JP2598443Y2 - Giant magnetostrictive actuator - Google Patents

Description

[Detailed description of the invention]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a giant magnetostrictive actuator suitably used for, for example, a giant magnetostrictive injection valve or an on-off valve, and more particularly to a giant magnetostrictive actuator capable of preventing a characteristic from being changed by thermal expansion. Type actuator.

[0002]

2. Description of the Related Art Generally, a cylindrical casing and an object to be driven provided at one end of the casing are extended in the casing in an axial direction so as to be driven, and one end is attached to the object to be driven. A giant magnetostrictive rod, and provided in the casing at a position around the giant magnetostrictive rod,
A fuel injection valve using a giant magnetostrictive actuator composed of an electromagnetic coil that expands and contracts the giant magnetostrictive rod in the axial direction by applying a magnetic field to the giant magnetostrictive rod is known, for example, from JP-A-3-243174. ing.

[0003] In this kind of prior art fuel injection valve,
A valve seat having a fuel injection port is provided at one end of the casing, and the valve body is urged in a normally closed direction by a valve spring so that an inwardly-opening valve body to be driven is seated on the valve seat. At the same time, one end of the giant magnetostrictive rod is fixed to the valve body, and when the giant magnetostrictive rod is reduced by the magnetic field from the electromagnetic coil, the giant magnetostrictive rod lifts the valve body against the valve spring, The fuel in the casing is injected outward from the injection port.

On the other end of the casing, a lid is provided which is in contact with the other end face of the giant magnetostrictive rod, and the giant magnetostrictive rod is pressed by the lid together with the valve body toward the valve seat. The spring load of the valve spring is adjusted.
When the giant magnetostrictive rod is reduced and deformed by the magnetic field from the electromagnetic coil, it is restricted from being separated from the lid, so that the valve can be reliably lifted from the valve seat against the valve spring. Has become.

[0005]

In the above-mentioned prior art, a valve body to be driven is provided at one end of the casing, and a lid is provided at the other end of the casing. And the giant magnetostrictive rod is positioned in the casing between the magnets.If the electromagnetic coil provided around the giant magnetostrictive rod generates heat by power supply from the outside, the giant magnetostrictive rod may be heated by the influence of heat at this time. Thermal expansion may occur in the axial direction between the lid and the valve. The giant magnetostrictive rod has a larger coefficient of thermal expansion than the casing, and the lid is integrally fixed to the casing. Therefore, the giant magnetostrictive rod extends toward the valve body during thermal expansion.

Therefore, according to the prior art, not only the spring load of the valve spring changes due to the thermal expansion of the giant magnetostrictive rod, but also when the giant magnetostrictive rod is deformed by the magnetic field from the electromagnetic coil, the lift amount of the valve body is reduced. Therefore, there is a problem that the characteristics and the like of the injection flow rate fluctuate due to thermal influence.

Further, if the valve element to be driven is of an open-open type, and the valve element is opened when the giant magnetostrictive rod expands and deforms, the valve element opens in the valve opening direction due to thermal expansion of the giant magnetostrictive rod. And may be displaced from the valve seat, causing a problem such as poor sealing.

The present invention has been made in view of the above-mentioned problems of the prior art. In the present invention, even when the giant magnetostrictive rod thermally expands, it can be offset by the thermal expansion of the stopper cylinder, resulting in poor characteristics and the like. It is an object of the present invention to provide a giant magnetostrictive actuator capable of effectively preventing the occurrence of a magnetic field.

[0009]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems , the present invention provides a cylindrical casing and the casing.
In order to drive a driving object provided at one end of the
It is provided to extend in the axial direction in the
A giant magnetostrictive rod attached to a moving object;
To provide an initial load to the giant magnetostrictive rod.
A constant spring and the cable located around the giant magnetostrictive rod.
A magnetic field is applied to the giant magnetostrictive rod provided in the sing
This makes the giant magnetostrictive rod expand and contract in the axial direction.
The present invention is applied to a giant magnetostrictive actuator consisting of an il and an il.
The feature of the configuration devised in claim 1 is employed, the <br/> between the electromagnetic coil and the super-magnetostrictive rod, cylinder of a nonmagnetic material having a thermal expansion coefficient which corresponds to said ultra-magnetostrictive rod Shape
Made is provided a stopper cylinder with Tsu also the length of housing over the giant magnetostrictive rod in the axial direction, the stopper cylinder is fixed to one end side of the open end to the casing, the other end serving as a closed end Is in contact with the other end of the giant magnetostrictive rod,
The other end of the casing is provided with an urging means for constantly urging the closed end side of the stopper cylinder toward the open end side. In addition, the invention of claim 2 is provided on the other end side of the casing.
Is provided with a plug for variably adjusting the biasing force of the biasing means.
It has a configuration consisting of

[0010]

According to the present invention, when the giant magnetostrictive rod thermally expands in the axial direction due to heat generation of the electromagnetic coil, the stopper cylinder also thermally expands in the axial direction correspondingly. Thus, the thermal expansion at this time can be absorbed so as to be offset at the other end of the stopper cylinder. In addition, since the urging means provided on the other end side of the casing urges the closed end side of the stopper cylinder toward the opening end side of the casing, the load on the stopper cylinder by the urging means is adjusted. Thus, it is possible to restrict the thermal expansion of the stopper cylinder before the giant magnetostrictive rod due to the heat generated by the electromagnetic coil, and it is possible to adjust the stopper cylinder and the giant magnetostrictive rod so that the thermal expansion amounts thereof are substantially equal. In addition,
According to the invention of claim 2, the stopper provided on the other end side of the casing
Depending on the body, the biasing force of the biasing means can be adjusted variably.
Wear.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. 1 to 4 taking a giant magnetostrictive injection valve as an example.

In FIG. 1, reference numeral 1 denotes a cylindrical casing formed of a magnetic material such as an electromagnetic stainless steel into a stepped cylindrical shape.
A, 1B, and an annular projection 1C is provided on the inner peripheral side above the caulking portion 1B by a predetermined dimension.

Reference numeral 2 denotes a bottomed cylindrical valve body provided on the lower inner peripheral side of the casing 1. The valve body 2 has a cylindrical shape with an outer diameter corresponding to the inner diameter of the casing 1 as shown in FIG. A formed cylindrical portion 2A, a bottom portion 2B extending radially inward from the lower end side of the cylindrical portion 2A and formed in a relatively thick disk shape, and extending upward from the center of the bottom portion 2B. A small-diameter guide cylinder 2D formed with a plurality of guide projections 2C, 2C,... Extending in the axial direction while being spaced apart in the circumferential direction on the inner peripheral side; Valve seat 2E formed by tapering and expanding on the inner peripheral side of 2B
The valve seat 2E forms a fuel injection port between the valve seat 2E and a valve portion 4D of the valve body 4 described later.

Here, the valve body 2 has a casing 1
And the annular projection 1C is connected to the upper end of the cylindrical portion 2A via a flange portion 16D of a stopper tube 16 described later.
The bottom surface of the bottom portion 2B is fixed to the caulking portion 1B in a state where the bottom portion 2B is brought into contact with the casing 1 so as to be integrated into the casing 1. Further, fuel flow holes 3 and 3 are formed in the cylindrical portion 2A of the valve body 2 through the casing 1 in a radial direction through the casing 1, and each of the flow holes 3 is provided with a fuel pump through a fuel pipe or the like. (Not shown) flows through the valve body 2.

Reference numeral 4 denotes an outwardly opening type valve element to be driven. The valve element 4 has an annular step portion 4C between an upper shaft portion 4A and a lower shaft portion 4B, and a lower shaft portion. A hemispherical valve portion 4D is integrally formed on the lower end side of 4B. The lower shaft portion 4B of the valve body 4 is inserted into the guide cylinder 2D of the valve body 2, and the spherical upper surface of the valve portion 4D is separated and seated on the valve seat 2E. A valve spring 5 is disposed between the annular step 4C of the valve body 4 and the bottom 2B of the valve body 2 around the guide cylinder 2D. It is normally biased in the valve closing direction. When the valve body 4 is opened by the giant magnetostrictive rod 14 to be described later against the valve spring 5, the fuel in the valve body 2 communicates with the valve seat 2E via the guide projections 2C of the guide cylinder 2D. It is injected outward from between the portion 4D.

Reference numeral 6 denotes a spring receiver movably provided in the valve body 2. The spring receiver 6 has a cylindrical projection 6A on the lower surface side.
Is provided so as to protrude downward, and an upper shaft portion 4A of the valve body 4 is slidably inserted into the cylindrical convex portion 6A. A minute gap S is interposed between the upper surface 6B of the cylindrical convex portion 6A and the upper end of the upper shaft portion 4A, and the valve portion 4D is inadvertently separated from the valve seat 2E when the valve body 4 thermally expands. To prevent them from doing so. A shallow recess 6C is formed in the center of the upper surface side of the spring receiver 6, and the lower end of the giant magnetostrictive rod 14 is fitted in the recess 6C via a buffer plate 15 described later.

Reference numeral 7 denotes a setting spring located around the cylindrical convex portion 6A of the spring receiver 6 and disposed between the spring receiver 6 and the bottom 2B of the valve body 2. The setting spring 7 is a valve spring. The initial load is applied to the giant magnetostrictive rod 14 by constantly urging the giant magnetostrictive rod 14 upward together with the rod 5 via the spring receiver 6 and the like.

Reference numeral 8 denotes a stepped cylindrical coil bobbin disposed in the casing 1, 9 denotes an electromagnetic coil wound around the coil bobbin 8, and the electromagnetic coil 9 stands upright on the upper end side of the coil bobbin 8. It is connected to the terminal pins 10 and 10 and is excited by external power supply. The electromagnetic coil 9 applies a magnetic field to the giant magnetostrictive rod 14 to expand and deform the giant magnetostrictive rod 14 in the axial direction, thereby driving the valve body 4 in the valve opening direction. A sliding hole 8A extending in the axial direction is formed on the inner peripheral side of the coil bobbin 8, and the sliding hole 8A
A stopper tube 16 is inserted therein.

Reference numeral 11 denotes a cylindrical lid which is disposed in the casing 1 in contact with the upper end of the coil bobbin 8;
1 is formed of a magnetic material in a cylindrical shape,
7 together with a magnetic path. Then, the lid 11 is fixed by caulking in the casing 1 via a caulking portion 1A,
The coil bobbin 8 is positioned in the casing 1 between itself and the annular projection 1C. Here, small-diameter cylindrical sealing members 12 and 12 are attached to the lid 11 around each terminal pin 10, and each of the sealing members 12 receives rainwater from the outside from the coil pin 8 around the terminal pin 10. In addition, it prevents intrusion into the inside and insulates between the lid 11 and each terminal pin 10. A mounting hole 13 is formed in the center of the lid 11 so as to penetrate in the axial direction. The mounting hole 13 has a screw hole 13A for a plug 19 described later on the upper side.
The lower side of 3A is a sliding hole 13B for the pusher 17.

Numeral 14 denotes a giant magnetostrictive rod inserted through a stopper tube 16 into a sliding hole 8A of the coil bobbin 8.
The giant magnetostrictive rod 14 is formed as an elongated cylindrical rod from a giant magnetostrictive material such as neodymium (Nd) -iron mother alloy or dysprosium (Dy) -iron or terbium (Tb) -iron mother alloy. Due to the magnetic field from No. 9, it is elongated and deformed in the axial direction at a ratio of 1000 PPM (1000 × 10 ⁻⁶ ) to the total length L with a magnetic field of 1 kOe (kilo Oersted), for example. The giant magnetostrictive rod 1
No. 4 has a coefficient of thermal expansion α (linear expansion coefficient) of, for example, about 1 × 10 ⁻⁵ / ° C., and measures an axial dimension (L × α) with respect to the total length L every time the ambient temperature increases by 1 ° C. Only thermal expansion.

Here, the giant magnetostrictive rod 14 is axially positioned with its upper end side end surface 14A abutting against a stopper portion 16C of a stopper tube 16, which will be described later, and the lower end side is formed of the stopper tube 1
6 projects slightly downward from the opening end side, and is fitted into the recess 6 </ b> C of the spring receiver 6 via the buffer plate 15. The giant magnetostrictive rod 14 is constantly urged upward by the setting spring 7 via the spring receiver 6, and its upper end is pressed against the stopper portion 16 </ b> C of the stopper cylinder 16. The buffer plate 15 is formed in a disc shape with a predetermined thickness from an elastic resin material. When the giant magnetostrictive rod 14 expands and deforms to open the valve body 4, the shock received from the valve body 4 is reduced. .

Further, reference numeral 16 denotes a sliding hole 8 of the coil bobbin 8.
1A shows a stopper tube inserted with the giant magnetostrictive rod 14 together with the giant magnetostrictive rod 14. The stopper tube 16 is formed in a slender cylindrical shape from a metal material or the like having a coefficient of thermal expansion α corresponding to the giant magnetostrictive rod 14. A disc-shaped stopper portion 16C having a flat contact surface 16B on the lower surface side is integrally formed on the upper end side of 16A. Further, a large-diameter flange portion 16D projecting outward in the radial direction is integrally formed at the lower end side of the cylindrical portion 16A which is the opening end side of the stopper cylinder 16, and the flange portion 16D
Is sandwiched between the annular projection 1C of the casing 1 and the upper end of the cylindrical portion 2A of the valve body 2, and is fixed to the casing 1.

The cylindrical portion 16A of the stopper cylinder 16
Has a length dimension corresponding to the total length L of the giant magnetostrictive rod 14 including the thickness of the stopper portion 16C and the flange portion 16D, and when the giant magnetostrictive rod 14 housed therein is thermally expanded in the axial direction, Thermal expansion occurs with a corresponding axial length. Thus, the stopper tube 16 absorbs the thermal expansion of the giant magnetostrictive rod 14 on the side of the stopper 16C, and at this time, prevents the giant magnetostrictive rod 14 from displacing the spring receiver 6 in the axial direction. The contact surface 16B of the stopper portion 16C of the stopper cylinder 16 is in surface contact with the upper end surface 14A of the giant magnetostrictive rod 14 with a relatively large contact area.

Reference numeral 17 denotes a pusher provided in the mounting hole 13 of the lid 11, and as shown in FIG. 3, the pusher 17 is formed in a cylindrical shape having a diameter corresponding to the sliding hole 13B. A radial portion 17A, a pressing portion 17B coaxially located at the distal end side of the large diameter portion 17A, protruding downward, and formed in a cylindrical shape with a diameter corresponding to the sliding hole 8A of the coil bobbin 8; Located coaxially on the proximal side of 17A,
A small-diameter shaft portion 17C protruding upward from the large-diameter portion 17A.
And is formed in a stepped cylindrical shape as a whole by a magnetic material. The pusher 17 is provided with a pressing portion 17B.
Is inserted into the sliding hole 8A of the coil bobbin 8, and abuts the stopper portion 16C of the stopper cylinder 16 in the sliding hole 8A.

Reference numeral 18 denotes an urging spring as urging means.
The urging spring 18 is constituted by a coil spring, and is disposed between the large-diameter portion 17A and the plug 19 around the shaft 17C of the pusher 17. The urging spring 18 presses the pressing portion 17B of the pusher 17 against the stopper portion 16C of the stopper tube 16, and presses the stopper portion 16C of the stopper tube 16 toward the flange portion 16D with a spring load of, for example, about 7 kgf. I'm going.

Reference numeral 19 denotes a stopper attached to the lid 11 so as to cover the attachment hole 13 from above, and the stopper 19 has a cylindrical shape with a thread formed on the outer peripheral surface as shown in FIG. And a thick annular lid portion 19B integrally formed on the base end side of the spring holding portion 19A, and the center of the lid portion 19B communicates with the inside of the spring holding portion 19A. , An insertion hole 19C through which the shaft 17C of the pusher 17 is inserted
Are formed. The plug 19 is attached to the spring holder 1.
9A with the biasing spring 18 housed therein,
Of the urging spring 18 at this time.
Is adjusted between the shaft portion 17C of the pusher 17 and the spring holding portion 19A to about 7 kgf.

The giant magnetostrictive injection valve according to the present embodiment has the above-described configuration, and its operation will now be described.

First, the characteristic line 20 shown in FIG.
When a magnetic field is applied to the giant magnetostrictive rod 14 by the electromagnetic coil 9 as described above, the giant magnetostrictive rod 14 expands and deforms in accordance with the strength of the magnetic field at this time, and the spring support 6 is attached to the buffer plate 15. The fuel in the valve body 2 is injected to the outside from between the valve seat 2E and the valve portion 4D by displacing the valve portion 4D downward and separating the valve portion 4D from the valve seat 2E. In this case, the upper end side end surface 14A of the giant magnetostrictive rod 14
Abuts against the stopper portion 16C of the stopper cylinder 16 and the upward displacement is restricted, so that the giant magnetostrictive rod 14 expands and deforms downward, and the valve body 4 is opened against the setting spring 7 and the valve spring 5. Let it.

Further, since the valve element 4 is an outward-opening type, when the giant magnetostrictive injection valve is used as an in-cylinder direct injection type injection valve, the pressure in the combustion chamber (not shown) is increased. Is the valve 4
When the valve body 4 is externally actuated, the valve body 4 is pressed against the valve seat 2E and continues to be seated, so that the valve body 4 can be prevented from opening carelessly until the injection pulse is supplied to the electromagnetic coil 9.

The upper end surface 14A of the giant magnetostrictive rod 14 is replaced with a stopper 16C of a stopper tube 16,
When the casing 1 is fixed to the casing 1 via the lid or the like as described in the related art, the thermal expansion coefficient α of the giant magnetostrictive rod 14 is larger than the thermal expansion coefficient of the casing 1.
In the case of No. 4, upward expansion due to thermal expansion is restricted, and downward expansion occurs. When the giant magnetostrictive rod 14 thermally expands downward, the valve body 4 is pushed downward by this, and in the worst case, the valve portion 4D of the valve body 4 separates from the valve seat 2E to cause a sealing failure. Or the injection pulse is applied to the electromagnetic coil 9
To expand and deform the giant magnetostrictive rod 14 to open and close the valve body 4, the thermal expansion of the giant magnetostrictive rod 14 is added, and the lift amount of the valve body 4 is larger than the normal lift amount. Will be.

Therefore, in this embodiment, the stopper tube 16 is formed in a cylindrical shape from a non-magnetic material having a thermal expansion coefficient corresponding to the thermal expansion coefficient α of the giant magnetostrictive rod 14, and the length of the cylindrical portion 16A is measured. Correspond to the entire length L of the giant magnetostrictive rod 14, the upper end side end face 14 </ b> A of the giant magnetostrictive rod 14 is pressed against the stopper portion 16 </ b> C, and the giant magnetostrictive rod 14 is positioned. Thus, when the giant magnetostrictive rod 14 thermally expands, the cylindrical portion 16A of the stopper cylinder 16 also thermally expands. Therefore, the amount of thermal expansion of the giant magnetostrictive rod 14 is absorbed by the stopper 16C of the stopper cylinder 16. It can cancel each other out, allowing upward extension due to thermal expansion of the giant magnetostrictive rod 14 and preventing downward extension.

On the other hand, the stopper cylinder 16 is
Is located closer to the electromagnetic coil 9 than
The stopper tube 16 may thermally expand prior to the giant magnetostrictive rod 14 due to the heat generated by the electromagnetic coil 9. In this case, the amount of thermal expansion of the stopper tube 16 becomes larger than the amount of thermal expansion of the giant magnetostrictive rod 14, The tip of the giant magnetostrictive rod 14 is shifted in the direction opposite to the lift direction of the valve body 4, so that even if the giant magnetostrictive rod 14 is driven by the magnetic field from the electromagnetic coil 9,
Is reduced as indicated by the characteristic line 21 in FIG.

However, in this embodiment, the cover 11 has the mounting hole 13 formed therein, and the plug 19 is mounted in the screw hole 13A of the mounting hole 13, and the pusher 17 and the urging member are provided in the plug 19. A spring 18 is disposed, and the stopper cylinder 16 is
The stopper 16C is urged toward the opening end with a spring load of, for example, about 7 kgf.
The stopper tube 16 is prevented from thermally expanding before the giant magnetostrictive rod 14 due to the heat generated in the stopper tube 16, and the stopper tube 16 and the giant magnetostrictive rod 14 can be adjusted so that the thermal expansion amounts thereof are substantially equal.
Can be maintained at a constant value over a long period of time as shown by the characteristic line 22.

Therefore, according to the present embodiment, the stopper tube 16 is thermally expanded before the giant magnetostrictive rod 14 by the heat from the electromagnetic coil 9 or the like by setting the screwing amount of the plug 19 by an experiment or the like. Since the thermal expansion of the stopper cylinder 16 and the giant magnetostrictive rod 14 can be matched, it is possible to effectively prevent a change in the lift amount of the valve body 4 due to the thermal expansion of the giant magnetostrictive rod 14. The valve body 4 can be opened and closed with a regular lift amount. Further, it is possible to prevent the spring load of the setting spring 7 from changing due to the thermal expansion of the giant magnetostrictive rod 14, and it is possible to continue to apply a constant initial load to the giant magnetostrictive rod 14.

On the other hand, the valve 4
Is thermally expanded, the small gap S shown in FIG. 2 formed between the upper shaft portion 4A of the valve body 4 and the spring receiver 6 causes
The thermal expansion of the valve body 4 can be absorbed, and even in this case, it is possible to prevent the valve portion 4D from being unintentionally separated from the valve seat 2E.
When an injection pulse is supplied to the electromagnetic coil 9 to open the valve body 4 and the giant magnetostrictive rod 14 is elongated and deformed by the magnetic field at this time, the spring receiver 6 is displaced downward against the setting spring 7. Then, the collision with the upper shaft portion 4A of the valve body 4 is performed so as to eliminate the minute gap S. However, the shock at this time can be prevented from being directly transmitted to the giant magnetostrictive rod 14 by the buffer plate 15, and the durability of the giant magnetostrictive rod 14 can be reduced. Performance can be improved.

In the above embodiment, the valve body 4 and the spring receiver 6
Are formed as separate members, but alternatively, the valve body 4 and the spring receiver 6 may be integrated. In this case, the valve spring 5 is omitted, and the setting spring 7 is omitted. Thus, the valve body 4 may be constantly urged in the valve closing direction.

Further, in the above-described embodiment, the outwardly opening type valve element 4 is provided.
The present invention is not limited to this, but is applied to, for example, a giant magnetostrictive injection valve using an inward-opening valve as described in the prior art. May be
In this case, a giant magnetostrictive rod that contracts and deforms in the axial direction when a magnetic field is applied may be used.

Further, the giant magnetostrictive actuator of the present invention is not limited to the one applied to the giant magnetostrictive injection valve. For example, the giant magnetostrictive actuator may be used in place of an electromagnetic solenoid such as an electromagnetic on-off valve. In this case, one end of the giant magnetostrictive rod may be attached to a spool valve, a poppet valve, or the like to be driven. Further, the present invention may be applied to a disc brake or the like. In this case, a configuration may be adopted in which the expansion and contraction deformation of the giant magnetostrictive rod is transmitted to a friction pad to apply a braking force to the disc.

[0039]

[Devised effect] As described above in detail, according to the considered <br/> draft according to claim 1, between the electromagnetic coil and the super-magnetostrictive rod, with a thermal expansion coefficient which corresponds to said ultra-magnetostrictive rod the stopper cylinder with Tsu also the length of housing over the ultra-magnetostrictive rod is formed into a cylindrical shape in the axial direction by non-magnetic material provided with, the stopper cylinder is fixed to one end side of the open end to the casing, Urging means for bringing the other end side, which is the closed end, into contact with the other end side of the giant magnetostrictive rod, and constantly energizing the other end side of the casing, with the closed end side of the stopper cylinder toward the open end side; the because provided, to come <br/> and thermally expanded by such heating giant magnetostrictive rod of the electromagnetic coil, it is possible to offset the thermal expansion amount of the super magnetostrictive rod by the thermal expansion of the stopper cylinder. And in the casing
Initial load is applied to the giant magnetostrictive rod by the setting spring
Can be provided.

Further, since the closed end side of the stopper cylinder by the biasing means provided on the other end of the casing is configured to urge the open end of the casing, the stopper tube by heat generation of the electromagnetic coil is super if you try to thermal expansion prior to the magnetostrictive rod may be by Rukoto adjusting the load of the stopper cylinder by the urging means, the thermal expansion amount of the stopper tube and the giant magnetostrictive rod Komu combined to be substantially equal,
It is possible to effectively prevent the occurrence of characteristic defects and the like. In this case,
According to the invention as set forth in claim 2, the casing is provided on the other end side.
The stopper can variably adjust the biasing force of the biasing means,
Work to match the thermal expansion of the cylinder and the giant magnetostrictive rod
It can be done easily.

When applied to a giant magnetostrictive injection valve or the like, it is possible to prevent the lift amount of the valve body from changing due to thermal expansion, and it is possible to prevent the occurrence of sealing failure and the like.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view illustrating a giant magnetostrictive injection valve according to an embodiment of the present invention.

FIG. 2 is an enlarged view of a main part in FIG. 1 showing a valve body side.

FIG. 3 is an enlarged view of a main part in FIG. 1 showing an upper end side of a giant magnetostrictive rod.

FIG. 4 is a characteristic diagram illustrating an injection pulse and a lift amount of a valve body.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Casing 2 Valve body 2E Valve seat 3 Fuel flow hole 4 Valve (drive object) 5 Valve spring 6 Spring support 7 Setting spring 9 Electromagnetic coil 14 Giant magnetostrictive rod 16 Stopper cylinder 16C Stopper part 16D Flange part 17 Pusher 18 Spring (urging means) 19 plug

Claims (2)

(57) [Scope of request for utility model registration] 1. A cylindrical casing which is provided in the casing so as to extend in the axial direction so as to drive an object to be driven provided at one end of the casing, and one end of which is attached to the object to be driven. To the magnetostrictive rod and the casing
Provided to apply an initial load to the giant magnetostrictive rod.
Neto, from said positioned around the giant magnetostrictive rod disposed within the casing, an electromagnetic coil for stretching the Ri該 giant magnetostrictive rod by the <br/> applying a magnetic field to the giant magnetostrictive rod in the axial direction made in super magnetostrictive actuator, between the front Symbol electromagnetic coil and a super magnetostrictive rod, cylindrical non-magnetic material having a thermal expansion coefficient which corresponds to said ultra-magnetostrictive rod
The stopper cylinder with Tsu also the length that accommodates over axially formed ultra magnetostrictive rod provided, the stopper cylinder is fixed to one end side of the open end to the casing, a closed end and the other end side is configured to contact the other end of the super magnetostrictive rod, providing the biasing means for constantly biased toward the closed end side of the stopper tube into the open end side to the other end of the pre-Symbol casing A giant magnetostrictive actuator. (2) At the other end of the casing, the urging
A plug is provided for variably adjusting the urging force of the means.
The giant magnetostrictive actuator according to claim 1.