JPH06241333A - Solenoid valve - Google Patents

Abstract

PURPOSE:To mainly prevent air from mingling into oil charged in a linear solenoid part by forming a valve hole adapted to be opened and closed by a valve element and an annular chamber positioned at the outer periphery of the main valve body, in a passage communicating inlet and outlet ports of a valve body. CONSTITUTION:A solenoid valve is located in a space in the air at the outer surface of a base H, and is connected to an outlet flow passage L2 branching from a feed passage L1 through which hydraulic oil is fed from a pump PN to an actuator AC by way of a pressure reducing valve RV and an orifice OF so as to relief a part of the hydraulic oil into a tank T. Further, the main part of the solenoid valve is composed of a valve part A and a linear solenoid part B. In this arrangement, a passage communicating between an inlet port 2 and an outlet port 9 is formed therein with a valve hole 3 adapted to be opened and closed by a valve element 10 and an annular chamber 6 positioned at the outer periphery of the valve body 1. Further, the annular chamber 6 is communicated with the valve hole 3, downstream of the valve element 10, and is communicated with the outlet port 9 only in its upper area.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solenoid valve, and more particularly to a solenoid relief valve whose relief pressure is regulated and controlled.

[0002]

2. Description of the Related Art An electromagnetic relief valve in the prior art is
As shown in FIG. 3, an outflow passage L, which is attached to a space in the air on the outer side surface of a base body H such as an automobile mission housing with its axis lined horizontally, is branched from a supply passage for supplying hydraulic oil from a pump to an actuator. The pressure in the supply passage is controlled by shutting off or communicating with the oil tank T around the electromagnetic relief valve. The left-right direction in the following description is the direction in FIG.

The above electromagnetic relief valve has a relief valve portion A.
And a linear solenoid portion B which is in a coaxial relationship so as to operate it and are integrally connected. The cylindrical valve main body 1 of the relief valve portion A and the solenoid housing 30 of the linear solenoid portion B are coaxially connected by the butting of the outer flange portions, and the valve main body 1
The axial center hole 31 and the hollow hole of the solenoid housing 30 are continuous hollow holes.

In the relief valve portion A, a through hole 32 that radially extends from the outer peripheral surface of the intermediate portion of the valve body 1 to the central hole 31.
Are formed. The ball valve body 10 is fitted in the center hole 31, and the ball valve body 10 is a valve seat formed in the center hole 31.
A plug body 13 having a central hole 12 formed in the axial direction is fitted to the rear end side of the central hole 31 so as to come into contact with the plug 11. In the center hole 12 of the plug body 13, a poppet 15 that contacts the ball valve body 10 and a compression coil spring 16 that contacts the poppet 15 are inserted.

In the linear solenoid part B, a valve rod 26 is slidably inserted in an axial direction into a hollow hole in a solenoid housing 30 in which the solenoid 21 is fitted.
A plunger 27 is fitted near the rear end (left end) of
The tip of the plunger 27 faces a yoke portion 30 a formed in the solenoid housing 30. A lid plate 14 is attached to the back surface of the plug body 13, and a lid plate 29 is attached to the rear end (left end) of the solenoid housing 30 so as to close the hollow hole. The internal space of the part B is filled with oil.

The tip end of the valve rod 26 slidably penetrates the cover plate 14 to project into the central hole 12 of the plug body 13 and abut the compression coil spring 16. Further, the valve rod 26 has a cover plate at its rear end.
It can retract until it hits 29. Therefore, the ball valve body 10
Is pressed against the valve seat 11 by the spring force of the compression coil spring 16.

An exciting current is input to the solenoid 21 from an external control device (not shown). At least the valve body 1, the solenoid housing 30 and the plunger 27 are magnetic bodies, and the valve rod 26 and The valve body 1 is a non-magnetic body.

In the electromagnetic relief valve configured as described above, the valve body 1 is attached to the base body H by being fitted into the mounting hole on the outer surface of the base body H with the O-ring interposed.
The center hole 31 of the valve body 1 communicates with the outflow passage L of the base H. The hydraulic oil having a constant pressure P ₀ from the pump flows through the supply passage and is supplied to the actuator. At that time,
It also flows toward the outflow passage L.

Therefore, when the exciting current is not input to the solenoid 21 (the upper half state of FIG. 3), the valve rod 26 is retracted and the plunger is retracted so that the spring force of the compression coil spring 16 is removed. 27 is opposed to the yoke portion 30a of the solenoid housing 30 with an appropriate gap, and the ball valve body 10 is pressed against the valve seat 11 via the poppet 15.

When a controlled exciting current from an external control device (not shown) is inputted to the solenoid 21, a magnetic force line circuit passing through the solenoid housing 30 and the plunger 27 is constructed, and the magnitude of the exciting current is adjusted according to the magnitude of the exciting current. Suction force F
m works between the yoke portion 30a and the plunger 27, and the valve rod 26
Presses the compression coil spring 16. As a result, the poppet
Through 15 the ball valve body 10 is pressed against the valve seat 11 by the spring force Fs of the compression coil spring 16 which is compressed according to the suction force Fm. That is, the spring force Fs increases / decreases according to the attraction force Fm of the solenoid 21, that is, the magnitude of the exciting current.

Therefore, when the pressure F generated by the hydraulic pressure P of the working oil supplied to the actuator acting on the ball valve body 10 is less than the spring force Fs, the working oil flows out from the outflow passage L into the oil tank T. When the ball valve body 10 is shut off by 10 and is equal to or more than the spring force Fs of the coil spring 16,
Apart from 11, a part of the hydraulic oil in the outflow passage L flows out to the oil tank T through the center hole 31 and the circulation hole 32.

Therefore, the hydraulic pressure P of the hydraulic oil supplied to the actuator is maintained at the hydraulic pressure corresponding to the spring force Fs. That is, the relief pressure of the relief valve is set and controlled by controlling the exciting current.

[0013]

In the solenoid valve as described above, the solenoid valve itself is attached to the space in the air on the outer surface of the base body H such as the transmission housing of an automobile with its axis being horizontal. The inside of the central hole 31 of the valve body 1 is always entirely exposed to air, especially when the relief valve portion A, that is, the ball valve body 10 is closed. Therefore,
Air has also entered the center hole 12 of the plug body 13, and the solenoid housing 30 of the linear solenoid part B due to temperature change 30
Air based on the expansion and contraction of the filling oil inside the cover plate 14 and valve stem
It enters the solenoid housing 30 through the sliding clearance with 26.

The air that has penetrated into the filling oil in the solenoid housing 30 causes an obstacle in the reciprocating movement of the plunger 27 of the linear solenoid portion B, and in particular, a reduction in the vibration isolation effect due to the filling oil. An object of the present invention is to prevent air from entering the filling oil in the linear solenoid portion of such a solenoid valve.

[0015]

SUMMARY OF THE INVENTION A solenoid valve according to the present invention includes a valve body having a valve body having a passage communicating with an inlet and an outlet, and a valve body for opening and closing the passage, and a valve body. And a linear solenoid portion for operating the valve body, the solenoid opening having a working opening facing the passage of the valve body, and an outer surface of the mounting base so that the inlet is connected to the outlet of the mounting base. In a solenoid valve which is mounted in a space in the air of which the axis is horizontal, the passage in the valve body includes a valve hole opened and closed by a valve body and an annular chamber formed on the outer periphery of the valve body, and the annular chamber is , Communicates with the valve hole downstream of the valve body, and communicates with the outlet only in the upper range.

[0016]

When the valve body is opened at a pressure equal to or higher than the predetermined pressure set by the linear solenoid section or by the operation of the linear solenoid section, oil flows from the inlet into the valve hole of the solenoid valve, and the annular chamber is closed. And flows out through the upper outlet.

At this time, since the oil flowing through the valve hole and the annular chamber of the solenoid valve is maintained in the state of being stored in the valve hole and the annular chamber, the filling oil in the solenoid housing of the linear solenoid part is changed due to the temperature change. Even if it expands and contracts, only the filling oil and the stored oil flow in and out, and no air enters the filling oil in the solenoid housing.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An electromagnetic relief valve according to an embodiment of the present invention will be described with reference to the drawings. The up, down, left, and right directions in the following description are the directions in the drawings. The electromagnetic relief valve shown in FIG. 1 is mounted with a horizontal axis in a space in the air on the outer surface of a base body H such as a transmission housing of an automobile. Then, an electromagnetic relief valve is connected to an outflow passage L ₂ branched from a supply passage L ₁ for supplying hydraulic oil of a constant pressure from the pump PN to the actuator AC via the pressure reducing valve RV and the orifice OF, and is set to this electromagnetic relief valve. When the pressure in the outflow passage L ₂ becomes higher than the pressure thus set, part of the hydraulic oil in the outflow passage L ₂ is allowed to escape to the oil tank T around the electromagnetic relief valve through the discharge flow passage.

The electromagnetic relief valve described above has a relief valve portion A.
And a linear solenoid portion B which is in a coaxial relationship so as to operate it and are integrally connected. The non-magnetic stepped cylindrical valve body 1 in the relief valve portion A and the magnetic deep cup-shaped first solenoid housing 20 in the linear solenoid portion B are formed at the rear end (left end) of the valve body 1. The outer flange portion 1a that is formed and the outer flange portion 20a that is formed at the tip (right end) of the first solenoid housing 20 are butted against each other and coupled in a coaxial relationship, and the hollow hole of the valve body 1 and the first solenoid housing The 20 hollow holes are continuous hollow holes.

In the relief valve portion A, the valve body 1 has a small-diameter mounting portion 1b at the front end (right end) and an outer flange portion 1a at the rear end (left end) as described above, and the mounting portion 1b side. A center hole composed of a front end hole 2, a small diameter hole 3, a medium diameter hole 4 and a large diameter hole 5 sequentially penetrates in the axial direction. Further, a circumferential groove 6 having an appropriate size in the axial direction is formed on the outer peripheral surface of the intermediate portion of the valve body 1, and the circumferential groove 6 penetrates in the radial direction from the groove bottom of the circumferential groove 6 to the medium diameter hole 4 of the central hole. Four circulation holes 7 are formed at equal intervals on the circumference (at intervals of 90 degrees in the illustrated example).
Two of the four through holes 7 are formed in the vertical direction.

A sleeve 8 is fitted over the entire length of the outer peripheral surface of the intermediate portion of the valve body 1 in an oil-tight manner.
A radial discharge hole (outlet) 9 opening in the oil tank T around the electromagnetic relief valve penetrates upward. Circumferential groove 6
Forms an annular chamber in which the discharge hole 9 is opened only at the uppermost position by the sleeve 8.

A ball valve body 10 is fitted in the small diameter hole 3 so that the ball valve body 10 can abut on a valve seat 11 which is a shoulder of a taper step portion between the tip hole 2 and the small diameter hole 3. Has become. The large-diameter hole 5 is fitted with a plug body 13 having a substantially frustoconical front end (right end) and a central hole 12 formed in the axial direction. A cover plate 14 having a shape of a circle is fitted. An appropriate gap is maintained between the frustoconical surface of the plug 13 and the inner peripheral surface of the medium diameter hole 4. Center hole 12 of stopper 13
A poppet 15 that contacts the ball valve body 10 and a compression coil spring 16 that contacts the poppet 15 are inserted therein.

In the linear solenoid section B, a solenoid 21 is fitted on the outer peripheral surface of the first solenoid housing 20. The second solenoid housing 22, which is a magnetic cylindrical member formed with an inner flange portion 22a (at the left end in the drawing) having an inner diameter substantially the same as the outer peripheral surface of the first solenoid housing 20, is the outer periphery of the solenoid 21. The surface of the solenoid 21 is sandwiched between the outer flange portion 20a of the first solenoid housing 20 and the inner flange portion 22a of the second solenoid housing 22. The rim portion of the second solenoid housing 22 is fixed to the outer flange portion 20a of the first solenoid housing 20 and the outer peripheral surface of the outer flange portion 1a of the valve body 1.

A valve rod 26 is slidably fitted in the hollow hole of the first solenoid housing 20 in the axial direction through rolling bearings 25, 25 held by a sleeve 23 and holders 24, 24, respectively. Plunger 27 near the rear end (left end) of rod 26
, The plunger 27 is loosely fitted to the inner peripheral surface of the inner flange 22a of the second solenoid housing 22 with a small gap, and the tip (right end) becomes the cylindrical tip portion 27a.
The first solenoid housing 20 faces the yoke portion 20b, which is the rear end small diameter portion, and can be fitted with an appropriate gap. Then, through the plunger 27, the communication hole 28
Is formed, and the communication hole 28 contributes to the breathing action of the plunger 27 in outward double action.

The tip of the sleeve 23 is in contact with the back surface of the plug body 13, and the holder 24 holds the lid plate 14 with the plug body 13. A lid plate 29 is attached to the rear end (left end) of the second solenoid housing 22 so as to close the hollow hole, and the inner space of the linear solenoid portion B closed by the lid plate 14 and the lid plate 29 is arranged in the inner space. , Filled with oil.

The tip end of the valve rod 26 slidably penetrates the cover plate 14 to project into the central hole 12 of the plug body 13 and abut the compression coil spring 16. Further, the valve rod 26 has a cover plate at its rear end.
It can retract until it hits 29. Therefore, the ball valve body 10
Is pressed against the valve seat 11 by the spring force of the compression coil spring 16.

An exciting current is input to the solenoid 21 from an external control device (not shown). At least the first solenoid housing 20, the plunger 27 and the second solenoid housing 22 are magnetic bodies, Valve rod
26, the sleeve 23, the holder 24, and the valve body 1 are non-magnetic materials.

In the electromagnetic relief valve configured as described above, the mounting portion 1b of the valve body 1 is fitted into the mounting hole on the outer surface of the base body H with the O-ring 30 interposed therebetween, and thus the base body H is formed.
The center hole of the valve body 1, that is, the tip hole 2 is connected to the outflow passage L ₂ of the base H.

The operation and action of the above electromagnetic relief valve will be described. The upper half of FIG. 1 shows a state in which the exciting current from the control device is not input to the solenoid 21, and the lower half shows a state in which the exciting current is input to the solenoid 21. The hydraulic oil reduced in pressure from the pump PN to the constant pressure P ₀ by the pressure reducing valve RV is supplied to the supply passage L ₁ via the orifice OF. Then, the hydraulic oil flowing into the supply passage L ₁ is supplied to the actuator AC and also flows into the outflow passage L ₂ .

When the exciting current is not input to the solenoid 21, the spring force of the compression coil spring 16 causes the valve rod 26
Is retracted until its rear end contacts the cover plate 29, and the compression coil spring 16 is opened to an initial state, for example, an unloaded state. That is, the plunger 27 is in the most retracted position. Therefore, the ball valve body 10 is easily separated from the valve seat 11, and the supplied working oil is in the unloaded state, and the tip hole 2, the small diameter hole 3, the medium diameter hole 4, the flow hole 7, the circumferential groove 6 and the discharge hole. It flows through 9 to the oil tank T.
Therefore, the hydraulic pressure P of the hydraulic oil supplied to the actuator AC
Is almost zero.

The cylindrical tip portion 27a of the plunger 27
Are opposed to the yoke portion 20b of the first solenoid housing 20 with an appropriate gap. When a controlled exciting current from an external control device (not shown) is input to the solenoid 21, a magnetic force line circuit passing through the first solenoid housing 20, the second solenoid housing 22 and the plunger 27 is formed, and the magnitude of the exciting current is increased. Suction force Fm
Acts between the yoke portion 20b and the cylindrical tip portion 27a of the punja 27, and the valve rod 26 presses the compression coil spring 16. As a result, the ball valve body 10 receives the suction force Fm through the poppet 15.
The spring force Fs of the compression coil spring 16 compressed in accordance with the above is pressed against the valve seat 11. That is, the adjusting spring force Fs of the compression coil spring 16 increases or decreases according to the attraction force Fm of the solenoid 21, that is, the magnitude of the exciting current.

Therefore, if the pressure F generated by the hydraulic pressure P of the hydraulic oil supplied to the actuator AC acting on the ball valve body 10 is less than the adjusting spring force Fs of the coil spring 16, the oil pressure is transferred to the oil tank T via the electromagnetic relief valve. Of the hydraulic oil in the outflow passage L ₂ of the ball valve body 10 is blocked by the ball valve body 10.
When the pressure F acting on the valve spring is equal to or greater than the adjusting spring force Fs of the coil spring 16, the ball valve body 10 separates from the valve seat 11 and the outflow passage L
A part of the hydraulic oil ₂ has a tip hole 2, a small diameter hole 3, a medium diameter hole 4,
It flows out through the circulation hole 7, the circumferential groove 6 and the discharge hole 9 into the oil tank T. Therefore, the hydraulic pressure P of the hydraulic oil supplied to the actuator AC through the supply passage L ₁ is maintained at the hydraulic pressure corresponding to the adjusting spring force Fs.

That is, the relief pressure of the relief valve is set and controlled by controlling the exciting current. Since the orifice OF is provided in the supply passage L ₁ , the pump PN on the upstream side of the orifice OF is controlled even if the hydraulic pressure P is controlled.
The influence on the constant pressure P ₀ supplied from is reduced, and a large fluctuation is not given.

Therefore, in controlling the relief pressure, the valve rod
26 and the plunger 27 move together in the axial direction, the oil is filled in the internal space of the solenoid part B and the oil before and after the plunger 27 flows through the communication hole 28 when the plunger 27 reciprocates. It does not resist the reciprocal movement of the valve rod 36.

In any state, the outflow passage L ₂
The hydraulic oil flowing from the oil tank to the oil tank is temporarily stored in a storage chamber made of an annular chamber formed by the tip hole 2, the small diameter hole 3 and the medium diameter hole 4 of the valve body 1 and the circumferential groove 6, and only above. It is discharged from a discharge hole 9 opened in the. Therefore, even if the electromagnetic relief valve is installed in the air space of the oil tank T, the central hole 12 of the plug body 13 is inserted into the space in the solenoid housing composed of the first solenoid housing 20 and the second solenoid housing 22. Therefore, the air in the external space does not flow.

Therefore, even if the filling oil in the solenoid housing (20, 22) of the linear solenoid portion B expands and contracts due to the temperature change, only the filling oil in the solenoid housing and the working oil in the reservoir chamber flow in and out. Air does not enter the filling oil in the solenoid housing (20, 22).

When the operating oil flowing out from the outflow passage L ₂ into the oil tank T is contaminated with dust or the like from the actuator or the like, the small-diameter hole 3, the medium-diameter hole 4, and the downward flow hole 7 are used. Since dust and the like settle on the bottom of the annular chamber, the filling oil in the solenoid housing and the small diameter hole 3 and the medium diameter hole 4
Dust and the like do not enter the filling oil when flowing in and out of the working oil inside.

In the above embodiment, the electromagnetic relief valve is used as the solenoid valve, but the solenoid valve according to the present invention can be applied to solenoid valves having other functions.

[0039]

In the solenoid valve according to the present invention, the space inside the solenoid housing does not directly flow to the outer space even when the solenoid valve itself is mounted in the space in the air. Therefore, even if the filling oil in the solenoid housing of the linear solenoid part expands and contracts due to temperature change, air does not enter the filling oil in the solenoid housing. It prevents the reciprocal movement of the plunger of the solenoid part from being impaired, especially the reduction of the vibration isolation effect of the filling oil.

[Brief description of drawings]

FIG. 1 is a sectional view of an electromagnetic relief valve according to an embodiment of the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

FIG. 3 is a cross-sectional view of a conventional electromagnetic relief valve.

[Explanation of symbols]

A Relief valve part B Linear solenoid part 1 Valve body 2 Tip hole 3 Small diameter hole 4 Medium diameter hole 5 Large diameter hole 6 Circumferential groove (annular chamber) 7 Flow hole 8 Sleeve 9 Discharge hole (outlet) 10 Ball valve body 11 Valve seat 12 Center hole 13 Stopper 14, 29 Cover plate 15 Poppet 16 Compression coil spring 20b Yoke portion 21 Solenoid 23 Sleeve 26 Valve rod 27 Plunger 28 Communication hole H Base PN pump AC actuator L ₁ Supply passage L ₂ Outflow passage T Oil tank

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoichiro Maekawa 1-1-1, Asahi-cho, Kariya city, Aichi Toyota Koki Co., Ltd.

Claims (1)

[Claims] 1. A valve unit having a valve body having a passage communicating with an inlet and an outlet, and a valve body opening and closing the passage, and an operating opening coupled to the valve body and having an operating opening of the valve body. The linear housing is provided with a solenoid housing that faces the passage and operates a valve body, and the axis is horizontal to the space in the air on the outer surface of the mounting base so that the inlet is connected to the outlet of the mounting base. In the mounted solenoid valve, the passage in the valve body includes a valve hole opened and closed by a valve body and an annular chamber formed on the outer periphery of the valve body, and the annular chamber communicates with the valve hole downstream of the valve body. At the same time, the solenoid valve is characterized by communicating with the outlet only in the upper range.