The present invention relates generally to an improved heat exchange apparatus such as an evaporative closed circuit cooling tower, evaporative fluid cooler or evaporative condenser. More specifically, the present invention relates to an evaporative fluid cooler or evaporative condenser having indirect evaporative fluid heat exchange sections arranged in such manner that an evaporative liquid, usually water, is distributed across the indirect heat exchange section. When compared to other similarly sized indirect, evaporative heat exchange products, the indirect heat exchange section of present invention is capable of achieving greater heat transfer capability per unit size and lower operating cost due to a use of less water flow rate as evaporative liquid.
In accordance with the present invention, a generally uniform temperature liquid is distributed over the outside surface of an indirect heat exchange section, which is comprised of a series of individual, enclosed circuits tier conducting a fluid stream to be heated or cooled. When used as a closed circuit cooling tower or evaporative condenser, heat is indirectly transferred from the fluid stream to the surrounding film of evaporative liquid. Heat retained by the evaporative liquid is directly transferred to an air stream passing through the indirect evaporative heat exchange section. The evaporative liquid draining from the indirect heat exchange section, is then collected in a sump and then pumped upwardly for redistribution across the indirect evaporative heat exchange section.
Depending upon the specific application, the fluid stream can be used to either liberate or absorb heat to or from the air stream, making the value of the heat exchanged to the air stream either positive or negative.
The present invention is concerned with an indirect heat exchange apparatus and method which achieves maximization of the heat exchange efficiencies of the indirect heat exchange section.
In an indirect evaporative heat exchanger, three fluid streams are involved; an air stream, an evaporative liquid stream, and an enclosed fluid stream. The enclosed fluid stream first exchanges sensible heat with the evaporative liquid through indirect heat transfer, since it does not directly contact the evaporative liquid, and then the evaporative liquid and the air stream evaporatively exchange heat and mass when they directly contact each other.
The majority of closed circuit cooling towers evaporative fluid coolers and evaporative condensers are stand alone indirect evaporative heat exchangers.
The present invention represents a unique improvement over the prior art by offering the most efficient way to operate such heat exchangers.
In a closed circuit cooling tower or evaporative fluid cooler, an initially hot fluid, usually water, is generally directed downwardly through a series of circuits, usually in the form of serpentine tubes or coils, which comprise an indirect evaporative heat exchange section, where the hot fluid undergoes indirect sensible heat exchange with a cooler evaporative liquid, again usually water, gravitating over the outside surfaces of the circuits. As heat is transferred sensibly from the hot fluid, the evaporative liquid initially increases in temperature as it gravitates downwardly through the indirect evaporative heat exchange section. Simultaneously, cooler ambient air is drawn over the circuits in a path that is counterflow, concurrent or cross current with the gravitating evaporative liquid. Heat absorbed by the evaporative liquid is transferred to the moving air stream as it flows downwardly over the circuits.
The evaporative liquid passing through the indirect heat exchange section is collected in the sump which has the same temperature as in the water distribution system.
When applied as an evaporative condenser, the process is the same as explained for the closed circuit fluid cooling apparatus except that since the refrigerant condenses at an isothermal condition, the flow of the fluid, now a refrigerant gas, is typically piped to the top of the coil in order to facilitate downward drainage of the condensate.
In the closed circuit fluid cooling tower of the present invention, it was discovered that distributing a lesser amount of evaporative liquid than in existing systems and thought to be required for optimal performance over the indirect evaporative heat exchange section had a substantial effect upon the performance of heat exchange within that section.
A method of operating an indirect heat exchanger comprising
The steps of providing:
providing an indirect heat exchanger comprising
a plurality of coils having length sections and bend sections,
a fan to draw air across the plurality of coils,
a water distribution system located above the plurality of coils and
comprising
a series of discharge sections, an inlet header connected to the series of discharge sections,
a plurality of openings in each discharge section that allow water to be distributed downwardly over the plurality of coils and a sump to collect the water after passing over the plurality of coils,
wherein the water distribution system also comprises an exit opening in the sump, and a pump connected to the exit opening, and a return line to supply the water from the sump to the inlet header of the water distribution system,
wherein said water discharge rate is fixed at 3.0 GPM/ft̂2±0.5 GPM/ft̂2
when the indirect heat exchanger falls within the parameters described in equation 1 set forth below.
A method of operating an indirect heat exchanger comprising:
providing an indirect heat exchanger comprising
a plurality of coils having length sections and bend sections,
a fan to draw air across the plurality of coils,
a water distribution system located above the plurality of coils and
comprising
a series of discharge sections, an inlet header connected to the series of discharge sections,
a plurality of openings in each discharge section that allow water to be distributed downwardly over the plurality of coils and a sump to collect the water after passing over the plurality of coils,
wherein the water distribution system also comprises an exit opening in the sump, and a pump connected to the exit opening, and a return line to supply the water from the sump to the inlet header of the water distribution system,
wherein the water being discharged from the water distribution system onto the plurality of coils is between 2.0 and 4.0 gallons per minute per square foot of the surface area of the plurality of coils.
A method of operating an indirect heat exchanger comprising:
providing an indirect heat exchanger comprising
a plurality of coils having length sections and bend sections,
a fan to draw air across the plurality of coils,
a water distribution system located above the plurality of coils and
comprising
a series of discharge sections, an inlet header connected to the series of discharge sections,
a plurality of openings in each discharge section that allow water to be distributed downwardly over the plurality of coils and a sump to collect the water after passing over the plurality of coils,
wherein the water distribution system also comprises an exit opening in the sump, and a pump operatively connected to a return line to supply the water from the sump to the inlet header of the water distribution system,
wherein the pump can be operated to provide water from the sump to the inlet header at a water discharge rate,
the water discharge rate being calculated according to:
DZP=Cf*NROWS*[(NCKTS*Dp)/Cw]̂2 Equation 1
Wherein DZP is the density zone profile of the plurality of coils, and the water discharge rate is between 2.0 and 4.0 gallons per minute per square foot of top surface area of the plurality of coils when 02P is greater than 10.
A method of operating an indirect heat exchanger comprising:
providing an indirect heat exchanger comprising
a plurality of coils having length sections and bend sections,
with each coil having an inlet opening and an exit opening,
an inlet coil header connected to the inlet opening of each coil and
an outlet coil header connected to the outlet opening of each coil,
the plurality of coils formed into a coil structure,
a fan to draw air through the coil structure,
a water distribution system located above coil structure,
the water distribution system comprising
a plurality of water discharge sections,
an inlet distribution header connected to the plurality of water discharge sections,
a plurality of openings in each water discharge section that allow water to be distributed downwardly over the coil structure,
and a sump to collect the water after passing over the coil structure,
wherein the water distribution system also comprises an exit opening in the sump, and a pump connected to the exit opening, and a return line to supply the water from the sump to the inlet distribution header,
wherein an airside static pressure drop of the coil structure is measured as SP,
wherein the pump can operate at various speeds to provide varying pumping rates,
and wherein the pumping rate can be varied to adjust a total water discharge rate from the plurality of water discharge sections onto the coil structure according to a formula
that if SP is greater than 1 inch of water column, the total water discharge rate onto the coil structure is between 2 and 4 gallons per minute per square foot of surface area of the coil structure.
It is therefore an object of the present invention to provide an apparatus and method for evaporative fluid cooling or evaporative condensing, whereby an indirect heat exchange section delivers improved heat transfer performance.
It is another object of the invention to provide an apparatus and method for evaporative fluid cooling or evaporative condensing, whereby an indirect heat exchange system originally designed for high spray flow rates can be retrofitted to deliver improved heat transfer performance.
It is another object of the invention to provide an apparatus and method for evaporative fluid cooling or evaporative condensing, whereby an indirect heat exchange system originally designed for high spray flow rates can be retrofitted to deliver improved heat transfer performance with pump energy cost savings.
Referring now to
Depending upon the heat exchange capacity required from apparatus 120, the number of water distribution lines 138 can vary from 1 to 6 legs per indirect evaporative coil section 124, with the length of each leg varying between 3-36 feet. Depending on spray water flow rate, the number of discharge openings or nozzles 142 per heat exchanger coil 124 indirect section will vary between 9-180 nozzles. Likewise, pump 130 is sized to provide the optimum spray flow rate described for a continuous supply of cooling water pumped to spray nozzles 142 to produce a supply of water across the entire span of the coil assembly 124. The optimum supply rate is 2.5 to 3.5 gallons per minute of water per square foot of the top surface area of coil assembly 124. Upper drift eliminator 144 is interposed between the top of the liquid distribution lines 138 and fan 134 to remove the water droplets entrapped by the primary air stream while evaporatively cooling the water descending through indirect heat exchange coils 124.
For many years, it was thought that optimum indirect heat exchanger operation was achieved by a heavier flow of evaporative liquid over indirect heat exchanger coils. Such flows were frequently in the range of 4.5 to 6 or even higher gallons per minute per square foot of indirect heat exchanger coil top surface area. Such flows are undesirable due to the electricity required to operate pumps to deliver that high of flow rates of evaporative liquid from the cooling tower sump. Further, air pressure drop through the heat exchanger coils is increased with the presence of that high amount of evaporative liquid passing through the outside of heat exchanger coils. Such air pressure drop impedes fan performance and overall efficiency of the indirect heat exchanger. Noise from excessive fan, fan motor size, and more dense falling water droplets are also undesirable consequences of the high evaporative liquid flow rates.
The present inventive design and operation of such indirect heat exchangers results largely from a realization that an optimum performance is achieved with a lesser flow rate of evaporative liquid across the coils. Ideal flow rates are from 2 to 4 gallons per minute of evaporative liquid per square foot of indirect heat exchanger coil top surface area, and optimum flow rates are from 2.5 to 3.5 gallons per minute of evaporative liquid per square foot of indirect heat exchanger coil top surface area. Such flow rates are especially efficient from a heat exchange point of view when the coil density of closed circuit cooling tower indirect heat exchanger increases as will be described below. Another realization in the performance of indirect heat exchangers having dense coil sections is that a high flow rate of evaporative liquid across the coil section actually does not lead to improved performance. The reason for this is that the evaporative liquid being supplied at the high flow rates does not contact the outside of the coils for enough time to absorb heat in an efficient manner while excess thickness of the evaporative water film increases the thermal resistance. The ideal flow rates of the present inventive design and operation of an indirect heat exchanger of 2 to 4 gallons per minute of evaporative liquid per square foot of indirect heat exchanger coil top surface area optimizes the sensible and latent heat exchange ability of the evaporative liquid passing across the coils.
Another realization in the performance of indirect heat exchangers having coil sections is that the effect of the lower flow rate of evaporative liquid over the coils is related to the projected tube area relative to the coil width and the number of tubes deep of the coil structure, and to a lesser degree the projected fin area if the coil has fins, and to a lesser degree the operating fluid conditions, and to an even lesser degree the volume of air moved across the coil structure by the fan or fan motor power related to the desired operation of the indirect heat exchanger. While the operating conditions and amount of airflow impact the performance effect of lower spray flow rates, the primary three governing factors are described in such relationship can be expressed generally as the Density Zone Profile
DZP=Cf*NROWS*[(NCKTS*Dp)/Cw]̂2 Equation 1
Following this equation, when the DZP number is greater than 14, then the sensitivity to capacity improvements with reduced spray flow rates become significant, 5-10% depending on operating parameters and air flow rates. When the DZP number is between 10 to 14, the sensitivity to capacity improvement with reduced spray flow rates become minor, between 2-4% depending on operating parameters and air flow rates. When the DZP number is very close to 10, then the sensitivity to capacity improvement with reduced spray flow rates become negligible, typically ±only 1% depending on operating parameters and air flow rates. Finally, when the DZP number is less than 10, the sensitivity to capacity improvement with reduced spray flow rates become reversed, meaning it is better to maintain higher spray flow rates.
It should be noted however, that with DZP<10, higher spray flow rates only gain a few percent in capacity and the benefits of higher spray flow rates and hence higher spray flow pump power consumption should be examined on a case by case basis. In most cases, having too much spray pump horsepower even when DZP<10 only benefits the customer application during extreme loadings which is not a significant part of the year. For the Cf, fin correction factor, there are a lot of variables when describing fins on heat transfer tubes such as fin density, fin thickness, fin width, fin height and fin efficiency. To simplify the fin correction factor, the inventors reviewed these variables and came up with a rather simple governing relationship, as shown in Table 1.
In table 2, the DZP numbers for a number of examples are demonstrated:
For 6 row sparsified or dense double serpentine (SERP) coils, NROWS=2*6=12;
for 12 row sparsified and dense double serpentine (SERP) coils, NROWS=2*12=24.
It should be noted that most coils that are sold in closed circuit cooling towers and evaporative condensers today have DZP>10 and a good majority of the coils have DZP numbers>14 making the transition from higher spray flow rates to lower spray flow rates suggested by this invention worthwhile for the majority of customers' applications.
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In the case where an indirect heat exchanger was previously installed which incorporates higher spray flow rates>3.5 GPM/Ft̂2, a retrofit can be performed on that heat exchange apparatus to take advantage of the capacity gain at lower spray flow rates and if desired at lower spray pump power consumption. The ways to accomplish this are:
Install spray system designed for spray flows at 2.5-3.5 GPM/ft̂2
Reduce the spray pump flow rate to 2.5-3.5 GPM/FT̂2 by:
1) Changing pump impellor
2) Changing pump
3) Installing a variable speed drive (but set at constant speed)
4) Install a flow control valve on existing pump discharge pipe
5) Install a flow restrictor in existing pump discharge
6) Install a flow restrictor in existing pump discharge piping
Or a combination of these steps.
Once the retrofit is complete, the spray flow rate must be measured to insure 2.5 GPM/FT̂2<flow rate<3.5 GPM/FT̂2 in order to achieve the capacity gain. Once the flow rate is set, the spray pattern must be checked to insure proper coverage, especially when the fan(s) is off.
Number | Date | Country | |
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61732514 | Dec 2012 | US |