Patent Number: 047626682
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the drawings, shown in FIGS. 1 and 2 is an ultrasonic cleaning device, generally indicated by the numeral 10, mounted around a pipe 12 of a fluid system for cleaning a venturi flow nozzle 14 mounted within the pipe. The cleaning device includes a plate 15 which is split into two sections 16 and 17 for ease of installation around the pipe 12. The plate sections 16 and 17 are fastened together and secured to the pipe by suitable bracket or clamp means 18. Mounted on the edges of the plate 10 are a plurality of brackets 19 adapted to be attached to suitable support structure (not shown) to further hold the cleaning device in position. A plurality of transducer assemblies 22 are mounted on plate 10 by a suitable means such as brackets 23 which may be bolted to the plate. The transducer assemblies generate and transmit sound waves. In the embodiment shown in FIG. 1, four such transducer assemblies 22 are shown spaced 90.degree. from each other around the circumference of pipe 12. A suitable transducer assembly is manufactured by Swen Sonic Corporation and is designated as a Sonic Horn Assembly, 10 kHz, No. 101032. As best shown in FIG. 3, each transducer assembly 22 includes a cover 24 having mounting brackets 23 thereon. The cover 24 encloses a transducer 25 for generating sound waves and preferably is comprised of a series of U-shaped nickel laminations assembled into a single unit with electrical coils surrounding each leg of the U-shaped configuration. The cover functions to deaden the sound waves. Attached to the bottom of the U-shaped configuration by suitable means such as silver brazing, is a horn 26 preferably constructed of solid stainless steel. The horn functions to concentrate the sound waves generated by the transducer and transmit them to an extension rod 27 formed of a suitable material such as stainless steel. In the embodiment shown in FIG. 3, the horn is shown with straight sides tapering inwardly from the transducer to the rod 27. The horn, however, may have other configurations such as stepped sides narrowing to the rod or be formed in the general shape of a parabolic curve. The rod 27 preferably is threadably attached to the horn 26 by means of a threaded extension or portion 28 formed at one end of the rod. As most clearly shown in FIGS. 6-9, the pipe 12 is provided with an opening or hole 30 to accommodate the rod 27 of each transducer assembly employed. A guiding and sealing assembly, generally indicated by the numeral 32, is provided for each rod and is rigidly secured by suitable means such as welds 33 to the pipe 12 around each pipe opening 30. Rather than being supported by plate 15, each transducer assembly 22 may be supported solely by a guiding and sealing assembly 32. In the embodiment shown in FIG. 6, the guiding and sealing assembly includes a lower circular base member or housing 35 having an upper circular cover member 36 threadably attached thereto. Base member 35 is provided with a central opening 37 therethrough to accommodate rod 27. Opening 37 contains an enlarged portion 38 at its upper end to accommodate one or more packing rings 39 which provide a seal around rod 27. A lower retainer ring 40 is provided in enlarged portion 38 underneath the packing rings while an upper retainer ring 41 is provided above the packing rings 39 in the enlarged portion 38 of central opening 37. Upper retainer ring 41 may be secured to base member 35 by suitable means such as bolts 42. Openings or holes 43 are formed in the top of the cover member 36 to provide an outlet for removing any fluid which may leak past the packing material into the space between cover member 36 and retainer ring 41. Cover member 36 further is provided with a central opening 44 to receive the upper end of rod 27. In the embodiment shown in FIG. 6, the rod 27 is provided at its lower end with a threaded portion or extension 46 which is threadably connected to the venturi flow nozzle 14 at the throat 51 of the nozzle. Rod 27 has a circular lip or ring 47 spaced from the end which is to be connected to the horn 26 whereby the lip 47 provides a safety feature stop for rod 27 by abutting against the upper inner surface of cover member 36. Thus, in case rod 27 should become disconnected at its lower end from nozzle 14, lip 47 would function as a safety stop to prevent the rod from being blown out. The nozzle 14 may be provided with a flattened portion 52 at the point where the bottom end of rod 27 contacts the nozzle. As further shown in FIGS. 4 and 6, the walls of nozzle 14 are provided with a plurality of openings 53 to permit fluid passing through the nozzle to enter the space between the inner wall of pipe 12 and the outer wall of nozzle 14 to equalize the fluid pressure inside and outside of the nozzle. To install the rod 27, it is inserted through the central opening 37 in base member 35 and threaded portion 46 is threaded into nozzle 14. Cover member 36 is then attached to base member 34 with threaded portion 28 extending therethrough and the horn 26 is then threaded onto threaded portion 28 of rod 27. Additional embodiments of the guiding and sealing assembly 32 are shown in FIGS. 7-9. Since many of the parts in these additional embodiments are the same as the parts described in connection with the embodiment of FIG. 6, similar parts in the other embodiments will be designated by the same numerals used in connection with the embodiment shown in FIG. 6. In the embodiment shown in FIG. 7, the rod 27 is threaded into nozzle 14 at its bottom end and a bellville spring 56 is mounted around the upper portion of the rod positioned between lip 47 and the upper inner surface of cover member 36. Accordingly, spring 56 biases the rod downwardly towards the nozzle 14. In addition, a bellows 57 surrounds rod 27 at its upper end. Bellows 57 is attached at its upper end to lip 47 and at its lower end to the opening in retainer ring 41. A metal O-ring 58 is provided between retainer ring 41 and base member 35. The bellows 57 and the O-ring 58 serve as seals to prevent any fluid from pipe 12 entering into the compartment inside cover member 36. The remaining parts of the embodiment of FIG. 7 function in the same manner as that set forth in connection with the embodiment of FIG. 6. In the embodiment shown in FIG. 8, the packing rings 39 are located in grooves 60 formed around the periphery of the central opening in cover member 36 to provide a seal against fluid from pipe 12 leaking to the outside. Moreover, in the embodiment of FIG. 8 a pair of bellville springs 56 are employed to bias the rod 27 towards the nozzle 14. In addition, the bottom of the rod 27 forcibly contacts the flattened portion 52 of nozzle 14 rather than being threadably connected thereto. Lip 47 functions as a safety stop in the same manner as that described in connection with the embodiment of FIG. 6. Metal O-ring 58 in this embodiment is positioned directly between base member 35 and cover member 36. Moreover, in this embodiment the bolts 42 directly connect cover member 36 with base member 35. In the embodiment shown in FIG. 9, cover member 36 is in the form of a flat plate secured around rod 27 by bolts 42 which thread therethrough as well being threaded through retainer ring 41 into base member 35 to secure the assembly together. In this embodiment, retainer rings 40 are positioned both above and below the packing rings 39. Like the embodiment of FIG. 8, the embodiment of FIG. 9 also has rod 27 forcibly contacting flattened portion 52 of nozzle 14 rather than being threadably connected thereto. Rod 27 is biased downwardly towards nozzle 14 by bellville spring 56 mounted around the rod between lip 47 and cover member 36. Lip 47 functions as a safety stop in the same manner as that described in connection with the embodiment of FIG. 6. Additional embodiments of an ultrasonic cleaning device according to the present invention are shown in FIGS. 10 and 11. Since many of the parts in these additional embodiments are the same as parts described in connection with the embodiments of FIGS. 6-9, similar parts in these additional embodiments will be designated by the same numerals used in connection with the emodiment shown in FIGS. 6-9. In the embodiment of the device shown in FIG. 10, the transducer 25 is inserted through the opening 30 in pipe 12 to the point where the inner end of the transducer is in contact with the nozzle 14 at the throat 51 thereof. The inner end of the transducer may be provided with a threaded portion or screw 70 which is threadably engaged with the nozzle to securely connect the transducer thereto at flattened portion 52 on the outside of the nozzle. The other outer end of the transducer is provided with an extension or rod 72 which is engaged by a hold down or compression spring 74 positioned in a central opening 75 in the inner end of a suitable fitting 76 whereby the spring is compressed between the outer end of opening 75 and the outer end of transducer 25. The spring 74 functions to bias the transducer towards the nozzle. Fitting 76 may be a Conax fitting having a central passageway 77 therethrough to receive suitable electrical connections 62 leading from any suitable power source to the transducer. The inner end portion 78 of fitting 76 is threaded and tapers outwardly from the inner end to the main body of the fitting. The outer portion of pipe opening 30 is similarly threaded and tapered outwardly to be threadably engaged by the threaded end portion 78 of the fitting. Accordingly, the threaded end portion 78 of fitting 76 seals the pipe opening 30 to prevent any fluid from leaking out through opening 30. The fitting 76, including its associated portions, and spring 74 constitute a mounting and sealing assembly 80 for sealing the pipe opening and for biasing the transducer towards the nozzle. The embodiment of the device shown in FIG. 11 is similar to the embodiment shown in FIG. 10 but additionally includes a base member 82 having an outwardly tapered threaded central opening 83 therein for threadably engaging tapered end portion 78 of the fitting 76. Base member 82 is fixedly secured to pipe 12 by means of bolts 84. In this embodiment, the inner end portion of fitting 76 is not threaded but is tapered to be snugly received within the outwardly tapered upper portion of pipe opening 30. Although not shown in the drawings, in both embodiments of FIGS. 10 and 11, the threaded portions 70 at the inner end of the transducer 25 may be eliminated and the transducers biased against the nozzle 14 at flattened portion 52 by the spring 74 to maintain the transducer in position. In that case, it is necessary that the outer ends of the transducers 25 extend a short distance into the inner end of pipe openings 30 to ensure that the transducer is maintained in its proper position. In the embodiment whereby the transducers do include threaded portion 70, however, it is not necessary that the transducer extend into the inner end of the pipe opening 30. Moreover, as in the case with the embodiments of FIGS. 6-9, a plurality of transducers may be employed in connection with each nozzle. In operation of the cleaning device of the present invention, the cleaning device may be mounted to pipe 12 and venturi nozzle 14 as shown in FIG. 1 or each transducer assembly 22 may be supported solely by each guiding and sealing assembly 32. Power is supplied to the transducers by any suitable source through electrical connections 62. During use, an automatic timer may be employed to actuate the transducers of the cleaning device as desired. The use of sound waves to prevent fouling in a venturi flow nozzle by preventing deposits from building up is extremely effective. The sound waves create ultrasonic cavitation which scrubs the surface of the inside of the nozzle by means of countless, minute, cavity implosions created in the fluid flowing therethrough. These cavities are not air bubbles which rise to the surface, but rather are tiny voids created and collapsed with the passage of each sound pressure wave. The energy released as each tiny cavity collapses against the surface, results in a powerful, thorough cleaning action which leaves the surface itself completely intact and clean. The ultrasonic cavitation is produced by generating mechanical vibrations in the transducer elements which then transmit the vibrations as sound waves to the horn which in turn concentrates the sound waves to the rod for effective transmission directly to the venturi flow nozzle. The present invention is useful in many different industries such as the nuclear power industry and the chemical industry. For example, as shown in FIG. 5, the cleaning device 10 may be installed in connection with a flow venturi nozzle located in the main feedwater pipe 64 of a pressurized water nuclear powered electrical generating plant between the steam generator 65 and the main feedwater control valve 66. It is apparent from the foregoing that many advantageous features are provided by the present invention. Cleaning of the venturi flow nozzles can be done on line and does not require plant shutdown and pipe drainage. The cleaning can be done automatically and does not require manual operation such as that required with jet spraying. The components of the cleaning device are extremely durable and require little if any replacement or spare parts and are essentially maintenance free. In addition, the device is relatively inexpensive when compared to other alternatives, as well as being easy to install. Numerous alterations and modifications of the structure herein disclosed will suggest themselves to those skilled in the art. It is to be understood, however, that the present disclosure relates to the preferred embodiments of the invention which are for purposes of illustration only and are not to be construed as a limitation of the invention. All such modifications which do not depart from the spirit of the invention are intended to be included within the scope of the appended claims.