The present invention relates to a solenoid, which is used in various apparatus such as a key for money box of register, an unlock mechanism of shift lever for automobile.
More specifically, the present invention relates to a solenoid, which is inexpensive and small and can be easily attached.
An existing solenoid is generally configured by a section channel shaped yoke body having upright side walls directed upward in the opposed side edges of the bottom, a stopper receiver fixed on the bottom, a plunger attached to the plunger (iron core), and a yoke lid for closing the opening portion of the yoke.
Conventional solenoid is configured so that a magnetic field is generated around the coil when the coil is energized through the counterpart connector portion (female terminal) inserted to the connector part (male terminal).
An example of such a solenoid is disclosed in Patent Document 1.
In Japanese Patent Kokai Application Publication No. JP2013-222806A (Patent Document 1), a flapper-type solenoid is proposed that, includes a bobbin having an electromagnetic coil that is disposed in a yoke, a magnetic core that is disposed in the bobbin, a flapper that is disposed above the yoke to be able to swing freely by a spring member engaged with the base end portion as the primary components,
wherein at least the bobbin and the flapper that is disposed above the bobbin to be able to swing freely are formed from a plastic material, and the bobbin and the flapper are integrally connected through the spring member having an arc-shaped cross section.
This flapper-type solenoid is configured so that a magnetic field is generated around the coil when the coil is energized through lead wire(s).
Conventional flapper-type solenoids, such as the flapper-type solenoid disclosed in Patent Document 1, are configured so that the solenoid and the opposite party (various apparatus) are generally connected to each other by inserting male terminal(s) projecting from a connector part of the solenoid into female terminal(s) provided with a counterpart connector part, or through lead wire(s) so as to generate a magnetic field around a coil by energizing the coil.
Therefore, there is a problem in that a large space is required for providing the connector part or the lead wire(s) in the conventional solenoids.
Furthermore, in attaching the conventional solenoid to various apparatus, there is a problem in that the attaching work is complicated since two steps of a step of attaching the solenoid body to the apparatus and a step of connecting the solenoid and the apparatus through the connector part or the lead wire(s) are required.
In light of the foregoing, an object of the present invention is to provide a solenoid that is inexpensive and small and can be easily attached to various apparatus without a lead wire.
To achieve the above-described object, an aspect of the present invention described in claim 1 is a solenoid that contains a yoke, a bobbin having an electromagnetic coil disposed inside the yoke, and an iron core disposed inside the bobbin,
According to an aspect of the present invention described in claim 2, in the solenoid described in claim 1,
According to an aspect of the present invention described in claim 3, in the solenoid described in claim 1 or 2,
According to an aspect of the present invention described in claim 4, in the solenoid described in any one of claims 1 to 3,
According to an aspect of the present invention described in claim 5, in the solenoid described in claim 1,
According to an aspect of the present invention described in claim 6, in the solenoid described in claim 5,
According to an aspect of the present invention described in claim 7, in the solenoid described in claim 1,
According to an aspect of the present invention described in claim 8, in the solenoid described in claim 7,
According to an aspect of the present invention described in claim 9, in the solenoid described in claim 8,
The solenoid according to the present invention contains a yoke, a bobbin having an electromagnetic coil disposed inside the yoke, and an iron core disposed inside the bobbin.
In this solenoid, a connector part incorporating a prescribed number of terminal metal fittings is provided on one end portion of the bobbin.
Thus, in this solenoid, a relatively large space is not required for disposing lead wire(s) as in the prior art. Therefore, the solenoid is small, so that the solenoid can be inexpensively produced.
In the solenoid, among the terminal metal fittings, the terminal, which is connected electrically to an external terminal provided with an apparatus having the solenoid, may be configured by a female terminal.
By such a configuration, in this solenoid, a relatively large space is not required for providing a male terminal. In addition, when attaching the solenoid to the apparatus, the solenoid can be easily incorporated in the apparatus by inserting a male terminal, which is provided as a terminal on an external connector (external power source) provided with the apparatus, into the female terminal. Therefore, since it is not required to connect the solenoid and the apparatus through a connector part or lead wire(s), the assembly efficiency can be largely improved.
Furthermore, in the solenoid, the connector part may be provided on one axial end part of the bobbin.
Such a configuration allows the size of the solenoid to be reduced further.
In the solenoid, the bobbin may be configured as a coupling body in which two bobbins are axially coupled to each other. In this case, the iron core may be configured by a first fixed iron core having the upper end fixed to the lower face of the yoke lid, a second fixed iron core having the lower end fixed to the bottom face of the yoke, and a movable iron core disposed to be able to oscillate freely between the first fixed iron core and the second fixed iron core, and the connector part may have three terminal metal fittings which are provided at prescribed spaces, and among the electromagnetic coils, one end of a winding forming a first electromagnetic coil may be electrically connected to a first terminal metal fitting, the other end of the winding forming the first electromagnetic coil and one end of a winding forming a second electromagnetic coil may be electrically connected to a second terminal metal fitting, and the other end of the winding forming the second electromagnetic coil may be electrically connected to a third terminal metal fitting, respectively.
When one electromagnetic coil of two upper and lower electromagnetic coils, which are wound around the coupling body, is energized, the movable iron core is oscillated freely in the direction of the electromagnetic coil, which is energized, by such a configuration.
Hereinafter, the solenoid according to the present invention will be described in detail below with reference to the accompanying drawings.
Note that the present invention is not limited only to examples disclosed herein, and various modifications can be made thereto without changing the gist of the present invention.
As illustrated in
In
Note that in
In
The bobbin 3 is for winding a winding (conductor wire) which configures the electromagnetic coil 4, and contains, as a main body thereof, a tubular barrel part 3a around which the winding is wound. The connector part 6, which incorporates a prescribed number of terminal metal fittings, is provided on one axial end part of the barrel part 3a.
Note that in the Examples, the bobbin 3 is formed from an insulating synthetic resin.
In
Such a configuration allows the size of the solenoid to be reduced further.
Note that in the Examples, the case body 6a configuring the connector part 6 is configured to be integrally formed with the flange portion of the other end side of the bobbin 3; however, the case body 6a and the flange portion may not necessarily be integrally formed, and they may be separately formed respectively.
Furthermore, in
In
Note that in
Thus, the through hole 3c has an inner diameter approximately equal to the outer diameter of the pipe 9.
In the Examples, the bobbin is configured by one bobbin body. However, the bobbin may be configured as a bobbin coupling body which is formed by coupling two or more bobbin bodies.
Note that the number of the bobbin body may be appropriately changed according to the use, configuration, and the like of the solenoid.
As a main characteristic of the present invention, the connector part incorporating a prescribed number of terminal metal fitting(s), preferably female connecting terminal(s), which is (are) electrically connected to external terminal(s) provided with various apparatus, is provided on one end part of the bobbin, which is installed inside a central portion of the yoke.
The configuration of such connector part is not particularly limited as long as the terminal metal fitting is electrically connected to the external terminal, which is provided with various apparatus.
By such a configuration, the solenoid is small since a relatively large space is not required for disposing lead wire(s) as in the prior art, so that the solenoid can be inexpensively produced.
The connector part 6, which incorporates a prescribed number of terminal metal fitting(s), can be provided on one end part of the bobbin 3.
The connector part 6 is preferably provided on one axial end part (upper end or lower end) of the bobbin 3.
Such a configuration allows the size of the solenoid to be reduced further.
In
Note that in
As illustrated in
In
Furthermore, in
Note that in
In case that the terminal metal fittings 71 and 72 are respectively configured by a female terminal, the lateral side opening portions 6f and 6f are used in inserting male terminals, which are provided with various apparatus as external terminals 101 and 101, into the terminal metal fittings 71 and 72 when the male terminals are electrically contacted with the terminal metal fittings 71 and 72.
Furthermore, as illustrated in
Both of the terminal metal fittings 71 and 72 are formed from a material having conductivity, and are configured to have the one end connected electrically to a winding and the other end connected electrically by contacting with contact portions of external terminals (not illustrated) provided with the external connector of the opposite party (various apparatus).
Note that in the Examples, the terminal metal fittings 71 and 72 are formed from a material having spring properties as well as conductivity; however, the configuration of terminal metal fitting is not particularly limited as long as the terminal metal fitting is formed from at least a material having conductivity so as to connect electrically to the external terminal of the external connector as a terminal.
An embodiment of the terminal metal fitting may be selected according to an embodiment of the external terminal provided with the apparatus to be attached. The terminal metal fitting is preferably selected from a female terminal.
By such a configuration, a relatively large space is not required for disposing a male terminal, and additionally when attaching the solenoid to the apparatus, the solenoid can be easily incorporated in the apparatus by inserting male terminal(s), which is (are) provided as a terminal to an external connector (external power source) provided with the apparatus, into the female terminal(s). Thus, since it is not required to connect the solenoid and the apparatus through a connector part or lead wire(s), the assembly efficiency can be largely improved.
As illustrated in
The engaging portions 71b and 72b are formed by bending the front end portions in a longitudinal direction of the terminal bodies 71a and 72a, and are formed in a U-shaped opening outwardly. The engaging portions 71b and 72b engage with the engaging projections 66a and 66a of the case body 6a.
The elastic contact portions 71c and 72c are formed by bending the tip portions of the engaging portions 71b and 72b vertically backward to make them parallel to the terminal bodies 71a and 72a, and contact with external terminals of the external connector.
Thus, the elastic contact portions 71c and 72c are elastically displaceable in the plate thickness direction, and can contact elastically with the external terminals (male terminals) inserted from the terminal insertion ports 6f and 6f.
The winding connecting portions 71d and 72d are formed protruding upward from the rear edge sides in a longitudinal direction of the terminal bodies 71a and 72a to connect electrically to a winding.
Furthermore, winding guide portions 71e and 72e are formed by folding back the extension pieces, which are protruded from the rear end edge of the terminal bodies 71a and 72a, to guide a winding.
As described above, in
Thus, the terminal metal fittings 71 and 72 are held in the case body 6a by pressing the terminal bodies 71a and 72a into the holding groove portions 65a and 65a in a state where the engaging portions 71b and 72b engage with the engaging projections 66a and 66a.
Note that in the Examples, the terminal metal fittings 71 and 72 are attached to the case body 6a by pressing the terminal metal fittings 71 and 72 into the holding groove portions 65a and 65a which are formed on the stepped portion 63a of the case body 6a; however, the terminal metal fittings 71 and 72 can be attached to the case body 6a by using a known method such as a method of burying the terminal metal fitting into the case body through integral molding.
Furthermore, in the Examples, the number of the terminal metal fitting is two. However, the number of the terminal metal fitting may be appropriately changed according to the number of a winding, which forms an electromagnetic coil, or the like.
In
In addition, a through hole 6e is formed on a center portion of the case cover 6b so as to correspond to the through hole 6d, which formed on a center portion of the case body 6a. As illustrated in
Such bobbin having the connector part configures a coil device, for example, by connecting one end (winding-start end portion) of a winding electrically to one terminal metal fitting 71, and further drawing the winding, which is led out from the winding-start end portion of the winding, in the winding guide portion 67a, and then drawing it in the winding guide portion 67b after winding it around an outer peripheral portion of the barrel part 3a in a prescribed winding direction to form an electromagnetic coil 4, and connecting the other end (winding-finish end portion) of the winding electrically to the other terminal metal fitting 72.
As illustrated in
The iron core 5 is formed from iron or the like, and has a cylindrical shape, and is disposed in the bobbin 3.
The specific configuration of the iron core 5 is particularly limited. A known configuration can be selected according to a specific configuration, form, and the like of the applied solenoid.
For example, the iron core 5 may be configured by a fixed iron core only, a movable iron core only, or a combination of a fixed iron core and a movable iron core.
In
Specifically, as illustrated in
Furthermore, as illustrated in
Such a configuration allows the plunger 5a to be oscillated freely inside the bobbin 3 in the axial direction by a magnetic field generated by the energization of the electromagnetic coil 4.
Note that in
Thus, the attaching member 10 is not always required.
Furthermore, in
The pipe 9 produces an effect for making the oscillation of the plunger 5a smooth by guiding the sliding of the plunger 5a, which configures the iron core 5, inside the pipe 9, and additionally an effect for solving a problem that the plunger 5a is hardly oscillated by contraction of the bobbin 3 in the use under a high temperature environment.
Note that the pipe 9 is configured so that the axial length thereof is approximately equal to the length from the upper face of the yoke lid 8 to the bottom face of the yoke 2 (upper face of the base portion 2a), and the flat plate-shaped flange portion 3b, which is formed protruding outward in a radical direction from one axial end of the pipe 9, is locked in the upper face of the yoke lid 8.
According to the solenoid 1 having such a configuration, since the plunger 5a is oscillated freely inside the bobbin 3 in the axial direction by a magnetic field generated from the electromagnetic coil 4 by energization between the solenoid 1 and an external connector (external power source) provided with various apparatus. Thus, various apparatus, which is coupled with the plunger 5a through the attaching member 10 attached to the upper end of the plunger 5a, also conducts prescribed operation(s) accompanied by the oscillation of the plunger 5a.
In the present invention, the configuration of solenoid is not limited to the above descriptions. Therefore, the present invention includes a solenoid configured by a plurality of solenoids, such as a U-type solenoid, more concretely, a solenoid in which a plurality of solenoids containing a yoke, a bobbin having an electromagnetic coil disposed inside the yoke, and an iron core disposed inside the bobbin as the unit are coupled.
The solenoid 11 illustrated in
The solenoid 11 has the approximately same configuration as the solenoid 1, and configures what is called a flapper-type solenoid. The solenoid 11 differs from the solenoid 1 in that, the iron core 15 is only configured by a columnar fixed iron core having a prescribed length, the connector part 16 incorporating a prescribed number of terminal metal fittings (not illustrated) is provided on a lower end of the bobbin 13, and instead of the yoke lid, the flapper (movable plate) 18 is attached to the upper portion of the yoke 12 to be able to swing freely.
As illustrated in
Note that in
At a center portion of the outer face of one of the raised portion 12b of the yoke 12, a protrusion 12g is provided protruding slightly downwardly, and one end of a spring member S that constantly energizes the flapper 18 in a direction causing the flapper 18 to move away from the yoke 12 is engaged with the protrusion 12g.
Meanwhile, as illustrated in
The connector part 16 is integrally provided on the lower end of the bobbin 13, and has the same configuration as the connector part 6, and is configured so that the terminal metal fittings incorporated in the connector part 16 are contacted with the external terminals (male terminals) inserted from terminal insertion ports 16f and 16f opened in the side, which are formed to penetrate through the front wall of the connector part 16.
In
Furthermore, the iron core 15 is deposed inside the bobbin 13 in a state where the lower end of the iron core 15 is fixed to the base portion 12a of the yoke 12.
In the solenoid 11 having such a configuration, the flapper 18 moves away from the yoke 12 by energizing force of the spring member S in a state where an energization is not conducted, and since a magnetic field is generated when the electromagnetic coil 14 is energized, the flapper 18, which is deposed to be able to swing freely on the upper portion of the iron core 15, is sucked to the iron core 15.
The solenoid 21 illustrated in
The solenoid 21 has the approximately same configuration as the solenoid 1. As illustrated in
The bobbin 23 is configured by a first bobbin 231, a second bobbin 232 disposed in series (in alignment in an axial direction) to the first bobbin 231, and a connecting part 233 coupling the first bobbin 231 and the second bobbin 232 in an axial direction (in series). As illustrated in
Note that in the Examples, the connecting part 233 is configured by a plate-shaped body having a required size; however, the configuration of connecting part is not particularly limited as long as one end portion of the first bobbin 231 can be coupled with one portion of the second bobbin 232 in series.
Ribs 233a, 233b and 233c, which protrude outward in a radical direction and extend in an axis direction, are formed by forming guide grooves 233d and 233e having a required depth on center portion and both end portions in an outer face in a radical direction of the connecting part 233 at prescribed spaces.
The guide grooves 233d and 233e configure a winding guide portion for guiding one end (winding-start side) and the other end (winding-finish side) of a winding, which is wound around an outer peripheral portion of the barrel part of the bobbin disposed in a position apart from the connector part 26 (the first bobbin 231 in
The connector part 26 has the approximately same configuration as that of the solenoid 1. As illustrated in
In
Among the terminal metal fittings, one end of a winding forming a first electromagnetic coil 24a is electrically connected to a first connecting terminal 71, the other end of a winding forming a second electromagnetic coil 24b is electrically connected to a second connecting terminal 72, and the other end of the winding forming the first electromagnetic coil 24a and one end of the winding forming the second electromagnetic coil 24b are electrically connected to the central relay terminal 73, respectively.
The iron core 25 is configured by a plunger 25a mounted inside the bobbin coupling body 23 to be able to oscillate freely, and a pair of stoppers 25b and 25c which are disposed on both end of the plunger 25a for preventing the plunger 25a from deviating from the inside of the yoke 22.
As illustrated in
While both of the upper end portion of the stopper 25c and the lower end portion of the stopper 25b are formed in the shape of a truncated cone, and a recess, which faces the lower end portion of the stopper 25b and the upper end portion of the stopper 25c respectively, is formed on both ends of the plunger 25a disposed between the stoppers 25b and 25c by notching toward the interior thereof in axial direction in a required depth, and they are fitted to each other.
Note that the stopper 25b is made longer by an axial length of the connector part 26 than the stopper 25c.
In this example, the columnar pipe 29, which has an outer diameter approximately equal to the inner diameter of the barrel part of the bobbin coupling body 23, is provided inside the bobbin coupling body 23, and the plunger 25a, which has an outer diameter approximately equal to the inner diameter of the pipe 29, is arranged inside the pipe 29.
The pipe 29 is configured so that the axial length thereof is approximately equal to the length from the upper face of the yoke lid 28 to the bottom face of the yoke 22 (upper face of the base portion 22a). A flat plate-shaped flange portion, which is formed protruding outward in a radical direction from one axial end of the pipe 29, is locked in the lower face of the bobbin coupling body 23.
Note that, as illustrated in
In the solenoid 21 having such a configuration, in a state where an energization is not conducted, by a pair of magnets 30 and 30 provided at an axial center portion of the bobbin coupling body 23, the plunger 25a is disposed in the vicinity of the center portion in a stationary state, and when one electromagnetic coil of electromagnetic coils 24a and 24b, which are wound around the bobbin coupling body 23, is energized, the plunger 25a is oscillated freely in the direction of the electromagnetic coil, which is energized.
The plunger 25a is coupled with a prescribed member of various apparatus or device through a guide bar G for an attaching member. Therefore, the guide bar G is also oscillated freely in the axial direction accompanied by the oscillation of the plunger 5a, and as a result, this apparatus or device conducts prescribed operation(s).
In attaching the solenoid of the present invention to various apparatus, for example, as illustrated in
Thus, the solenoid of the present invention can be easily attached to various apparatus by simply fitting into a prescribed position of the apparatus.
In the solenoid according to the present invention, since a connector part incorporating a prescribed number of terminal metal fitting(s), in particular, female terminal(s) is provided on one end part of a bobbin having an electromagnetic coil, which is disposed inside a yoke, the solenoid is inexpensive and small, and can be easily attached to various apparatus. Thus, the solenoid can be used in a wide range of fields.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/010385 | 3/13/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/183675 | 9/17/2020 | WO | A |
Number | Name | Date | Kind |
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3022450 | Chase, Jr. | Feb 1962 | A |
3634735 | Komatsu | Jan 1972 | A |
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5821840 | Ricker | Oct 1998 | A |
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20130328649 | Robertson | Dec 2013 | A1 |
20190096557 | Church | Mar 2019 | A1 |
20200027636 | Kobayashi | Jan 2020 | A1 |
20210012938 | Dams | Jan 2021 | A1 |
20220189671 | Ushikubo | Jun 2022 | A1 |
Number | Date | Country |
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52-50356 | Nov 1977 | JP |
2002-289422 | Oct 2002 | JP |
2012-186237 | Sep 2012 | JP |
2013-206911 | Oct 2013 | JP |
2013-222806 | Oct 2013 | JP |
WO 2018173189 | Sep 2018 | WO |
Number | Date | Country | |
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20220181060 A1 | Jun 2022 | US |