US3919732A - Descaling system for condenser cooling tubes - Google Patents

Descaling system for condenser cooling tubes Download PDF

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US3919732A
US3919732A US517614A US51761474A US3919732A US 3919732 A US3919732 A US 3919732A US 517614 A US517614 A US 517614A US 51761474 A US51761474 A US 51761474A US 3919732 A US3919732 A US 3919732A
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descaling
vessel
pipe
elements
cooling water
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US517614A
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Yoshio Honma
Junichi Takahashi
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Toshiba Corp
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Tokyo Shibaura Electric Co Ltd
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28GCLEANING OF INTERNAL OR EXTERNAL SURFACES OF HEAT-EXCHANGE OR HEAT-TRANSFER CONDUITS, e.g. WATER TUBES OR BOILERS
    • F28G1/00Non-rotary, e.g. reciprocated, appliances
    • F28G1/12Fluid-propelled scrapers, bullets, or like solid bodies

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  • ABSTRACT A descaling system for condenser cooling tubes having numerous descaling elements consisting of sponge balls forced through said cooling tubes, wherein a vessel for receiving said descaling elements to soak them with cooling water is fitted with a cage member which is designed to allow the passage of cooling water along and provided at the bottom with a pipe communicating with a 3-port switching valve; the 3-port switching valve is connected to the end of a feed pipe for delivering descaling elements to a cooling water circulation line and that of a discharge pipe for drawing out used descaling elements; and these feed and discharge pipes are made to communicate with the cage member according to the selective operation of the 3-port switching valve.
  • This invention relates to a descaling system for cleaning the interior of the cooling tubes of a condenser by conducting numerous descaling elements therethrough.
  • sponge balls are used as descaling elements.
  • the sponge balls are received in a water soaking vessel, where the balls are fully soaked with cooling water by the action of evacuating means disposed therein.
  • the water-soaked sponge balls are delivered to a cooling water circulation line through a passageway communicating with the water soaking vessel.
  • the sponge balls are carried several times through the cooling water circulation line and passageway for a prescribed length of time to descale the interior of the cooling tubes of a condenser.
  • the used sponge balls Upon completion of descaling, the used sponge balls are collected in a reservoir provided in the passageway, and discharged therefrom to the outside. Fresh sponge balls are charged into the water soaking vessel manually by an operator.
  • the prior art descaling system had the drawbacks that fresh sponge balls were manually charged by an operator each time and the descaling system had to be stopped during said charging operation, rendering this operation time-consuming and preventing the descaling operation from being continuously carried out with high efficiency.
  • the descaling system of this invention for the condenser cooling tubes has the features that the operations of soaking descaling elements with water, recovering and discharging them are undertaken by a unitary device equipped with a 3-port switching valve, so as to concurrently carry out these operations.
  • This invention has the advantages of simplifying the arrangement of a descaling system with the resultant prominent decrease of manufacturing cost and effecting various operations associated with descaling elements by a single device with increased efficiency. Further feature of the invention is that a holder stored with a prescribed quantity of fresh descaling elements communicates with a descaling line through a valve and a proper amount of fresh descaling elements can be supplied to the descaling line by selective operation of said valve, thereby eliminating the necessity of stopping the descaling operation during the charge of fresh descaling elements and consequently elevating the descaling efficiency.
  • a wire net is stretched substantially in a horizontal direction in a tightly closed vessel to prevent descaling elements from floating up to the surface of cooling water, thereby enabling the descaling elements to be fully soaked with water.
  • the peripheral wall of the vessel is provided with a peep window for an operator to observe the interior of the vessel allowing the operator distinctly to recognize the conditions in which the de- 2 scaling elements charged in the vessel are soaked with water and recovered.
  • the holder stored with fresh descaling elements is fitted with pneumatic means for introducing air into the holder forcefully to deliver fresh descaling elements to the descaling line.
  • Another object of the invention is to provide a descaling system capable of carrying out an efficient descaling operation.
  • Still another object of the invention is to provide a descaling system attaining the full soaking of descaling elements with water and the distinct observation of the soaking operation.
  • FIG. 1 is a schematic illustration of the major section of the descaling system of this invention for condenser cooling tubes;
  • FIG. 2 schematically shows the other minor section of said descaling system on a somewhat smaller scale than in FIG. 1;
  • FIG. 3 is a schematic oblique view of a 3-port switching valve used with the descaling system of FIG. 1;
  • FIGS. 4 to 6 present part of the descaling system of FIG. 1 by way of illustrating its operation, showing the manner in which the movement of descaling elements is controlled, with the I-port switching valve indicated in cross section as in FIG. 1.
  • a condenser 10 comprises a plurality of cooling water tubes 11 communicating at both ends with water boxes 100, I012.
  • One water box 10a is connected to one end of a feed pipe 12 constituting part of a cooling water circulation line.
  • the other end of said feed pipe I2 (not shown) is dipped in, for example, sea water.
  • the other water box I01) communicates with one end of a discharge pipe 13 constituting part of the cooling water circulation line.
  • the other end of said discharge pipe is dipped in, for example, sea water.
  • the cooling water circulation line is provided inside with a circulation pump (not shown).
  • the pump draws sea water, for example. as cooling water into the cooling tubes 11 of the condenser 10 through the feed pipe 12 and water box 10a.
  • the cooling water carries out heat exchange and is transferred to the other water box 101) and then drawn out therefrom into the sea through the discharge pipe 13.
  • FIG. 1 a tightly closed cylindrical vessel 14 is indicated in a larger size for better understanding than the condenser 10.
  • a large number of descaling elements 15 consisting of water-absorptive sponge balls are received in the vessel 14 as later described.
  • This vessel 14 concurrently soaks fresh descaling elements 15 with water and recovers and discharges used descaling elements.
  • a cage member 16 is positioned in the vessel 14 substantially at a vertical midpoint. The upper peripheral edge of the cage 16 is fixed to the inner peripheral wall of the vessel 14.
  • a pipe 17 having a fully large. diameter for passage of descaling elements 15 is inte- 3 grally fitted to the bottom of said cage member 16.
  • the cylindrical vessel 14 is divided by the cage member-16 into two upper and lower chambers.
  • the cooling water alone in the vessel 14 can freely pass through both upper and lower chambers due to numerous openings 16a being bored in the cage member 16.
  • descaling elements 15 can not pass through both chambers due to the small diameter of said openings 16a of the cage member 16.
  • the cage member 16 is formed of wire netting and the openings 16a represent the meshes of said netting.
  • a wire net 18 is stretched above the cage member 16 substantially in a horizontal direction. This wire net 18 extends up to the inner wall of the vessel 14. The point within the vessel 14 at which the wire net 18 is stretched is made lower than the prescribed height to which cooling water is filled in the vessel 14.
  • the wire net 18 whose meshes are not large enough to allow the passage of the descaling elements 15 is submerged in water while the descaling elements 15 are being soaked with water, preventing said elements 15 from floating up to the water surface.
  • a peep window 19 is bored in the peripheral wall of the vessel 14 at almost as high a level as the wire net 18 so as to allow an operator to observe the condition of the interior of the vessel 14.
  • An evacuating device 20 (indicated in chain lines) is installed obliquely above the vessel 14. This evacuating device 20 communicates with a free space 22 provided in the upper portion of the vessel 14 through a pipe 21 so as to evacuate or deaerate the vessel 14 to a prescribed extent.
  • the evacuating device 20 comprises an air ejector or vacuum pump 23 and deaeration valves 24, 25, and may sometimes be additionally fitted with a water mist operator or fitter.
  • a descaling element supply pipe 26 is provided on the outer peripheral wall of the vessel 14 between the wire net 18 and cage member 16, with the forward end 260 of the supply pipe 26 opened to the interior of the vessel 14.
  • the rear end 26b of the supply pipe 26 is connected through an inlet valve 27 to an upstream circulation pipe 28 of descaling elements 15, which in turn communicates through a collector 29 with the discharge pipe 13 constituting part of the cooling water circulation line.
  • the descaling element circulation pipe 28 is provided inside with a circulation pump (not shown) forcefully to conduct descaling elements therethrough.
  • the descaling element supply pipe 26 is further connected to the outlet end 3111 of a descaling element holder 31 (FIG. 2) through a descaling element inlet valve 30.
  • the holder 31 is stored with a prescribed quantity of fresh descaling elements 15 for replenishment. This replenishment is effected by selective operation of the inlet valve 30 under an operators manual control.
  • the descaling element holder 31 is provided with an inlet port (not shown) through which descaling elements 15 are charged into the holder 31 up to its capacity.
  • the descaling element holder 31 is connected through a pipe 32 and valve 33 to an air supply source 34, which may consist of an air pump, though its concrete arrangement is not shown.
  • the air supply source 34 introduces air into the descaling element holder 31 through the pipe 32, and, when the valve 30 is opened, forcefully sends forth descaling elements 15 from said holder 31.
  • the descaling element holder 31 takes a vertical position and the outlet 4 end 31a of the descaling element holder 31 is directed downward, then descaling elements 15 may be discharged simply by gravitational fall.
  • provision of the air supply source 34 enables the descaling elements 15 to be rapidly delivered to the supply line 26.
  • the upper outer peripheral wall of the vessel 14 is fitted with a level gauge 35 for measuring and indicating the water level in the vessel 14 and a manometer 36 for measuring pressure prevailing within the vessel 14. These instruments enable an operator to recognize the interior condition of the vessel 14 from readings thereon.
  • the pipe 17 fitted to the bottom end of the cage member 16 is connected to a 3-port switching valve 37, which comprises, as shown in FIG. 3, a valve casing 41 bored with three ports 38, 39, 40, a valve rod 42, and a cylindrical valve element 43 rotated by said valve rod 42.
  • a 3-port switching valve 37 which comprises, as shown in FIG. 3, a valve casing 41 bored with three ports 38, 39, 40, a valve rod 42, and a cylindrical valve element 43 rotated by said valve rod 42.
  • the peripheral wall of the valve element 43 is provided with a notch 44.
  • the notch 44 and the remainig portion 43a of the peripheral wall of the valve element 43 cooperate selectively to open or close the three ports 38 to 40 bored in the valve casing 41 surrounding the valve element 43 according to the rotation of the valve rod 42.
  • the notch 44 itself acts as a passageway for descaling elements.
  • the pipe 17 fitted to the bottom end of the cage member 16 communicates with the port 38.
  • a descaling element feed pipe 45 one end 450 of which communicates with the port 39, is horizontally disposed in the lower portion of the vessel 14.'The other end 4512 of said feed pipe 45 is exposed to the outside of the vessel 14 and is connected to a downstream pipe 47 of descaling elements through an outlet valve 46. Said downstream pipe 47 communicates with the feed pipe 12 constituting part of the cooling water circulation line.
  • a discharge pipe 48 one end 480 of which communicates with the port 40, is disposed horizontally in the lower portion of the vessel 14 on the opposite side of the 3-port switching valve 37 to the above-mentioned feed pipe 45.
  • the other end 48b of the discharge pipe 48 is exposed to the outside of the vessel 14 and connected to a pipe 50 through a discharge valve 49.
  • the rear end of the pipe 50 is bent downward.
  • the peripheral wall of that portion of the discharge pipe 48 which is received in the vessel 14 is bored with a pair of slitshaped openings 51, through which the cooling water of the vessel 14 flows into the discharge pipe 48.
  • the number and size of said openings 51 are not limited to those of this embodiment.
  • cooling water is filled in the vessel 14 to a level shown in FIG. 1, after passing through the circulation line and supply pipe 26, while an operator observes readings on the level gauge 35. Since the wire net 18 is submerged in the cooling water, descaling elements are held down by the wire net 18 and can not float up to the water surface. At this time, the valves 27, 30 are closed and the evacuating device 20 is actuated to evacuate the interior of the vessel 14 to a prescribed level. Attainment of a prescribed degree of vacuity can be recognized from readings on the manometer 36. When the vacuity of the vessel 14 sufficiently increases, descaling elements 15 are fully soaked with cooling water.
  • the wire net 18 is previously so positioned as to be always submerged in the water, thereby preventing the cooling water level from being brought down to said wire net 18.
  • the line 21 of the evacuating device 20 communicating with the space 22 allowed in the upper portion of the vessel 14 enables the evacuating device 20 to exert its action over the free surface of the cooling water, attaining rapid deaeration. As the result, the evacuating device 20 is little soaked with unnecessary cooling water mist, eliminating the provision of any filter or mist separator.
  • the evacu ating device 20 is stopped, and the inlet valve 27 and outlet valve 46 is opened. Also the 3-port switching valve 37 takes the position as shown in FIGS. 1 and 5, namely, the position in which the port 40 alone is closed and the ports 38, 39 communicate with each other. At this time, the discharge valve 49 still remains closed.
  • a circulation pump (not shown) is put into operation, descaling elements are conducted, as shown in FIG. 5, from the vessel 14 to the notch 44 constituting a valve chamber through the pipe 17 and port 38 and then to the feed pipe 45 through the port 39 and finally to the00062pipe 12 through the downstream circulation pipe 47.
  • descaling elements 15 After passing through the feed pipe 12 and the water box 100, descaling elements 15 are scattered into a plurality of cooling tubes 11 and delivered to the water box 1012, while scraping off foreign matter deposited on the inner walls of the cooling 1 pipes and then to the discharge pipe 13. Descaling elements 15 running down through the discharge pipe 13 together with cooling water are trapped by the collector 29 and then brought into the downstream circulation pipe 28, and finally into the vessel 14 through the supply pipe 26. After completing the above-mentioned circulation cycle, descaling elements 15 are again delivered to the cooling water circulation line.
  • the repeated passage of descaling elements 15 through the cooling tubes 11 of the condenser 10 for a prescribed length of time effects the desired descaling operation.
  • the inlet valve 30 (FIG. 2) is opened to supply a required quantity of fresh descaling elements 15 from the holder 31 to the circulation line, thereby eliminating the undesirable stoppage of the circulation of descaling elements 15 at the time of replenishment.
  • cooling water flowing into the vessel 14 through the supply pipe 26 together with descaling elements 15 freely passes downward through the numerous openings 16a of the cage member 16 into the discharge pipe 48 through the paired slit like openings 51 bored in the peripheral wall of the discharge pipe 48.
  • the cooling watered arrows of FIG. 4 passes through the port 40 and the notch or valve chamber 44 of the valve element 43 and is delivered to the feed pipe 45 through the port 39, because the discharge valve 49 is closed. Thereafter, the cooling water runs through the outlet valve 46 now left open to the downstream circulation pipe 47.
  • Used descaling elements 15 which have all been collected in the cage member 16 by the above-mentioned recovering operation are now subjected to the discharging operation.
  • This discharging operation is carried out in the following way.
  • the inlet valve 27 is closed to stop the influx of cooling water into the vessel 14.
  • the water level within the vessel 14 falls to the position of the slits 51, with the descaling elements 15 alone left in the cage member 16.
  • the outlet valve 46 is closed and the discharge valve 49 is opened, while the 3-part switching valve 37 has its position changed from FIG. 4 to FIG. 6. Accordingly, the port 39 is closed, and the port 38 is opened for communication with the port 40, enabling the descaling elements collected in the cage member 16 to pass through the pipe 17 and port 38 into the notch or valve chamber 44, then to the discharge pipe 48 through the port 40 and finally to be discharged to the outside through the discharge valve 49 now open and the pipe 50. Whether all the used descaling elements 15 have been removed from the cage member 16 can be recognized by an operators observation of the interior of the vessel 14 through the peep window 19.
  • valve rod 42 of the 3-port switching valve 37 extends out of the vessel 14 to be manually rotated by an operator.
  • the 3-port switching valve 37 used in this embodiment may be designed with a different arrangement from FIG. 3. Namely. said valve 37 may consist of a ball type in which the valve element 43 is made into a ball form, instead of the cylindrical type of this embodiment. As used herein, the 3-port switching valve 37 includes a cock.
  • 3-port switching valve 37 enables all the operations of soaking descaling elements 15 with water and recovering and discharging them to be carried out in a single unitary vessel 14, eliminating the necessity of providing a separate reservoir and associated piping and in consequence attaining the simplification of the arrangement of the descaling system, the reduction of manufacturing cost and high operating efficiency.
  • a descaling system for condenser cooling tubes de signed to conduct a large number of descaling elements through the cooling tubes from a cooling water feed line and draw out used descaling elements from the discharge line of cooling water characterized in that said descaling system comprises a tightly closed vessel; a cage member whose outer peripheral wall is fixed to the inner peripheral wall of the vessel and whose bottom end is fitted with a pipe for passage of descaling elements, and which acts as a receptacle for the descaling elements and allows the free passage of cooling water alone; a descaling element supply pipe whose forward end communicates with the vessel and whose rear end communicates with a cooling water discharge line; evacuating means for deaerating the vessel; a 3-port switching valve connected to the pipe fitted to the bottom end of the cage member; a feed pipe, one end of which is connected to the 3-port switching valve for communication with the pipe of the cage member by selective operation of said valve and the other end of which communicates with a cooling water feed line; and a discharge pipe for drawing out
  • a descaling system which further comprises a descaling element holder whose inlet end communicates with the supply pipe through a second valve, and which is alwaysfilled with a prescribed quantity of descaling elements and delivers fresh descaling elements to the supply pipe according to the selective operation of said second valve.
  • a descaling system which further comprises air supply means for introducing air into the descaling element holder, thereby forcefully to deliver the descaling elements received in said holder to the supply pipe.
  • a descaling system which further comprises a wire net disposed above the cage member substantially in a horizontal direction, said wire net being submerged in the cooling water when descaling elements are soaked therewith, thereby preventing the soaked descaling elements from floating up to the free surface of the cooling water.
  • a descaling system according to claim 1, wherein the vessel has its peripheral wall bored with a peep window for an operator to observe the interior of the ves-

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Cleaning In General (AREA)
  • Cleaning By Liquid Or Steam (AREA)

Abstract

A descaling system for condenser cooling tubes having numerous descaling elements consisting of sponge balls forced through said cooling tubes, wherein a vessel for receiving said descaling elements to soak them with cooling water is fitted with a cage member which is designed to allow the passage of cooling water along and provided at the bottom with a pipe communicating with a 3-port switching valve; the 3-port switching valve is connected to the end of a feed pipe for delivering descaling elements to a cooling water circulation line and that of a discharge pipe for drawing out used descaling elements; and these feed and discharge pipes are made to communicate with the cage member according to the selective operation of the 3-port switching valve.

Description

United States Patent [191 Honma et a1.
[ DESCALING SYSTEM FOR CONDENSER COOLING TUBES [75] Inventors: Yoshio Honma, Yokosuka; Junichi Takahashi, Yokohama, both of Japan [73] Assignees: Tokyo Shibaura Electric Co., Ltd.,
Kawasaki; Toshiba Engineering Co., Ltd., Tokyo, both of Japan 22 Filed: Oct.24,1974
21 Appl. No.: 517,614
[30] Foreign Application Priority Data [451 Nov. 18, 1975 3,707,442 12/1972 Takahashi et a1 165/95 X 3,841,397 10/1974 Eimer 165/95 X 3,872,920 3/1975 Honma 15/3.5l X
Primary Examiner-Edward L. Roberts Attorney, Agent, or FirmObl0n, Fisher, Spivak, McClelland & Maier [57] ABSTRACT A descaling system for condenser cooling tubes having numerous descaling elements consisting of sponge balls forced through said cooling tubes, wherein a vessel for receiving said descaling elements to soak them with cooling water is fitted with a cage member which is designed to allow the passage of cooling water along and provided at the bottom with a pipe communicating with a 3-port switching valve; the 3-port switching valve is connected to the end of a feed pipe for delivering descaling elements to a cooling water circulation line and that of a discharge pipe for drawing out used descaling elements; and these feed and discharge pipes are made to communicate with the cage member according to the selective operation of the 3-port switching valve.
5 Claims, 6 Drawing Figures U.S'. Patent1\1ov.1s,1975 Sheet2of2 3,919,732
DESCALING SYSTEMFOR CONDENSER COOLING TUBES BACKGROUND OF THE INVENTION This invention relates to a descaling system for cleaning the interior of the cooling tubes of a condenser by conducting numerous descaling elements therethrough.
For such type of descaling system, numerous sponge balls are used as descaling elements. The sponge balls are received in a water soaking vessel, where the balls are fully soaked with cooling water by the action of evacuating means disposed therein. The water-soaked sponge balls are delivered to a cooling water circulation line through a passageway communicating with the water soaking vessel. The sponge balls are carried several times through the cooling water circulation line and passageway for a prescribed length of time to descale the interior of the cooling tubes of a condenser. Upon completion of descaling, the used sponge balls are collected in a reservoir provided in the passageway, and discharged therefrom to the outside. Fresh sponge balls are charged into the water soaking vessel manually by an operator.
With the prior art descaling system, the operation of soaking sponge balls used as descaling elements with cooling water and the operation of recovering and discharging used sponge balls have been effected by the water soaking vessel and reservoir respectively.
Further, the prior art descaling system had the drawbacks that fresh sponge balls were manually charged by an operator each time and the descaling system had to be stopped during said charging operation, rendering this operation time-consuming and preventing the descaling operation from being continuously carried out with high efficiency.
SUMMARY OF THE INVENTION The descaling system of this invention for the condenser cooling tubes has the features that the operations of soaking descaling elements with water, recovering and discharging them are undertaken by a unitary device equipped with a 3-port switching valve, so as to concurrently carry out these operations.
This invention has the advantages of simplifying the arrangement of a descaling system with the resultant prominent decrease of manufacturing cost and effecting various operations associated with descaling elements by a single device with increased efficiency. Further feature of the invention is that a holder stored with a prescribed quantity of fresh descaling elements communicates with a descaling line through a valve and a proper amount of fresh descaling elements can be supplied to the descaling line by selective operation of said valve, thereby eliminating the necessity of stopping the descaling operation during the charge of fresh descaling elements and consequently elevating the descaling efficiency.
According to a preferred embodiment of this invention, a wire net is stretched substantially in a horizontal direction in a tightly closed vessel to prevent descaling elements from floating up to the surface of cooling water, thereby enabling the descaling elements to be fully soaked with water. The peripheral wall of the vessel is provided with a peep window for an operator to observe the interior of the vessel allowing the operator distinctly to recognize the conditions in which the de- 2 scaling elements charged in the vessel are soaked with water and recovered. The holder stored with fresh descaling elements is fitted with pneumatic means for introducing air into the holder forcefully to deliver fresh descaling elements to the descaling line.
It is accordingly the primary object of this invention to provide an inexpensive descaling system of simple arrangement.
Another object of the invention is to provide a descaling system capable of carrying out an efficient descaling operation.
Still another object of the invention is to provide a descaling system attaining the full soaking of descaling elements with water and the distinct observation of the soaking operation.
Further objects of the invention will be easily understood with reference to the description of the preferred embodimenzt and the appended drawings.
BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a schematic illustration of the major section of the descaling system of this invention for condenser cooling tubes;
FIG. 2 schematically shows the other minor section of said descaling system on a somewhat smaller scale than in FIG. 1;
FIG. 3 is a schematic oblique view of a 3-port switching valve used with the descaling system of FIG. 1; and
FIGS. 4 to 6 present part of the descaling system of FIG. 1 by way of illustrating its operation, showing the manner in which the movement of descaling elements is controlled, with the I-port switching valve indicated in cross section as in FIG. 1.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIG. 1, a condenser 10 comprises a plurality of cooling water tubes 11 communicating at both ends with water boxes 100, I012. One water box 10a is connected to one end of a feed pipe 12 constituting part of a cooling water circulation line. The other end of said feed pipe I2 (not shown) is dipped in, for example, sea water. The other water box I01) communicates with one end of a discharge pipe 13 constituting part of the cooling water circulation line. The other end of said discharge pipe is dipped in, for example, sea water.
The cooling water circulation line is provided inside with a circulation pump (not shown). The pump draws sea water, for example. as cooling water into the cooling tubes 11 of the condenser 10 through the feed pipe 12 and water box 10a. The cooling water carries out heat exchange and is transferred to the other water box 101) and then drawn out therefrom into the sea through the discharge pipe 13.
The circulation line of the above-mentioned arrangement is fitted with the later detailed descaling system. In FIG. 1, a tightly closed cylindrical vessel 14 is indicated in a larger size for better understanding than the condenser 10. A large number of descaling elements 15 consisting of water-absorptive sponge balls are received in the vessel 14 as later described. This vessel 14 concurrently soaks fresh descaling elements 15 with water and recovers and discharges used descaling elements. A cage member 16 is positioned in the vessel 14 substantially at a vertical midpoint. The upper peripheral edge of the cage 16 is fixed to the inner peripheral wall of the vessel 14. A pipe 17 having a fully large. diameter for passage of descaling elements 15 is inte- 3 grally fitted to the bottom of said cage member 16. The cylindrical vessel 14 is divided by the cage member-16 into two upper and lower chambers. The cooling water alone in the vessel 14 can freely pass through both upper and lower chambers due to numerous openings 16a being bored in the cage member 16. On the other hand, descaling elements 15 can not pass through both chambers due to the small diameter of said openings 16a of the cage member 16. In practice, the cage member 16 is formed of wire netting and the openings 16a represent the meshes of said netting.
A wire net 18 is stretched above the cage member 16 substantially in a horizontal direction. This wire net 18 extends up to the inner wall of the vessel 14. The point within the vessel 14 at which the wire net 18 is stretched is made lower than the prescribed height to which cooling water is filled in the vessel 14. The wire net 18 whose meshes are not large enough to allow the passage of the descaling elements 15 is submerged in water while the descaling elements 15 are being soaked with water, preventing said elements 15 from floating up to the water surface.
A peep window 19 is bored in the peripheral wall of the vessel 14 at almost as high a level as the wire net 18 so as to allow an operator to observe the condition of the interior of the vessel 14.
An evacuating device 20 (indicated in chain lines) is installed obliquely above the vessel 14. This evacuating device 20 communicates with a free space 22 provided in the upper portion of the vessel 14 through a pipe 21 so as to evacuate or deaerate the vessel 14 to a prescribed extent. The evacuating device 20 comprises an air ejector or vacuum pump 23 and deaeration valves 24, 25, and may sometimes be additionally fitted with a water mist operator or fitter.
A descaling element supply pipe 26 is provided on the outer peripheral wall of the vessel 14 between the wire net 18 and cage member 16, with the forward end 260 of the supply pipe 26 opened to the interior of the vessel 14. The rear end 26b of the supply pipe 26 is connected through an inlet valve 27 to an upstream circulation pipe 28 of descaling elements 15, which in turn communicates through a collector 29 with the discharge pipe 13 constituting part of the cooling water circulation line. Further, the descaling element circulation pipe 28 is provided inside with a circulation pump (not shown) forcefully to conduct descaling elements therethrough.
The descaling element supply pipe 26 is further connected to the outlet end 3111 of a descaling element holder 31 (FIG. 2) through a descaling element inlet valve 30. The holder 31 is stored with a prescribed quantity of fresh descaling elements 15 for replenishment. This replenishment is effected by selective operation of the inlet valve 30 under an operators manual control. The descaling element holder 31 is provided with an inlet port (not shown) through which descaling elements 15 are charged into the holder 31 up to its capacity.
The descaling element holder 31 is connected through a pipe 32 and valve 33 to an air supply source 34, which may consist of an air pump, though its concrete arrangement is not shown. The air supply source 34 introduces air into the descaling element holder 31 through the pipe 32, and, when the valve 30 is opened, forcefully sends forth descaling elements 15 from said holder 31. Where, as shown in FIG. 2, the descaling element holder 31 takes a vertical position and the outlet 4 end 31a of the descaling element holder 31 is directed downward, then descaling elements 15 may be discharged simply by gravitational fall. However, provision of the air supply source 34 enables the descaling elements 15 to be rapidly delivered to the supply line 26.
The upper outer peripheral wall of the vessel 14 is fitted with a level gauge 35 for measuring and indicating the water level in the vessel 14 and a manometer 36 for measuring pressure prevailing within the vessel 14. These instruments enable an operator to recognize the interior condition of the vessel 14 from readings thereon.
The pipe 17 fitted to the bottom end of the cage member 16 is connected to a 3-port switching valve 37, which comprises, as shown in FIG. 3, a valve casing 41 bored with three ports 38, 39, 40, a valve rod 42, and a cylindrical valve element 43 rotated by said valve rod 42. As apparent from FIG. 3, the peripheral wall of the valve element 43 is provided with a notch 44. The notch 44 and the remainig portion 43a of the peripheral wall of the valve element 43 cooperate selectively to open or close the three ports 38 to 40 bored in the valve casing 41 surrounding the valve element 43 according to the rotation of the valve rod 42. The notch 44 itself acts as a passageway for descaling elements. The pipe 17 fitted to the bottom end of the cage member 16 communicates with the port 38.
A descaling element feed pipe 45, one end 450 of which communicates with the port 39, is horizontally disposed in the lower portion of the vessel 14.'The other end 4512 of said feed pipe 45 is exposed to the outside of the vessel 14 and is connected to a downstream pipe 47 of descaling elements through an outlet valve 46. Said downstream pipe 47 communicates with the feed pipe 12 constituting part of the cooling water circulation line.
A discharge pipe 48, one end 480 of which communicates with the port 40, is disposed horizontally in the lower portion of the vessel 14 on the opposite side of the 3-port switching valve 37 to the above-mentioned feed pipe 45. The other end 48b of the discharge pipe 48 is exposed to the outside of the vessel 14 and connected to a pipe 50 through a discharge valve 49. The rear end of the pipe 50 is bent downward. The peripheral wall of that portion of the discharge pipe 48 which is received in the vessel 14 is bored with a pair of slitshaped openings 51, through which the cooling water of the vessel 14 flows into the discharge pipe 48. The number and size of said openings 51 are not limited to those of this embodiment.
There will now be described the manner in which the descaling system of this invention arranged as described above cleans the interior of the cooling tubes of a condenser.
When the inlet valve 30 is opened, numerous descaling elements consisting of sponge balls are carried along with streams of air supplied by the air supply source 34 from the descaling element holder 31 into the vessel 14 through the forward end 26a of the supply pipe 26 to be received in the cage member 16. At this time, the 3-port switching valve 37 takes the position of FIG. 4 with the port 38 closed, preventing descaling elements from falling downward through the pipe 17.
When the inlet valve 27 is opened, cooling water is filled in the vessel 14 to a level shown in FIG. 1, after passing through the circulation line and supply pipe 26, while an operator observes readings on the level gauge 35. Since the wire net 18 is submerged in the cooling water, descaling elements are held down by the wire net 18 and can not float up to the water surface. At this time, the valves 27, 30 are closed and the evacuating device 20 is actuated to evacuate the interior of the vessel 14 to a prescribed level. Attainment of a prescribed degree of vacuity can be recognized from readings on the manometer 36. When the vacuity of the vessel 14 sufficiently increases, descaling elements 15 are fully soaked with cooling water. Though, at this time, the level of cooling water slightly falls, the wire net 18 is previously so positioned as to be always submerged in the water, thereby preventing the cooling water level from being brought down to said wire net 18. The line 21 of the evacuating device 20 communicating with the space 22 allowed in the upper portion of the vessel 14 enables the evacuating device 20 to exert its action over the free surface of the cooling water, attaining rapid deaeration. As the result, the evacuating device 20 is little soaked with unnecessary cooling water mist, eliminating the provision of any filter or mist separator.
After descaling elements are fully soaked, the evacu ating device 20 is stopped, and the inlet valve 27 and outlet valve 46 is opened. Also the 3-port switching valve 37 takes the position as shown in FIGS. 1 and 5, namely, the position in which the port 40 alone is closed and the ports 38, 39 communicate with each other. At this time, the discharge valve 49 still remains closed. When a circulation pump (not shown) is put into operation, descaling elements are conducted, as shown in FIG. 5, from the vessel 14 to the notch 44 constituting a valve chamber through the pipe 17 and port 38 and then to the feed pipe 45 through the port 39 and finally to the00062pipe 12 through the downstream circulation pipe 47. After passing through the feed pipe 12 and the water box 100, descaling elements 15 are scattered into a plurality of cooling tubes 11 and delivered to the water box 1012, while scraping off foreign matter deposited on the inner walls of the cooling 1 pipes and then to the discharge pipe 13. Descaling elements 15 running down through the discharge pipe 13 together with cooling water are trapped by the collector 29 and then brought into the downstream circulation pipe 28, and finally into the vessel 14 through the supply pipe 26. After completing the above-mentioned circulation cycle, descaling elements 15 are again delivered to the cooling water circulation line.
The repeated passage of descaling elements 15 through the cooling tubes 11 of the condenser 10 for a prescribed length of time effects the desired descaling operation. Where it is desired to replenish fresh descaling elements 15 during circulation, the inlet valve 30 (FIG. 2) is opened to supply a required quantity of fresh descaling elements 15 from the holder 31 to the circulation line, thereby eliminating the undesirable stoppage of the circulation of descaling elements 15 at the time of replenishment.
Where used descaling elements 15 are recovered from the circulation line upon completion of the descaling operation, it is advised to lock the 3-port switching valve 37 to the position of HG. 4. Since the port 38 is closed, used descaling elements 15 are all collected in the cage member 16 under an operators observation through the peep window 19.
On the other hand, cooling water flowing into the vessel 14 through the supply pipe 26 together with descaling elements 15 freely passes downward through the numerous openings 16a of the cage member 16 into the discharge pipe 48 through the paired slit like openings 51 bored in the peripheral wall of the discharge pipe 48. The cooling watered arrows of FIG. 4 passes through the port 40 and the notch or valve chamber 44 of the valve element 43 and is delivered to the feed pipe 45 through the port 39, because the discharge valve 49 is closed. Thereafter, the cooling water runs through the outlet valve 46 now left open to the downstream circulation pipe 47.
Used descaling elements 15 which have all been collected in the cage member 16 by the above-mentioned recovering operation are now subjected to the discharging operation. This discharging operation is carried out in the following way. The inlet valve 27 is closed to stop the influx of cooling water into the vessel 14.
The water level within the vessel 14 falls to the position of the slits 51, with the descaling elements 15 alone left in the cage member 16. The outlet valve 46 is closed and the discharge valve 49 is opened, while the 3-part switching valve 37 has its position changed from FIG. 4 to FIG. 6. Accordingly, the port 39 is closed, and the port 38 is opened for communication with the port 40, enabling the descaling elements collected in the cage member 16 to pass through the pipe 17 and port 38 into the notch or valve chamber 44, then to the discharge pipe 48 through the port 40 and finally to be discharged to the outside through the discharge valve 49 now open and the pipe 50. Whether all the used descaling elements 15 have been removed from the cage member 16 can be recognized by an operators observation of the interior of the vessel 14 through the peep window 19.
Though not shown, the valve rod 42 of the 3-port switching valve 37 extends out of the vessel 14 to be manually rotated by an operator. The 3-port switching valve 37 used in this embodiment may be designed with a different arrangement from FIG. 3. Namely. said valve 37 may consist of a ball type in which the valve element 43 is made into a ball form, instead of the cylindrical type of this embodiment. As used herein, the 3-port switching valve 37 includes a cock.
The rotation of the 3-port switching valve 37 and the operation of the other valves such as the inlet valve 27, outlet valve 46, discharge valve 49 and inlet valve 30 are manually effected by an operator. However, it is possible remotely to control their operation.
Application of the above-mentioned 3-port switching valve 37 enables all the operations of soaking descaling elements 15 with water and recovering and discharging them to be carried out in a single unitary vessel 14, eliminating the necessity of providing a separate reservoir and associated piping and in consequence attaining the simplification of the arrangement of the descaling system, the reduction of manufacturing cost and high operating efficiency.
What we claim is: v
1. A descaling system for condenser cooling tubes de signed to conduct a large number of descaling elements through the cooling tubes from a cooling water feed line and draw out used descaling elements from the discharge line of cooling water, characterized in that said descaling system comprises a tightly closed vessel; a cage member whose outer peripheral wall is fixed to the inner peripheral wall of the vessel and whose bottom end is fitted with a pipe for passage of descaling elements, and which acts as a receptacle for the descaling elements and allows the free passage of cooling water alone; a descaling element supply pipe whose forward end communicates with the vessel and whose rear end communicates with a cooling water discharge line; evacuating means for deaerating the vessel; a 3-port switching valve connected to the pipe fitted to the bottom end of the cage member; a feed pipe, one end of which is connected to the 3-port switching valve for communication with the pipe of the cage member by selective operation of said valve and the other end of which communicates with a cooling water feed line; and a discharge pipe for drawing out descaling elements from the vessel, one end of said discharge pipe being connected to the 3-port switching valve for communication with the pipe of the cage member by selective operation of said valve and the other end of said discharge pipe extending outside of the vessel, and said discharge pipe further having its peripheral wall bored with openings for conducting the cooling water of the vessel into said pipe.
2. A descaling system according to claim 1, which further comprises a descaling element holder whose inlet end communicates with the supply pipe through a second valve, and which is alwaysfilled with a prescribed quantity of descaling elements and delivers fresh descaling elements to the supply pipe according to the selective operation of said second valve.
3. A descaling system according to claim 2, which further comprises air supply means for introducing air into the descaling element holder, thereby forcefully to deliver the descaling elements received in said holder to the supply pipe.
4. A descaling system according to claim 1, which further comprises a wire net disposed above the cage member substantially in a horizontal direction, said wire net being submerged in the cooling water when descaling elements are soaked therewith, thereby preventing the soaked descaling elements from floating up to the free surface of the cooling water.
5. A descaling system according to claim 1, wherein the vessel has its peripheral wall bored with a peep window for an operator to observe the interior of the ves-

Claims (5)

1. A descaling system for condenser cooling tubes designed to conduct a large number of descaling elements through the cooling tubes from a cooling water feed line and draw out used descaling elements from the discharge line of cooling water, characterized in that said descaling system comprises a tightly closed vessel; a cage member whose outer peripheral wall is fixed to the inner peripheral wall of the vessel and whose bottom end is fitted with a pipe for passage of descaling elements, and which acts as a receptacle for the descaling elements and allows the free passage of cooling water alone; a descaling element supply pipe whose forward end communicates with the vessel and whose rear end communicates with a cooling water discharge line; evacuating means for deaerating the vessel; a 3-port switching valve connected to the pipe fitted to the bottom end of the cage member; a feed pipe, one end of which is connected to the 3-port switching valve for communication with the pipe of the cage member by selective operation of said valve and the other end of which communicates with a cooling water feed line; and a discharge pipe for drawing out descaling elements from the vessel, one end of said discharge pipe being connected to the 3port switching valve for communication with the pipe of the cage member by selective operation of said valve and the other end of said discharge pipe extending outside of the vessel, and said discharge pipe further having its peripheral wall bored with openings for conducting the cooling water of the vessel into said pipe.
2. A descaling system according to claim 1, which further comprises a descaling element holder whose inlet end communicates with the supply pipe through a second valve, and which is always filled with a prescribed quantity of descaling elements and delivers fresh descaling elements to the supply pipe according to the selective operation of said second valve.
3. A descaling system according to claim 2, which further comprises air supply means for introducing air into the descaling element holder, thereby forcefully to deliver the descaling elements received in said holder to the supply pipe.
4. A descaling system according to claim 1, which further comprises a wire net disposed above the cage member substantially in a horizontal direction, said wire net being submerged in the cooling water when descaling elements are soaked therewith, thereby preventing the soaked descaling elements from floating up to the free surface of the cooling water.
5. A descaling system according to claim 1, wherein the vessel has its peripheral wall bored with a peep window for an operator to observe the interior of the vessel.
US517614A 1973-11-08 1974-10-24 Descaling system for condenser cooling tubes Expired - Lifetime US3919732A (en)

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US4051839A (en) * 1976-02-27 1977-10-04 Cory Food Services, Inc. Lime breakup means
US4079782A (en) * 1974-11-14 1978-03-21 The Leslie Company Self cleaning heat exchanger circuit
US4135574A (en) * 1976-03-26 1979-01-23 Ludwig Taprogge, Reinigungsanlagen Fur Rohren-Warmeaustauscher Device for recovering cleaning elements from a heat-exchanger stream
US4208220A (en) * 1978-05-15 1980-06-17 The Research Corporation Of The University Of Hawaii Method and apparatus for cleaning heat exchanger tubes mounted transversely to vertical flow of seawater
US4304295A (en) * 1979-04-23 1981-12-08 Hitachi, Ltd. Cleaning body intercepting apparatus for tube-type heat-exchanger
US4420038A (en) * 1980-06-30 1983-12-13 Hitachi, Ltd. Cleaning system for heat conductive conduits of a heat exchanger
US4447925A (en) * 1981-04-01 1984-05-15 Firma Alfred Gutmann Gmbh And Co. Sluice apparatus for cleaning the interior of pipes
US4620589A (en) * 1984-01-31 1986-11-04 Josef Koller Device for cleaning the pipes of pipe heat-exchangers
US4694892A (en) * 1985-05-03 1987-09-22 Gea Energiesystemtechnik Gmbh & Co. Apparatus for retrieving spherically shaped cleansing bodies
US4696318A (en) * 1985-11-12 1987-09-29 Slickbar Products Corp. Washing methods and apparatus for heat exchanger tube cleaning plugs
US4865121A (en) * 1986-08-29 1989-09-12 Ben Dosa Chaim Cleaning system for fluid-conducting tubing
US4984629A (en) * 1989-09-13 1991-01-15 Water Services Of America, Inc. Ball collector and filling apparatus for circulating ball cleaning system
US5266169A (en) * 1992-06-03 1993-11-30 Praxair Technology, Inc. Apparatus for separating and recycling cleaning particles for cleaning furnace tubes
US5388636A (en) * 1993-11-18 1995-02-14 C.Q.M. Ltd. System for cleaning the inside of tubing
WO1995014205A1 (en) * 1993-11-18 1995-05-26 C.Q.M. Ltd. Cleaning system for cleaning the inside of fluid conducting tubing and associated apparatus
US5433229A (en) * 1994-04-06 1995-07-18 Slickbar Products Corp. System for recovering and washing tube cleaning plugs
US5447193A (en) * 1993-11-18 1995-09-05 C.Q.M. Ltd. Apparatus for injecting a volume of liquid into a liquid-conducting system
US5482111A (en) * 1993-06-22 1996-01-09 Technos Et Compagnie Installations for cleaning tubes by circulating spongy balls, in particular improvements relating to impregnating the balls with water
US5680665A (en) * 1996-04-16 1997-10-28 Water Services Of America, Inc. Ball conditioning, sorting and collecting apparatus for circulating ball cleaning system
US5926892A (en) * 1996-09-10 1999-07-27 Kyokuto Rubber Co., Ltd. Heat exchanger washing apparatus and heat exchanger washing method
US6530427B1 (en) * 1999-11-04 2003-03-11 E. Beaudrey Et Cie Control installation for solid cleaning members circulating in a heat exchanger
US20100236757A1 (en) * 2009-03-19 2010-09-23 Chen-Fa Chou Cleaning system for a water-cooled heat exchanger
US20160084594A1 (en) * 2014-03-05 2016-03-24 Pingsuo JIANG Rubber ball cleaning multipoint centralized ball serving system for condenser
US20180372433A1 (en) * 2017-06-23 2018-12-27 Eugene B Heat exchanger cleaning installation and associated system

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Cited By (29)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4079782A (en) * 1974-11-14 1978-03-21 The Leslie Company Self cleaning heat exchanger circuit
US4051839A (en) * 1976-02-27 1977-10-04 Cory Food Services, Inc. Lime breakup means
US4135574A (en) * 1976-03-26 1979-01-23 Ludwig Taprogge, Reinigungsanlagen Fur Rohren-Warmeaustauscher Device for recovering cleaning elements from a heat-exchanger stream
US4208220A (en) * 1978-05-15 1980-06-17 The Research Corporation Of The University Of Hawaii Method and apparatus for cleaning heat exchanger tubes mounted transversely to vertical flow of seawater
US4304295A (en) * 1979-04-23 1981-12-08 Hitachi, Ltd. Cleaning body intercepting apparatus for tube-type heat-exchanger
US4420038A (en) * 1980-06-30 1983-12-13 Hitachi, Ltd. Cleaning system for heat conductive conduits of a heat exchanger
US4447925A (en) * 1981-04-01 1984-05-15 Firma Alfred Gutmann Gmbh And Co. Sluice apparatus for cleaning the interior of pipes
US4620589A (en) * 1984-01-31 1986-11-04 Josef Koller Device for cleaning the pipes of pipe heat-exchangers
US4694892A (en) * 1985-05-03 1987-09-22 Gea Energiesystemtechnik Gmbh & Co. Apparatus for retrieving spherically shaped cleansing bodies
US4696318A (en) * 1985-11-12 1987-09-29 Slickbar Products Corp. Washing methods and apparatus for heat exchanger tube cleaning plugs
US4865121A (en) * 1986-08-29 1989-09-12 Ben Dosa Chaim Cleaning system for fluid-conducting tubing
EP0417332A1 (en) * 1986-08-29 1991-03-20 Ball Technic Israel Ltd. Cleaning system for fluidconducting tubing
AU620438B2 (en) * 1986-08-29 1992-02-20 Chaim Ben-Dosa Cleaning system for fluid-conducting tubing
US4984629A (en) * 1989-09-13 1991-01-15 Water Services Of America, Inc. Ball collector and filling apparatus for circulating ball cleaning system
US5266169A (en) * 1992-06-03 1993-11-30 Praxair Technology, Inc. Apparatus for separating and recycling cleaning particles for cleaning furnace tubes
US5482111A (en) * 1993-06-22 1996-01-09 Technos Et Compagnie Installations for cleaning tubes by circulating spongy balls, in particular improvements relating to impregnating the balls with water
AU692203B2 (en) * 1993-11-18 1998-06-04 C. Q. M. Ltd. Cleaning system for cleaning the inside of fluid conducting tubing and associated apparatus
US5447193A (en) * 1993-11-18 1995-09-05 C.Q.M. Ltd. Apparatus for injecting a volume of liquid into a liquid-conducting system
WO1995014205A1 (en) * 1993-11-18 1995-05-26 C.Q.M. Ltd. Cleaning system for cleaning the inside of fluid conducting tubing and associated apparatus
US5388636A (en) * 1993-11-18 1995-02-14 C.Q.M. Ltd. System for cleaning the inside of tubing
US5433229A (en) * 1994-04-06 1995-07-18 Slickbar Products Corp. System for recovering and washing tube cleaning plugs
US5680665A (en) * 1996-04-16 1997-10-28 Water Services Of America, Inc. Ball conditioning, sorting and collecting apparatus for circulating ball cleaning system
US5926892A (en) * 1996-09-10 1999-07-27 Kyokuto Rubber Co., Ltd. Heat exchanger washing apparatus and heat exchanger washing method
US6530427B1 (en) * 1999-11-04 2003-03-11 E. Beaudrey Et Cie Control installation for solid cleaning members circulating in a heat exchanger
US20100236757A1 (en) * 2009-03-19 2010-09-23 Chen-Fa Chou Cleaning system for a water-cooled heat exchanger
US20160084594A1 (en) * 2014-03-05 2016-03-24 Pingsuo JIANG Rubber ball cleaning multipoint centralized ball serving system for condenser
US9791222B2 (en) * 2014-03-05 2017-10-17 Shaanxi Hand Energy Conservation And Environmental Protection Technology Co., Ltd Rubber ball cleaning multipoint centralized ball serving system for condenser
US20180372433A1 (en) * 2017-06-23 2018-12-27 Eugene B Heat exchanger cleaning installation and associated system
US10816284B2 (en) * 2017-06-23 2020-10-27 Eugene B Cleaning installation for cleaning a heat exchanger

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DE2451909B2 (en) 1978-12-07
DE2451909C3 (en) 1979-08-23

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