Patent Application
20230400255
This disclosure relates to heat exchange systems and, more specifically, to control systems for heat exchange systems.
Some indirect heat exchangers operate by transmitting hot fluid through a conduit and passing cool air over that conduit. For example, a heat exchanger may include a fluid-receiving coil positioned in an air flow path. As the air passes over the coil, heat is indirectly exchanged between the fluid and the air via the coil.
To increase the efficiency of the indirect heat exchange process, some heat exchangers utilize adiabatic cooling systems that dispense evaporative liquid, such as water, over an adiabatic pad. The adiabatic pad is positioned in the flow path of the air upstream of the coil. The liquid in the adiabatic pad evaporates into the air passing through the pad which lowers the temperature of the air before the air passes over the coil. The cooler air passing over the coil improves the efficiency of the indirect heat exchange process.
One shortcoming of some existing heat exchangers is that when the heat exchanger begins dispensing the evaporative liquid onto the adiabatic pad, the flow of air through the adiabatic pad strips liquid particles from the adiabatic pad and carries the liquid particles from the adiabatic pad and onto the heat exchanger coil. The liquid particles removed from the adiabatic pad, referred to herein as drift, may be undesirable due to the scale and mineral deposits left behind on the coil as the liquid evaporates. The scale and mineral deposit buildup may reduce the efficiency of the heat exchange and may restrict or even block the flow of air through the coil. Thus, the lifespan of the heat exchanger may be reduced and/or the heat exchanger may require maintenance to remove the scale and mineral buildup resulting in downtime for the heat exchanger.
A heat exchange apparatus, such as a cooling tower, is provided having a heat exchanger, a liquid absorbent material, a liquid distribution system to distribute liquid onto the liquid absorbent material, and an airflow generator operable to generate airflow from the liquid absorbent material to the heat exchanger. The heat exchanger transfers heat between a working fluid and air moving relative to the heat exchanger. The heat exchanger may include a direct heat exchanger and/or an indirect heat exchanger. The direct heat exchanger may include, for example, fill and the indirect heat exchanger may include, for example, a coil (e.g., a serpentine coil or microchannel-coil) and/or a plate. The heat exchange apparatus has a controller that operates at least one of the liquid distribution system and the airflow generator to inhibit drift of liquid from the liquid absorbent material onto the heat exchanger.
In one embodiment, the controller has dry and wet modes of operation. In the dry mode, the controller inhibits the liquid distribution system of the heat exchange apparatus from dispensing liquid onto the liquid absorbent material. In the wet mode, the controller causes the liquid distribution system to distribute liquid onto the liquid absorbent material. The controller limits liquid drift from the liquid absorbent material onto the heat exchanger, for example, by setting a limit on an operational parameter of the heat exchange apparatus as the controller changes from a dry mode of operation to a wet mode of operation.
In one embodiment, the airflow generator includes a fan and the controller operates the fan to inhibit drift of liquid from the liquid absorbent material onto the heat exchanger. For example, the airflow generator may include a fan and the controller may set a maximum operational speed of the fan as the liquid absorbent material is being wetted. Thus, the controller will temporarily limit the operational speed of the fan, such as 50% of the maximum speed of the fan, even if the controller determines a fan speed higher than the set maximum operational speed is required to achieve a return fluid temperature requested by a heating ventilation air conditioning (HVAC) controller of a building. The set maximum operational speed of the fan provides an upper limit on the airflow velocity through the liquid absorbent material, which may reduce the number of liquid droplets in the airflow as the airflow exits the liquid absorbent material. Further, the maximum operational speed of the fan establishes an upper limit on the velocity of liquid droplets in the airflow and permits the liquid droplets in the airflow to fall into a liquid collector of the heat exchange apparatus under the effect of gravity. The maximum operational speed of the fan protects the heat exchanger from damage caused by drift from the liquid absorbent material until the liquid absorbent material is adequately saturated as discussed in greater detail below. Further, the controller may adjust the maximum operational speed of the fan as the liquid absorbent material is being wetted based on, for example, time and/or the amount of liquid absorbed by the liquid absorbent material.
Once the liquid absorbent material is sufficiently wetted, the controller sets the maximum operational speed of the fan to a higher speed, e.g., 100% of the maximum speed of the fan. The controller is thereby able to operate the fan throughout the full range of speeds of the fan (e.g., 0% to 100% of the maximum fan speed) as needed to achieve the return fluid temperature requested by the HVAC system controller. In one embodiment, the maximum operational speed of the fan once the liquid absorbent material is sufficiently wetted is the maximum speed of the fan set by the fan's manufacturer.
Liquid traveling along the sufficiently wetted liquid absorbent material is kept on the liquid absorbent material by, for example, surface tension of the liquid and the capillary action of the liquid in the adhesive material. Thus, the liquid on the liquid absorbent material is less able to leave the liquid absorbent material as drift once the liquid absorbent material is sufficiently wetted. The fan may therefore be operated at 100% of the maximum speed of the fan if needed without generating undesirable drift.
In another embodiment, the controller operates the liquid distribution system to limit drift from the liquid absorbent material onto the heat exchanger. For example, the controller may set a maximum liquid distribution rate of the liquid onto the liquid absorbent material until the liquid absorbent material is sufficiently wetted.
In one embodiment, the heat exchange apparatus includes a drift sensor operatively connected to the controller. Upon the sensor detecting liquid droplets in the airflow traveling toward the heat exchanger, the controller adjusts the operation of the airflow generator and/or liquid distribution system to reduce the drift from the liquid absorbent material.
With respect to
With respect to
The indirect heat exchangers 104 each include an inlet header 105A for receiving a fluid, an outlet header 107A, and a coil 117 connecting the inlet and outlet headers 105A, 107A. The coil 117 has a plurality of runs intermediate the inlet and outlet headers 105A, 107A. In one embodiment, the coil 117 includes one or more tubes each having an interior that permits fluid to travel therethrough and a sidewall extending about the interior. The coil 117 may have a number of configurations, such as pairs of straight runs connected by U-bends. In another embodiment, the coil 117 includes serpentine tubes. The coil 117 may or may not include fins.
With respect to
The fluid received at the inlet header 105A may include, for example, liquid water, water vapor (e.g. steam), a mixture of liquid water and water vapor, ammonia, brine, and/or a glycol (e.g., propylene, ethylene). In one embodiment, the fluid may include a refrigerant such as R-134a, R410, R404, and/or R744. The inlet header 105A has a fluid inlet 105 and the outlet header 107A a fluid outlet 107. The fluid enters the inlet header 105A at fluid inlet 105, travels through the coil 117, and is collected at outlet header 107A before flowing out of the indirect heat exchanger 104 via the fluid outlet 107.
The rotation of the fans 110 causes air to move from the air inlet 111, through the adiabatic pads 108, into plenum spaces 103, across the coils 117 of the indirect heat exchangers 104, upward through the fan assemblies 102, and out of an air outlet 113 of the cooling tower 102. In one approach, the fluid in the coil 117 has a higher temperature than the air flowing over the coil 117 such that heat transfers through the tube sidewalls of the coil 117 from the higher temperature fluid in the interior of the coil 117 to the cooler airflow moving over the exterior of the coil 117.
The liquid distribution system 106 includes a liquid supply valve connected to a liquid supply. The liquid utilized by the liquid distribution system 106 may be, for example, water (e.g., tap water, rain water, and/or non-potable water). In some embodiments, the liquid distribution system receives water from a water treatment system that converts raw water into processed water having properties and/or additives (e.g., anti-fungal, anti-microbial) suitable for distribution in the cooling tower 100. In one embodiment, the liquid supply valve includes a makeup valve 116, that may be opened to distribute liquid into one or more troughs 118 of the cooling tower 100. The makeup valve 116 may be opened to dispense liquid into the troughs 118 when the sump 120 is empty, when the liquid level in the sump 120 is low, and/or to introduce fresh liquid into the cooling tower 100. The trough 118 includes one or more outlets, such as holes, through which the liquid in the trough 118 may be dispensed onto the adiabatic pads 108 by the liquid distribution system 106. The troughs 118 may extend along the length (into the page in
With respect to
The cooling tower 100 may include one or more sensors 128 to monitor one or more variables of the cooling tower 100. The sensor 128 may include, for example, a temperature sensor, a humidity sensor, a water sensor, and/or a weight sensor. The one or more sensors 128 may include one or more sensors inside of the housing 101 and one or more sensors outside of the housing 101. For example, a sensor 128 may be mounted in the plenum 103 between the adiabatic pad 108 and the indirect heat exchanger 104 to monitor the temperature and/or humidity of the air that has passed through the adiabatic pad 108. The sensor 128 may measure the wet bulb and/or dry bulb temperature of the air. A sensor 128 may also be mounted outside of the cooling tower 100 and upstream of the adiabatic pad 108 to monitor the temperature and/or humidity of the air before the air passes through the adiabatic pad 108. In some forms, one or more sensors 128 may be embedded within the adiabatic pad 108 to detect the presence of water within the pad 108 at the sensor 128. For example, water sensors may be embedded at various heights of the pad 108 to monitor which portions of the pad 108 have absorbed liquid distributed from the liquid distribution system 106. For instance, a water sensor may be mounted at the lower end of the pad 108 where the liquid is distributed to the top of the pad 108 to detect when liquid has reached the lower portion of the pad 108 (e.g., indicating the pad 108 is soaked/nearly soaked). Water sensors may also be mounted on various components within the cooling tower 100 to monitor liquid drift within the cooling tower 100. For example, one or more water sensors may be mounted on the indirect heat exchanger 104 or on the fluid collection tray 123 to detect when liquid particles are drifting from the pad 108. As another example, one or more laser sensors may be mounted within the cooling tower to detect liquid particles in the air drifting from the pad 108 toward the indirect heat exchanger 104.
With respect to
For example, the processor 130 may receive a control signal including a set point temperature for the fluid exiting the outlets 107 of the indirect heat exchanger 104. The processor 130 may determine operating parameters for the cooling tower 100 to meet the set point temperature. For example, the processor 130 may control the speed of the fan assemblies 102, whether the pump 122 is on/off, and whether the makeup valve 116 is open or closed. The processor 130 may communicate control signals to the fan assembly 102 and/or the liquid distribution system 106 to meet the set point temperature. The processor 130 may communicate the control signals to the fan assembly 102 and/or the liquid distribution system 106 via the communication circuitry 134. The controller 126 may be connected to multiple cooling towers 100 and configured to operate each cooling tower 100 to meet the cooling demands of the building. The communication circuitry 134 may be configured to communicate via wired and/or wireless communication protocols, such as Ethernet, Wi-Fi, Bluetooth, cellular and the like.
The controller 116 operates the fan assemblies 102 to generate airflow through the cooling tower 100. The controller 126 may operate the fan assembly 102 to draw air through the adiabatic pads 108 and across the indirect heat exchangers 104 to cool the fluid flowing within the coils 117. The controller 100 may also operate the liquid distribution system 106 control the distribution of liquid onto the adiabatic pads 108. The controller 116 is thus able to operate the cooling tower 100 in a dry mode where the controller 116 inhibits the liquid distribution system 106 from distributing liquid on the adiabatic pads 108 and in a wet mode where the controller 116 causes the liquid distribution systems 106 to distribute liquid onto the adiabatic pads 108.
Depending on operating conditions, the cooling tower 100 may have increased cooling capacity when operated in the wet mode. When the adiabatic pads 108 are soaked or saturated with the liquid from the liquid distribution systems 106, the temperature of the air flowing through the adiabatic pads 108 is reduced as the liquid evaporates into the air. The cooled air then flows over the indirect heat exchangers 104. Because the temperature of the air is reduced as it flows through the soaked adiabatic pads 108, the air is able to remove more heat from the fluid passing through the coils 117 of the indirect heat exchangers 104. The controller 126 may operate the cooling tower 100 in a wet mode to meet a specified cooling demand (e.g., such that the fluid exiting the outlets 107 of the indirect heat exchangers 104 is at a certain temperature or pressure) that, for example, the cooling tower 100 is not able to meet when operating in the dry mode. The controller 126 may also operate the cooling tower 100 in the wet mode to meet a specified cooling demand while reducing the speed of the fan assemblies 102. Reducing the speed of the fan assemblies 102 may reduce the amount of electricity used to operate the fan assemblies 102 which may lower the operational cost of the cooling tower 100 (e.g., at times of peak energy usage/cost).
The controller 126 may be configured to operate the cooling tower 100 (e.g., the fan assembly 102 and/or liquid distribution system 106) to inhibit drift of liquid from the adiabatic pad 108 toward the indirect heat exchanger 104. Liquid that drifts from the adiabatic pad 108 and contacts the hot indirect heat exchangers 104 may evaporate from surfaces of the indirect heat exchangers 104 leaving behind scale or mineral deposits on the indirect heat exchanger 104. The scale buildup on the indirect heat exchangers 104 is undesirable as it may reduce the efficiency of the heat transfer from the indirect heat exchanger 104 to the air, restricts the airflow through the coil 117, and may reduce the lifespan of the indirect heat exchangers 104. Liquid drift is prone to occur as the adiabatic pad 108 has not yet been soaked or saturated with liquid as the cooling tower 100 switches from the dry mode to the wet mode. When the adiabatic pad 108 is initially being soaked and a liquid saturation level of the adiabatic pad 108 is low, liquid is prone to being drawn from the adiabatic pad 108 by the airflow generated by the fan assembly 102 toward the indirect heat exchanger 104. As the saturation level of the adiabatic pad 108 increases, the liquid is progressively less prone to being stripped from or drawn out of the adiabatic pad 108, e.g., due to the strong adhesion and cohesion properties of water within the adiabatic pad 108 keeping the water within the adiabatic pad 108. By limiting or inhibiting the amount of liquid drift, the scale buildup on the indirect heat exchanger 104 is mitigated which may result in increased uptime, reduced maintenance, and a longer lifespan for the indirect heat exchanger 104 and/or cooling tower 100.
Additionally, many current heat exchanger coils are coated to prevent corrosion from liquid drift. By inhibiting liquid drift, uncoated heat exchanger coils 117 may be used which may increase the heat transfer efficiency of the coils 117 of the indirect heat exchanger 14 and/or cooling tower 100. Further, uncoated heat exchanger coils 117 may be less expensive than corresponding coated heat exchanger coils because the coating process is avoided. Specifically, the coating process typically utilizes electrodeposition to provide an anticorrosion coating on the metal of the heat exchanger coils 117. The uncoated heat exchanger coils 117 may be, for example, stainless steel or copper with aluminum fins.
In some forms, upon the controller 126 switching the operation of the cooling tower 100 from the dry mode to the wet mode, the controller 126 operates the cooling tower 100 in a transition phase. In the transition phase, the controller 126 may limit an operational parameter of the cooling tower 100 as the adiabatic pad 108 is being soaked to inhibit the drift from the adiabatic pad 108 before transitioning to an operation phase where the operational parameter is no longer limited. In some forms, the controller 126 adjusts the operation of the cooling tower 100 based on data received from sensors 128 indicative of the amount of drift within the cooling tower 100. The controller 126 may adjust the operation of the cooling tower 100 to inhibit or limit drift from occurring. Where some liquid drift is acceptable, the controller 126 operates the cooling tower 100 such that the liquid drift is within the acceptable range. For example, in cooling towers 100 where the indirect heat exchangers 104 slope away from the adiabatic pads 108 such there are gaps 140 between lower portions 104A of the indirect heat exchangers 104 and lower portions 108A of the adiabatic pad 108 (e.g., as shown in
With reference to
If the controller 126 determines 204 to transition to the wet mode, the controller 126 starts 206 a timer. The controller 126 increments 208 the timer and determines 210 how the liquid distribution system 106 is distributing liquid to the adiabatic pads 108. For example, the controller 126 determines whether the liquid distribution system 106 is dispensing liquid via the makeup valve 116, by operating the pump 122, or both. In some forms, the controller 126 sends control signals (e.g., via the communication circuitry 134) to the liquid distribution system 106 instructing the liquid distribution system 106 (or directly controls the individual components thereof) to dispense liquid via the makeup valve 116, by operating the pump 122, or both and may determine 210 how the liquid distribution system 106 is distributing liquid by reviewing the current or most recent control signals sent to the liquid distribution system 106. In some forms, the controller 126 receives data from sensors indicating whether the pump 122 is operating and/or whether the makeup valve 116 is open and dispensing liquid.
How the liquid distribution system 106 is distributing liquid may indicate the flow rate of the liquid from the liquid distribution system 106 onto the adiabatic pads 108. With respect to
At segment 256, the liquid distribution system 106 shuts off the makeup valve 116 and is distributing liquid onto the adiabatic pads 108 by operating only the pump 122 to provide liquid to the troughs 118. The pump 122 pumps liquid from the sump 120 into the troughs 118, and the openings of the troughs 118 permit liquid to drip out of the trough 118 and onto the adiabatic pads 108. The flow rate of the liquid onto the adiabatic pads 108 is flow rate Fp which is greater than flow rate Fm. The pump 122 may provide liquid into the troughs 118 at a higher rate than the makeup valve 116 provides liquid into the troughs 118. With more liquid in the trough 118, the head of liquid in the troughs 118 is increased (e.g., due to the higher liquid level) which forces the liquid to flow out of the trough 118 and onto the adiabatic pad 108 at a faster flow rate. At segment 258, the makeup valve 116 is opened while the pump 122 operates. The flow rate onto the pad is Fp+m which is greater than Fp. With both the makeup valve 116 and pump 122 dispensing liquid into the troughs 118, the height of the liquid in the troughs 118 is even higher than when only the pump 122 is operating, increasing the head of the liquid at the outlets of the trough 118 and forcing the liquid onto the pad 108 at a higher flow rate, Fp+m.
Based on the determination 210 of how the liquid distribution system 106 is distributing liquid onto the adiabatic pad 108, the controller 126 determines 212, 214, 216 and sets an upper limit on the operation of the fan assembly 102, such as the maximum operational speed of the fan assembly 102. The maximum operational speed of the fan assembly 102 may be a percentage of the maximum speed the fan assembly 102 is able to be operated at. For example, where the fan assembly 102 is capable of operating up to 2000 RPM, and the maximum operational speed of the fan assembly is set at 50%, the controller 126 does not operate the fan assembly 102 at more than 1000 RPM regardless of the cooling requested by the HVAC system controller.
The controller 126 may determine 212, 214, 216 the maximum operational speed of the fan assembly 102 by referencing a data source (e.g., data structure, lookup table, graph, and/or equation) that indicates what the maximum operational speed of the fan assembly 102 should be based on the time since the cooling tower 100 entered the wet mode and how the liquid distribution system 106 is distributing liquid. For example, the data source may be indicative of data collected from experimental tests for the cooling tower 100 that indicate what the maximum operational speed 102 of the fan assembly 102 is able to be without causing unacceptable drift from the adiabatic pads 108 based on the time since the liquid distribution system 106 began dispensing liquid and how the liquid distribution system 106 is distributing the liquid (e.g., makeup valve, pump, or both). The maximum operational speed data may differ based on the model and internal configuration of the cooling tower 100.
With respect to
Where the controller 126 determines the liquid distribution system 106 is distributing liquid via the pump 122 only, the controller 126 refers to the line 274 and determines 214 the maximum operational speed of the fan assembly 102 based on the time that has passed since the cooling tower 100 entered the wet mode, as stored in the timer. For example, where the timer is two minutes, the controller 126 may set the maximum operational speed of the fan assembly 102 at 70%. As another example, where the timer is four minutes, the controller 126 may set the maximum operational speed of the fan assembly 102 at 100%.
Where the controller 126 determines the liquid distribution system 106 is distributing liquid via both the makeup valve 116 and the pump 122, the controller 126 refers to line 276 and determines 216 the maximum operational speed of the fan assembly 102 based on the time that has passed since the cooling tower 100 entered the wet mode, as stored in the timer. In this example, the line 276 is similar to the line 274. This may be due in part to a maximum absorption rate of the adiabatic pad 108 limiting how quickly the pad 108 is able to be soaked. As discussed herein, the amount of liquid absorbed into the pad 108— or how soaked the pad 108 is—may be indicative of the maximum speed at which the fan assembly 102 can be operated to limit drift. While in this example the line 276 is the similar to the line 274, in other examples and applications the lines 274, 276 may be different from one another such that a different maximum operational speed of the fan assembly 102 may be selected based on whether the pump or both the makeup valve and pump are distributing liquid.
Upon determining the maximum operational speed of the fan assembly 102, the controller 126 may determine 218 whether the maximum operational speed of the fan assembly 102 is at 100% such that the fan speed is no longer limited. If not, the controller 126 returns back to step 208, increments the timer and repeats steps 210-218 as described above. If the maximum operational speed of the fan assembly 102 is 100%, the transition phase is complete and the process ends 220.
If the controller 126 determines 304 to transition to the wet mode, the controller 126 calculates a liquid saturation parameter, such as pad-soaked-ratio (PSR), indicative of the liquid saturation level of the adiabatic pad 108. In one example, the controller 126 determines the PSR using data from one or more sensors 128 that indicate the dry bulb temperature and wet bulb temperature of the air that has passed through the adiabatic pad 108. The sensors 128 may include temperature and/or humidity sensors mounted within the plenum space 103 of the cooling tower 100 between the adiabatic pad 108 and the indirect heat exchanger 104 in the path of the airflow 109. As one example, the controller 126 may calculate the PSR by determining and comparing the dry bulb temperature of the air downstream of the adiabatic pad 108 to the wet bulb temperature. For instance, the PSR is the ratio of the wet bulb temperature to the dry bulb temperature. As the amount of liquid absorbed into the pad 108 increases, the relative humidity of the air downstream of the pad 108 increases thus lowering the dry bulb temperature toward the wet bulb temperature. When the dry bulb temperature equals the wet bulb temperature, the PSR is 100%.
As another example, the controller 126 may estimate the PSR by measuring and comparing the temperature and/or humidity of the air before and after the air passes through the adiabatic pad 108. As yet another example, where sensors 128 include liquid sensors embedded in the adiabatic pads 108, the controller 126 may estimate the PSR based on the position of the sensors detecting the liquid as the adiabatic pads 108 progressively saturating along the height of the adiabatic pads 108. More specifically, due to the troughs 118 distributing liquid onto the upper end portions 108B of the adiabatic pads 108, the adiabatic pads 108 may first become saturated at the upper end portions 108B, then intermediate portions 108C, and finally lower end portions 108A.
As an example, where a liquid sensor 128A is halfway between the upper and lower ends of the adiabatic pad 108, the controller 126 may determine the PSR is at least 50% when the liquid sensor detects liquid. Where a liquid sensor 128B is positioned at the lower end of the pad 128 (e.g., 9/10 ths of the distance from the upper end to the lower end of the pad 108), the controller 126 may determine the PSR is at least 90% when the liquid sensor 128 detects liquid. In some forms, the pad 108 may have a series of sensors 128 disposed along the height of the pad 108 to monitor which portions of the pad 108 are soaked. As yet another example, the sensor 128 may include a weight sensor configured to measure the weight of the adiabatic pad 108. As the pad 108 absorbs more liquid, the measured weight of the pad 108 increases. The controller 126 may refer to a lookup table to determine the amount of liquid absorbed into the pad, and thus the PSR, based on the measured weight of the pad 108. The weight sensor 128 may be positioned beneath the adiabatic pads 108 to measure the weight of the adiabatic pads 108. As another example, the adiabatic pads 108 may hang from or be mounted to a frame or structural member of the cooling tower 100. A sensor, such as a strain gauge, may be used to measure the weight of the adiabatic pads 108, for example, based on a measured deflection of the structural member of the cooling tower 100.
The controller 126 may determine 308 how the liquid distribution system 106 is distributing liquid to the adiabatic pad 108 as described with regard to step 210 of method 200 above. For instance, the controller 126 may determine whether the liquid distribution system 106 is providing liquid via the makeup valve 116, the pump 122, or both.
Based on the determination 308 of how the liquid distribution system 106 is providing liquid to the adiabatic pad 108, the controller 126 determines 310, 312, 314 and sets an upper limit on the operation of the fan assembly 102, such as the maximum operational speed of the fan assembly 102. The controller 126 may determine 310, 312, 314 the maximum operational speed of the fan assembly 102 by referencing a data source (e.g., data structure, lookup table, graph, equation) that indicates what the maximum operational speed of the fan assembly 102 should be based on the PSR of the adiabatic pad 108. Data may be collected from experimental tests for the cooling tower 100 that indicate what the maximum operational speed 102 of the fan assembly 102 is able to be without causing unacceptable drift from the adiabatic pads 108 based on the PSR and how the liquid distribution system 106 is distributing the liquid (e.g., makeup valve, pump, or both). With respect to
Where the controller 126 determines the liquid distribution system 106 is distributing liquid via the pump 122 only, the controller 126 refers to line 354 and determines 314 the maximum operational speed of the fan assembly 102 based on the PSR of the adiabatic pad 108, as determined at step 306. For example, where the PSR is 20%, the controller 126 may set the maximum operational speed of the fan assembly 102 to about 50%. As another example, where the PSR is 60%, the controller 126 may set the maximum operational speed of the fan assembly 102 at about 80%.
Where the controller 126 determines the liquid distribution system 106 is distributing liquid via both the makeup valve 116 and the pump 122, the controller 126 refers to the line 356 and determines 312 the maximum operational speed of the fan assembly 102 based on the PSR of the adiabatic pads 108, determined at step 306. For example, where the PSR is 20%, the controller 126 may set the maximum operational speed of the fan assembly 102 to about 35%. As another example, where the PSR is 60%, the controller 126 may set the maximum operational speed of the fan assembly 102 at about 70%.
Upon determining the maximum operational speed of the fan assembly 102, the controller 126 may determine 316 whether the maximum operational speed of the fan assembly 102 is 100% such that the fan speed is no longer limited. If not, the controller 126 returns back to step 306 to recalculate the PSR of the pad 108 and repeats steps 308-316 as described above. If the maximum operational speed of the fan assembly 102 is 100%, the transition phase is complete and the process ends 318. The controller 126 may adjust the maximum operational speed of the fan assembly 102 based on the conditions of the cooling tower 100 as described above, for example, as the adiabatic pad 108 becomes dirty.
In some embodiments, the cooling tower 100 includes sensors 128 mounted within the cooling tower 100 to detect drift. When drift is detected by these sensors 128, the controller 126 may reduce the speed of the fan assembly 102 to adjust the flow of drift to an acceptable region of the cooling tower 100, for example, where the liquid particles fall in the fluid collection tray 123 and do not reach the coil 117. The sensors 128 may be, for example, water sensors that detect the presence of water particles or droplets. One or more water sensors may be mounted on the coil 117 to detect the presence of liquid on the on the coil 117. The water sensors may communicate data to the controller 126 for processing. The controller 126 may adjust the operation of the fan assembly 102 and/or liquid dispensing system 106 based on the water sensor data. In some forms, the controller 126 may generate an alarm when liquid is detected on the coil 117. The controller 126 may communicate, via the communication circuitry 134, the alarm to a remote computing device such as a server computer.
For example, an alarm may be generated where liquid is detected on the coil 117 when the controller 126 is operating the fan assembly 102 and/or liquid distribution system 106 in ranges where unacceptable drift should not be occurring. The alarm may call for maintenance or inspection and/or may log that liquid drift reached the coil 117 along with the operating parameters at which the undesired liquid drift occurred. Alternatively or additionally, one or more water sensors may be mounted on the fluid collection tray 123 to detect when liquid is falling onto the fluid collection tray 123. The water sensors may be mounted at a portion of the fluid collection tray 123 near the coil 117 to detect the presence of liquid particles drifting near the coil 117. In some forms, the controller 126 reduces the speed of the fan assemblies 102 and/or the flow rate of the liquid dispensed from the liquid dispensing system 106 upon detecting liquid on the coil 117 and/or tray 123 until liquid drift is no longer detected.
In some embodiments, the cooling tower 100 may include sensors 128 that detect the presence of liquid particles or droplets in the airflow from the adiabatic pad 108 toward the coil 117. For instance, the sensors 128 may include one or more laser sensors positioned within the cooling tower 100. For example, the laser sensors may include a laser beam generator and a detector mounted within the cooling tower 100. The laser beam generator may generate a laser beam that is detected by the detector. As liquid particles are stripped from the adiabatic pad 108 and carried toward the coil 117, the liquid particles may break the laser beam such that the laser beam is temporarily not detected at the detector. The laser sensor and/or controller 126 may count the number of breaks in the laser beam to quantify the drift in the plenums 103. As another example, the sensors 128 may include one or more radar sensors positioned within the cooling tower 100. The radar sensors may generate radio waves and detect reflections of the radio waves from the drift. As another example, the sensors 128 may include one or more cameras mounted within the cooling tower 100 and positioned to capture images of the plenum 103 downstream of the adiabatic pads 108. In some forms, the cameras may be configured to capture images at high speeds and strobe lighting may be used as the images are captured. A computing device, such as controller 126, may process the images to detect liquid droplets in the images and to determine the amount of drift. The controller 126 may adjust the operation of the cooling tower 100 based on the detected amount of drift to inhibit drift from reaching the indirect heat exchanger 104.
In some situations, the controller 126 may adjust the operation of the liquid dispensing system 106 to inhibit liquid drift instead of or in addition to controlling the speed of the fan assembly 102. For example, in some cooling towers 100, the fan assembly 102 is configured to operate in a failsafe mode (e.g., when the control signal to the fan is lost) where the fan assembly 102 runs at full speed or 100% of the maximum speed of the fan assembly 102 to ensure adequate cooling in the event the controller 126 has to provide its maximum cooling capacity. As another example, the speed of the fan assembly 102 is controlled by a device other than the controller 126 such that the controller 126 is unable to adjust the operational speed of the fan assembly 102. In such situations, where the controller 126 determines to operate the cooling tower 100 in the wet mode, the controller 126 may operate the liquid dispensing system 106 to slowly wet the adiabatic pad 108 to inhibit drift as the cooling tower 100 transitions to the wet mode. The controller 126 may reference a data source (e.g., data structure, lookup table, graph, and/or equation) that indicates what the maximum liquid distribution rate of the liquid distribution system 106 is able to be set to so that drift is limited or inhibited based on the speed the fan assembly 102 is operating at. For example, the maximum liquid dispensing rate may be determined experimentally by monitoring the amount of drift from the adiabatic pads 108 onto the indirect heat exchangers 104 at various fan speeds and flow rates of liquid onto the adiabatic pad 108. The controller 126 may receive data from one or more sensors 128 indicative of the PSR of the pad 108. The controller 126 may adjust the maximum liquid flow rate based on the PSR, for example, as the PSR increases the controller 126 may increase the maximum liquid flow rate of the liquid distribution system 106. As another example, the controller 126 may monitor the amount of time that since the liquid distribution system 106 began dispensing liquid onto the adiabatic pads 108 and adjust the maximum liquid flow rate of the liquid distribution system 106 over time. In some forms, the controller 126 receives data from water sensors detecting drift from the adiabatic pad 108 within the cooling tower 100 as described above and adjusts the maximum liquid distribution rate based on the amount of drift that is detected.
With respect to
Upon determining to transition to the wet mode, the controller may determine 406 how to distribute liquid onto the adiabatic pad 108 via the liquid distribution system 106, for example, via the makeup valve 116, the pump 122 in the sump 120, or both. As described above with respect to
Whether the controller 126 is able to distribute fluid via the makeup valve 116, the pump 122, or both may depend on the amount of liquid in the sump 120. As mentioned above, the cooling tower 100 may include one or more floats 119 or sensors within the sump 120 that monitor the amount of fluid in the basin 121. Where the fluid level in the basin 121 is detected to be below a low-level threshold, the controller 126 may determine to open the makeup valve 116 to distribute liquid and to inhibit operation of the pump 122. Where the fluid level in the basin 121 is detected to be above a high-level threshold, the controller 126 may determine to close or keep closed the makeup valve 116 and to run the pump 122 to distributed liquid. Where the fluid level is above the low-level threshold and below the high-level threshold, the controller 126 may determine to open the makeup valve 116 and/or to run the pump 122. The float 119 may include a low-level float for monitoring the liquid level below the low level threshold, a mid-level float for monitoring the liquid level between the low and high level thresholds, and a high level float for monitoring the liquid level above the high level threshold. The controller 126 may open the drain valve 124 when the liquid level exceeds a certain height.
With respect to
The cooling tower system 600 is arranged to operate in a hybrid mode with one or more cooling towers 600A-C in the wet mode and the remaining cooling tower(s) 600A-C in the dry mode. Operating in the hybrid mode may conserve evaporative liquid where controller 650 has determined that operating all the adiabatic pads of the cooling towers 600A-C in the dry mode is not sufficient to meet the heat exchanging demands but that operating all the adiabatic pads is not needed. For example, controller 650 may turn on pump 642 which wets right adiabatic pad 622 and left adiabatic pad 632 and does not energize pumps 640 and 641, which keeps adiabatic pads 620, 621, 630 and 631 dry.
With respect to
Uses of singular terms such as “a,” “an,” are intended to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms. It is intended that the phrase “at least one of” as used herein be interpreted in the disjunctive sense. For example, the phrase “at least one of A and B” is intended to encompass A, B, or both A and B.
While there have been illustrated and described particular embodiments of the present invention, it will be appreciated that numerous changes and modifications will occur to those skilled in the art, and it is intended for the present invention to cover all those changes and modifications which fall within the scope of the appended claims.
