ATS 100 during the switch.
As mentioned above, the safety board 106 is in electrical communication with one or more of the components of the ATS 100. Thus, electrical signals may be transmitted between the various components of the ATS 100 and the safety board 106. Such signals are illustrated in
The communication cable 220 of the magnetic latch switch provides electrical transmission paths between the safety board 106 and/or the control board 108 and the magnetic latching switch 202 for transmitting one or more control signals between the components. As should be appreciated, the magnetic latching switch 202 illustrated in
Also included in the ATS 300 are the components that comprise the ATS switching system as illustrated in
To provide the control signals to the latching relays 302, 304, a safety board 306 or safety circuit is also included in the ATS 300. To communicate with the latching relays 302, 304, one or more communication lines 220 may be connected between the safety board 306 and the latching relays, although not shown in
Also included in the ATS 300 is a control board 308. Similar to the safety board 306, the control board provides one or more control signals to the safety board and/or the utility magnetic latching relay 302 and the generator magnetic latching relay 304 to control the operation of the ATS. For example, the control board 308 may provide an open or close control signal to the latches 302, 304. Thus, although not shown in
The operation of the ATS is now described in relation to
As shown in
Beginning in stage A 402 as illustrated in
The stage A 402 safety feature is illustrated in
Returning to
Similarly, the generator status switch 505a is inverted by a generator status switch relay 505b connected to the generator latch 304 and placed in the path of the utility close signal. Thus, if the generator switch is closed, the generator status switch 505a is similarly closed, the inversion of which would cause generator status switch relay 505b to be open, thereby breaking the path of the utility CLOSE signal. In addition, utility status switch 505c will be closed, thus insuring no potential can be applied across the utility relay close coil. In other words, the utility switch 302 cannot receive a CLOSE signal from a controller if the generator status switch 505a is closed. The operation of utility status switch relay 504a-c and generator status switch relay 505a-c in relation to the switch status of the utility and generator switch operate to prevent the connection, or closing, of one latch if the other latch is already closed or connected.
In stage C 406, a single output signal from the control board operates to drive both the generator and utility latches. In general, the control board of the ATS provides a control signal to close either the generator latch or the utility latch such that only one of the latches can be closed at any given time. This functionality is illustrated in the circuit of
The operation of stage C 406 ensures that only one latch can be controlled at a time, while further enforcing the interlocking of state B 404 described above. For example, in the situation where both latches are open and a CLOSE signal is provided to each latch at the same time (thereby bypassing the interlocking of the status switches described above), only one of the latches would receive the CLOSE signal based on the select signal provided to relays 506a-506d.
The stage D 408 safety feature relies on relays energized by a load busbar 310 to prevent a latch 302, 304 from receiving a CLOSE signal when the load busbar is energized. In particular and shown best in
In use, the CLOSE signal is connected in series with the contacts of the first phase relay 508b and the second phase relay 509b. The first phase relay 508a-b and second phase relay 509a-b are normally closed relays such that, if either relay is energized by voltage present on the load busbar 310, the relay is opened and the CLOSE signal path is broken. In the instance when the load busbar 310 is energized (meaning that one of the power sources are providing power to the load), a CLOSE control signal cannot be sent to either magnetic latching switch 302, 304.
In stage E 410, one or more relays are utilized by the ATS to determine a strong 24 volt signal from the control board to the safety board and latching switches. In one embodiment, certain safety features, such as the interlocking feature of stage B 404 relies on a 24 volt connection from the control board. Thus, in stage E 410, a power detect relay 510a-b associated with the 24 volt signal from the control board may be connected in series in the CLOSE signal path to the latches 302, 304. The power detect relay 510a-b is configured such that when the 24 volt signal is not present at the relay, the relay opens and the CLOSE signal path is broken. In this manner, a CLOSE control signal cannot be received at either latch 302, 304 if a bad or missing 24 volt signal is detected from the control board.
The various stages of safety features described above are implemented through the safety board of the ATS 500. For example, an OPEN signal is received at either latch 302, 304 based on the select signal controlling relays 506a and 506b. In particular, an asserted select signal allows for relay 506a to close (and relay 506b to open) allowing for the OPEN signal to be received at the generator latch 304. Alternatively, a deasserted select signal allows for relay 506b to close (and relay 506a to open) allowing for the OPEN signal to be received at the utility latch 302.
To receive a CLOSE signal from the control board, several safety features or stages are provided in the ATS 500. For example, the CLOSE signal is connected in series to a power detect relay 510 that is only closed (thereby providing transmission of the CLOSE signal) if a 24 volt signal is received at the relay from the control board. This is illustrated as stage E 410 of
The select signal from the control board also controls relays in the CLOSE signal path. More particularly, an asserted select signal (detected at switch relay 506x) allows for relay 506c to close (and relay 506d to open) allowing for the CLOSE signal to be present on the CLOSE signal path to generator latch 304. A deasserted select signal 506x allows for relay 506d to close (and relay 506c to open) allowing the CLOSE signal to be present on the CLOSE signal path to utility latch 302. This is illustrated as stage C 406 of
Also, a utility loop 502 is connected in series in the disconnect path for the generator latching relay 304 such that a missing utility loop prevents the generator latching relay disconnect switch from closing. Similarly, the generator loop 503 is connected in series in the disconnect path for the utility latching relay 302 such that a missing utility loop prevents the utility latching relay disconnect switch from closing. This is illustrated as stage A 402. Through the various stages of the ATS 500, back feeding of a power source to the load during switching is prevented.
As mentioned above, the control board (or control circuit) of the ATS system may provide one or more control signals to control the operation of the ATS.
Control board 600 may include a dynamic storage device, referred to as main memory 616, or a random access memory (RAM) or other computer-readable devices coupled to the processor bus 612 for storing information and instructions to be executed by the processors 602-606. Main memory 616 also may be used for storing temporary variables or other intermediate information during execution of instructions by the processors 602-606. Control board 600 may include a read only memory (ROM) and/or other static storage device coupled to the processor bus 612 for storing static information and instructions for the processors 602-606. The control circuit set forth in
According to one embodiment, the above techniques may be performed by the control board 600 in response to processor 604 executing one or more sequences of one or more instructions contained in main memory 616. These instructions may be read into main memory 616 from another machine-readable medium, such as a storage device. Execution of the sequences of instructions contained in main memory 616 may cause processors 602-606 to perform the process steps described herein. In alternative embodiments, circuitry may be used in place of or in combination with the software instructions. Thus, embodiments of the present disclosure may include both hardware and software components.
A machine readable medium includes any mechanism for storing information in a form (e.g., software, processing application) readable by a machine (e.g., a computer). Such media may take the form of, but is not limited to, non-volatile media and volatile media. Non-volatile media includes optical or magnetic disks. Volatile media includes dynamic memory, such as main memory 616. Common forms of machine-readable medium may include, but is not limited to, magnetic storage medium (e.g., floppy diskette); optical storage medium (e.g., CD-ROM); magneto-optical storage medium; read only memory (ROM); random access memory (RAM); erasable programmable memory (e.g., EPROM and EEPROM); flash memory; or other types of medium suitable for storing electronic instructions.
In addition to providing the control signals for the ATS, the control board may perform several other functions related to the performance and monitoring of one or more power sources connected to the ATS. For example, the National Electric Code requires that generators used for optional standby power either be capable of operating the entire load or have means to limit the connected load to that which the generator can supply. A typical residence with 240 volt service at 200 amperes could consume a maximum of 48,000 VA or 38,400 VA continuously (80% of maximum). This same residence may only consume 10,000 to 15,000 VA if some circuits could be disabled or only permitted when other loads were at a low level.
Typically air conditioning and heating loads (resistance heating and water heating) are candidates for control because they require large amounts of power and because they may be “deferred” without substantial inconvenience. Most solutions to this problem use current transformers to measure the generator current and compare the current consumed to the maximum current rating of the generator. Some provide the protection without the use of current transformers by monitoring the frequency of the generator as the generator frequency is reduced at high load.
In one configuration of the control board, current transformers measure the load current delivered to the premises, which may be either the generator or the utility or any other type of power source. Additional circuitry measures the actual power consumed, not just the current. This takes into account the reactive portion of the load, allowing larger loads to be connected. It also permits optional communication of the power being consumed to the user. This may be advantageous during prolonged outages when knowledge of power use may permit a better utilization of loads. Additionally, it provides an indication of the power being consumed when utility power is used. Awareness of power consumption is believed to result in more judicious use of appliances leading to lower consumption, lower utility bills and to conservation.
Yet another embodiment of the control board provides a more efficient utilization of the generator power. Prior art methods employ a single parameter to determine if the generator will be overloaded. Simple current transformers are used on generator lines and the current transformer output is scaled, rectified and filtered. In converting the AC current levels to average DC levels the selection of the filter time constant can have significant impact. If the time constant is too short, brief current excursions may result in loads being needlessly shed or deferred. If the time constant is too long, the generator may be overloaded and shut itself down. In another method, the frequency is calculated by measuring the generator voltage. Additionally, the energy content of the fuel (commonly natural gas, propane or diesel fuel) varies. This means that the power that may be derived from the generator must necessarily vary also. Therefore simply comparing the filtered DC current levels to the generator rating will result in either unused capacity or unnecessary generator shut downs due to overload. The present disclosure of the control board uses a combination of overload detection parameters that include power, frequency and voltage. This is advantageous because generators are mechanical devices with varying rotating mass, inertia, and control system time constants. These generators must employ feedback loops to maintain their frequency and their output voltage.
Embodiments of the present disclosure include various steps, which are described in this specification. The steps may be performed by hardware components or may be embodied in machine-executable instructions, which may be used to cause a general-purpose or special-purpose processor programmed with the instructions to perform the steps. Alternatively, the steps may be performed by a combination of hardware, software and/or firmware.
The foregoing merely illustrates the principles of the invention. Various modifications and alterations to the described embodiments will be apparent to those skilled in the art in view of the teachings herein. It will thus be appreciated that those skilled in the art will be able to devise numerous systems, arrangements and methods which, although not explicitly shown or described herein, embody the principles of the invention and are thus within the spirit and scope of the present invention. From the above description and drawings, it will be understood by those of ordinary skill in the art that the particular embodiments shown and described are for purposes of illustrations only and are not intended to limit the scope of the present invention. References to details of particular embodiments are not intended to limit the scope of the invention.
This application claims priority under 35 U.S.C. §119(e) to U.S. Provisional Application No. 61/754,307 entitled “AUTOMATIC TRANSFER SWITCH”, filed on Jan. 18, 2013 which is incorporated by reference in its entirety herein.
Number | Date | Country | |
---|---|---|---|
61754307 | Jan 2013 | US |