JP4623983B2 - Linear solenoid valve - Google Patents

Description

  The present invention relates to a linear solenoid valve capable of generating an electromagnetic force proportional to an energization amount to a solenoid portion and displacing a valve body by the electromagnetic force.

  2. Description of the Related Art Conventionally, an electromagnetic valve that displaces a valve body by attracting a movable iron core to a fixed iron core by an electromagnetic force generated under the excitation action of a solenoid coil has been used.

  For example, Patent Document 1 discloses a technical idea of coating a non-magnetic and wear-resistant thin film on the entire surface of a movable iron core constituting an electromagnetic valve in order to suppress a decrease in magnetic flux density of a magnetic circuit. Is disclosed.

Japanese Utility Model Publication No. 63-56371

  However, in the electromagnetic valve disclosed in Patent Document 1, since the thin film is coated on the entire surface of the movable core having a predetermined diameter, the outer diameter of the movable core increases by the thickness of the thin film. . For this reason, it is necessary to manage not only the outer diameter of the movable core itself, but also the thickness of the coated thin film.

  Further, in the electromagnetic valve disclosed in Patent Document 1, there is a possibility that the thin film coated on the entire surface of the movable core may be peeled off from the outer surface of the movable core, or swelled, and it is necessary to prevent this. is there.

  The present invention has been made in consideration of the above points, and an object of the present invention is to provide a linear solenoid valve capable of forming a magnetic gap with high accuracy without requiring coating of a nonmagnetic thin film. .

  In this section, for ease of understanding, the reference numerals in the accompanying drawings will be described in parentheses. However, the contents described in this section should not be construed as being limited to those given the reference numerals.

The present invention provides a linear solenoid valve that generates an electromagnetic force proportional to the energization amount to the solenoid portion and displaces the valve body by the electromagnetic force.
A valve body including a valve body (18) having an inlet port (56) and an outlet port (58) through which pressure fluid flows and a housing (14);
A solenoid part (12) provided in the housing and having a coil (32) wound around a coil bobbin (30) and a movable core (26) attracted to the fixed core (24) under the energization action on the coil. When,
A valve mechanism (16) having a valve body (66) that is provided on the valve body and switches between a communication state and a non-communication state of the inlet port and the outlet port by transmitting the displacement of the movable core;
With
The housing includes a cylindrical portion (15), and a cylindrical yoke (22) formed on the inner peripheral side of the cylindrical portion so as to be separated from the cylindrical portion and disposed substantially parallel to the cylindrical portion, A thin portion (19) having a cylindrical portion and a bottom portion (17) formed integrally with the yoke and having a smaller thickness than other portions of the bottom portion is formed on the bottom portion. And
A nonmagnetic layer (65) having a predetermined thickness is formed on the outer surface of the movable core,
On the end surface of the movable core that faces the thin portion, a protrusion (53) that can contact the thin portion and has a nonmagnetic layer and functions as a stopper is formed.
The end surface of the movable core that faces the thin portion reaches a position that exceeds the coil inserted between the cylindrical portion and the yoke when the protrusion comes into contact with the thin portion, and An end portion in the vicinity of the end surface is disposed at a position corresponding to the inner wall surface of the bottom portion.

  According to the present invention, since the nonmagnetic layer is formed on the entire outer surface of the movable core, for example, by surface modification, it can function as a magnetic gap in a magnetic circuit generated by energizing the coil. .

  Further, since the nonmagnetic layer is formed on the entire outer surface of the movable core, it can be easily formed in a predetermined dimension by managing the outer diameter of only the movable core. Therefore, the magnetic gap formed by the clearance between the yoke and the movable core can be managed with high accuracy, and extremely good magnetic characteristics can be obtained.

  By forming the nonmagnetic layer formed on the outer surface of the movable core into a thin wall having a predetermined thickness, the magnetic gap generated between the movable core and the yoke can be made extremely small. Can be improved and a large suction force can be obtained. In addition, the size can be reduced as compared with a device that generates an equivalent suction force.

  By forming the nonmagnetic layer formed on the outer surface of the movable core into a predetermined thickness, the magnetic gap generated between the movable core and the yoke can be increased, so that the movable Side forces acting between the core and the yoke can be suppressed.

  By forming the nonmagnetic layer by induction hardening on the movable core, the surface modification process can be performed at a high speed.

  Furthermore, by making the cross-sectional shape of the coil wound around the coil bobbin square or rectangular, the gap generated between the stacked coils can be made extremely small. Therefore, the winding space of the coil wound around the coil bobbin can be reduced.

  Furthermore, by providing a thin annular guide portion with respect to the yoke, it is possible to obtain a good guide for the movable core and improve the linearity.

  According to the present invention, the following effects can be obtained.

  That is, by forming a nonmagnetic layer having a predetermined thickness on the outer surface of the movable core, it is possible to form the magnetic gap with high accuracy without the need for coating the nonmagnetic thin film. Thereby, extremely good magnetic characteristics can be obtained.

  Preferred embodiments of the linear solenoid valve according to the present invention will be described below and described in detail with reference to the accompanying drawings.

  In FIG. 1, reference numeral 10 indicates a hydraulic control valve according to an embodiment of the present invention.

  The hydraulic control valve 10 is formed in a bottomed cylindrical shape with a magnetic material such as SUM (JIS standard), for example, and has a housing 14 provided with a solenoid portion (linear solenoid portion) 12 therein, and the housing 14 is integrated with the housing 14. And a valve body 18 having a valve mechanism portion 16 provided therein. The housing 14 and the valve body 18 function as a valve main body.

  The housing 14 includes a cylindrical portion 15, a cylindrical yoke 22 formed at a predetermined interval on the inner peripheral side of the cylindrical portion 15 and disposed substantially parallel to the cylindrical portion 15, and more than the cylindrical portion 15. The cylindrical portion 15, the yoke 22, and the bottom portion 17 are integrally formed. The inner wall of the bottom portion 17 is provided with a thin portion 19 formed by cutting out a substantially U-shaped recess.

  In this case, by setting the bottom portion 17 of the housing 14 at the portion facing the end face of the movable core 26 described later to the thin portion 19, the thin portion 19 functions as a magnetic resistance, and the thin portion 19 of the housing 14 Therefore, it is possible to make the magnetic flux difficult to flow as much as possible.

  The solenoid unit 12 includes a coil assembly 20 accommodated in the housing 14 and a cylindrical shape that is integrally formed with the housing 14 on the closed end side of the housing 14 and disposed inside the coil assembly 20. A yoke 22, a fixed core 24 that is coupled to the opening end of the housing 14 and is disposed along the axial direction inside the coil assembly 120 with a predetermined clearance from the yoke 22, the yoke 22, And a movable core 26 slidably inserted into the fixed core 24.

  The coil assembly 20 is formed of a synthetic resin material and has a coil bobbin 30 having flanges 28a and 28b at both ends along the axial direction, and is wound around the coil bobbin 30 a plurality of times. As shown, the coil 32 is formed of a square wire formed in a square cross section.

  By forming the coil 32 to have a square cross section, contact between the coils 32 wound around the coil bobbin 30 becomes surface contact. Therefore, the coil 32 is stably and aligned at a predetermined position. Thereby, as shown in FIG. 7, one flange 28 a (28 b) of the coil bobbin 30 can be made unnecessary. By eliminating the one flange 28a (28b), the axial dimension of the entire solenoid portion 12 is shortened, and the size can be reduced.

  In addition, when a coil according to the prior art formed in a circular cross section as shown in FIG. 12 is wound around a coil bobbin, a force that collapses toward the flange acts due to the tension when winding the coil. In the coil 32 having a square cross section, the force that collapses toward the flange 28a (28b) due to the surface contact between the coils 32 does not work, so that one flange 28a (28b) can be dispensed with.

  As shown in FIGS. 8 and 9, another coil 32 a made of a flat wire formed in a rectangular cross section may be used. In this case, the coil 32 formed in a square cross section can be set with a smaller winding space than the coil 32a formed in a rectangular cross section. Furthermore, in the coil 32 having a square cross section, since the peripheral dimension of the cross section can be reduced as compared with the coil 32a having a rectangular cross section, the cross-sectional area of the insulating coating on the coil 32 can be set small.

  The yoke 22 and the fixed core 24 that are spaced apart from each other by a predetermined distance are formed on the outer peripheral surface of the annular vertical surface portion 34 formed on one end surface of the cylindrical yoke 22 and the concave portion 36 of the fixed core 24. A conical surface portion 38 is provided. A tapered portion 35 for reducing leakage magnetic flux is chamfered and formed on one end surface of the yoke 22 adjacent to the vertical surface portion 34.

  The yoke 22 and the fixed core 24 are formed with a cylindrical portion and a recess 36 corresponding to the shape of the movable core 26, and the movable core 26 is slid between the cylindrical yoke 22 and the recess 36 of the fixed core 24. A linear solenoid structure to be moved can be used.

  In this case, as shown in FIG. 10, the vertical surface portion 34 of the yoke 22 facing the conical surface portion 38 of the fixed core 24 along the axial direction is a predetermined length toward the conical surface portion 38 of the fixed core 24. A projecting thin annular guide 39 may be formed.

  A gap 41 having a predetermined clearance is formed between the annular guide portion 39 and the conical surface portion 38 of the fixed core 24. In this case, by providing the thin annular guide portion 39 with respect to the yoke 22, good guideability for the movable core 26 can be obtained, and linearity can be improved.

  Between the housing 14 and the coil 32, there is provided a resin sealing body 40 that molds the outer peripheral surface of the coil 32 and a part of the coil bobbin 30, and the resin sealing body 40 is a coupler portion that energizes the coil 32. 42 is integrally formed of resin material. The coupler portion 42 is provided so that the terminal portion 44a of the terminal 44 electrically connected to the coil 32 is exposed.

  By covering the outer peripheral surface of the coil 32 with the resin sealing body 40, the coil 32 can be stably protected. Further, when the flange 28a (28b) formed at one end of the coil bobbin 30 is not necessary, the unnecessary portion of the flange 28a (28b) is covered with the resin sealing body 40, thereby further increasing the coil. 32 is stably protected.

  The movable core 26 includes a movable core body 45 made of a cylindrical body, a convex portion 47 formed at the center of one end face of the movable core body 45 and slightly protruding toward the fixed core 24 side, and the movable core. A protrusion 53 is formed at the center of the other end surface of the main body 45 and protrudes toward the thin portion 19 by a predetermined length.

  A ring body 52 that is formed of a nonmagnetic material and functions as a spacer for preventing residual magnetism in the solenoid portion 12 is mounted on the outer periphery of the convex portion 47.

  That is, residual magnetism is generated in the fixed core 24 or the movable core 26 when the energization of the solenoid unit 12 is interrupted, and the movable core 26 may not be separated from the fixed core 24 under the action of the residual magnetism. By providing the ring body 52 via the convex portion 47, a predetermined clearance is formed between the fixed core 24 and the occurrence of residual magnetism can be suppressed.

  At the center of the other end surface of the movable core main body 45, a protrusion 53 that functions as a stopper capable of coming into contact with the thin portion 19 of the bottom portion 17 of the housing 14 is integrally formed with the movable core main body 45. . The protruding portion 53 is made of a nonmagnetic layer 65 and functions as a spacer for preventing residual magnetism in the solenoid portion 12, similarly to the ring body 52. An axial communication groove 54 is formed on the outer peripheral surface of the movable core body 45 so as to communicate between both end surfaces.

  A nonmagnetic layer 65 having a predetermined depth is formed on the entire outer surface of the movable core 26 (see FIGS. 3 and 4).

  The nonmagnetic layer 65 of the movable core 26 is formed, for example, by performing a surface modification process such as a carburizing process and / or a nitriding process. This carburizing treatment and nitriding treatment are advantageous in that post-treatment is unnecessary by suppressing the dimensional change of the movable core 26 because the magnetic permeability is improved by surface treatment at a relatively low temperature.

  Examples of the carburizing treatment include solid carburizing, liquid carburizing (carbonitriding method), gas carburizing, plasma carburizing, etc., and the nitriding treatment includes gas nitriding, liquid nitriding (salt bath nitriding), soft nitriding, ion Nitriding and the like are included.

  Further, in order to form the nonmagnetic layer 65 on the outer surface of the movable core 26, for example, an induction hardening process may be performed. When the nonmagnetic layer 65 is formed by performing induction hardening, high-speed heat treatment is possible, and the manufacturing process can be shortened. The method for forming the nonmagnetic layer 65 on the outer surface of the movable core 26 is not limited to the surface modification treatment such as the carburizing treatment, nitriding treatment, and induction hardening treatment, and for example, irradiation with a laser beam. It is also possible to use other surface modification treatments such as.

  The movable core 26 may be made of, for example, ferritic stainless steel such as SUS410L or SUS405 (JIS standard), general steel such as S10C (JIS standard), or free-cutting steel material such as SUM (JIS standard). .

  As shown in FIG. 3, when the thickness of the nonmagnetic layer 65 formed on the outer surface of the movable core 26 is thin, the thickness of the nonmagnetic layer 65 is preferably in the range of 10 μm to 30 μm. The thickness T1 is preferably set to 20 μm. At that time, since the magnetic gap generated between the movable core 26 and the yoke 22 can be made extremely small, the magnetic force can be improved, and thus a large attractive force can be obtained. For this reason, in this Embodiment, size reduction can be achieved compared with what generate | occur | produces an equal suction | attraction force.

  Further, as shown in FIG. 4, when the thickness of the nonmagnetic layer 65 formed on the outer surface of the movable core 26 is thick, the thickness of the nonmagnetic layer 65 is in the range of 50 μm to 100 μm. The thickness T2 is preferably set to 75 μm. At this time, since the magnetic gap generated between the movable core 26 and the yoke 22 can be increased, the side force acting between the movable core 26 and the yoke 22 can be suppressed. In this case, for example, a linear solenoid having a low hysteresis characteristic can be obtained by applying to a linear solenoid of a type in which the hysteresis is increased by the side force.

  The magnetic material forming the movable core 26 can improve durability by using a material containing Cr in an amount of 12% by weight or less.

  In addition, although the convex part 47 and the protrusion part 53 are integrally formed with the movable core main body 45 as FIG.3 and FIG.4 shows, it is not limited to this, For example, a movable core main body A shaft (not shown) formed separately from the movable core body 45 is fitted into a through hole (not shown) formed along the axis of 45, and one end portion of the shaft is connected to one end surface of the movable core body 45. The protrusion 47 may be configured to protrude from the other end of the movable core body 45 by a predetermined length from the other end surface of the movable core body 45, and the protrusion 53 may be configured.

  A through hole 50 through which a shaft portion 46 of a spool valve 66 described later is inserted is formed in the center portion of the fixed core 24 along the axial direction.

  The valve mechanism 16 includes a valve body 18 having an inlet port 56, an outlet port 58, a drain port 60, and a breather port 62 communicating with an oil tank (not shown) on the side, and a space inside the valve body 18. The part 64 has a spool valve (valve element) 66 disposed so as to be displaceable along the axial direction.

  In the spool valve 66, a first land portion 66a, a second land portion 66b, and a third land portion 66c are formed in this order from the solenoid portion 12, and the first land portion 66a and the second land portion 66b are the same. The third land portion 66c is formed to have a diameter slightly smaller than the first and second land portions 66a and 66b.

  A space portion 64 of the valve body 18 is closed by an end block 68, and a return spring that constantly presses the spool valve 66 toward the solenoid portion 12 between the end block 68 and the spool valve 66. 70 is disposed. The return spring 70 is not limited to a coil spring, and may be constituted by an elastic body including a leaf spring (not shown), for example.

  A shaft portion 46 that is in contact with the end surface of the convex portion 47 of the movable core 26 is integrally formed on the end portion side of the spool valve 66 adjacent to the solenoid portion 12, and the spring force of the return spring 70 is applied to the spool valve 66 and By being applied to the movable core 26 via the shaft portion 46, the movable core 26 is in a state of being pressed toward the direction of the arrow X1 in FIG.

  The hydraulic control valve 10 according to the embodiment of the present invention is basically configured as described above. Next, the operation and effects thereof will be described.

  When the solenoid unit 12 is not energized (OFF state), as shown in FIG. 1, the spool valve 66 is pressed in the direction of arrow X <b> 1 in FIG. 1 by the spring force (pressing force) of the return spring 70. In this state, the communication between the inlet port 56 and the outlet port 58 is blocked.

  Therefore, by energizing a power source (not shown) and energizing the coil 32, the solenoid unit 12 is excited and turned on, and an electromagnetic force is generated by the magnetic circuit 82 as shown in FIG. In this case, an electromagnetic force proportional to the amount of current supplied to the coil 32 is generated, and the electromagnetic force is applied to the movable core 26. Therefore, when the spool valve 66 is displaced in the direction of the arrow X2 against the pressing force of the return spring 70 under the action of the electromagnetic force, the communication between the drain port 60 and the outlet port 58 is blocked, The inlet port 56 and the outlet port 58 communicate with each other (see FIG. 2).

  Accordingly, the pressure oil supplied from a hydraulic source (not shown) is supplied to a hydraulic operating device (not shown) through the inlet port 56 and the outlet port 58 via a passage (not shown). When the energization to the solenoid unit 12 is stopped, the solenoid unit 12 is turned off and returned to the initial position shown in FIG.

  In this embodiment, since the nonmagnetic layer 65 is formed on the entire outer surface of the movable core 26 by the surface modification process, the movable core 26 functions as a magnetic gap in the magnetic circuit 82 generated by energizing the coil 32. Can do.

  Further, since the non-magnetic layer 65 is formed on the entire outer surface of the movable core 26, it can be easily formed to a predetermined dimension by managing the outer diameter of only the movable core 26. Therefore, the magnetic gap formed by the clearance between the yoke 22 and the movable core 26 can be managed with high accuracy, and extremely good magnetic characteristics can be obtained.

  Further, the nonmagnetic layer 65 is formed on the entire outer surface of the movable core 26, so that the movable core 26 is prevented from sticking to the inner wall surface of the yoke 22, and the nonmagnetic thin film used in the prior art or A nonmagnetic member (for example, a nonmagnetic pipe) or the like becomes unnecessary.

  Therefore, since the non-magnetic thin film is not required, the thickness of the non-magnetic thin film that affects the outer diameter of the movable core 26 is not controlled, and peeling, swelling, unevenness, pinholes, etc. Since there is no possibility of occurrence, durability can be improved and a product having good quality can be obtained.

  Furthermore, the thickness of the nonmagnetic layer 65 formed on the entire outer surface of the movable core 26 is made thin or thick, so that the size of the magnetic gap (the outer peripheral surface of the movable core 26 and the inner wall surface of the yoke 22 is reduced). Clearance) can be adjusted. As a result, a desired attractive force corresponding to the size of the magnetic gap can be obtained. When the magnetic gap is set as small as possible without adversely affecting the slidability, the tilt of the movable core 26 that is displaced toward the fixed core 24 side can be suppressed, and stable magnetic characteristics can be obtained.

  Moreover, in this Embodiment, the clearance gap produced between the laminated | stacked coils 32 can be made very small by making the cross-sectional shape of the coil 32 wound around the coil bobbin 30 which comprises the solenoid part 12 into a square. Therefore, for example, when compared with a conventional technique in which a solenoid coil having a circular cross section has the same number of turns, the total cross sectional area of the coil 32 (the entire space of the coil 32 wound around the coil bobbin 30) can be set small. .

  Paradoxically, this means that the ratio of the conductor cross-sectional area tightened in the winding space of the coil 32, that is, the conductor occupation ratio, can be set larger than that of the circular cross-section.

  Therefore, since the winding space of the coil 32 can be reduced, the shape of the coil bobbin 30 can be reduced, and ultimately the solenoid unit 12 as a whole can be reduced in size.

  Further, for example, when the winding space is the same as that of the solenoid coil having a circular cross section, in the present embodiment using the coil 32 having a square cross section, the number of turns on the coil bobbin 30 can be increased. The attraction force (electromagnetic force) generated at 12 can be increased.

  Further, in the present embodiment, since the winding space of the coil 32 can be reduced, the continuous total dimension (full length) of the coil 32 can be reduced. Therefore, the resistance value of the coil 32 can be reduced, and the power consumption consumed when the coil 32 is energized can be suppressed.

  For example, when the coil 32 having a circular cross section is formed so as to have the same resistance value as that of the coil having a circular cross section, in the present embodiment, the number of windings around the coil bobbin 30 can be set to a large value. Electromagnetic force) can be improved.

  Furthermore, in the present embodiment, since the contact surface between the stacked coils 32 is a surface contact, the single line occupancy in the winding space can be set larger than that of the coil having a circular cross section. it can.

  Therefore, the gap generated between the stacked coils 32 can be made extremely small, and the occupation density of each coil 32 per unit volume of the winding space can be improved. Thereby, the heat conductivity (heat dissipation) in a winding space can be improved. For example, when applied to an electromagnetic valve that is used in an environment where the ambient temperature is lower than the coil heat generation temperature, the heat dissipation is improved. Therefore, in addition to the fact that the resistance value of the coil 32 can be set small as described above, further energization is performed. Heat generation in the coil 32 during heat generation can be reduced, and therefore the resistance value can be further reduced.

  Furthermore, the solenoid part 12 including the coil 32 formed in a square cross section can be suitably applied as a vehicle-mounted solenoid valve. In-vehicle components are generally limited to a minimum applied voltage (for example, 8 V) by a battery voltage. And since it is requested | required as a vehicle-mounted solenoid valve to ensure the minimum magnetomotive force (electric current value), for example, when the same magnetic circuit is used, a maximum resistance value will be decided inevitably. Here, since the resistance value of the coil 32 generally increases as the temperature of the coil 32 increases, the maximum resistance value must be a value that also takes into account the increased resistance value. For example, if the maximum resistance value is set without taking this rising resistance value into consideration, the necessary current value cannot be obtained, and the minimum magnetomotive force may not be obtained. That is, when used as an in-vehicle solenoid valve, it is necessary to secure a magnetomotive force (current value) even if the resistance value of the coil 32 is energized through the solenoid unit 12 and the temperature of the coil 32 is increased.

  Therefore, if the resistance value of the coil 32 and the resistance value of the coil 32 during energization heat generation are low, a high current value can be secured by Ohm's law, which is extremely beneficial. That is, by making the cross-sectional shape of the coil 32 square, for example, in the solenoid unit 12 that can obtain the same magnetomotive force, the resistance value of the coil 32 is reduced to reduce power consumption. The amount of heat generated by the coil 32 during energization decreases, and the resistance value during energization heat generation can be reduced.

  As a result, since the resistance value of the coil 32 during energization heat generation can be reduced to ensure a high current value, it can be suitably used as an in-vehicle electromagnetic valve in which the minimum applied voltage is limited. Further, for example, the solenoid unit 12 having the coil 32 having a square cross section compared to other solenoid units having the same minimum magnetomotive force constituted by coils having a circular cross section has a current value that can be increased. Since the number of turns on the coil bobbin 30 can be reduced, further downsizing can be achieved.

  Further, in the present embodiment, a protrusion 53 functioning as a stopper is provided on the end surface of the movable core 26 facing the thin portion 19 of the housing 14, and the protrusion 53 is a spacer for preventing residual magnetism in the solenoid portion 12. It can function as a so-called magnet killer.

  That is, the magnetic flux is less likely to flow with respect to the thin portion 19 of the housing 14, and the magnetic flux is less likely to flow at the central portion of the thin portion 19. Therefore, by providing the projection 53 at the center of the movable core 26 corresponding to the center of the thin portion 19, it is possible to prevent the magnetic flux from flowing to the projection 53 as much as possible.

  Further, by providing the protrusion 53 on the end face of the movable core 26, the R portion 72 (see FIG. 5) can be formed on the inner wall of the recess at the bottom of the housing 14 with which the protrusion 53 abuts. Becomes easy.

  Furthermore, since the end surface of the movable core 26 having the projection 53 faces the wall surface of the thin portion 19 with the projection 53 interposed therebetween, the end surface of the movable core 26 is opposed to the thin portion 19 side of the housing 14. It is possible to prevent the magnetic flux from flowing in.

  Furthermore, in the present embodiment, the outer peripheral surface of the end portion of the movable core 26 corresponds to the position corresponding to the inner wall surface of the bottom portion 17 of the housing 14 between the bottom portion 17 of the housing 14 and the cylindrical yoke 22. (Refer to section A in FIG. 5). For this reason, the magnetic flux is transferred from the bottom portion 17 of the housing 14 to the movable core 26 side also on the inner wall surface of the bottom portion 17 and the outer peripheral surface of the movable core 26 (see FIG. 11). Accordingly, the magnetic flux is smoothly transferred between the bottom portion 17 of the housing 14 and the end portion of the movable core 26, and the amount of magnetic flux can be increased.

  As a result, the suction force in the solenoid unit 12 can be improved, and when the suction force is equivalent, the overall configuration of the hydraulic control valve 10 according to the present embodiment can be reduced in size.

It is a longitudinal cross-sectional view along the axial direction of the hydraulic control valve which concerns on embodiment of this invention. It is a longitudinal cross-sectional view which shows the state which the spool valve displaced by exciting the solenoid part of the hydraulic control valve shown in FIG. FIG. 2 is an enlarged longitudinal sectional view in the case where a nonmagnetic layer formed on the entire outer surface of the movable core shown in FIG. 1 is thin. FIG. 2 is an enlarged vertical cross-sectional view when a nonmagnetic layer formed on the entire outer surface of the movable core shown in FIG. 1 is thick. It is a partial expanded longitudinal cross-sectional view of the coil assembly which comprises the said hydraulic control valve. It is the partial expanded longitudinal cross-sectional view by which the coil of the cross-sectional square was wound by the coil bobbin. It is a partial expanded longitudinal cross-sectional view which shows the state from which the flange formed in the coil bobbin was removed. FIG. 6 is a partially enlarged longitudinal sectional view according to a modified example of the coil assembly shown in FIG. 5. FIG. 5 is a partially enlarged longitudinal sectional view in which a coil having a rectangular cross section is wound around a coil bobbin. It is a partial expanded longitudinal cross-sectional view which shows the annular guide part formed in the edge part of a yoke. It is a partially omitted enlarged explanatory view showing a magnetic circuit formed in a solenoid part. It is the partial expanded longitudinal cross-sectional view by which the coil which concerns on a prior art was wound by the coil bobbin.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Hydraulic control valve 12 ... Solenoid part 14 ... Housing 16 ... Valve mechanism part 17 ... Bottom part 18 ... Valve body 19 ... Thin part 20 ... Coil assembly 22 ... Yoke 24 ... Fixed core 26 ... Movable core 28a, 28b ... Flange 30 ... Coil bobbins 32 and 32a ... Coil 34 ... Vertical face part 36 ... Recess 38 ... Conical face part 39 ... Ring guide part 40 ... Resin sealing body 46 ... Shaft part 50 ... Through hole 54 ... Communication groove 56 ... Inlet port 58 ... Outlet port 64 ... Space part 65 ... Nonmagnetic layer 66 ... Spool valve 70 ... Return spring

Claims (7)

In the linear solenoid valve that generates an electromagnetic force proportional to the energization amount to the solenoid unit and displaces the valve body by the electromagnetic force,
A valve body including a valve body and a housing having an inlet port and an outlet port through which pressure fluid flows; and
A solenoid provided in the housing and having a coil wound around a coil bobbin, and a movable core that is attracted to the fixed core under an energization action on the coil;
A valve mechanism provided on the valve body and having a valve body that switches between a communication state and a non-communication state of the inlet port and the outlet port by transmitting the displacement of the movable core;
With
The housing includes a cylindrical portion, a cylindrical yoke formed on the inner peripheral side of the cylindrical portion so as to be separated from the cylindrical portion, and disposed substantially parallel to the cylindrical portion, and the cylindrical portion and the yoke And a bottom portion formed integrally with the bottom portion, and a thin portion having a small thickness compared to other portions of the bottom portion is formed on the bottom portion,
A nonmagnetic layer having a predetermined thickness is formed on the outer surface of the movable core,
On the end surface of the movable core that faces the thin portion, a protrusion that can contact the thin portion and has a nonmagnetic layer and functions as a stopper is formed.
The end surface of the movable core that faces the thin portion reaches a position that exceeds the coil inserted between the cylindrical portion and the yoke when the protrusion comes into contact with the thin portion, and An end portion in the vicinity of the end surface is disposed at a position corresponding to the inner wall surface of the bottom portion. The valve of claim 1,
The linear solenoid valve according to claim 1, wherein the nonmagnetic layer formed on the outer surface of the movable core is formed to be thin with a predetermined thickness. The valve of claim 1,
The linear solenoid valve according to claim 1, wherein the nonmagnetic layer formed on the outer surface of the movable core is formed to have a predetermined thickness. The valve of claim 1,
The linear solenoid valve according to claim 1, wherein the nonmagnetic layer is formed by a high-frequency quenching process for the movable core. The valve of claim 1,
The linear solenoid valve according to claim 1, wherein the coil has a square cross section. The valve of claim 1,
The linear solenoid valve according to claim 1, wherein the coil has a rectangular cross section. The valve of claim 1,
A linear solenoid valve characterized in that a cylindrical yoke is provided between the movable core and the coil bobbin, and a thin annular guide portion is formed at the end of the yoke facing the fixed core.

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