US2024053103A1PendingUtilityA1
Evaporative wet surface air cooler
Est. expiryDec 23, 2040(~14.4 yrs left)· nominal 20-yr term from priority
F28C 1/00F28F 25/087F28F 25/06F28D 9/04F28F 2275/06F28D 7/04F28F 1/04F28D 5/00
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Claims
Abstract
A wet surface air cooler (WSAC), including an evaporative spiral plate heat exchanger for flowing a process medium therethrough, a spray system for spraying a cooling medium directly onto the evaporative spiral plate heat exchanger and a fan for causing air to flow through the evaporative spiral plate heat exchanger, the combination of the sprayed cooling medium onto the evaporative spiral plate heat exchanger and the air flowing therethrough causes the cooling medium to at least partially evaporate to lower the temperature of the process medium.
Claims
exact text as granted — not AI-modified1 . A wet surface air cooler (WSAC), comprising:
an evaporative spiral plate heat exchanger including a first channel configured to receive a process medium; a spray system configured to spray a cooling medium onto the evaporative spiral plate heat exchanger; and a fan configured to force air to flow through the evaporative spiral plate heat exchanger, wherein the combination of the sprayed cooling medium onto the evaporative spiral plate heat exchanger and the air flowing through the evaporative spiral plate heat exchanger causes the cooling medium to at least partially evaporate to cause a temperature of the process medium to decrease.
2 . The WSAC of claim 1 , wherein the first channel of the evaporative spiral plate heat exchanger has a spiral shape and includes a plurality of winds for flowing the process medium,
wherein the evaporative spiral plate heat exchanger further includes a set of second channels extending axially through the evaporative spiral plate heat exchanger for receiving air and cooling medium, and wherein each second channel is provided between winds of the first channel.
3 . The WSAC of claim 2 , wherein the first channel is a closed path extending between an inlet and an outlet and is closed at top and bottom surfaces of the evaporative spiral plate heat exchanger, and
wherein the second channels are open at the top and bottom surfaces of the evaporative spiral plate heat exchanger.
4 . The WSAC of claim 3 , wherein the inlet is provided at a radial center of the evaporative spiral plate heat exchanger and the outlet is provided at an outermost radial surface of the evaporative spiral plate heat exchanger, or
wherein the inlet is provided at the outermost radial surface of the evaporative spiral plate heat exchanger and the outlet is provided at the radial center of the evaporative spiral plate heat exchanger.
5 . The WSAC of claim 2 , wherein the evaporative spiral plate heat exchanger has a cross-flow arrangement in which a direction of air and/or the cooling medium flowing through the second channels is perpendicular to a direction of the process medium flowing through the first channel.
6 . The WSAC of claim 1 , further comprising a lower housing including a plurality of airflow passages and a basin,
wherein the basin is configured to receive the cooling medium sprayed by the spray system.
7 . The WSAC of claim 6 , wherein the airflow passages of the lower housing are configured to allow air to flow from inside of the WSAC to outside of the WSAC from outside of the WSAC to inside of the WSAC.
8 . The WSAC of claim 6 , wherein the fan is provided above the evaporative spiral plate heat exchanger, and
wherein the evaporative spiral plate heat exchanger is provided on the lower housing.
9 . The WSAC of claim 6 , wherein the lower housing is a lower module, and wherein the fan and the spray system are part of an upper module, and
wherein the upper module is configured to be removably fastened to an upper surface of the evaporative spiral plate heat exchanger and the lower module is configured to be removably fastened to a lower surface of the evaporative spiral plate heat exchanger.
10 . The WSAC of claim 1 , wherein the fan, the spray system and the evaporative spiral plate heat exchanger are stacked in a vertical direction.
11 . The WSAC of claim 1 , wherein the spray system is a concentric spray system including a plurality of distribution channels that are spaced from one another to distribute the cooling medium over the evaporative spiral plate heat exchanger.
12 . The WSAC of claim 1 , wherein the fan is horizontally spaced from the evaporative spiral plate heat exchanger.
13 . The WSAC of claim 12 , further comprising a lower housing including a basin,
wherein the basin is configured to receive the cooling medium sprayed by the spray system, wherein the fan and the evaporative spiral plate heat exchanger are provided on a top surface of the lower housing, and wherein the spray system is provided above the evaporative spiral plate heat exchanger.
14 . The WSAC of claim 13 , wherein the fan is configured to force air across the basin and through the evaporative spiral plate heat exchanger or through the evaporative spiral plate heat exchanger and across the basin.
15 . The WSAC of claim 1 , wherein the spiral plate heat exchanger comprises at least one spiral sheet wound to form the first channel.
16 . A method of cooling with a wet surface air cooler (WSAC), the WSAC comprising:
an evaporative spiral plate heat exchanger including a first channel configured to receive a process medium; a spray system configured to spray a cooling medium onto the spiral plate heat exchanger; and a fan configured to force air to flow through the evaporative spiral plate heat exchanger, the method comprising: flowing the process medium through the first channel; and simultaneously spraying, by the spray system, the cooling medium and operating the fan to flow air through the evaporative heat exchanger and cause the cooling medium to at least partially evaporate and cause a temperature of the process medium to decrease.
17 . The method of claim 16 , wherein the first channel of the evaporative spiral plate heat exchanger has a spiral shape and includes a plurality of winds for flowing the process medium,
wherein the evaporative spiral plate heat exchanger further includes a set of second channels extending axially through the evaporative spiral plate heat exchanger, and wherein each second channel is provided between winds of the first channel, the method further comprising, during the simultaneously spraying the cooling medium and operating the fan, flowing the cooling medium and air through the second channels in a same direction or in opposite directions.
18 . The method of claim 17 , wherein the first channel is a closed path extending between an inlet and an outlet and is closed at top and bottom surfaces of the evaporative spiral plate heat exchanger, and
wherein the second channels are open at the top and bottom surfaces of the evaporative spiral plate heat exchanger, said method further comprising: flowing the process medium from a center of the evaporative spiral plate heat exchanger, radially outwardly through the first channel to an outer surface of the evaporative spiral plate heat exchanger; allowing the cooling medium to flow downwardly through gravity; and forcing the air upwardly, opposite to the direction of the cooling medium.
19 . The method of claim 17 , wherein the first channel is a closed path extending between an inlet and an outlet and is closed at top and bottom surfaces of the evaporative spiral plate heat exchanger, and
wherein the second channels are open at the top and bottom surfaces of the evaporative spiral plate heat exchanger, said method further comprising: flowing the process medium from an outer surface of the evaporative spiral plate heat exchanger, radially inwardly through the first channel to a center of the evaporative spiral plate heat exchanger; allowing the cooling medium to flow downwardly through gravity; and forcing the air upwardly, opposite to the direction of the cooling medium.
20 . The method of claim 16 , wherein the fan and the spray system are part of an upper module, and the WSAC further comprising a lower module including a plurality of airflow passages and a basin,
said method further comprising removably fastening the upper module to an upper surface of the evaporative spiral plate heat exchanger and removably fastening the lower module to a lower surface of the evaporative spiral plate heat exchanger.
21 . The method of claim 16 , wherein the spiral plate heat exchanger comprises at least one spiral sheet wound to form the first channel.Join the waitlist — get patent alerts
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