The present application is National Phase of International Application No. PCT/JP2011/003379 filed Jun. 14, 2011, and claims priority from Japanese Application No. 2010-180242, filed Aug. 11, 2010.
The present invention relates to a contact device having a fixed contactor and a movable contactor interposed into a current path, and an electromagnetic switch that uses the contact device, the contact device being capable of easily extinguishing an arc that is generated when the fixed contactor and the movable contactor are opened, that is, when the current is interrupted.
Among conventional electromagnetic relays and electromagnetic contactors functioning as contact devices for opening/closing current paths, various contact mechanisms have been proposed for extinguishing an arc that is generated when movable contactors and fixed contactors are opened to be separated from each other, in order to bring a closed state of the contact mechanisms where the fixed contactor and the movable contactor are in contact with each other, to an open state by interrupting a current.
For example, there is proposed an electromagnetic relay that has a pair of fixed contactors disposed away from each other by a predetermined distance, a movable contactor disposed to be capable of contacting with and separating from the pair of fixed contactors, and an electromagnetic block that drives the movable contactor. A U-shaped magnetic holding member is positioned on the outside of a sealing container that faces either side surface in a position where the fixed contactors and the movable contactor face each other, and two pairs of permanent magnets are positioned on the inside of the magnetic holding member in order to extinguish an arc easily by stretching the arc using a magnetic force of the permanent magnets (see Patent Document 1, for example).
However, although the arc can be stretched and extinguished easily by the magnetic force of the permanent magnets, the prior art described in above-mentioned Patent Document 1 has a problem where the gap between the pair of fixed contactors and the movable contactor needs to be enlarged in order to reliably eliminate the arc. Another problem is that a U-shaped magnetic supporting member and two pairs of the permanent magnets supported by the magnetic supporting member are required on the outside of the sealing container, which results in an increase in the number of parts and assembly processes, as well as the production costs.
In order to solve such problems, a sealed relay device is proposed in which arc discharge is extinguished in a configuration where a flat section is formed at a tip end of a semicircular contact part between a fixed contactor and a movable contactor contacting the fixed contactor, a permanent magnet is embedded in a direction perpendicular or parallel to the flat section, and a magnetic flux is formed in a direction perpendicular to an arc that is generated when the sealed relay device is in an open state (see Patent Document 2, for example).
However, the prior art Publications described in Patent Documents 1 and 2 have an unsolved problem where a permanent magnet is required to favorably extinguish an arc that is generated during the open state.
The present invention, therefore, was conceived in view of the unsolved problem of the prior art, and an object of the present invention is to provide a contact device capable of easily extinguishing an arc generated between a fixed contactor and a movable contactor without using a permanent magnet, the arc being generated when the contact device is in an open state, and an electromagnetic switch that uses this contact device.
In order to achieve the object described above, a first aspect of a contact device according to the present invention has: a pair of fixed contactors fixed to a surface of an insulation container with a predetermined space therebetween and each being shaped in a columnar form with at least a tip end contact surface protruding into the insulation container; and a movable contactor disposed to be capable contacting with and separating from the pair of fixed contactors. Surfaces of the pair of fixed contactors facing the movable contactor are configured by annular peripheral walls having concave parts at central parts thereof.
According to this configuration, surfaces of the columnar fixed contactors that face the movable contactor are configured by annular peripheral walls having concave parts at central parts thereof. Thus, an annular arc is generated between the movable contactor and the surfaces of the annular peripheral walls facing the movable contactor, in the open state where the fixed contactors and the movable contactor separate from each other. This annular arc is cooled by being rotated in a circumferential direction by a magnetic field of a current passing through the fixed contactors. Therefore, the arc can be extinguished, without using a permanent magnet.
In a second aspect of the contact device according to the present invention, arc extinguishing permanent magnets configured to drive an arc to the outside of the fixed contactors are attached to the concave parts, the arc being generated when the contact device is in an open state.
According to this configuration, the arc that is rotated in the circumferential direction can be driven to the outside by the arc extinguishing permanent magnets. Therefore, the arc can be extinguished reliably.
In a third aspect of the contact device according to the present invention, parts of the arc extinguishing permanent magnets on the movable contactor side are magnetized to an N-pole.
According to this configuration, the parts of the arc extinguishing permanent magnets on the movable contactor side are magnetized to an N-pole. This results in creating a magnetic force that reaches an S-pole from the N-pole through the outside of the permanent magnets, and in driving the annular arc generated during an open state of the contact device, to the outside of the arc extinguishing permanent magnets.
In a fourth aspect of the contact device according to the present invention, the insulation container is an airtight container sealing a gas therein.
According to this configuration, the fixed contacts and the movable contact are disposed within the airtight container sealing a gas. Thus, the arc can be eliminated reliably.
An aspect of an electromagnetic switch according to the present invention has the contact device of any one of the first to fourth aspects described above, and is characterized in that the movable contactor is coupled to a movable core of an operation electromagnet, and the fixed contactors are respectively connected to external connection terminals.
This configuration can provide an electromagnetic switch that is capable of extinguishing an arc using a simple structure, the arc being generated when the electromagnetic switch is in an open state.
According to the present invention, the surfaces of the columnar fixed contactors facing the movable contactor are configured by the annular peripheral walls having the concave parts at the central parts thereof. Thus, an annular arc is generated between the movable contactor and the surfaces of the annular peripheral walls facing the movable contactor, in the open state where the fixed contactors and the movable contactor separate from each other. This annular arc is cooled by being rotated in the circumferential direction by a magnetic field of a current passing through the fixed contactors. Therefore, the arc can be extinguished, without using a permanent magnet.
Because the arc extinguishing permanent magnet for driving the arc outwardly is disposed within the concave part, the arc can be extinguished more reliably.
Moreover, applying the contact device having the abovementioned effect to the electromagnetic switch can provide an electromagnetic switch such as an electromagnetic contactor or an electromagnetic relay, which is capable of extinguishing an arc using a simple structure, the arc being generated when the electromagnetic switch is in an open state.
a) is an enlarged cross-sectional diagram of a contact device of the present invention; and
An embodiment of the present invention is described hereinafter with reference to the diagrams.
Within the outer case 1, a contact device 2 in which a contact mechanism is disposed, and an electromagnetic unit 3 serving as an electromagnetic device for driving the contact device 2 are stored in a manner that the electromagnetic unit 3 is positioned on the bottom plate 1b.
As is clear from
As shown in
Lower end surfaces of the arc extinguishing permanent magnets 10 are positioned to be located higher than lower end surfaces of the small-diameter cylinder parts 8 of the fixed contactors 6a, 6b, but may be positioned to be flush with lower surfaces of the small-diameter cylinder parts 8. In other words, as described hereinafter, the height of the lower end surfaces of the arc extinguishing permanent magnets 10 is not particularly limited as long as an arc can be driven to the outside of each annular peripheral wall 9 when the arc is generated during an open state of the contact device.
The fixed contactors 6a, 6b are fixed to the upper case 4a by an adhesive or the like to seal the through-holes 5a, 5b, while the small-diameter cylinder parts 8 are inserted into the through-holes 5a, 5b of the upper case 4a.
In the contact device 2, the flat movable contactor 11 is disposed facing the lower end surfaces of the small-diameter cylinder parts 8 of the fixed contactors 6a, 6b, with a predetermined short gap therewith, to be capable of contacting with and separating from these lower end surfaces. This movable contactor 11 is urged upward by a contact spring 13 and attached to a contactor holder 12.
The contactor holder 12 is inserted into an insertion hole formed in the lower case 4b, and guided in a vertical direction. The contactor holder 12 is coupled to a movable core of the electromagnetic unit 3, which is described hereinafter, and then driven in the vertical direction.
The insulation airtight container 4 configured by the upper case 4a and the lower case 4b encapsulates gas therein.
Furthermore, external connection terminal strips 15a, 15b are screwed to the large-diameter head parts 7 of the fixed contactors 6a, 6b.
As shown in
A coil holder 24 having an exciting coil 23 wrapped therearound is attached to an outer circumferential surface of the tubular part 21b of the magnetic yoke 21, and a bottomed tubular cap 26 that has a movable core 25 installed slidably therein is disposed on an inner circumferential surface of the tubular part 21b. A rubber seat 27, which absorbs an impact of the falling of the movable core 25 by contacting with a bottom surface of the movable core 25, is disposed on a bottom surface of the cap 26.
A coupling shaft 28 is fitted to a central part of the movable core 25. A head part of the coupling shaft 28 is extended upward via a through-hole 29 formed in the upper surface magnetic yoke 22, and is coupled to the contactor holder 12.
Moreover, a spring insertion hole 30 is formed around the coupling shaft 28 of the movable core 25, and a return spring 31 for urging the movable core 25 downward is attached between the spring insertion hole 30 and the upper surface magnetic yoke 22.
In addition, the insulation airtight container 4 and the upper surface magnetic yoke 22 are bonded to each other by a bonding member 32.
Operations of the embodiment are described next.
Suppose that the external connection terminal strip 15a is connected to, for example, a power supply source for supplying a large current, and that the external connection terminal strip 15b is connected to a load.
Suppose, in this state, that the exciting coil 23 of the electromagnetic unit 3 is in a non-power-supply state and that no excitation force is generated in the electromagnetic unit 3 for moving the movable core 25. In this state, the movable core 25 is urged by the return spring 31 in a downward direction to separate from the upper surface magnetic yoke 22 and abutting against the rubber seat 27. Therefore, the movable contactor 11, which is supported by the contactor holder 12 that is coupled to the movable core 25 by the coupling shaft 28, faces the lower end surfaces of the small-diameter cylinder parts 8 of the fixed contactors 6a, 6b with the predetermined short gap therewith, and the contact device 2 is opened.
In this open state of the contact device 2, applying a voltage to the exciting coil 23 of the electromagnetic unit 3 produces the excitation force in the electromagnetic unit 3, pushing the movable core 25 upward against the return spring 31. In response to this, the contactor holder 12 that is coupled to the movable core 25 by the coupling shaft 28 moves upward, and the movable contactor 11 contacts with bottom surfaces of the small-diameter cylinder parts 8 of the fixed contactors 6a, 6b by contact pressure of the contact spring 13.
As a result, the contact device 2 enters a closed state in which a large current i of an external power supply source is supplied to the load via the external connection terminal strip 15a, the fixed contactor 6a, the movable contactor 11, the fixed contactor 6b, and the external connection terminal strip 15b.
When interrupting the supply of current to the load in this closed state of the contact device 2, the application of voltage to the exciting coil 23 of the electromagnetic unit 3 is stopped.
Consequently, the excitation force for moving the movable core 25 upward disappears in the electromagnetic unit 3, whereby the movable core 25 is dropped by the urging force of the return spring 31. This falling of the movable core 25 drops the contactor holder 12 that is coupled thereto by the coupling shaft 28. Accordingly, the movable contactor 11 stays in contact with the fixed contactors 6a, 6b, while the contact pressure is applied to the movable contactor 11 by the contact spring 13. Thereafter, as soon as the contact pressure of the contact spring 13 disappears, the contact device 2 enters the open state in which the movable contactor 11 separates downward from the fixed contactors 6a, 6b.
In this open start state, an arc is generated between the fixed contactors 6a, 6b and the movable contactor 11. At this moment, the arc forms an annular shape because the contact surfaces between the fixed contactors 6a, 6b and the movable contactor 11 are configured by the annular peripheral walls 9 in which the concave parts 9a are formed in the central parts thereof. Moreover, because the high current flows downward through the fixed contactor 6a, a magnetic field of a self current path of the fixed contactor 6a generates a counterclockwise magnetic flux φ1, as shown in
Moreover, the columnar arc extinguishing permanent magnets 10 are fixed to the inside of the concave parts 9a that are formed on the surfaces of the fixed contactors 6a, 6b facing the movable contactor 11. In each of the arc extinguishing permanent magnets 10, the lower end side thereof on the movable contactor 11 side is magnetized to the N-pole, and the upper end side thereof is magnetized to the S-pole. This results in forming a magnetic flux φ2 that reaches the S-pole on the upper end side of the arc extinguishing permanent magnet 10 from the N-pole side of the lower end through the outside of the arc extinguishing permanent magnet 10, as shown in
According to the present embodiment described above, the annular peripheral walls 9 in which the concave parts 9a are formed in the central parts thereof are formed on the surfaces of the fixed contactors 6a, 6b facing the movable contactor 11. Therefore, an annular arc is formed during the open state of the contact device where the fixed contactors 6a, 6b separate from the movable contactor 11. The annular arc is rotated in the circumferential direction by the magnetic flux φ1 of the current passing through the fixed contactors 6a, 6b, facilitating the cooling of the arc (energy absorption). As a result, the arc can be extinguished reliably without using the arc extinguishing permanent magnets 10.
In addition, positioning the arc extinguishing permanent magnets 10 in the concave parts 9a can reliably extinguish the art within a shorter period of time. In this case, it is only necessary to position and fix the arc extinguishing permanent magnets 10 in the concave parts 9a by means of an adhesive or the like, allowing an easy attachment of the arc extinguishing permanent magnets 10 to the fixed contactors 6a, 6b. Alternatively, the concave parts 9a can be, for example, cut and formed coaxially with the central axes of the fixed contactors 6a, 6b. Accordingly, the arc extinguishing permanent magnets 10 can also be reliably positioned coaxially with the central axes of the fixed contactors 6a, 6b.
Moreover, precisely extinguishing the arc can narrow the gap between the fixed contactors 6a, 6b and the movable contactor 11 and reduce an open time period for interrupting the current.
Note that the present embodiment has described the case in which the fixed contactors 6a, 6b are configured by the large-diameter head parts 7 and the small-diameter cylinder parts 8, but the present invention is not limited thereto; therefore, the entire fixed contactors 6a, 6b may be formed into cylinders.
The cross-sectional shape of the small-diameter cylinder parts 8 of the fixed contactors 6a, 6b is not limited to a circular shape; therefore, the cross-sectional shape of the small-diameter cylinder parts 8 can be any shape, including ellipses and squares, and in accordance with this, the cross-sectional shape of the concave parts 9a and the arc extinguishing permanent magnets 10 may be changed to an identical shape.
Furthermore, the present embodiment has described the case in which the arc extinguishing permanent magnets 10 are positioned in the concave parts 9a of the fixed contactors 6a, 6b, but sufficient arc extinction performance can be still accomplished without providing the arc extinguishing permanent magnets 10.
Moreover, the present embodiment has described the case in which the insulation airtight container 4 functioning as an arc-extinguishing chamber sealing a gas therein, but the present invention is not limited thereto; therefore, the gas may not be sealed.
In addition, the present embodiment has described the case in which the movable contactor 11 is formed flat, but the present invention is not limited thereto; therefore, a central part between contact points of the movable contactor 11 that face the fixed contactors 6a, 6b may be shaped into a concave or a convex.
The configuration of the electromagnetic unit 3 is not limited to the present embodiment; therefore, any configuration can be applied as long as the contactor holder 12 can be moved electromagnetically.
Moreover, the present embodiment has described the case in which the contact device 2 of the present invention is applied to an electromagnetic contactor, but the present invention is not limited thereto; therefore, the contact device 2 can be applied to an electromagnetic relay or any switches, including an electromagnetic switch.
The present invention can provide a contact device in which the surfaces of the fixed contactors facing the movable contactor are configured by the annular peripheral walls having the concave parts in the central parts thereof. In the contact device having such a configuration, an annular arc is generated between the movable contactor and the surfaces of the annular peripheral walls that face the movable contactor when the contact device is in the open state. This contact device can cool the annular arc by rotating the arc in the circumferential direction by means of the magnetic field of the current flowing through the fixed contactors, and thereby extinguish the arc. The present invention can also provide an electromagnetic switch that uses this contact device.
1 . . . Outer case, 2 . . . Contact device, 3 . . . Electromagnetic unit, 4 . . . Insulation airtight container, 4a . . . Upper case, 4b . . . Lower case, 6a, 6b . . . Fixed contact, 7 . . . Large-diameter head part, 8 . . . Small-diameter cylinder part, 9 . . . Concave part, 10 . . . Arc extinguishing permanent magnet, 11 . . . Movable contact, 12 . . . Contactor holder, 13 . . . Contact spring, 15a, 15b . . . External connection terminal strip, 21 . . . Magnetic yoke, 22 . . . Upper surface magnetic yoke, 23 . . . Exciting coil, 24 . . . Coil holder, 25 . . . Movable core, 26 . . . Cap, 28 . . . Coupling shaft, 31 . . . Return spring
Number | Date | Country | Kind |
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2010-180242 | Aug 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/003379 | 6/14/2011 | WO | 00 | 12/21/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/020529 | 2/16/2012 | WO | A |
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2010-10057 | Jan 2010 | JP |
Entry |
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PCT, “International Search Report for PCT/JP2011/003379”, Jul. 12, 2011. |
Number | Date | Country | |
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20130127571 A1 | May 2013 | US |