JP2016219617A - solenoid - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solenoid capable of easily adjusting response speed.SOLUTION: A solenoid includes: a first stator core made of a magnetic material: a stator winding provided on the outer periphery of the first stator core; and a movable element made of the magnetic material arranged coaxially with the first stator core. Between the movable element and the first stator core, a plurality of magnetic flux paths exist, and the solenoid further includes eddy current generating means formed of a nonmagnetic conductive material. At least one of the above-mentioned magnetic flux paths at least penetrates through or interlink with the above-mentioned eddy current generating means.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a solenoid.

  The present invention relates to a solenoid that opens and closes a valve for controlling the flow rate of combustible steam in an internal combustion engine by linearly moving a mover made of a magnetic material by magnetic force.

  As a flow control valve for combustible steam in an internal combustion engine, for example, a solenoid as disclosed in Patent Document 1 and Patent Document 2 is known. In the solenoid, the valve is opened and closed by a linear motion of a magnetic material mover by a magnetic attractive force. A conventional solenoid is composed of a flow path section through which combustible steam flows and a magnetic path configuration section that opens and closes a valve. The magnetic path constituent part is composed of a stator and a mover made of a magnetic material. A stator winding capable of supplying an exciting current from a power source is installed in the magnetic path constituting unit. When an exciting current is supplied from the power source to the stator winding, the magnetic path component is magnetized, a magnetic attraction force is generated between the stator and the mover, and the mover moves in a linear motion. Open and close the valve.

  When a constant exciting current is supplied to the stator winding by such a solenoid, the magnetic flux flowing through the mover and the stator increases as the distance between the mover and the stator decreases. For this reason, as the mover approaches the stator, the magnetic attractive force acting between the mover and the stator increases, and the mover accelerates. When the mover moving at high speed collides with the stator, it becomes a problem to generate a loud collision sound.

  With respect to this problem, in Patent Document 1 and Patent Document 2, when the magnetic flux changes, at least the magnetic flux interlinks or penetrates into the eddy current generating means made of a nonmagnetic conductive material that generates eddy current. A method has been proposed in which eddy current is generated in the eddy current generating means, and the amount of magnetic flux that increases when the mover approaches the stator is reduced, the increase in magnetic attraction force is suppressed, and acceleration of the mover is suppressed. .

Japanese Utility Model Publication No. 06-002622 Japanese Patent Application Laid-Open No. 07-086029

  In the conventional solenoid, the eddy current generating means made of a non-magnetic conductive material generates an eddy current when an exciting current flows through the stator winding, thereby suppressing the acceleration of the mover. However, since eddy currents are always generated regardless of the position of the mover, not only immediately before the collision of the mover that needs to be suppressed with the stator but also immediately after the stator winding that does not need to be suppressed is excited However, there is a problem that it is difficult to suppress acceleration and adjust the response speed.

  The present invention has been made in view of the above, and an object thereof is to provide a solenoid capable of easily adjusting a response speed.

  In order to achieve the above-described object, a solenoid according to the present invention includes a first stator core made of a magnetic material, a stator winding provided on an outer periphery of the first stator core, and the first stator core. A mover made of a magnetic material arranged coaxially, and a plurality of magnetic flux paths exist between the mover and the first stator core, and is made of a nonmagnetic conductive material. The eddy current generating means is further provided, and at least one of the magnetic flux paths penetrates or links at least the eddy current generating means.

  According to the present invention, the response speed can be easily adjusted.

It is a fracture | rupture perspective view which shows the structure of the solenoid regarding Embodiment 1 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 1 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 1 of this invention. It is a figure which shows the variation | change_quantity (d (PHI) / dt) of the magnetic flux with respect to the position of a needle | mover regarding Embodiment 1 of this invention. It is the figure which looked at the eddy current generation source from the mover side said to an axial direction regarding Embodiment 1 of this invention, and is a figure which shows the state in which the eddy current is flowing. It is the figure which looked at the eddy current generation source from the mover side said to an axial direction regarding Embodiment 1 of this invention, and is a figure which shows the state where the eddy current does not flow. It is a figure which shows the state of the first half of a stroke regarding Embodiment 2 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 2 of this invention. It is the figure which looked at the eddy current generation source from the mover side said to an axial direction regarding Embodiment 2 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 3 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 3 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 4 of this invention. It is a figure which shows the state of the stroke latter half regarding Embodiment 4 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 5 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 5 of this invention. It is a figure which shows the state of stroke early stage regarding Embodiment 6 of this invention. It is a figure which shows the state of an intermediate stroke regarding Embodiment 6 of this invention. It is a figure which shows the state of the stroke end stage regarding Embodiment 6 of this invention. It is a figure which shows the variation | change_quantity (d (PHI) / dt) of the magnetic flux with respect to the position of a needle | mover regarding Embodiment 6 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 7 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 7 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 8 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 8 of this invention. It is a figure which shows the state of the first half of a stroke regarding Embodiment 9 of this invention. It is a figure which shows the state of the second half of a stroke regarding Embodiment 9 of this invention. It is a figure which shows the state of stroke beginning regarding Embodiment 10 of this invention. It is a figure which shows the state of an intermediate stroke regarding Embodiment 10 of this invention. It is a figure which shows the state of the stroke end stage regarding Embodiment 10 of this invention. It is a figure which shows the variation | change_quantity (d (PHI) / dt) of the magnetic flux with respect to the position of a needle | mover regarding Embodiment 10 of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals indicate the same or corresponding parts.

Embodiment 1 FIG.
1 is a cutaway perspective view showing the structure of a solenoid according to Embodiment 1 of the present invention. The solenoid includes a first stator core 1 made of a magnetic material, a stator winding 3 wound around the outer periphery of the first stator core 1, and an axial reciprocation arranged coaxially with the first stator core 1. The movable member 7 made of a magnetic material capable of operation, the second stator core 2 made of a magnetic material and disposed outside the stator winding 3, and the flow passage portion 4 made of resin are provided.

  The flow path part 4 includes an introduction port 9 for introducing a fluid into the flow path part 4 and a lead-out port 5 for deriving the fluid from the flow path part 4 to the outside.

  The solenoid shown in FIG. 1 has an axially symmetric structure in which all cross sections including the central axis are substantially the same, and will be described below using a two-dimensional cross section.

  2 and 3 are two-dimensional sectional views showing the structure of the solenoid according to the present invention. FIG. 2 is a diagram showing the state of the first half of the stroke, and FIG. 3 is a diagram showing the state of the second half of the stroke. The first half of the stroke indicates the first half of the time when the mover performs the valve opening operation, and the second half of the stroke indicates the second half of the time when the mover performs the valve opening operation. Yes. The same applies to FIGS. 7, 8, 10, 11, 12, 13, 14, and 15.

  The operation principle of the solenoid will be described with reference to FIGS. A cylindrical third stator core 11 serving as a central axis is disposed on the inner peripheral side of the first stator core 1 shown in FIGS. 2 and 3, and the third stator core 11 and the mover 7 are arranged. The spring 12 is arranged on the central axis of the. The spring 12 expands and contracts in the central axis direction.

  The first stator core 1 has a cylindrical shape and is excited by supplying an excitation current to the stator winding 3 to form a magnetic circuit.

  The mover 7 has a cylindrical shape, is loosely inserted in the inner periphery of the stator winding 3 so as to be capable of reciprocating in the axial direction, and forms a magnetic circuit together with the first stator core 1. When the mover 7 reciprocates in the axial direction, it functions as a valve.

  The second stator core 2 forms a magnetic circuit together with the first stator core 1 and the movable element 7 by supplying an exciting current to the stator winding 3, and has a substantially cylindrical shape, and one end portion is formed. The first stator core 1 and the first stator core 1 are closely fixed so that the magnetic resistance does not increase.

  The opposite end of the second stator core 2 has a hole larger than the diameter of the mover 7 so that the mover 7 can reciprocate.

  The magnetic flux generated by supplying the exciting current to the stator winding 3 mainly flows through a path having a small magnetic resistance. Hereinafter, the magnetic flux flowing through the path having a small magnetic resistance is referred to as a main magnetic flux 6. The main magnetic flux 6 forms a magnetic circuit by circulating through the first stator core 1, the second stator core 2, and the mover 7.

  When the stator winding 3 is disconnected, the mover 7 is urged toward the introduction port 9 by the spring 12, thereby closing the flow path of the introduction port 9 and closing the valve. A rubber 8 is installed at the end of the mover 7 on the side of the introduction port 9 to enhance confidentiality when the valve is closed.

  When a constant voltage is applied to both ends of the stator winding 3, an excitation current is supplied to the stator winding 3, and the first stator core 1, the second stator core 2, and the mover, which are magnetic materials, are supplied. 7 is excited.

  A magnetic attraction force acts between the excited mover 7 and the first stator core 1, and the mover 7 moves in the direction of the first stator core 1. , And a valve-opening state in which combustible vapor passes through the flow path portion 4 is established.

  The solenoid of the first embodiment having the above configuration is used, for example, in a flow rate control device for combustible steam of an internal combustion engine.

  Next, a method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS.

  The first stator core 1 has a step shape in which the axial length is changed in at least three steps in the radial direction, and extends in the direction of the mover 7 in the order of an outer diameter side step, an inner diameter side step, and an intermediate step. .

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the inner peripheral side with respect to the step on the outer diameter side of the first stator core 1.

  The eddy current generating means 10 formed of a nonmagnetic conductive material is disposed in the middle stage of the first stator core 1. The eddy current generating means 10 is formed in an annular shape when viewed from the movable element 7 side in the axial direction.

  When the stator winding 3 is changed from the disconnected state to the exciting current supply state, that is, when the stator winding 3 is shifted from the valve closing state to the valve opening state, the mover 7 is biased by the spring 12, and the first stator core 1. And the most distant position in the axial direction. Therefore, the main magnetic flux 6 generated when the exciting current is supplied to the stator winding 3 passes through the tip of the mover 7 which is the path having the lowest magnetic resistance and the tip of the first stator core 1 on the outer diameter side. The magnetic attraction force acts between the first stator core 1 and the mover 7, and the mover 7 moves in the direction of the first stator core 1.

  Since the main magnetic flux 6 flows on the outer peripheral side of the eddy current generating means 10 for a certain period after the mover 7 starts to move in the direction of the first stator core 1, no eddy current is generated in the conductive material.

  Eddy currents are not generated unless the amount of magnetic flux that interlinks or penetrates the conductive material, or that interlinks and penetrates, does not change.

  When a certain period of time has passed since the supply of the excitation current to the stator winding 3 is started, the distance between the mover 7 and the step on the inner diameter side of the first stator core 1 is reduced. The magnetic resistance between the inner core side of the stator core 1 is reduced, and the main magnetic flux 6 is branched into the first path 13 and the second path 14.

  Hereinafter, when the main magnetic flux 6 branches into a plurality of paths, the branched paths are referred to as a first path (flux path) 13 and a second path (flux path) 14.

  Since the 1st path | route 13 passes the outer peripheral side of the eddy current generation means 10, since an eddy current generation means 10 is neither linked nor penetrated, an eddy current does not flow. That is, the first path does not penetrate or interlink with the eddy current generating means, and the second path at least penetrates or links with the eddy current generating means.

  On the other hand, in the second path 14, the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, so the amount of change (dΦ / dt) in the magnetic flux is small. Since the magnetic resistance between the first stage and the second stage becomes smaller, the amount of magnetic flux increases as the mover 7 and the first stator core 1 approach each other, so the amount of change in magnetic flux (dΦ / dt) increases. As a result, the amount of change (dΦ / dt) of the main magnetic flux 6 linking the inner peripheral side of the eddy current generating means 10 closed in the circumferential direction increases, so that an eddy current is generated in the eddy current generating means 10.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  Since an eddy current flows through the eddy current generating means 10, a magnetic flux in the direction opposite to the main magnetic flux 6 is generated, so that an increase in magnetic attraction force is hindered and acceleration of the mover 7 is suppressed. An eddy current is generated at an arbitrary position of the mover 7 to suppress the acceleration of the mover 7 and to reduce the collision sound with the stator.

  FIG. 4 shows the change amount (dΦ / dt) of the magnetic flux in the first and second paths 14 with respect to the stroke amount of the mover 7. The amount of change (dΦ / dt) in the magnetic flux according to the first embodiment will be described with reference to FIG.

  The stroke 0% is the position of the movable element 7 when the valve is closed, and the movable range of the movable element 7 is from 0% to 100%. In each of the first and second paths 14, the amount of change (dΦ / dt) in magnetic flux per unit time varies depending on the position of the mover 7.

  In the first path 13, in the first half of the stroke, as the mover 7 approaches the first stator core 1, the magnetic resistance decreases and the amount of magnetic flux increases, so the amount of change in magnetic flux (dΦ / dt) is large. In FIG. 4, the amount of magnetic flux does not increase due to magnetic saturation, and the amount of change in magnetic flux (dΦ / dt) decreases.

  On the other hand, in the second path 14, the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, so the amount of change in magnetic flux (dΦ / dt) is small, but in the second half of the stroke, the mover 7 approaches the first stator core 1. Since the magnetic resistance decreases, the amount of magnetic flux increases, and the amount of change in magnetic flux (dΦ / dt) increases.

  In the first embodiment, the amount of change (dΦ / dt) in the magnetic flux of the second path 14 is large only in the second half of the stroke, so that eddy current flows through the eddy current generating means 10 only in the second half of the stroke.

  The amount of change in magnetic flux (dΦ / dt) in the first path 13 is also large in the first half of the stroke. However, as described above, the first path 13 passes through the outer peripheral side of the eddy current generating means 10, so the eddy current generating means. The eddy current does not flow through the eddy current generating means 10 without passing through the chain. As described above, in at least one of the plurality of paths, the amount of change in magnetic flux per unit time (dΦ / dt) varies depending on the position of the mover 7. For this reason, it becomes possible to generate an eddy current at an arbitrary position of the mover 7, and it is possible to reduce the collision speed by reducing the collision speed with the stator without reducing the response speed of the mover 7.

  Next, the necessity of closing the eddy current generating means 10 in the circumferential direction will be described with reference to FIGS. 5 and 6. FIGS. 5 and 6 are views of the eddy current generating means 10 as viewed from the movable element 7 side in the axial direction. If the eddy current generating means 10 is closed in the circumferential direction as shown in FIG. 5, the magnetic flux in the second path 14 is linked to the inner peripheral side of the closed eddy current generating means 10. Eddy current 15 flows. On the other hand, when the eddy current generating means 10 is not closed in the circumferential direction as shown in FIG. 6, the eddy current 15 does not flow because the electrical resistance of the path through which the eddy current 15 flows increases.

  In the first embodiment, since the eddy current generating means 10 is arranged not in the mover 7 but in the first stator core 1, there is a low possibility that the eddy current generating means is detached when the mover 7 moves.

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described. In addition, this Embodiment 2 may be the same as that of Embodiment 1 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. 7 and 8. In the second embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the direction of the mover 7 in the order of the step on the outer diameter side and the step on the inner diameter side. It extends.

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the inner peripheral side with respect to the step on the outer diameter side of the first stator core 1.

  The eddy current generating means 10 is disposed on the inner diameter side of the first stator core 1. In this configuration, since the first path 13 of the main magnetic flux 6 passes through the outer peripheral side of the eddy current generating means 10, no eddy current flows even if the amount of magnetic flux changes.

  On the other hand, in the second path 14, the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, so the amount of change in magnetic flux (dΦ / dt) is small, but in the second half of the stroke, the mover 7 approaches the first stator core 1. Since the magnetic resistance decreases, the amount of change in magnetic flux (dΦ / dt) increases.

  Since the second path 14 penetrates the eddy current generation means 10, the eddy current generation means 10 generates an eddy current. The amount of change in magnetic flux (dΦ / dt) with respect to the stroke in the second embodiment is shown in FIG.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

In the second embodiment, the eddy current generating means 10 does not have to be closed in the circumferential direction, and an eddy current is generated regardless of the shape, so that there are few restrictions on manufacturing, and the manufacturability is good. FIG.
The reason will be described with reference to FIG.

  FIG. 9 is a view of the eddy current generating means 10 of the second embodiment as viewed from the side of the mover 7 in the axial direction. The magnetic flux passing through the second path 14 penetrates the eddy current generating means 10. Therefore, since the eddy current 15 flowing through the path shown in the figure is generated, the eddy current 15 flows even if the eddy current generating means 10 is not closed in the circumferential direction.

Embodiment 3 FIG.
Next, a third embodiment of the present invention will be described. In addition, this Embodiment 3 may be the same as that of Embodiment 1 or 2 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. 10 and 11. In the third embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least three steps in the radial direction, and is movable in the order of an inner diameter side step, an outer diameter side step, and an intermediate step. It extends in the direction of the child 7.

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the outer peripheral side than the step on the inner diameter side of the first stator core 1.

  The eddy current generating means 10 is arranged in the middle stage of the first stator core 1. The eddy current generating means 10 is formed in an annular shape when viewed from the movable element 7 side in the axial direction.

  In this configuration, since the first path 13 of the main magnetic flux 6 passes through the outer peripheral side of the eddy current generating means 10, no eddy current flows even if the amount of magnetic flux changes.

  On the other hand, since the second path 14 is a path in which the magnetic resistance is the smallest in the first half of the stroke, a larger amount of magnetic flux passes through and the more the magnetic flux flows as the mover 7 approaches the first stator core 1, the change in the magnetic flux. The amount (dΦ / dt) is large.

  Since the second path 14 passes through the inner peripheral side of the eddy current generating means 10, the eddy current generating means 10 generates eddy current.

  The second path 14 generates eddy currents in the eddy current generating means 10 in the second half of the stroke because the magnetic flux saturation (dΦ / dt) occurs due to magnetic saturation at the inner diameter side of the first stator core 1. I won't let you.

  The amount of change in magnetic flux (dΦ / dt) with respect to the stroke in the third embodiment is illustrated in the same way as the first path 13 and the second path 14 in FIG.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  In the third embodiment, the main magnetic flux 6 interlinks with the eddy current generating means, but does not penetrate. Therefore, as in the first embodiment, the eddy current must be closed unless the eddy current generating means 10 is closed in the circumferential direction. Does not occur.

  In the third embodiment, an eddy current is generated in the first half of the stroke. For example, when a spring having a large spring constant is easily accelerated in the first half of the stroke and is difficult to accelerate in the second half of the stroke, This has the effect of suppressing excessive acceleration of the mover.

Embodiment 4 FIG.
Next, a fourth embodiment of the present invention will be described. In addition, this Embodiment 4 may be the same as that of any of Embodiment 1-3 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. In the fourth embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the order of the step on the inner diameter side and the step on the outer diameter side in the direction of the mover 7. It extends.

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the outer peripheral side than the step on the inner diameter side of the first stator core 1. The eddy current generating means 10 is arranged in a step on the outer diameter side of the first stator core 1. In this configuration, the first path 13 of the main magnetic flux 6 passes through the inner diameter side of the eddy current generating means 10 via the inner diameter side of the first stator core 1.

  Since the first path 13 has the smallest magnetic resistance in the first half of the stroke, a large amount of magnetic flux passes through it. Since a larger amount of magnetic flux flows as the mover 7 approaches the first stator core 1, the amount of change in magnetic flux (dΦ / dt) is larger. Therefore, if the eddy current generating means 10 is closed in the circumferential direction, the first path 13 generates eddy current in the eddy current generating means 10 in the first half of the stroke.

  In the first path, in the latter half of the stroke, magnetic flux saturation (dΦ / dt) occurs in the inner diameter side of the first stator core 1, so that the eddy current is generated in the eddy current generating means 10. I won't let you.

  The second path 14 passes through the outer diameter side step of the first stator core 1 and penetrates the eddy current generating means 10.

  In the second path 14, the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, so the amount of change in magnetic flux (dΦ / dt) is small, but in the second half of the stroke, the mover 7 approaches the first stator core 1 and the magnetic resistance Decreases, the amount of change in magnetic flux (dΦ / dt) increases.

  The amount of change (dΦ / dt) in the magnetic flux with respect to the stroke in the fourth embodiment is shown in FIG.

  Therefore, the second path 14 causes the eddy current generating means 10 to generate eddy current in the second half of the stroke.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  In the fourth embodiment, whether or not eddy currents are generated in the first half of the stroke can be changed depending on whether or not the eddy current generating means 10 has a closed shape in the circumferential direction. .

Embodiment 5. FIG.
Next, a fifth embodiment of the present invention will be described. In addition, this Embodiment 5 may be the same as that of any of Embodiment 1-4 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. 14 and 15. In the fifth embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the direction of the mover 7 in the order of the outer diameter side step and the inner diameter side step. It extends.

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the inner peripheral side with respect to the step on the outer diameter side of the first stator core 1.

  The eddy current generating means 10 is arranged at the end portion on the first stator core 1 side in the axial direction of the mover 7. In this configuration, the first path 13 of the main magnetic flux passes through a step on the inner diameter side of the first stator core 1, and the second path 14 passes through a step on the outer diameter side of the stator core.

  In the first path 13, the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, so the amount of change in magnetic flux (dΦ / dt) is small. However, in the second half of the stroke, the mover 7 approaches the first stator core 1 and the magnetic resistance is reduced. Decreases, the amount of change in magnetic flux (dΦ / dt) increases.

  Since the first path 13 penetrates the eddy current generating means 10 in the latter half of the stroke, the eddy current generating means 10 generates an eddy current.

  On the other hand, the second path 14 passes through the outer peripheral side of the eddy current generating means 10 regardless of the position of the mover 7, and the magnetic flux does not link or penetrate the eddy current generating means 10. Does not generate current.

  The amount of change in magnetic flux (dΦ / dt) with respect to the stroke in the fifth embodiment is illustrated, which is the same as that obtained by replacing the first path 13 and the second path 14 in FIG.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  In the fifth embodiment, since the eddy current generating means 10 moves in the axial direction together with the movable element in the movable element 7, convection is generated around the movable element 7, and the heat dissipation of the eddy current generating means 10 is good.

Embodiment 6 FIG.
Next, a sixth embodiment of the present invention will be described. In addition, this Embodiment 6 may be the same as that of any of Embodiment 1-5 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. 16, 17 and 18. In addition, the stroke initial stage, the stroke middle stage, and the stroke end stage have shown the temporal process in case the needle | mover performs valve opening operation | movement in that order. The same applies to FIGS. 26, 27, and 28.

  In the sixth embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the order of the step on the inner diameter side and the step on the outer diameter side in the direction of the mover 7. It extends.

  The mover 7 has a shape in which the end portion on the first stator core 1 side in the axial direction is arranged on the outer peripheral side than the step on the inner diameter side of the first stator core 1.

  The eddy current generating means 10 is arranged at the end portion on the first stator core 1 side in the axial direction of the mover 7. In this configuration, the first path 13 of the main magnetic flux 6 passes through the step on the outer diameter side of the first stator core 1, and the second path 14 passes through the step on the inner diameter side of the stator core.

  In the first path 13, since the magnetic resistance is large and the magnetic flux does not flow at the beginning of the stroke, the amount of change in magnetic flux (dΦ / dt) is small, but the mover 7 approaches the first stator core 1 in the middle and the end of the stroke. Since the resistance decreases, the amount of change in magnetic flux (dΦ / dt) increases.

  Since the first path 13 penetrates the eddy current generating means 10 in the middle and end of the stroke, the eddy current generating means 10 generates an eddy current regardless of whether the eddy current generating means 10 is closed in the circumferential direction.

  Since the second path 14 has the smallest magnetic resistance at the beginning of the stroke, a large amount of magnetic flux passes through it.

  In the second path 14, the magnetic resistance is the smallest at the early stage of the stroke, and as the mover 7 approaches the first stator core 1, a larger amount of magnetic flux flows. In order to penetrate the means 10, an eddy current is generated in the eddy current generating means 10.

  In the second path 14 after the middle of the stroke, the step on the inner diameter side of the first stator core 1 causes magnetic saturation, so the amount of change in magnetic flux (dΦ / dt) becomes small. Does not generate current.

  FIG. 19 shows the amount of change (dΦ / dt) in the magnetic flux with respect to the stroke in the sixth embodiment.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  The sixth embodiment has the effect that the eddy current generation timing can be finely adjusted by adjusting the arrangement and shape of the eddy current generating means 10.

Embodiment 7 FIG.
Next, a seventh embodiment of the present invention will be described. In addition, this Embodiment 7 may be the same as that of any of Embodiment 1-6 mentioned above except the part demonstrated below.

  A method for adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS.

  In the seventh embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the order of the outer diameter side step and the inner diameter side step in the direction of the mover 7. It extends.

  The mover 7 has a step shape in which the axial length is changed in at least two steps in the radial direction, and extends in the direction of the first stator core 1 in the order of the step on the inner diameter side and the step on the outer diameter side.

  The step on the inner diameter side of the mover 7 is arranged on the inner peripheral side from the step on the outer diameter side of the first stator core 1.

  The eddy current generating means 10 is disposed at the end portion on the first stator core 1 side in the axial direction of the outer diameter side step of the mover 7. In this configuration, the first path 13 of the main magnetic flux passes through the step on the inner diameter side of the mover 7.

  Since the first path 13 has the smallest magnetic resistance in the first half of the stroke, a large amount of magnetic flux passes therethrough, and the amount of change (dΦ / dt) in the magnetic flux increases as the mover 7 approaches the first stator core 1.

  Since the first path 13 passes through the inner peripheral side of the eddy current generating means 10, if the eddy current generating means 10 has a shape closed in the circumferential direction, the eddy current is supplied to the eddy current generating means 10 in the first half of the stroke. generate.

In the first path 13, in the second half of the stroke, the stage on the inner diameter side of the mover 7 is magnetically saturated and the amount of change in magnetic flux (dΦ / dt) is reduced, so that no eddy current is generated in the eddy current generating means 10.

  The second path 14 passes through the end face on the first stator core 1 side in the axial direction of the step on the outer diameter side of the mover 7.

  Since the second path 14 has a large magnetic resistance and no magnetic flux flows in the first half of the stroke, the amount of change in magnetic flux (dΦ / dt) is small and the eddy current generating means 10 does not generate an eddy current.

  In the second path 14, in the second half of the stroke, the mover 7 approaches the first stator core 1 and the magnetic resistance decreases, so that the amount of change in magnetic flux (dΦ / dt) increases.

  Since the second path 14 penetrates the eddy current generating means 10, the eddy current generating means 10 generates eddy current in the latter half of the stroke.

  The amount of change (dΦ / dt) of the magnetic flux with respect to the stroke in the seventh embodiment is shown in FIG.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  In the seventh embodiment, the step on the inner diameter side of the mover 7 prevents the eddy current generating means 10 from moving in the radial direction, so that the eddy current generating means 10 is not easily detached from the mover 7 and is robust.

Embodiment 8 FIG.
Next, an eighth embodiment of the present invention will be described. In addition, this Embodiment 8 may be the same as that of any of Embodiment 1-7 mentioned above except the part demonstrated below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS.

  In the eighth embodiment, the first stator core 1 has a step shape in which the axial length is changed in at least two steps in the radial direction, and in the order of the step on the inner diameter side and the step on the outer diameter side in the direction of the mover 7. It extends.

  The mover 7 has a step shape in which the axial length is changed in at least two steps in the radial direction, and extends in the direction of the first stator core 1 in the order of the step on the outer diameter side and the step on the inner diameter side.

  The step on the outer diameter side of the mover 7 is arranged on the outer peripheral side from the step on the inner diameter side of the first stator core 1.

  The eddy current generating means 10 is disposed at the end portion on the first stator core 1 side in the axial direction of the step on the inner diameter side of the mover 7. In this configuration, the first path 13 of the main magnetic flux (main magnetic flux) passes through the step on the outer diameter side of the mover 7.

  Since the first path 13 does not link or penetrate the eddy current generating means 10 which is the eddy current generating means 10, no eddy current is generated.

  Since the second path 14 passes through the end face on the first stator core 1 side in the axial direction of the step on the inner diameter side of the mover 7 and passes through the step on the inner diameter side of the first stator core 1, It penetrates the generating means 10.

  The second path 14 has a large magnetic resistance in the first half of the stroke and no magnetic flux flows, so that the amount of change in magnetic flux (dΦ / dt) is small, and the eddy current generating means 10 does not generate an eddy current.

  In the second path, the magnetic resistance decreases in the second half of the stroke, and the amount of change (dΦ / dt) in the magnetic flux increases as the mover 7 approaches the first stator core 1.

  Since the second path passes through the eddy current generating means 10 which is the eddy current generating means 10, the eddy current generating means 10 generates eddy current even if the eddy current generating means 10 is not closed in the circumferential direction.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  FIG. 4 shows the amount of change (dΦ / dt) in magnetic flux with respect to the stroke in the eighth embodiment.

  In the eighth embodiment, since the eddy current generating means 10 is arranged in the step on the inner diameter side of the mover, the eddy current generating means 10 is not easily detached even if it is thermally expanded and is robust.

Embodiment 9 FIG.
Next, a ninth embodiment of the present invention will be described. The ninth embodiment may be the same as any one of the first to eighth embodiments described above except for the parts described below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS.

  In the ninth embodiment, the mover 7 has a step shape in which the axial length is changed in at least three steps in the radial direction, and the first stator is arranged in the order of the outer diameter side step, the intermediate step, and the inner diameter side step. It extends in the core 1 direction.

  The end of the first stator core 1 on the mover 7 side in the axial direction is arranged on the outer peripheral side from the inner diameter side step of the mover 7 and on the inner peripheral side from the outer diameter side step of the mover 7.

  The eddy current generating means 10 is arranged at the center stage of the mover 7.

  In this configuration, the first path 13 of the main magnetic flux 6 passes through the inner diameter side of the mover 7, and the second path 14 passes through the outer diameter side step of the mover 7.

  In the first path 13, since the magnetic resistance is large and the magnetic flux does not flow in the first half of the stroke, the amount of change in the magnetic flux (dΦ / dt) is small, so the eddy current generating means 10 does not generate eddy current.

  In the first path 13, the magnetic resistance decreases in the second half of the stroke, and the amount of change in magnetic flux (dΦ / dt) increases as the mover 7 approaches the first stator core 1.

  Since the 1st path | route 13 passes the inner peripheral side of the eddy current generation means 10, if the eddy current generation means 10 is closed in the circumferential direction, an eddy current is generated in the eddy current generation means.

  Since the 2nd path | route 14 passes the outer peripheral side of the eddy current generation means 10, since the eddy current generation means 10 is neither linked nor penetrated, an eddy current is not generated.

  The amount of change in magnetic flux (dΦ / dt) with respect to the stroke in the ninth embodiment is similar to that obtained by replacing the first path 13 and the second path 14 in FIG.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  In the ninth embodiment, since both the inner diameter side and the outer diameter side of the eddy current generating means 10 are sandwiched between the movable elements 7, the eddy current generating means 10 is further movable than the seventh and eighth embodiments. Hard to come off from child 7.

Embodiment 10 FIG.
Next, an embodiment 10 of the invention will be described. The tenth embodiment may be the same as any one of the first to ninth embodiments described above except for the parts described below.

  A method of adjusting the presence or absence of eddy current generation according to the position of the mover 7 will be described with reference to FIGS. 26, 27, and 28.

  In the tenth embodiment, the mover 7 has a recess in which the eddy current generating means 10 is arranged on the outer peripheral surface.

  The eddy current generating means 10 is arranged at a position away from the first stator core 1 in the axial direction from the radial end surface facing the mover 7 of the second stator core 2 in the early stroke.

  The eddy current generating means 10 is disposed at a position facing the radial end surface facing the mover 7 of the second stator core 2 in the middle of the stroke.

  The eddy current generating means 10 is disposed at a position closer to the first stator core 1 and in the axial direction than the radial end face facing the mover 7 of the second stator core 2 at the end of the stroke.

  The first path 13 passes through the first stator core 1 side in the axial direction of the eddy current generating means 10, the second path 14 penetrates the eddy current generating means 10 in the radial direction, and the third path 16 Passes through the opposite side of the first stator core 1 in the axial direction of the eddy current generating means 10.

  Since the first path 13 passes through the outer peripheral side of the eddy current generating means 10 regardless of the position of the mover 7, the eddy current generating means 10 does not generate eddy current.

  In the second path 14, since the magnetic resistance is large and the magnetic flux does not flow at the beginning of the stroke, the change amount (dΦ / dt) of the magnetic flux is small, and the eddy current generating means 10 does not generate the eddy current.

  In the second path 14, since the magnetic resistance decreases and the magnetic flux flows in the middle of the stroke, as the mover 7 approaches the first stator core 1, the amount of change in magnetic flux (dΦ / dt) increases and eddy current generation occurs. An eddy current is generated in the means 10.

  The second path 14 does not cause the eddy current generating means 10 to generate an eddy current because the magnetic resistance increases at the end of the stroke, the magnetic flux does not flow, and the change amount (dΦ / dt) of the magnetic flux decreases.

  In the third path 16, since the magnetic resistance is large and the magnetic flux does not flow at the beginning and middle of the stroke, the amount of change (dΦ / dt) in the magnetic flux is small, and the eddy current generating means 10 does not generate eddy current.

  The third path 16 has the smallest magnetic resistance at the end of the stroke, and the amount of change in magnetic flux increases as the mover 7 approaches the first stator core 1.

  If the eddy current generating means 10 is closed in the circumferential direction, the third path 16 links the eddy current generating means 10, so that the eddy current generating means 10 generates eddy current.

  FIG. 29 shows the amount of change (dΦ / dt) in magnetic flux with respect to the stroke in the tenth embodiment.

  From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7. That is, the response speed can be easily adjusted.

  The tenth embodiment has good manufacturability because there is no fear that the positional relationship between the mover 7 and the first stator core 1 is changed by the arrangement of the eddy current generating means 10.

  In the first to tenth embodiments, the presence or absence of eddy current generation can be adjusted by changing the radial thickness of the step of the first stator core 1 or the mover 7. As the radial thickness is smaller, magnetic saturation is more likely to occur, and the amount of magnetic flux flowing through the plurality of paths of the main magnetic flux 6 can be adjusted.

In addition, the same effect can be obtained by using not only the step shape but also materials having different magnetic characteristics.
If the magnetic characteristics are changed, the likelihood of magnetic saturation is different, so that the amount of magnetic flux flowing through a plurality of paths can be adjusted.

From the above, the presence or absence of eddy current generation can be adjusted by the position of the mover 7.

  Although the contents of the present invention have been specifically described with reference to the preferred embodiments, various modifications can be made by those skilled in the art based on the basic technical idea and teachings of the present invention. It is self-explanatory.

  DESCRIPTION OF SYMBOLS 1 1st stator core, 3 stator windings, 7 mover, 10 Eddy current generation means, 13 1st path | route (magnetic flux path | route, 1st magnetic flux path | route), 14 2nd path | route (magnetic flux path | route, 2nd Magnetic flux path), 16 the third path (magnetic flux path).

Claims (5)

A first stator core made of magnetic material;
A stator winding provided on an outer periphery of the first stator core;
A mover made of a magnetic material arranged coaxially with the first stator core,
A plurality of magnetic flux paths exist between the mover and the first stator core,
An eddy current generating means formed of a nonmagnetic conductive material;
At least one of the magnetic flux paths penetrates or links at least the eddy current generating means,
solenoid. In at least one of the plurality of magnetic flux paths, the amount of change in magnetic flux per unit time varies depending on the position of the mover.
The solenoid according to claim 1. The eddy current generating means is provided in the first stator core,
The solenoid according to claim 1 or 2. The eddy current generating means is provided on the mover.
The solenoid according to claim 1 or 2. The first magnetic flux path does not penetrate or interlink with the eddy current generation means, and the second magnetic flux path penetrates or links at least with the eddy current generation means,
The solenoid according to any one of claims 1 to 4.

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