This invention claims priority from provisional application Ser. No. 61/132,604 for Transformer Cooling Monitor And Control System filed Jun. 21, 2008 whose teachings are incorporated herein
This invention relates to apparatus and methods for monitoring and controlling the cooling system of power transformers.
Power transformers designed to distribute large amounts of power, such as substation and distribution class power transformers generally include cooling systems to remove heat generated when large loads are applied to the transformers (i.e., when large currents are drawn from and through the transformer). The cooling systems are designed to remove heat to help keep the transformer and its components below predetermined critical temperatures. Maintaining the transformer temperature below a critical value enables the transformer to handle a designed load capacity or to increase the power handling capability of the transformer.
The cooling systems may include cooling fans to circulate air over the transformer. Alternatively, the transformer may be contained within a liquid (e.g., oil) filled tank with oil pumps being used to circulate the fluid through radiators attached to the tank and cooling fans circulating air over the radiators. The operation of the cooling system is vital for the transformer to deliver its designed power capacity. If the cooling is compromised, the transformer temperature may rise above desired values. Such a rise in temperature may result in the outright failure of the power transformer and at a minimum will result in some damage and an accelerated loss of life. That is, over time excessive heating will reduce transformer life and lead to premature failure which will affect the ability of a utility company to supply uninterrupted supply of power to its customers and will cost the operating utility significant replacement costs.
Problems with prior art systems may be explained with reference to
The heat generated within the transformer causes a rise in the temperature of the windings and in the space surrounding the windings and all around the transformer. When the temperature rises above a certain level many problems are created. For example, the resistance of the (copper) transformer windings increases as a function of the temperature rise. The resistance increase causes a further increase in the heat being dissipated, for the same value of load current, and further decreases the efficiency of the transformer. With increased temperature the transformer may also be subjected to increased eddy current and other losses. The temperature rise may also cause unacceptable expansion (and subsequent contraction) of the wires. Also, the insulation of the windings and other components may be adversely affected. Temperatures above designed and desirable levels result in undesirable stresses being applied to the transformer and or its components. This may cause irreversible damage to the transformer and its associated components and at a minimum creates stresses causing a range of damages which decrease its life expectancy.
It is therefore desirable and/or necessary to maintain the temperature of the power transformer below a predetermined level.
In
Admittedly, the prior teaches the use of cooling systems to protect a power transformer from excessive temperatures. However, a problem with known prior art systems, as illustrated in
Clearly, the prior art does not address the problem which arises when malfunctions and failures of the cooling system are not detected early and quickly. The prior art also does not address the need to monitor the functionality of the cooling system components. These problems and other drawbacks present in the prior art are overcome in systems embodying the invention.
A power transformer generates heat when supplying power to a load. Typically, several cooling devices are mounted on or about the power transformer and are operated (e.g., turned-on or energized) to remove excessive heat from the transformer so as to try to maintain the temperature of the transformer below predetermined levels. The cooling devices may include: (a) fans to blow a gaseous coolant (e.g., air) onto the transformer or onto radiators carrying a liquid coolant in contact with the transformer; and/or (b) pumps for circulating a liquid coolant (e.g., oil) about the transformer. The cooling devices of interest have a motor (e.g., a fan motor or a pump motor) which is energized in response to given temperature and/or heating conditions. In accordance with the invention, the currents flowing through the motors of cooling devices are sensed and monitored to determine whether the cooling devices are functioning correctly. The importance of sensing the motor currents is that it provides an immediate indication of the malfunction of its corresponding cooling device. This is highly significant since a failure of the cooling devices to perform its intended task is not immediately detectable due to the large thermal constants associated with the relatively massive power transformer assembly. Sensing the currents in the motors of the cooling devices enables the early detection of fault conditions. It also enables the monitoring of the operating conditions of the cooling devices for proper maintenance and operation of the entire cooling system.
In accordance with the invention the current in the motors of cooling devices (e.g., fans and/or fluid circulating pumps) is sensed to determine the operability of the cooling devices and to provide an early indication if, and when, a cooling device is malfunctioning.
Systems embodying the invention include means for sensing the current flowing through the motors of N sets of cooling devices for determining whether the cooling devices are functioning properly and to enable the substitution of a device which is functioning properly for one which malfunctioning. The N sets of cooling devices may be intended to be powered in a given sequence under normal conditions, in response to predetermined temperature conditions. In the event the malfunction of a cooling device is detected, means responsive to the sensed motor currents cause the immediate powering of another one of the N sets of cooling devices for the set including the malfunctioning cooling device; where N is an integer equal to or great than two (2).
Furthermore, in accordance with the invention, each motor of a cooling device is controlled (turned on and off) in response to (a) a first signal responsive to the temperature conditions pertaining to the power transformer; and (b) a second signal responsive to the functionality condition (conduction) of the motor.
Systems embodying the invention having more than one cooling device (e.g., multiple cooling fans or pumps) may include means for selectively testing their operability and means for switching an operable cooling device for a malfunctioning cooling device.
Recognizing that the motor of a cooling device (e.g., a fan motor or a pump motor) is malfunctioning enables corrective action to be taken before critical temperatures are exceeded. This results in an earlier alert system if the sensed current indicative of a malfunction is sensed. That is, if there is a malfunction of the cooling system, there is no need to wait for the long thermal time constant of the transformer and its associated equipment to remediate problems with the cooling system.
Systems embodying the invention may also include applying cooling in stages. For example, for sensed temperature above a first level and below a second level a first set of cooling fans is turned on, then for temperatures above the second level and below a third level a second set of cooling fans is turned on, then for temperatures above the third level and below a fourth level a third set of cooling fans is turned on. In addition, the current level drawn by the fan motors in each set is sensed such that if any one of the fans is malfunctioning, another one of the fans is turned on instead.
Still further, the currents in the motors of the cooling devices may be processed such that in the event the fan motor currents are outside a prescribed range (above or below given limits), an alarm condition may be generated including alerting an operator to the potentially dangerous condition.
Systems embodying the invention may also include means for monitoring the length of time the motors are operated and the current drawn by the motors to determine when preventative maintenance and/or replacement of the motors is in order.
In the accompanying drawings, which are not drawn to scale, like reference characters denote like components; and
As shown in
As shown in
The turn-on of switches S1, S2 and S3 is initiated by signals generated by temperature sensors 42 and/or 82 which are supplied to module 210 which is designed and programmed to respond to these signals. Sensors 42 and 82 may include any probe capable of sensing temperature and providing an appropriate signal to processing circuitry contained in module 210.
For purpose of example assume that when the temperature (T) is above a temperature T1 and below a temperature T2 switch S1 is to be closed supplying power to the FM1 and activating fan 6A. If the temperature (T) rises above T2, switch S2 is to be turned on (closed) supplying power to FM2 and activating fan 6B. If the temperature keeps on rising and reaches a level T3, then switch S3 is to be closed and power is supplied to FM3 activating fan 6C. It is assumed that the temperature T2 is greater than T1, T3 is greater than T2 and T4 is greater than T3. This describes the sequential activation of the fans, assuming they are all operating correctly. If the temperature rises above a level T4, an alarm is sounded to indicate the existence of an excessive condition. [Note: Three fans are shown for purpose of example only. There maybe more or less than three fans. Also, each one of FM1, FM2, FM3 may include a set of fans connected in parallel, as illustrated by FM1A and FM1B drawn in dashed lines in parallel with FM.]
However, in accordance with the invention, additional controls are place on the turn-on and turn off of the switches supplying power to the cooling devices, as discussed below. Assume now that S1 is closed and FMi is to be powered. The current through FM1 is sensed by CT12 and processed in circuits 190 and 210. If the sensed current through FM1 is within a predetermined range, FM1 is determined to be operational and S1 is closed. If there is a malfunction in S1 or in FM1, the current through CT12 will reflect either; (a) an undercurrent condition (e.g., a partial or full open circuit) with the current being below a first value or (b) an overcurrent condition (e.g., a partial or full short circuit) with the current being above a second value. If a malfunction is sensed by sensor 190, it produces a corresponding output signal which is then supplied to module 210. Circuits 190 and 210 are designed and programmed to recognize the type of fault condition to enable a range of corrective actions to be undertaken. If the fault is significant, switch SI is opened removing power from FM1. Concurrently, switch S2 is turned-on supplying power to FM2 and activating fan 6B and an alert signal may be produced indicating the nature of the fault. The corrective action taken can be supplied to the user (e.g., the entity having responsibility for the operation of the transformer). Also, the fault condition will be supplied to processing circuitry (not shown) tracking the condition of the cooling system and monitoring when needed maintenance is to be performed.
Likewise, if there is a malfunction in S2 or FM2, the sensed current through CT12 will be below or above a predetermined value. The sensed signal is sent to circuits 190 and 210 which are designed and programmed to recognize the type and nature of the fault condition. If the fault is significant, switch S2 is turned off removing power from FM2. Concurrently, a signal is generated to turn-on S3 supplying power to FM3, activating fan 6C, and alarms or alerts similar to those described above will be instituted and recorded. Thus, fault sensing of the cooling fans and correction for defective fans can be conducted automatically and the transformer power producing system is kept operational until an operator decides to take appropriate action. In brief, the current drawn by the fan motors is sensed such that, if any one of the fans is defective, another one of the fans is turned on instead. In addition, while remedial action is being taken an alarm may be generated to alert an operator to the potentially dangerous condition.
A significant feature of the system is that circuits 190 and 210 can be programmed to periodically and selectively test the operability of all the fan motors individually. That is, module 210 can be programmed to turn-on switch S1 (and turn off S2 and S3) and test for the presence and level of the current through FM1 sensed by CT12. Then S2 can be turned on and S1 and S3 turned off to test the operability of FM2. Then S3 can be turned on and S1 and S2 can be turned off to test the operability of FM3. This mode of operation permits the testing of each fan motor and the determination of its operating conditions and whether any fan motor is not operating correctly. This testing can be done on a regular basis to determine the operability of the cooling system. This enables preventive action to be taken at low cost and with little effort.
The current through the pump motor is sensed by CT412 which supplies the sensed signal to current sensor 490 and module 410 for processing the output of CT412 in a manner similar to that conducted by circuits 190 and 210, describe above. The sensor 490 includes processing circuitry for sensing the current level of the pump motor. If the current level of the pump motor is too high or too low there is an immediate detection of the problem condition and, depending on the extent of the fault condition, corrective actions are taken long before the resulting thermal conditions (e.g., overheating) are sensed. If more than one pump is used to service the system, they can be operated in a similar manner to that described for the fans.
As shown in
It has been shown that, in accordance with the invention, circuitry operating the switch for energizing the motor of a cooling device may be designed to perform the following functions:
The system shown in
Circuit 501 of
Assuming that the cooling devices are all operating correctly, Switch SA is closed when a signal from sensor 42 exceeds reference signal Tref1 or when a signal from sensor 82 exceeds reference signal Tref3. When Tref1 is exceeded, the output of comparator 23 goes from a logic “0” condition to a logic “1” condition which signal is applied to an OR gate 26 whose output is used to enable switch SA whose closure causes power to be applied to the first set of fans MA. The first set of fans may also be activated when a signal from sensor 82 exceeds a reference signal Tref3. When that occurs, the output of comparator 24 goes from a logic “0” condition to a logic “1” condition which signal is applied to OR gate 26 whose output is fed to gating circuit 503 whose output controls switch SA which will be enabled and power the first set of fans MA (if these fans are not malfunctioning).
When the signal at the output of circuit 16 exceeds Tref2, the output of comparator 21 goes from a logic “0” condition to a logic “1” condition which signal is applied to OR gate 25 whose output is fed to gating circuit 503 whose output controls switch SB which will be enabled and power the second set of fans MB (if these fans are not malfunctioning). Likewise, when the signal at the output of circuit 15 exceeds Tref4, the output of comparator 20 goes from a logic “0” condition to a logic “1” condition which signal is applied to OR gate 25 whose output is fed to gating circuit 503 whose output controls switch SB which will be enabled and power the second set of fans MB (if these fans are not malfunctioning).
The above describes the intended normal operation of the cooling fans in stages as a function of increases in temperature, when additional cooling is required and for the condition that the cooling devices are all functioning as intended.
As already noted, in circuits embodying the invention, the application of power to cooling devices is a function of: (a) the temperature level requirement; and (b) the operability of the cooling device. Thus, in order for any of the switches SA and SB to be enabled gating signals have to be generated which indicate that their corresponding cooling devices are operational (“working”). The gating signals are generated by sensing the currents flowing in the motors of the cooling devices. In
The outputs (e.g., Mi) generated by detection circuits (38i) may be combined with a selected output signal (TA, TB or TC) of the temperature processor (501, 210) in a gating arrangement 503 to control the sequencing of the switches applying power to the motors and to generate appropriate alarm signals as outlined in
The temperature of pertinent points/parts of the system is sensed by temperature sensors (e.g., 42, 82) which are coupled to corresponding temperature sensing modules (210, 410, 510) to produce signals (TA, TB or TC) to indicate whether the temperature is above a first level (T1), a second level (T2) or a third level (T3). If there are no defects, when TA is a logic 1 switch SA is to be closed, when TB is a logic 1 switch SB is to be closed, and when TC is a logic 1 switch SC is to be closed. However, in accordance with the invention these switches will only be closed if no malfunction of the cooling devices is detected.
The system also includes means [modules 190, 490, 26(i) and 38(i)] for sensing and storing information regarding the status of the motors operating the cooling devices and for producing signals indicative of the functioning or malfunctioning of the devices. For ease of illustration, the signal for motor MA is also shown as MA, motor MB as MB and motor MC as MC. Also, if a motor is functioning within its prescribed range its corresponding signal (Mi) is defined as a logic “1”; if it is operating outside its prescribed specification its corresponding signal is defined as a logic “0”.
The gating circuitry 503 may be an integrated circuit (IC) microprocessor or any discrete logic circuit which includes the circuitry needed to perform the functions shown in
Although it may not have been explicitly shown for all instances, It should be noted that when a cooling device is found to be defective, particularly when the defective condition is due to a short circuit condition, that the switch applying power to the defective cooling device will be disabled to prevent the application of power to the device.
The information pertaining to a defective cooling device may be stored in memory and the device turned off until it is replaced. Or the operability of the device may be tested periodically to determine whether its defective condition has changed.
The invention has been illustrated using cooling devices having motors and using means (e.g., current transformers) to sense the current in the motors. It should be appreciated that the invention may be practiced with any cooling device whose current and/or voltage and/or power usage can be sensed to determine the operability or malfunctioning of the device.
The invention has been illustrated using radiators. But any other type of heat exchanger can be used to practice the invention.
Number | Date | Country | |
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61132604 | Jun 2008 | US |