瑞士专利CH711202A2 A method of in-situ sealing fluid-cooled channels for a generator.

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专利摘要:
What is provided is a method of in situ sealing fluid cooled channels (600) for a generator. The cooled by fluid or liquid channels (600) are arranged outside a stator of the generator and substantially outside of stator bars. The method includes: removing cooling fluid from the fluid cooled channels and drying inner surfaces of the fluid cooled channels. An insertion step introduces a borescope and sealant applicator (513) through an opening in one of the fluid cooled channels (600). A locating step locates a solder joint (602) in the fluid cooled channel (600), and a positioning step positions the borescope and sealant applicator (513) near the solder joint (602). An attachment step applies a sealant to the interior of the fluid cooled channel in the solder joint. A viewing step may be used to view the solder joint (602) by means of the borescope to confirm that the attachment step was successful.
公开号:CH711202A2
申请号:CH00720/16
申请日:2016-06-06
公开日:2016-12-15
发明作者:Oldham Lambert James；Lawrence Schilf Eric
申请人:Gen Electric；
IPC主号:

专利说明:

BACKGROUND DLR INVENTION
The method described herein generally relates to an in situ method for sealing fluid cooled channels. More particularly, the method relates to an in situ method for sealing solder joints in fluid cooled channels for a generator.
It is known that the windings of a stator of a dynamoelectric machine can be cooled more effectively by causing a dielectric fluid, such as deionized water, to pass through the windings inside the main insulation, e.g. to flow in hollow wires of a multi-wire line rail. In a stator winding of a dynamo-electric machine, there are usually more than one of these insulated conductor rails in each contactor formed in the multilayer stator core. Very often, two such rods are used, wherein the upper or radially inner rod in the slot undergoes greater ohmic losses and consequently a greater heat development than the lower or radially outer rod. It is further known that the temperature difference between the upper and lower rods can be reduced by the use of a double pass system in which the fluid flows throughout the length of the machine in an upper rod and then returns through the machine in a lower rod. Thus, the coldest fluid flows through the upper rod, which has greater heat losses, and, after the temperature of the fluid has been increased slightly, returns through a lower rod having lower heat losses. The temperature difference between the upper and lower bars is thus reduced.
In a dual-pass system, the fluid pressure drop in the narrow flow channels in a large machine can lead to large pumping losses. It is therefore also known to use a single-pass system in which the fluid supplied to a series loop electrically connects the upper and lower bars at one end of the machine, passes in parallel through upper and lower bars and on the series loop at the opposite end Machine is collected to be cooled again and returned to the circulation. However, since both upper and lower rods are supplied with fluid of the same temperature, the upper rod with this arrangement will have a higher average temperature than the lower rods. Thus, changes in the load on the machine as well as the cycles of startup and shutdown due to differential thermal expansion and contraction can cause relative movement in a slot between the bars resulting in abrasion and damage to the insulation.
In large generators, the windings are designed such that the terminal ends or phase lines of a group of connected coils forming a phase winding are arranged at circumferentially separate locations around the circumference at one end of the core. The compounds are designed such that an upper rod electrically connected to a lower rod of the same phase, which with a. Distance of a phase angle of about 120 degrees is arranged, can be connected by means of a designated as a connecting ring curved conductor. The terminal ring is also electrically connected via the lower leads with feedthroughs that pass through the housing. In the case of a three-phase generator, there are usually six such terminal rings, six lower lines and six feedthroughs located at one end of the generator. The connection rings and the lower lines carry considerable currents and must also be cooled. This can likewise be done by cooling internal channels by means of a fluid.
The waveguides outside the stator include the phase lines, series loops and connection rings. Usually, deionized water is passed through these hollow conductors / channels. During the manufacture of the phase lines, series loops and terminal rings, many solder joints are required to connect the different conductors / channels and fittings. These solder joints often contain phosphorus, and the combination of phosphorus with water can lead to corrosion and consequently leaks. Of course, leakage of water in or around a generator of a utility is undesirable. If the solder joints fail or leaks are discovered, an option is based on completely replacing all phase lines, series loops, and terminal rings. The disadvantage is that this approach is very costly and time consuming. There are new parts that can take many months to develop and produce, and the installation of these parts can take days or even a week.
BRIEF DESCRIPTION OF THE INVENTION
In one aspect of the present invention, a method of in situ sealing fluid cooled channels for a generator is provided. The cooled by fluid or liquid channels are located outside a stator of the generator and substantially outside of stator bars. The method includes discharging cooling fluid from the fluid cooled channels and drying inner surfaces of the fluid cooled channels. An introducer introduces a horoscope and sealant applicator through an opening in one of the fluid cooled channels. A locating step locates a solder joint in the fluid cooled channel, and a positioning step positions the borescope and sealant applicator in proximity to the solder joint. An attachment step applies a sealant to the interior of the fluid cooled channel in the solder joint. A viewing step may be used to view the solder joint via the borescope to confirm that the attachment step was successful.
In any embodiment of the method, it may be advantageous that the method additionally comprises: repeating the steps of locating, positioning, attaching, and viewing until a desired number of solder joints are sealed.
In any embodiment of the method, it may be advantageous for the sealant to be based on an epoxy resin or a powder paint, and the fluid-cooled channels include at least one terminal ring, a series loop or a phase line.
In any embodiment of the method, it may be advantageous that the drying step further comprises: creating a vacuum in the interior of the fluid cooled channel.
In any embodiment of the method, it may be advantageous that the locating step further comprises measuring the depth of insertion of the borescope and the sealant applicator and comparing the depth of predetermined locations of solder joints.
In any embodiment of the method, it may be advantageous that the locating step further comprises: scanning the interior of the fluid-cooled channel by means of an ultrasonic transducer; Monitoring an output of the ultrasonic transducer; and wherein a solder joint is identified by a predetermined signal from the ultrasonic transducer.
In another aspect of the present invention, a method of in situ sealing fluid cooled channels for a generator is provided. The cooled by fluid or liquid channels are located outside a stator of the generator and substantially outside of stator bars. The method includes: inserting a borescope and an epoxy applicator through an opening in one of the fluid cooled channels, locating a solder joint in the fluid cooled channel, and positioning the borescope and the epoxy applicator near the solder joint. An attachment step attaches an epoxy resin to the interior of the fluid cooled channel at the solder joint. The steps of locating, positioning and mounting are repeated until a desired number of solder joints are coated and sealed with epoxy resin. The process is performed on the generator in situ.
In any embodiment of the method, it may be advantageous for the fluid-cooled channels to have at least one of a terminal ring, a series loop and / or a phase line.
In any embodiment of the method, it may be advantageous that the method additionally comprises: drying inner surfaces of the fluid-cooled channels.
In any embodiment of the method, it may be advantageous that the method additionally comprises: removing cooling fluid from the fluid-cooled channels.
In any embodiment of the method, it may be advantageous that the drying step further comprises generating a vacuum in the interior of the fluid cooled channel.
In any embodiment of the method, it may be advantageous that the method additionally includes viewing the solder joint to confirm that the attaching step was successful.
In any embodiment of the method, it may be advantageous that the locating step further comprises measuring a depth of insertion of the borescope and the epoxy applicator in the fluid cooled channel and comparing the depth of predetermined locations of solder joints.
In any embodiment of the method, it may be advantageous that the locating step further comprises: scanning the interior of the fluid-cooled channel by means of an ultrasonic transducer; Monitoring an output of the ultrasonic transducer; and wherein a solder joint is identified by a predetermined signal from the ultrasonic transducer.
In yet another aspect of the present invention, a method of in situ sealing fluid cooled channels for a generator is provided. The cooled by fluid or liquid channels are located outside a stator of the generator and substantially outside the stator bars. The method includes the steps of: inserting a borescope and a powder coating applicator through an opening in one of the fluid cooled channels; Locating a solder joint in the fluid cooled channel; Positioning the borescope and powder coating applicator near the solder joint; and attaching a powder layer paint to an interior of the fluid cooled channel in the solder joint. A retry step is used to repeat the steps of locating, positioning, and attaching until a desired number of solder joints are coated and sealed with the powder layer finish. The process is performed on the generator in situ.
In any embodiment of the method, it may be advantageous for the fluid-cooled channels to include at least one of a terminal ring, a series loop, and / or a phase line.
In any embodiment of the method, it may be advantageous that the method additionally comprises: removing cooling fluid from the fluid-cooled channels; Drying inner surfaces of the fluid cooled channels, the drying comprising creating a vacuum in the interior of the fluid cooled channel.
In any embodiment of the method, it may be advantageous that the method additionally comprises: viewing the solder joint to confirm that the attachment step was successful.
In any embodiment of the method, it may be advantageous that the locating step further comprises measuring a depth of insertion of the borescope and the epoxy applicator in the liquid-cooled channel and comparing the depth of predetermined locations of solder joints.
In any embodiment of the method, it may be advantageous that the locating step further comprises: scanning the interior of the fluid-cooled channel by means of an ultrasonic transducer; Monitoring an output of the ultrasonic transducer; and wherein a solder joint is identified by a predetermined signal from the ultrasonic transducer.
BRIEF DESCRIPTION OF THE DRAWINGS
[0026]<Tb> FIG. Figure 1 illustrates a partially sectioned horizontal view of the lower portion of a generator stator in the end turn area taken at the location of the phase lines, row loops, and terminal rings.<Tb> FIG. FIG. 2 illustrates a partial end view of the fluid cooled channels shown in FIG. 1, but with only a single terminal ring and lower lead shown and the pad removed for clarity. FIG.<Tb> FIG. 3 <SEP> illustrates an enlarged cross section through a lower conduit.<Tb> FIG. 4 <SEP> illustrates a schematic view of fluid cooled channels located outside the stator of a generator.<Tb> FIG. 5 <SEP> illustrates a simplified schematic view of a borescope and sealant applicator system, according to one aspect of the present invention.<Tb> FIG. FIG. 6 illustrates an enlarged cross-sectional view of the borescope and sealant applicator inserted into a fluid cooled channel according to one aspect of the present invention. FIG.<Tb> FIG. Figure 7 shows in a flow chart a method of in situ sealing fluid cooled channels of a generator according to one aspect of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, one or more specific aspects / embodiments of the present invention will be described. In an effort to provide a concise description of these aspects / embodiments, not all features of an actual implementation may be described in the specification. It should be appreciated that in developing each such implementation, as in any engineering or design project, numerous application-specific decisions must be made in order to achieve specific objectives of the designers, e.g. Compatibility with machine-related, system-related and economic constraints that may vary from one implementation to another. Moreover, it should be understood that while such a development effort may be complex and time consuming, it nonetheless would be routine to the design, manufacture and manufacture of those skilled in the art having the benefit of this description.
When elements of various embodiments of the present invention are introduced, the articles "a," "the," "the," and "the" are also meant to include one or more of the elements. The terms "having," "containing," and "having" are to be understood as inclusive, meaning that there may be additional elements that differ from the listed elements. Examples of operating parameters and / or environmental conditions do not exclude other parameters / conditions of the described embodiments. In addition, it should be understood that references to "an embodiment" or "feature" of the present invention are not to be interpreted as excluding the existence of additional embodiments also incorporating the listed features.
Referring to Fig. 1 and the structure of a known generator, an outer gas-tight envelope 1 contains a supply of hydrogen gas, which is used to cool the rotor and portions of the stator 2 (not shown). The stator 2 has lamination plates which are held in place by an inner cage 3 and circumferential end flanges 4. The upper (or radially inner) tie rods 5 and the lower (or radially outer) tie rods 6 extend from slots in the stator 2 into the end turn region. The upper bars 5 and the lower bars 6, as they emerge from the slot, are folded along the circumference in opposite directions and formed with a complex curvature to lie along a frusto-conical surface. In most places, they are simply connected together in a series loop to form a complete turn. However, they terminate around the stator periphery at circumferentially spaced locations on extended phase lines 7, 8 where they are connected to terminal rings 19. In Fig. 1, the ends of an upper phase conductor bar 7 and a lower phase conductor bar 8 are shown, but it is understood that these bars are rotated from their actual positions in the plane of the drawing to show their continuity from the slots. It will be understood that for purposes of this description, the stator will stop at the interface between the upper / lower bars 5, 6 and the phase lines 7, 8. Accordingly, the phase lines 7, 8, the series loops 17, 18 and the terminal rings 19 for this description are all considered to be fluid cooled channels and located outside the stator. Fluid is defined as a liquid (eg, water or other liquid coolant) or as a gas.
The end turns of the winding are supported in a cage construction having circumferentially spaced, axially extending outer support members 9, intermediate spacers 10 and inner support members 11. The inner elements 11 and outer elements 9 hold the phase lines by means of a tension band, for example by a resin impregnated glass fiber strand 12 between them. The outer elements 9 are fixed to be axially slidably displaceable by means of slidingly displaceable connecting pieces 13 with respect to the end flange 4.
A cooling fluid is supplied under pressure from a source of cooling fluid (not shown) to an inlet manifold 14, which is a hollow round tube supported by suitable means, such as bracket 15. A similar exhaust manifold collects the spent cooling fluid at the opposite end of the engine, whereupon the cooling fluid is cooled and recirculated, and pumped back to the intake manifold 14 in an uninterrupted refrigeration cycle, following suitable processing dependent upon the type of cooling fluid. The cooling fluid is supplied to the anchor line rails by a plurality of circumferentially spaced insulating tubes, e.g. 16, the row loops 17, 18 or the phase lines 7, 8 fed. The tubing 16 may be based on a compact polytetrafluoroethylene or on a multi-layered structure of a resilient insulating material that is reinforced to prevent collapse. These serve to isolate the windings from ground while supplying fluid thereto. For example only, the tubes 16 may be made of polytetrafluoroethylene (PTFE) or Teflon® (registered trademark of E.I. du Pont de Nemours & Co).
The lower phase lines 8 is also supplied by means of a group of generally designated 18 fittings cooling fluid. The group of fittings 18 may also be referred to as a series loop. However, series loops do not occur at the phase terminals, but series loops occur where there is no phase connection. A part of the fluid also flows through the connecting lines 26, 27, which connect the upper and lower phase lines 7, 8 with the connecting rings 19. The connection rings 19 have inner cooling channels 19 a and are held in suitable brackets 20 which are fixed to the outer support members 9 to be axially slidably displaceable with the Endwindungsstützkäfig. The lower lines 21 are electrically and hydraulically connected to two corresponding connection rings 19. The lower conduits 21 extend downwardly to connect to the main conduits 22 leading to the bushings (not shown).
By first considering the series loop 17 for the top phase line 7, it will be appreciated that the hollow wires pass through an opening in the walls of a conductive housing 50 and are electrically connected thereto by a leak-tight connection, such as by soldering , The interior 50a of the housing 50 is in fluid communication with a pipe fitting 51 and a connecting pipe 52. The pipe 52 is connected to a T-fitting 53 which is fed by one of the insulated hoses 16. Fluid from the other outlet of the T-fitting 53 does not flow directly into a lower rod, but instead is hydraulically connected to the lead 26 by means of a pipe fitting 53a. Although fluid is being supplied in parallel to the upper phase line 7 and the lead 26 from the T-fitting 53, they are directly electrically connected via the copper tapes 54 brazed therebetween. The lower phase line 8 is supplied with fluid by means of a similar series loop 18. The connecting line 27 is electrically connected to the housing of the series loop 18 via the copper bands 55 as before, while the fluid, as can be seen from the drawing, bypasses bands 55 through a pipe 56 in order to enter the housing via a pipe connection 56.
Fig. 2 illustrates a partial end view of the fluid cooled channels shown in Fig. 1, but showing only one of the terminal rings and one of the lower leads, and the overlay is omitted for clarity. Fig. 2 shows for clarification of the description only a connection rings and a lower line, but it will be clear that for each of the other connection rings and each of the lower lines purely similar arrangement is used. It is also understood that phase lines connected by a terminal ring will have the same electrical phase. In addition, since the upper and lower phase lines connected by a terminal ring are circumferentially arranged at a phase angle of about 120 degrees, the drawing is broken in segments to show this. Most of the end turns themselves and the end turn support construction are omitted for clarity.
Each of the insulating tubes 16 supplies cooling fluid for a complete coil based on upper and lower rods. Most coils are fed through series loops, generally designated 24. However, at some circumferentially spaced locations, a set of special phase line fittings, generally designated 25, are used. The phase line connector group 25 includes the two series loops 17 and 18 (see FIG. 1). At these points lead the tubing 16 of the series loop 17 fluid. Each series loop 17 divides the fluid into two parts. One part flows through the upper phase line 7, while the other part flows through a connecting line 26, which is electrically connected to the phase line 7. The other end of the connecting line 26 is electrically and hydraulically connected to the connecting ring 19, which extends over an arc, to unite with another, similar connecting line 27. The upper end of the connecting line 27 is connected both electrically and hydraulically via the series loop 18 (see FIG. 1) to the circumferentially spaced-apart lower phase line 8.
At an intermediate point on the connecting ring 19, the upper side of a lower line 21 is electrically and hydraulically connected, with its lower end connected to connecting lines 22 and then to the high-voltage bushings. As indicated by the arrows in Fig. 2, the lower conduit 21 is cooled by fluid flowing back downwardly in the direction of passage and through two spaced passageways. Referring to FIG. 3, which illustrates a cross section taken through the lead 21, it is shown that it has a rectangular rail 28 with two cooling channels 29, 30 separated by a dividing web 31 and surrounded by the insulation 32. A portion of the land 31 which separates the passageways 29, 30 is capped near the lower end to allow fluid backflow as shown in FIG. At the upper end of the conduit 21, the fluid flow passages 29, 30 merge with the inner passage 19a in the connecting ring 19, while an obstruction 19b interrupts the passage 19a. By following the arrows in FIG. 2, it becomes apparent that the fluid flows through the connecting line 26, through a section of the connecting ring 19, through the lower line 21, through the remaining connecting ring 19 and from there through the connecting line 27. It is understood that the channels, conductors and any electrical conductors may have rectangular or circular cross-sections. The connecting pipe 21 may also have a square section with a round duct, a rectangular section with a single rectangular duct, or any suitable construction or section, as required by the particular application.
Fig. 4 illustrates a schematic view of fluid cooled channels located outside the stator of a generator. The fluid cooled channels may include the ferrules 401 (equivalent to the ferrule 19 in FIGS. 1-2), loop loops 402 (equivalent to the loop loops 17, 18), and phase wirings 403 (equivalent to the phase lines 7 and 8). These channels also contain many solder joints 411, 412 and 413 that connect different channel sections to each other or different connectors to the lines. The solder joints 411, 412, and 413 usually contain a phosphorus-containing bond solder alloy, and some of these phosphorus solder joints may over time: develop leaks. In accordance with aspects of the present invention, a method is provided to seal these solder joints 411, 412, and 413 by attaching a sealant to the solder joints opposite the interior of the fluid-filled channels. The sealant can, as described in more detail below, be an epoxy resin or a powder coating lacquer.
Figure 5 illustrates, in a simplified schematic view, a borescope and sealant applicator system according to one aspect of the present invention. Boroscope 500 may include a control panel 502 having a display 504 and an input device 506. The display 504 may be used to view the interior of the fluid cooled channels of the generator. The input device 506 may be in the form of a keyboard, a joystick, a touchpad or any other interface and control device. The input device may be utilized to control movement and operation of the flexible cable 508. The flexible cable 508 is adapted to be inserted into the fluid cooled channels and may be of any length required for the particular application. The flexible cable 508 includes an imaging lens or camera 510 and a sealant supply 512 and a sealant applicator 513. In addition, the flexible cable may include readable markings 514 that indicate the depth of insertion within the fluid-filled channels. By way of example only, the mark 514 may be printed marks indicating the depth in inches (as shown) or the mark may be in feet, meters, centimeters or any suitable scale of mass, as desired. The sealant may be withdrawn from a sealant supply 516, passed along the feed tube 512, and sprayed onto the solder joint by the spray head or applicator 513. The spray head 513 may be configured to spray or spray and rotate in a 360 degree pattern to cover the entire inner cylindrical shape of the solder joint.
The sealant may be an epoxy resin or a powder paint. In the case of an epoxy resin, an epoxy resin can be applied in two components for penetration and wetting, followed by a modification of the same higher viscosity epoxy resin fluid. Thus, an initial or first component of the low viscosity epoxy resin fluid is attached to the solder joint, and the attached resin can readily flow into the different solder joint interstices into which the epoxy is incorporated. The second component of the resin has a higher viscosity than the first component and is overlappingly attached to the first component to form a sealing barrier between the cooling fluid in the channel and the solder joint, and in particular the brazed alloy. The epoxy resin fluid may be of the type described in U.S. Patent No. 5,350,815, assigned to the assignee of the present invention, the description of which is incorporated by reference in its entirety. It is also to be understood that other types of resins may be utilized, for example, those identified in US Patent No. 5,605,590, assigned to the assignee of the present invention, the description of which is incorporated by reference in its entirety. Further, the epoxy resin may also be applied in a one-step or monolayer process. It is clear that other types of resins can be used instead. For example, other epoxy resin fluids can be those based on the diglycidyl ether of bisphenol A, such as Epon 826 and Epon 828 manufactured by Shell Chemical Co., and other similar resins manufactured by other manufacturers such as Dow Chemical Co. and Ciba Chemical Co . getting produced; Fluid bisphenol F diglycidyl ether epoxy resins such as Epon DPL-862 (Shell Chemical Co.) or Araldite GY 281 and Araldite GY 308 (Ciba Chemical Co.). It can also be used offshoots of any of the epoxy resins produced by other manufacturers, mixtures of epoxy resins or epoxy resins modified with reactive diluents. The epoxy resins also contain an additive to give the resins a special color, such as white, to make them highly visible to the copper during repair. As a satisfactory additive, a titanium oxide is used.
In a powder coating, a powdered agent is applied by electrostatically charging the powder material and spraying it on the part. The part is then heated, and the powder particles melt to. to form a continuous film. Powder for powder coating may be thermoplastic powders that re-melt upon heating or thermosetting powders that do not remelt upon reheating. In the case of thermosetting powders, a chemical crosslinking reaction is initiated during the curing process at the curing temperature which reduces a chemical reaction, giving the powder coating many of its desirable properties. UV-curable powder coatings applied in the same manner as conventional powder coatings offer some advantages, for example a shorter cure time and / or a lower cure temperature, and therefore come into consideration as a suitable alternative to conventional thermosetting powders. Examples of suitable powder resins include epoxy powder resins, silicone powders, and silicone-resin hybrid systems (silicone / epoxy resins and silicone / acrylic fabrics), the entire specification of which is incorporated herein by reference in U.S. Patent 6,778,053, assigned to the assignee of the present invention Examples are disclosed.
Figure 6 illustrates an enlarged cross-sectional view of the borescope and sealant applicator inserted into a fluid cooled channel, according to an aspect of the present invention. The fluid cooled channel 600 may include the terminal rings 19, series loops 17, 18, and / or the phase lines 7, 8, or any other channel or connector outside the stator and one or more solder joints 602. The solder joints 602 may be exposed to or susceptible to leaks, so the sealant will prevent further leakage. The borescope may include one or more springs 610, and the springs facilitate centering the flexible cable 508 as it moves along the fluid cooled channel 600. The interior of the fluid cooled channel 600 may be scanned by a scanner 620, such as a nondestructive transducer or an ultrasonic transducer. The scanner 620 is in communication with the control panel 502 or any other display device / interface device. As the scanner 620 slides along the inside of the candy, the signal will change as it traverses a solder joint 602. This signal change identifies the location of the solder joint 602. For example, if the signal is sliding along a compact copper tube, the signal will be relatively constant. However, if it transitions to a solder joint between two united copper sections, the braze alloy will cause the scanner to return a slightly different signal or waveform. The resulting change indicates the location of the solder joint. The distance from the scanner 620 to the applicator 513 is known so that after the solder joint is found, the flexible cable 508 can be retracted the appropriate distance and then activated to reach and seal the solder joint. The flexible cable can be retracted a little further so that the camera 510 can detect and verify the sealing process. By way of example only, the predetermined distance between the. Scanner 620 and applicator 513 are about three inches, however, any suitable spacing may be used as desired. In addition, the scanner 620 may be supported by an extendable arm 622 and a spring 624 and extended or retracted. The arm 622 and spring 624 may be configured to retract into the flexible cable 508 when not in use and extend radially outward to bias the sensor against the interior of the channel 600 when scanning is desired ,
Fig. 7 shows in a flow chart a method for in situ sealing fluid cooled channels of a generator, according to one aspect of the present invention. The method 700 seals fluid cooled channels 7, 8, 17, 18, 19 for a generator in place. The fluid-cooled channels 7, 8, 17, 18, 19 are arranged outside a stator of the generator and substantially outside of stator bars. The fluid cooled channels may include the phase lines 7, 8, series loops 17, 18, the terminal rings 19, and any other fittings or channels disposed outside the stator 2. The method 700 includes a removal step 710 that removes cooling fluid from the fluid cooled channels. For example, the inlet manifold 14 can be disconnected so that the cooling fluid can be removed from the generator or at least from the fluid cooled channels outside the stator. An important feature is that the fluid cooled channels remain substantially in place and in situ, except for the one whose cooling fluid is to be removed and vented. After the removal step 710, a drying step 720 is used to dry the inner surfaces of the fluid cooled channels. For example, the drying step may involve creating a vacuum in the interior of the fluid cooled channels. The vacuum will "evaporate" any remaining cooling fluid. The term vacuum is defined as a negative or reduced pressure, or a condition in which air is completely or partially removed.
An insertion step 730 introduces a borescope 508 and a sealant applicator 513 through an opening in one of the fluid cooled channels. For example, the borescope could be inserted into the inlet manifold 14, into the series loops 17, 18, into the phase rings 7, 8, into the terminal rings 19, into the lower conduits 21, into the main conduits 22, or any other desired entry point. By way of example only, the flexible cable 508 may be inserted into the inlet manifold 14 and then into the hose 16, further into the series loop 17, and finally into the phase line 7. A localization step 740 locates a solder joint 602 in the fluid cooled channel. The location can be determined by known predetermined locations of the solder joints. For example, the distance of each solder connection from the inlet manifold 14 may be known such that the flexible cable may be inserted a known distance / depth (eg, 150 inches) at which insertion is stopped, and the location viewed with the camera 510 become. Alternatively, the interior of the fluid-cooled channel 600 may be scanned by means of an ultrasonic transducer 620 whose output is monitored, and where the location of a solder joint 602 is identified by a predetermined signal from the ultrasonic transducer. A positioning step 750 positions the borescope and sealant applicator near the solder joint. Once the solder joint is known, the borescope may be positioned near the solder joint as described above.
An attachment step 760 applies a sealant to the interior of the fluid-cooled channel at the solder joint. The sealant may be an epoxy or a powder paint. In practice, it may be desirable to first locate and seal the deepest solder joints. In this manner, as the sealing process progresses, the borescope and flexible cable 508 are withdrawn from coated joints. For example, if solder joints are present at depths of 50 inches, 100 inches and 150 inches, the solder joint would first be located and sealed at the depth of 150 inches. The flexible cable could be retracted to the 100-inch deep solder joint where this solder joint is sealed at this point, followed by the last 50-inch solder joint. In a viewing step 770, the solder joint is considered to confirm that the attach step 760 was successful. The camera 510 is used to pick up the sealant site and confirm that the attachment of the sealant is satisfactory. If the cover with sealant is insufficient, then that additional sealant may be applied; until the desired result is achieved. The locating step 740, the positioning step 750, the attaching step 760, and the viewing step 770 are repeated until a desired number of solder joints are sealed.
One of the advantages provided by the method of the present invention is that the fluid cooled channels (e.g., phase lines, rows, loops, ferrules, fittings, and the like) located outside the stator can be sealed in situ. This allows implementation of the method without having to disassemble a major portion of the stator or its associated fluid cooled channels. In addition, the time for which the generator is to be disconnected from the grid is significantly reduced compared to a total disassembly of the stator or the incorporation of new fluid cooled channels. The existing solder joints can be sealed and overhauled in less time at lower cost to the owner / owner of the generator.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices and systems, and any methods associated therewith perform. The patentable scope of the invention is defined by the claims, and may include other examples of skill in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
What is provided is a method of in situ sealing fluid cooled channels for a generator. The fluid or liquid cooled channels are located outside a stator of the generator and substantially outboard of stator bars. The method includes: removing cooling fluid from the fluid cooled channels and drying interior surfaces of the fluid cooled channels. An insertion step introduces a borescope and sealant applicator through an opening in one of the fluid cooled channels. A locating step locates a solder joint in the fluid cooled channel, and a positioning step positions the borescope and sealant applicator near the solder joint. An attachment step applies a sealant to the interior of the fluid cooled channel in the solder joint. A viewing step may be used to view the solder joint via the borescope to confirm that the attachment step was successful.
LIST OF REFERENCE NUMBERS
[0048]<Tb> 1 <September> Case<Tb> <September> stator<tb> 3 <SEP> inner cage<Tb> 4 <September> end flanges<tb> 5 <SEP> upper anchor rod<tb> 6 <SEP> lower anchor first<Tb> 7 <September> phase line<Tb> 8 <September> phase line<Tb> 9 <September> carrier element<tb> 10 <SEP> intermediate spacer<tb> 11 <SEP> inner support member<Tb> 12 <September> rope<Tb> 13 <September> connector<Tb> 14 <September> intake manifold<Tb> 15 <September> bracket<Tb> 16 <September> Hose<Tb> 17 <September> series loop<Tb> 18 <September> series loop<Tb> 19 <September> Connection Ring<tb> 19 a <SEP> inner cooling channel<Tb> 19b <September> obstacle<Tb> 20 <September> bracket<Tb> 21 <September> Connection cable<Tb> 22 <September> Connection cable<Tb> 24 <September> series loop<Tb> 25 <September> phase line terminal group<Tb> 26 <September> Connection cable<Tb> 27 <September> Connection cable<Tb> 28 <September> Staff<Tb> 29 <September> Channel<Tb> 30 <September> Channel<Tb> 31 <September> Steg<Tb> 32 <September> Insulation<tb> 50 <SEP> electrically conductive housing<Tb> 50a <September> housing interior<Tb> 51 <September> connector<Tb> 52 <September> Pipe<Tb> 53 <September> T-connector<Tb> 53 <September> connector<Tb> 54 <September> Band<Tb> 55 <September> Band<Tb> 56 <September> Pipe<Tb> 401 <September> Connection rings<Tb> 402 <September> series loop<tb> 40 3 <SEP> Phase line<Tb> 411 <September> solder<Tb> 412 <September> solder<Tb> 413 <September> solder<Tb> 500 <September> borescope<Tb> 502 <September> Control Panel<Tb> 504 <September> display device<Tb> 506 <September> Input Device<tb> 508 <SEP> flexible cable<Tb> 510 <September> Camera<Tb> 512 <September> sealant supply<Tb> 513 <September> A sealant<Tb> 514 <September> Mark<Tb> 516 <September> sealant supply<tb> 600 <SEP> liquid cooled channel<Tb> 602 <September> solder<Tb> 610 <September> Spring<Tb> 620 <September> scanner / ultrasound transducer<Tb> 622 <September> Arm<Tb> 624 <September> Spring<Tb> 700 <September> Process<Tb> 710 <September> Abführschritt<Tb> 720 <September> drying step<Tb> 730 <September> inserting step<Tb> 740 <September> location step<Tb> 750 <September> positioning step<Tb> 760 <September> attaching step<Tb> 770 <September> viewing step

权利要求:
Claims (11)
[1]
A method of in situ sealing fluid cooled channels for a generator, wherein the fluid cooled channels are located outside a stator of the generator and substantially outside stator bars, the method comprising:Removing cooling fluid from the fluid cooled channels;Drying inner surfaces of the fluid cooled channels;Inserting a borescope and a sealant applicator through an opening in one of the fluid cooled channels;Locating a solder joint in the fluid cooled channel;Positioning the borescope and the sealant applicator near the solder joint;Attaching a sealant to an interior of the fluid cooled channel at the solder joint; andView the solder joint using the borescope to confirm that the attachment step was successful.
[2]
2. The method of claim 1, wherein the method further includes:Repeating the steps of locating, positioning, attaching and viewing until a desired number of solder joints are sealed.
[3]
3. The method of claim 1 or 2, wherein the sealant comprises an epoxy resin or a powder layer paint, and the fluid-cooled channels have:a connection ring and / or a series loop and / or a phase line.
[4]
4. The method according to any one of the preceding claims, wherein the drying step further comprises:Creating a vacuum in the interior of the fluid cooled channel.
[5]
The method of any one of the preceding claims, wherein the locating step further comprises:Measuring a depth of insertion of the borescope and the sealant applicator and comparing the depth of predetermined locations of solder joints.
[6]
A method according to any one of the preceding claims, wherein the locating step further comprises:Scanning the interior of the fluid cooled channel by means of an ultrasonic transducer;Monitoring an output of the ultrasonic transducer; andwherein a solder joint is identified by a predetermined signal from the ultrasonic transducer.
[7]
A method of in situ sealing fluid cooled channels for a generator, wherein the fluid cooled channels are located outside a stator of the generator and substantially outside stator bars, the method comprising:Inserting a borescope and an epoxy applicator through an opening in one of the fluid cooled channels;Locating a solder joint in the fluid cooled channel;Positioning the borescope and the epoxy applicator near the solder joint;Attaching an epoxy resin to an interior of the fluid cooled channel at the solder joint;Repeating the steps of locating, positioning and mounting until a desired number of solder joints are coated and sealed with epoxy, and wherein the process is performed on the generator in situ.
[8]
8. The method of claim 7, further comprising:Discharging cooling fluid from the fluid cooled channels and / or drying interior surfaces of the fluid cooled channels.
[9]
9. The method of claim 7 or 8, wherein the locating step further comprises:Measuring a depth of insertion of the borescope and the epoxy applicator in the fluid cooled channel and comparing the depth of predetermined locations of solder joints.
[10]
10. The method according to any one of claims 7 to 9, wherein the localization step further comprises:Scanning the interior of the fluid cooled channel by means of an ultrasonic transducer;Monitoring an output of the ultrasonic transducer; andwherein a solder joint is identified by a predetermined signal from the ultrasonic transducer.
[11]
11. A method of in situ sealing fluid cooled channels for a generator, wherein the fluid cooled channels are located outside a stator of the generator and substantially outside stator bars, the method comprising:Inserting a borescope and a powder coating applicator through an opening in one of the fluid cooled channels;Locating a solder joint in the fluid cooled channel;Positioning the borescope and powder coating applicator near the solder joint;Applying a powder layer paint to an interior of the fluid cooled channel at the solder joint; andRepeating the steps of locating, positioning and mounting until a desired number of solder joints are coated with the powder layer and sealed, and wherein the process is performed on the generator in situ.

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同族专利:

公开号 | 公开日

JP2017005982A|2017-01-05|

US20160359396A1|2016-12-08|

DE102016109469A1|2016-12-08|

JP6882820B2|2021-06-02|

US9847702B2|2017-12-19|

CN106253592A|2016-12-21|

CN106253592B|2020-03-24|

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法律状态:
2017-03-15| NV| New agent|Representative=s name: GENERAL ELECTRIC TECHNOLOGY GMBH GLOBAL PATENT, CH |

2019-05-31| NV| New agent|Representative=s name: FREIGUTPARTNERS IP LAW FIRM DR. ROLF DITTMANN, CH |

2020-09-15| AZW| Rejection (application)|

优先权:

申请号 | 申请日 | 专利标题

US14/732,854|US9847702B2|2015-06-08|2015-06-08|In-situ method for sealing fluid cooled conduits for a generator|

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