JP5821905B2 - Dry capacitor - Google Patents

Description

  The present invention relates to a dry capacitor which is a gas-filled dry metal deposition film capacitor, and more particularly to a technique for improving the ground insulation characteristics.

  In a conventional dry capacitor, an element body made of one capacitor element or an element body made by connecting a plurality of capacitor elements is housed in a metal case, and the metal case is filled with gas. It has a configuration. Further, the element body may be housed in a metal case as an aggregate formed by connecting a plurality of element bodies. A capacitor | condenser element is a round wound element by which the metal vapor deposition film was wound, and the electrode part by metal spraying is formed in the end surface part.

  In the element body, the capacitor element is covered with an insulating resin formed by molding. Therefore, in order to make an electrical connection with the capacitor element, the lead wire electrically connected to the electrode portion of the capacitor element is drawn out of the element body. Similarly, when configured as an aggregate, the element body is covered with an insulating resin, and lead wires are drawn out of the aggregate. With this lead wire, electrical connection (connection) between element bodies (aggregates) and bushings provided on the upper surface of the metal case is performed in the metal case (for example, Patent Document 1, Patent Document 1). 2).

  Here, as the gas filled in the metal case, highly insulating SF6 (sulfur hexafluoride) gas has been used in order to ensure sufficient ground insulation characteristics. However, the amount of SF6 gas used has been gradually reduced from the viewpoint of global warming, and is beginning to be replaced with nitrogen gas. However, when nitrogen gas is used, there is a problem that the insulating property is remarkably inferior.

  For this reason, conventional dry capacitors are insulated by providing a structure that protects the connection points and wiring parts of lead wires with insulating tape and tubes, and a structure that secures an insulation distance by making the wiring parts extremely long. The improvement of the nature is aimed at.

  In addition, each capacitor element in the element body is connected with a connection plate, and the electrode portion and the connection plate of the capacitor element are covered with an insulating resin material and an insulating case to be insulated from the metal container. Therefore, a configuration that eliminates the need for gas filling has also been proposed (see, for example, Patent Document 3).

Japanese Utility Model Publication No. 60-18532 (published February 7, 1985) JP 2001-60529 A (published March 6, 2001) JP 2000-150299 A (published on May 30, 2000)

  However, the conventional dry capacitor described above has a problem in that the ground insulation characteristics are not stable because a defect that leads to a decrease in insulation occurs partially.

  In a conventional dry capacitor, a high-voltage lead wire, a low-voltage lead wire, a neutral point lead wire, a discharge resistance wire, and the like are drawn from an element body (aggregate). These lead wires are electrically connected to the bushing lead wire, the lead wire of another element body (aggregate), the discharge resistance, etc. using caulking terminals outside the element body (aggregate) in the metal case. Connected.

  Among these lead wires, the lead wires drawn out from the lower part of the element body (assembly) such as neutral point lead wires and low-voltage lead wires are covered with an insulating resin by a molding treatment at the bottom of the metal case (for example, Patent Document 2). Therefore, Imp. The ground insulation characteristics such as characteristics are excellent and are not particularly problematic.

  However, the lead wire drawn from the upper part of the element body (aggregate) such as a high-voltage lead wire or a discharge resistance wire is arranged with a wiring distance determined within a limited volume. For this reason, it is difficult to perform a mold treatment in the metal case like a lead wire drawn out from the lower part of the element body (aggregate), and it is covered with an insulating resin molded by the manufacturing process of the element body itself. It is not enough even if it is broken. Furthermore, when molding is performed with a particularly soft rubber-like resin, or when the resin is coated so that the lead wire rises straight, the lead wire and the resin may be separated in a later process after molding.

  In the dry capacitor using the above-described connection plate, the connection plate in which each capacitor element is connected and the connection plate provided by being electrically connected to the bushing are electrically connected above the element body (aggregate). Although connected, the metal of the connection plate and the connection plate is exposed. Therefore, the insulation between the element body and the metal container is good, but the insulation between the connection portion and the metal container is not sufficient.

  Therefore, for these produced dry capacitors, Imp. When the breakdown voltage test is performed, breakdown or partial discharge occurs at the lead wire connection portion or the wiring connection portion for element arrangement, and the ground insulation characteristics are extremely deteriorated. For this reason, there is a problem that the ground insulation characteristics are not stable.

  The present invention has been made in view of the above-described conventional problems, and an object thereof is to provide a dry capacitor capable of improving the ground insulation characteristics.

  In order to solve the above problems, the dry capacitor of the present invention comprises an element body comprising one capacitor element provided with an electrode portion by metal spraying on each end surface portion of a wound metal vapor-deposited film, or An element body in which a plurality of capacitor elements are connected is a dry capacitor in which at least one capacitor is housed in a metal case provided on the upper surface with an external terminal connectable to the outside. Each electrode portion located at the end includes an electric wire electrically connected to the electrode portion and drawn out of the element body, and each electrode portion located at the end is electrically insulative. Each of the wires covered by the resin and electrically connected by the wires drawn out of the element body is covered with an insulating second resin among the wires drawn out of the element body. Connected at the connected section The wire is covered with an insulator having one end located in the first resin covering the electrode portion of the element body and the other end located in the second resin covering the connection portion. It is characterized by.

  According to said structure, all the electric wires connected by the connection part are covered with the insulator, 1st resin, and 2nd resin in the metal case. Therefore, in the dry capacitor, since the insulation of the electric wire connected at the connection portion is enhanced, the ground insulation characteristics can be improved.

  In the dry capacitor of the present invention, the insulator is preferably formed by laminating pipe-shaped resin films. Thereby, since an insulator is a film laminated product, the tear prevention effect is further strengthened and it becomes possible to prevent the exposure of a strand.

  Further, in the dry capacitor of the present invention, a spacer in which through holes are formed at regular intervals is provided in the second resin covering the connection portion, and the electric wire connected at the connection portion is the insulator. It is preferable that the portion covered with is connected in a state of passing through the through hole of the spacer.

  According to said structure, 2nd resin is reliably filled between each electric wire currently connected by the connection part by providing the spacer. Therefore, it becomes possible to prevent the peeling of the electric wire.

  As described above, the dry capacitor of the present invention includes an electric wire that is electrically connected to the electrode portion and drawn out of the element body at each electrode portion that is electrically located at the end, Each electrode part located at the end is covered with an insulating first resin, and is electrically connected by an electric wire drawn out of the element body. Among the wires drawn out to the wire, the wires connected by the connecting portion covered with the insulating second resin are positioned at one end in the first resin covering the electrode portion of the element body, and It is the structure coat | covered with the insulator in which the other end is located in 2nd resin which covers a connection part.

  Therefore, the electric wires connected at the connection portion are all covered with the insulator, the first resin, and the second resin in the metal case. Therefore, in the dry type capacitor, since the insulation of the electric wire connected at the connection portion is enhanced, there is an effect that the ground insulation characteristic can be improved.

It is sectional drawing which shows one Embodiment of the dry type capacitor in this invention. It is sectional drawing which shows the structure of the element body in the said dry capacitor. It is a perspective view which shows the structure of the capacitor | condenser element in the said element | base_body. (A) is a top view and a cross-sectional view showing a state immediately after covering the lid in the above-described element manufacturing process, and (b) is a top view showing a state when the lid is rotated and fixed. It is sectional drawing. It is a perspective view which shows the structure by which the said element | base_body is connected by the connection part. It is sectional drawing which shows the structure of the said connection part vicinity.

  An embodiment of the present invention will be described below with reference to the drawings.

(High-pressure dry capacitor)
FIG. 1 is a cross-sectional view showing a configuration example of the high-voltage dry capacitor 1 of the present embodiment.

  The high-voltage dry capacitor 1 of the present embodiment is a dry high-voltage phase advance capacitor. As shown in FIG. 1, the high-voltage dry capacitor 1 includes an element body 2, a metal case 3, and a bushing 6.

  The element body 2 is formed by connecting a plurality of capacitor elements. Six element bodies 2 are provided, and two element bodies 2 are connected (connected) in parallel. The two connected in parallel are defined as one phase. The element body 2 is housed in a metal case 3. The element body 2 is fixed or held in the metal case 3 by various conventional methods, and the bottom of the metal case 3 is filled with an insulating resin by molding (bottom side resin filling portion 7).

  Several lead wires are drawn out from the element body 2, and some of them are connected by a connection portion 8. The connection part 8 is covered with an insulating resin by molding (connection part resin sealing part 9). The configuration of the element body 2 and the configuration near the connection portion 8 will be described later in detail.

  The metal case 3 includes a concave container 4 and a lid 5 and is a case capable of sealing the internal space. The metal case 3, that is, the container 4 and the lid 5 are made of metal. The metal case 3 is filled with an insulating gas. As the insulating gas, for example, nitrogen gas is suitable.

  The bushing 6 is an external terminal that can be connected to the outside, and is provided on the metal case 3. Three bushings 6 are arranged on the upper surface of the metal case 3, that is, on the upper surface of the lid 5 when covered with the container 4. Further, a bushing lead wire electrically connected to the bushing 6 is drawn into the metal case 3.

  In the high-pressure dry capacitor 1 having the above-described configuration, after the element body 2 is placed in the container 4, the lead wire drawn out of the element body 2 is connected according to the design. Then, by injecting and curing the insulating resin, the bottom resin filling portion 7 is formed at the bottom of the container 4. Next, after filling the container 4 with nitrogen gas, the lid 5 is closed and the metal case 3 is sealed. Thereby, the high voltage | pressure dry type capacitor 1 can be produced.

  In the high-voltage dry capacitor 1 described above, six element bodies 2 are provided and two element bodies 2 connected in parallel are configured as one phase. However, the present invention is not limited to this. Since the high-voltage dry capacitor 1 is a three-phase capacitor, it suffices to have at least three element bodies 2, and one element body 2 may be configured as one phase, or in series, parallel, or series-parallel. A plurality of element bodies 2 connected to each other may be configured as one phase. And the high voltage | pressure dry capacitor | condenser 1 may be comprised as a single phase capacitor | condenser, and the number of bushings 6 can be changed according to this.

  In addition, the metal case 3 is not limited to the configuration including the container 4 and the lid 5, and the shape and structure of the metal case 3 can be designed as long as the metal case 3 can be housed and sealed and the bushing 6 can be installed. Can be determined accordingly.

  Further, in the high-pressure dry capacitor 1 described above, the base resin filling portion 7 is formed at the bottom of the container 4 by injecting the insulating resin after the element body 2 is placed in the container 4. The element body 2 that has already been molded with an insulating resin so as to cover the lead-out portion and the lower half of the lowermost capacitor element may be disposed in the container 4.

  The element body 2 is not limited to the configuration in which the element body 2 is arranged in the vertical direction as shown in FIG. 1, but may be in the configuration in which the element body 2 is arranged in the horizontal direction (for example, a direction parallel to the installation surface of the bushing 6). Therefore, as described above, the structure in which the individual element bodies 2 (aggregates) are molded with the insulating resin to the extent described above is suitable for the case where they are arranged sideways.

(Element body)
Next, the configuration of the element body 2 will be described in detail with reference to FIGS.

  FIG. 2 is a cross-sectional view showing a configuration example of the element body 2. FIG. 3 is a perspective view showing a configuration example of the capacitor element 11. 4A and 4B show an example of a manufacturing process of the element body 2. FIG. 4A is a top view and a cross-sectional view showing a state immediately after the cover 14 is put on, and FIG. It is the top view and sectional drawing which show a mode when it is made to fix.

  As shown in FIG. 2, the element body 2 includes eight capacitor elements 11, a centering rod 12, a resin pipe 13, and a lid 14 connected in series.

  Here, for convenience of explanation, hereinafter, the capacitor elements 11 arranged in the element body 2 will be referred to by assigning numbers 1 to 8 from the one on the high potential side. Further, the arrangement side of the first capacitor element 11 is the upper side, and the arrangement side of the eighth capacitor element 11 is the lower side.

  As shown in FIG. 3, the capacitor element 11 is a round wound element in which a metal vapor deposition film 22 is wound around a cylindrical hard core core 21, and an electrode portion 23 by metal spraying is provided on each end surface portion thereof. Is formed. The capacitor element 11 has, for example, an outer size of a diameter d: 60 mm or less (preferably a diameter d: 30 to 60 mm) and a height h: 75 mm.

  The capacitor element 11 is arranged along the center axis direction of the centering rod 12 while the centering rod 12 is inserted into the hard core core 21. The capacitor element 11 is connected in series by a lead wire. The capacitor element 11 and the centering rod 12 thus arranged and connected are arranged in the resin pipe 13. The centering rod 12 is made of an insulator such as FRP (fiber reinforced plastic).

  The lead wire is electrically connected to the electrode portion 23 using, for example, solder. One lead wire is provided between each capacitor element 11. The capacitor elements 11 at both ends are provided with two lead wires each drawn out of the element body 2.

  From the upper electrode portion 23 of the first capacitor element 11, a high-voltage lead wire 15 a connected to the bushing lead wire and a discharge resistance wire 15 b electrically connected to the discharge resistor are drawn out of the element body 2. It is. A low-voltage lead wire 16 a and a neutral point lead wire 16 b are drawn out of the element body 2 from the lower electrode portion 23 of the eighth capacitor element 11. In the following description, when the lead wires drawn from the upper electrode portion 23 of the first capacitor element 11 are collectively referred to as the lead wire 15. When the lead wires drawn out from the lower electrode portion 23 of the eighth capacitor element 11 are collectively called, they are called lead wires 16.

  The resin pipe 13 is for mounting the capacitor element 11. The resin pipe 13 is made of an insulating resin and has a pipe shape. The resin pipe 13 in which the capacitor element 11 and the centering rod 12 are placed is filled with an insulating resin by molding (resin filling portion 19). The centering rod 12 is used for centering and dimensioning during molding.

  The lid 14 is made of resin and covers the end (opening) of the resin pipe 13 on the side where the first capacitor element 11 is disposed. The lid 14 serves as a mold for molding the inside of the resin pipe 13. A plurality of holes (openings) according to the design are formed in the lid 14, and at least the central hole 17 for penetrating the centering rod 12 and the electrode part 23 on the upper side of the first capacitor element 11. A lead hole 18 (18a, 18b) for drawing out the connected lead wire 15 (the high-voltage lead wire 15a and the discharge resistance wire 15b) and an injection port 20 for molding in the resin pipe 13 are formed. . The injection port 20 is an opening for injecting an insulating resin.

  Note that the lead-out hole 18 for drawing out the lead wire 15 is located away from immediately above the connection point where the lead wire 15 is connected to the electrode portion 23, as shown in FIG. 4B. In other words, the lead wire 15 electrically connected to the upper electrode part 23 of the first capacitor element 11 is not drawn out directly above, but from the connection point with the electrode part 23 in the resin filling part 19. It is drawn out and pulled out of the resin filling part 19.

  In the element body 2 having the above configuration, first, the capacitor element 11 is arranged on the centering rod 12 and connected. And after this capacitor | condenser element 11 and the centering rod 12 are put into the resin pipe 13, the cover 14 is covered.

  FIG. 4A shows a state immediately after the cover 14 is put on. At this time, the centering rod 12 and the lead wire 15 are once pulled out of the element body 2 through the center hole 17 and the lead hole 18 formed in the lid 14. At this time, in order to easily pull out the lead wire 15, the lid 14 is covered so that the lead-out hole 18 is located immediately above the connection point where the lead wire 15 is connected to the electrode portion 23.

  Next, the lid 14 is fixed after being rotated 90 ° counterclockwise from the state shown in FIG. FIG. 4B shows a state when the lid 14 is rotated and fixed. Thus, by fixing the lid 14 after rotating it from the position immediately above the connection point between the lead wire 15 and the electrode portion 23, the lead wire 15 is not pulled out directly (straightly), but instead is pulled out from the resin. It is possible to draw out the resin filling portion 19 after being drawn around in the filling portion 19.

  Next, with the lid 14 fixed, an insulating resin is injected into the resin pipe 13 from the injection port 20 formed in the lid 14 to the lid 14 (normal pressure casting). By curing, a resin filling portion 19 is formed between the resin pipe 13 and the capacitor element 11. Thereby, the element body 2 can be produced.

  In the fabricated element body 2, the high potential side (the arrangement side of the first capacitor element 11) is positioned on the lid 5 side (the arrangement side of the bushing 6), and the low potential side (the arrangement side of the eighth capacitor element 11). ) Is disposed in the metal case 3 so as to be located on the bottom side of the container 4. Thereafter, as described above, the lead wire drawn out of the element body 2 is connected according to the design, and the bottom resin filling portion 7 is formed on the bottom of the container 4 to fix the element body 2. Then, the high-pressure dry capacitor 1 can be produced by filling the nitrogen case and sealing the metal case 3.

  As described above, in the high voltage dry capacitor 1, the lead wires electrically connected to the upper electrode portion 23 of the first capacitor element 11 out of the lead wires 15 and 16 drawn out of the element body 2. 15. That is, the lead wire 15 (elementary wire) drawn from the electrode portion 23 that is not covered with the bottom resin filling portion 7 but covered with the resin filling portion 19 formed by the manufacturing process of the element body 2 itself. In the step of covering the body 2 with the insulating resin, the lead wire 15 on the side where the injection port 20 is located when the insulating resin is cast under normal pressure is pulled from the connection point with the electrode portion 23 in the resin filling portion 19. It is rotated and has the structure pulled out of the resin filling part 19.

  In the conventional dry capacitor, the lead wire drawn out from the electrode part covered with the insulating resin formed by the manufacturing process of the element body itself is limited in volume due to the arrangement of the element body. The wiring distance is determined and arranged. Moreover, since this lead wire may have been pulled out directly from the connection point with the electrode part, the insulating resin may be peeled off from the electric wire, and the ground insulation characteristics are not stable. Also, the quality is unstable.

  On the other hand, according to the structure of the element body 2 of the high-voltage dry capacitor 1, the lead wire 15 drawn out from the electrode part 23 covered with the resin filling part 19 formed by the manufacturing process of the element body 2 itself. Is drawn from the connection point with the electrode part 23 in the resin filling part 19 and pulled out of the resin filling part 19, for example, even if the part located outside the element body 2 is moved, the lead The line 15 is difficult to peel off.

  Further, the length of the lead wire 15 (wiring distance) can be increased without increasing the dimension in the pull-out direction as compared with the conventional configuration.

  Therefore, in the high-voltage dry capacitor 1, since the insulating property of the element body 2 is stabilized and enhanced, the ground insulation characteristics can be improved.

  In the element body 2 described above, eight capacitor elements 11 are arranged in one row and connected in series. However, the element body 2 is not limited to this, and is constituted by one capacitor element. Alternatively, a plurality of capacitor elements may be arranged in one or a plurality of rows and connected in series, parallel, or series-parallel.

  The lead wires drawn out of the element body 2 are not limited to the above-described high-voltage lead wire 15a, discharge resistance wire 15b, low-voltage lead wire 16a, and neutral point lead wire 16b, and the number thereof is not limited to four. . The number of lead wires 15 and 16 drawn outside the element body 2 may be one or three or more, respectively, and depends on the number of element elements 2 arranged in parallel. .

  In the element body 2 described above, since the lid 14 is rotated, the lead-out hole 18 for allowing the lead wire 15 to pass therethrough has a diameter larger than the diameter of the lead wire 15 so as to have a slight gap. preferable. As a result, the lid 14 can be easily rotated, and unnecessary stress can be prevented from being applied to the lead wire 15.

  Furthermore, it is not necessary to form the resin filling portion 19 over the entire area between the resin pipe 13 and the capacitor element 11, and the resin filling portion 19 is at least the upper electrode portion 23 and the lid 14 of the first capacitor element 11. What is necessary is just to be formed so that it may be filled.

  Therefore, the end portion on the low potential side of the element body 2 may be covered with the resin filling portion 19 or the electrode portion 23 of the capacitor element 11 may be exposed. This is because the end portion on the low potential side of the element body 2 is finally covered with the bottom resin filling portion 7 in the metal case 3.

  In other words, in the high-voltage dry capacitor 1, the formation region of the resin filling portion 19 can be changed according to the arrangement direction of the element body 2 in the metal case 3, and the metal case such as the bottom resin filling portion 7 can be changed. 3, the lead wire drawn out from the electrode part 23 covered with the resin filling part 19 without being covered with the resin molded in 3 is routed from the connection point with the electrode part 23 in the resin filling part 19. Thus, any structure may be used as long as it is drawn out of the resin filling portion 19.

  Here, in the element body 2 described above, the lid 14 is rotated 90 ° counterclockwise, but the present invention is not limited to this. That is, the rotation direction may be either clockwise or counterclockwise. Further, the rotation angle θ of the lid 14 only needs to be larger than 30 °, and “30 ° <θ ≦ 90 °” is more preferable. The basis for the value of the rotation angle is based on the result of a verification test described later.

(Lead)
By the way, in general, a lead wire is configured by covering a bare electric wire (elementary wire) made of a metal stranded wire with a resin. As the lead wires 15 and 16 drawn out of the element body 2, a lead wire (covered electric wire) having such a general configuration may be used. For example, the lead wires 15 and 16 can be made of plastic or rubber insulation coated electric wires.

  However, since the high-voltage dry capacitor 1 is required to satisfy high ground insulation characteristics, it is not desirable that the lead wire be damaged.

  Therefore, the lead wires 15 and 16 drawn out of the element body 2 are preferably covered with a pipe-like insulating pipe 34 made of an insulating resin, as shown in FIG. The insulating pipe 34 is provided so that the open ends on both sides are located in the sealing resin. That is, the insulating pipe 34 has one open end positioned in an insulating resin (resin filling portion 19 and bottom resin filling portion 7) covering the electrode portion 23 of the element body 2, and the other open end is It is provided so that it may be located in the connection part resin sealing part 9 which covers the connection part 8. FIG.

  As a result, the lead wires 15 and 16 themselves are not exposed in the metal case 3 (outside the element body 2), so that when the lead wires 15 and 16 are wired in the metal case 3, it is difficult to damage the lead wires. It becomes possible to make it hard to break and to facilitate wiring work. In addition, the strength of the lead wires 15 and 16 can be increased.

  Furthermore, the insulating pipe 34 is more preferably formed by laminating pipe-shaped plastic films (resin films). As a plastic film, a polypropylene film, a polyethylene terephthalate film, a polyethylene film etc. can be used, for example. Since it is a film laminated product, the tear prevention effect is further strengthened, and it becomes possible to prevent the exposure of the strands.

  Further, if the insulating pipe 34 is a film laminated product, the inside and outside of the pipe can be communicated even if both ends of the insulating pipe 34 are sealed with resin as will be described later. Therefore, even if evacuation or gas filling is performed, the same atmosphere is maintained inside and outside the pipe.

  The insulating pipe 34 may be provided in the outermost layer, and something may or may not be interposed between the wire and the insulating pipe 34. Moreover, it is preferable to attach the insulating pipe 34 not only to the case where the insulating pipe 34 is attached to the lead wires 15 and 16 but also to a lead wire (for example, a bushing lead wire) wired in the metal case 3.

(Connection)
Next, a configuration near the connection portion 8 will be described in detail with reference to FIGS.

  FIG. 5 is a perspective view showing an example of a configuration in which the element body 2 is connected by the connection portion 8 in the metal case 3. FIG. 6 is an enlarged view showing a configuration example in the vicinity of the connection portion 8.

  As shown in FIG. 5, in the metal case 3, the high-voltage lead wire 15a drawn from the element body 2 is connected to the bushing lead wire 52 at the connection portion 8a. The discharge resistance line 15 b is electrically connected to the discharge resistance 51. The neutral point lead wire 16b is electrically connected to the neutral point lead wire 16b of another element body 2 at the connection portion 8b. The connection part 8a and the connection part 8b are covered with the connection part resin sealing part 9a and the connection part resin sealing part 9b, respectively.

  In addition, in FIG. 1, the picture regarding a lead wire and a connection is simplified, FIG. 5 also shows an example, Comprising: Not all the lead wires and connection parts are shown in figure. Hereinafter, when the connection portions provided for connecting the lead wires 15 and 16 drawn from the element body 2 are collectively referred to as the connection portion 8.

  The connecting portion 8 is disposed near the upper side in the metal case 3. This is because, since the lead wires 15 and 16 are connected after the element body 2 is arranged in the metal case 3, the position where the operation is easy is located near the upper side in the metal case 3. Therefore, the lead wire 16 led out from the lower part of the element body 2 extends to the vicinity of the upper side in the metal case 3 through the bottom side resin filling portion 7.

  The connection part 8 is covered with the connection part resin sealing part 9. The connecting portion resin sealing portion 9 is an insulating resin such as an epoxy resin or a polyurethane resin, and is formed by molding the connecting portion 8 using a plastic mold. The plastic mold is stored in the metal case 3 as it is. That is, the plastic mold is not removed.

  As shown in FIG. 6, in the connection portion 8, a plurality of lead wires are connected. The lead wire includes a wire 32 made of metal and a covering portion 33 made of a resin that covers the wire 32, and an insulating pipe 34 is further covered. In order to electrically connect the vicinity of the tip of the lead wire, the covering portion 33 is removed and the element wire 32 is exposed. The insulating pipe 34 need not cover the end of the covering portion 33.

  A spacer 31 is attached to the insulating pipe 34. The spacer 31 has a straw-like shape (that is, through holes are formed at regular intervals), and is used to keep the lead wires at regular intervals.

  The lead wire to be connected at the connection portion 8 is first passed through the through hole of the spacer 31. And after connecting with the connection part 8 in this state, the spacer 31 is arrange | positioned in the part of the insulation pipe 34, and the periphery of the connection part 8 including the spacer 31 is molded with resin.

  This makes it possible to reliably fill the resin between the lead wires bundled at equal intervals. Therefore, peeling of the lead wire can be prevented. In addition, by performing molding as described above, one open end of the insulating pipe 34 is positioned in the connection portion resin sealing portion 9.

  According to the configuration in the vicinity of the connection portion 8 described above, the lead wires 15 and 16 connected by the connection portion 8 are provided inside the metal case 3 (outside the element body 2), the insulating pipe 34, the resin filling portion 19 or the bottom side. All are covered with the resin filling portion 7 and the connecting portion resin sealing portion 9. Therefore, in the high-voltage dry capacitor 1, the insulation properties of the lead wires 15 and 16 connected by the connection portion 8 are enhanced, so that the ground insulation characteristics can be improved.

  As described above, the dry capacitor is composed of an element body including one capacitor element in which an electrode part by metal spraying is provided on each end face part of a wound metal vapor-deposited film, or a plurality of capacitor elements are connected. The element body is a dry type capacitor in which at least one external terminal that can be connected to the outside is provided in the upper surface, and the element body is electrically connected to each end. The electrode portion includes an electric wire that is electrically connected to the electrode portion and drawn out of the element body, and each electrode portion that is electrically positioned at the end is covered with an insulating resin, and Electrical connection is made by the electric wire drawn out of the element body, and the electric wire drawn out of the element body is covered with an insulating resin formed by the manufacturing process of the element body itself. electrode Wire being drawn from is routed from the connection point of the electrode portion in the insulating resin, it is characterized by being drawn out of the insulating resin.

  In conventional dry capacitors, the wires drawn from the electrode parts covered with insulating resin formed by the manufacturing process of the element itself are wired in a limited volume due to the arrangement of the element. The distance is determined and arranged. Moreover, since this electric wire may be pulled out from the connection point with an electrode part, insulating resin may peel from an electric wire and the ground insulation characteristic was not stable.

  On the other hand, according to the above configuration, the wire drawn from the electrode part covered with the insulating resin formed by the manufacturing process of the element body itself is connected to the electrode part in the insulating resin. For example, even if a portion located outside the element body is moved, the electric wire is difficult to peel off.

  Moreover, according to said structure, it becomes possible to lengthen the length (wiring distance) of the said electric wire, without increasing the dimension of a drawer | drawing-out direction compared with the conventional structure.

  Therefore, in the dry capacitor, since the insulation of the element body is stabilized and enhanced, the ground insulation characteristics can be improved.

  In order to enhance the above effect, the dry capacitor of the present invention is such that an electric wire drawn out from an electrode part covered with an insulating resin formed by the manufacturing process of the element body itself is perpendicular to the electrode part. When viewed from a certain direction, it is desirable that the insulating resin is routed at an angle θ (30 ° <θ ≦ 90 °) from the connection point with the electrode portion.

  A dry capacitor is an element body including one capacitor element in which an electrode part by metal spraying is provided on each end face part of a wound metal vapor-deposited film, or a plurality of capacitor elements are connected. The element body is a dry type capacitor in which at least one external terminal that can be connected to the outside is provided in the upper surface, and the element body is electrically connected to each electrode portion. And each of the electrode portions that are electrically connected to the electrode portion and drawn out of the element body and are electrically positioned at the end are covered with an insulating first resin, Electrical connection is made by the electric wire drawn out of the element body, and the electric wire drawn out of the element body is covered with the first resin molded by the manufacturing process of the element body itself. Electrode part The electric wire drawn out from the connection point with the electrode part in the first resin is drawn out of the first resin, and among the electric wires drawn out of the element body, an insulating property is drawn. One end of the electric wire connected by the connecting portion covered with the second resin is located in the first resin that covers the electrode portion of the element body, and the other end in the second resin that covers the connecting portion. The structure may be covered with an insulator in which is located.

  In the dry capacitor, the electric wire drawn out from the electrode part covered with the insulating resin formed by the manufacturing process of the element body itself is not in the insulating resin as viewed from the direction perpendicular to the electrode part. In this case, it is preferably drawn around at an angle θ (30 ° <θ ≦ 90 °) from the connection point with the electrode portion.

  In the dry capacitor, the insulator is preferably formed by laminating a pipe-shaped resin film.

  In the dry capacitor, a spacer in which through holes are formed at regular intervals is provided in the second resin that covers the connection portion, and the electric wire connected at the connection portion is covered with the insulator. It is preferable that the connected portion is connected in a state of passing through the through hole of the spacer.

  The results of actually producing the high-voltage dry capacitor 1 and verifying the withstand voltage are shown below.

  In this verification, Imp. A breakdown voltage test was performed. Imp. The breakdown voltage test refers to a lightning impulse withstand voltage test based on the provisions of JIS C 4902 “High Voltage and Extra High Voltage Phase-advanced Capacitors and Accessories”. Imp. In the breakdown voltage test, in a dry state, a positive wave impulse voltage having a waveform [(1.2 to 5) × 50] μs is applied three times repeatedly between the line terminal and the ground terminal (the bushing 6 is applied at a high voltage, metal Case 3 was grounded), and it was verified whether the high-voltage dry capacitor 1 could withstand this.

Example 1
In the high-voltage dry capacitor 1, the lead wire 15 electrically connected to the upper electrode portion 23 of the first capacitor element 11 is drawn directly above (no rotation), and the direction perpendicular to the electrode portion 23 Three specimens are manufactured: one that is rotated by 30 ° when viewed from the top (30 ° rotation) and one that is rotated by 90 ° and viewed from the same direction (90 ° rotation) Imp. A breakdown voltage test was conducted and Imp. The breakdown voltage was measured. n = 5, and nitrogen was used as the filling gas.

  When the rotation angle of the two lead wires 15 extending from the upper electrode portion 23 of the capacitor element 11 is larger than 90 °, the lead wires 15 cross each other and come close to each other, and sometimes come into contact with each other. There is. Such a state is not preferable for the ground insulation characteristics of the high-voltage dry capacitor 1. For this reason, the rotation angle is not set to be larger than 90 ° in advance.

  The measurement results are shown in Table 1. In Table 1, Imp. The average value of the breakdown voltage is shown as a ratio when the JIS rated voltage is set to 1.00.

  As shown in Table 1, when the lead wire 15 is rotated by 30 ° and pulled out, Imp. The breakdown voltage is high. In addition, the lead wire 15 rotated 90 ° and drawn out is more Imp. The breakdown voltage is high.

  Therefore, it was found that the ground insulation characteristics can be improved by rotating and pulling out the lead wire 15.

  Further, if the rotation angle is larger than 30 °, Imp. It has the ability to withstand the breakdown voltage test. Therefore, in order to sufficiently satisfy the JIS standard, the rotation angle θ only needs to be larger than 30 °, and in consideration of problems caused by the rotation of the two lead wires 15, “30 ° <θ ≦ 90 °” is more satisfied. It turned out to be preferable.

  Of course, when there are three or more lead wires 15, even when there is only one lead wire, troubles due to rotation occur in the same way. Therefore, when the rotation angle θ is “30 ° <θ ≦ 90 °”, the same applies. The effect of can be obtained.

(Example 2)
In the high-voltage dry capacitor 1, the lead wires 15 and 16 drawn from the element body 2 are used as they are (no insulation pipe), the insulation pipe 34 is covered (use an insulation pipe), and the insulation pipe 34 is used. At the same time, three test samples were prepared, both of which had both open ends molded with resin (insulated pipe both ends mold), and Imp. A breakdown voltage test was conducted and Imp. The breakdown voltage was measured. Nitrogen was used as the filling gas.

  The measurement results are shown in Table 2. In Table 2, Imp. The breakdown voltage is shown as a ratio when the JIS rated voltage is set to 1.00.

  As shown in Table 2, when the insulating pipe 34 is coated, Imp. The breakdown voltage is high. In addition, when the insulating pipe 34 is used and both open ends thereof are molded with resin, Imp. The breakdown voltage is high.

  Therefore, it was found that the ground insulation characteristics can be improved by using the insulating pipe 34 and sealing the both open ends with resin.

  In addition, when the insulating pipe 34 is used and both open ends thereof are molded with a resin, Imp. It has the ability to withstand the breakdown voltage test. Therefore, it was found that this configuration sufficiently satisfies the JIS standard.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims. That is, embodiments obtained by combining technical means appropriately modified within the scope of the claims are also included in the technical scope of the present invention.

  INDUSTRIAL APPLICABILITY The present invention can only be suitably used in the field related to a dry type high-voltage phase-advancing capacitor that is used in parallel with a load in a circuit exceeding 600V AC for the purpose of power factor improvement and voltage adjustment. In addition, the present invention can be suitably used in a field related to a manufacturing method of a dry type high-voltage phase advance capacitor, and further widely used in fields related to various electric facilities including a dry type high-voltage phase advance capacitor.

1 High-voltage dry capacitor (dry capacitor)
2 Element 3 Metal case 4 Container 5 Lid 6 Bushing (external terminal)
7 Bottom resin filling part (insulating resin, first resin)
8, 8a, 8b Connection part 9, 9a, 9b Connection part resin sealing part (second resin)
11 Capacitor element 12 Centering rod 13 Resin pipe 14 Lid 15a High-voltage lead wire (electric wire)
15b Discharge resistance wire (electric wire)
16a Low voltage lead wire (electric wire)
16b Neutral point lead wire (electric wire)
17 Central hole 18a, 18b Lead hole 19 Resin filling part (insulating resin, first resin)
20 Inlet 21 Hardcore core 22 Metal vapor deposition film 23 Electrode part 31 Spacer 32 Wire 33 Covering part 34 Insulation pipe (insulator)
51 Discharge resistance

Claims (2)

An element body including one capacitor element in which an electrode part by metal spraying is provided on each end face part of the wound metal vapor-deposited film, or an element body in which a plurality of capacitor elements are connected, A dry capacitor in which at least one external terminal that can be connected is housed in a metal case provided on the upper surface,
The above body is
An electric wire including at least a high-voltage lead wire electrically connected to the electrode portion and drawn out of the element body , and a low-voltage lead wire for lower pressure than the high-voltage lead wire, in each electrode portion located at the end electrically With
Each of the electrode portions located electrically at the ends is covered with an insulating first resin, and is electrically connected by an electric wire drawn out of the element body,
Of the electric wires drawn out of the element body, the electric wires connected by the connection portion covered with the insulating second resin are connected to one open end inside the first resin covering the electrode portion of the element body. And is covered with an insulator in which the other open end is located inside the second resin that covers the connection part,
A dry capacitor, wherein the insulator is formed by laminating pipe-shaped resin films. Spacers in which through holes are formed at regular intervals are provided in the second resin covering the connection part,
2. The dry capacitor according to claim 1, wherein the electric wire connected at the connection portion is connected in a state where a portion covered with the insulator is passed through a through hole of the spacer.

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