JP2597612Y2 - Solenoid spool valve - Google Patents

Description

[Detailed description of the invention]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic spool valve, for example, a pressure control electromagnetic spool valve and an electromagnetic opening / closing spool valve.

[0002]

2. Description of the Related Art A conventional electromagnetic spool valve is disclosed in Japanese Utility Model Laid-Open No. 3-117178, for example. The electromagnetic spool valve includes a spool valve portion and a linear solenoid portion which is coaxially operated to operate the spool valve portion, and is used in, for example, an automatic transmission of an automobile.

The spool valve portion is embedded in a hollow lateral hole formed in the transmission housing. A linear solenoid portion coaxial with the spool valve portion has a base end fixed to an end of the spool valve portion. And protrudes into the air above the oil level in the oil tank. In the spool valve portion, a spool housing sliding hole is formed so as to penetrate in the axial direction, and the spool is slidably fitted in the sliding hole in the axial direction.

On the inner peripheral surface of the sliding hole, a large-diameter hole portion in which a drain passage upwardly communicating from the linear solenoid portion side is communicated.
An annular groove communicating with the supply passage and an annular groove communicating with the output passage are formed. The drain passage is opened on the upper outer peripheral surface of the housing of the linear solenoid portion.

The valve spool has an annular groove communicating with the output passage due to axial displacement and a variable throttle selectively opening and closing the annular groove communicating with the pressure oil supply passage or the annular groove communicating with the drain passage. Land portions are formed corresponding to the grooves. Oil is filled in the solenoid housing space of the linear solenoid that displaces the spool.

In the above-mentioned electromagnetic spool valve, the spool is displaced in the axial direction by the operation of the linear solenoid unit by the controlled exciting current, so that the pressure oil supply passage and the drain passage are shut off, and the output oil passage is supplied to the output passage. The passage and the drain passage are selectively opened and closed as much as possible to control the oil pressure to the output passage, and the oil from the drain passage flows out of the linear solenoid portion through the opening on the upper outer peripheral surface of the housing.

At this time, the internal space of the linear solenoid portion is in contact with the large-diameter hole of the spool housing, and the oil inside the linear solenoid portion is discharged from the large-diameter hole of the spool housing with the respiration by the operation of the linear solenoid portion. It flows into and out of the drain passage.

[0008]

In the electromagnetic spool valve of the prior art described above, that is, the electromagnetic spool valve described in Japanese Utility Model Laid-Open Publication No. 3-117178, oil is discharged from an output passage connected to a hydraulically operated device. The drain passage of
After reaching the joining area between the spool valve section and the linear solenoid section, it extends upward in the same area and opens to the upper outer peripheral surface of the linear solenoid section.

Therefore, the oil mixed with iron powder and dust generated in the hydraulic operating device flows through the spool valve portion to the connecting portion of the linear solenoid portion and flows out to the outside, so that the connecting portion of the linear solenoid portion In this case, the oil enters the inside of the linear solenoid unit due to the respiration by the operation of the linear solenoid unit. As a result, iron powder, dust, and the like are mixed in the oil filled in the linear solenoid unit, causing an obstacle to the operation of the linear solenoid unit.

Further, when the oil tank is installed at a position in the air above the oil level of the oil tank, since the opening of the drain passage is on the upper outer peripheral surface of the linear solenoid portion, the oil level is maintained to that extent. However, although the filled state of the oil inside the linear solenoid part is also maintained, if the oil level decreases due to contraction / expansion due to temperature change, oil evaporation, leakage from other places, etc., the oil will immediately enter the linear solenoid part. Air intrusion can occur. As a result, the absorption of vibration by oil in the operation of the electromagnetic spool valve is impeded by the incorporation of air in oil. The present invention provides an electromagnetic spool valve that does not have the above-mentioned disadvantages.

[0011]

An electromagnetic spool valve according to the present invention is provided with a valve body in which a sliding hole having a pressure oil supply passage, and annular grooves communicating with a drain passage and an output passage is formed .
Was fitted spool slidably axially sliding hole, the
Spool corresponding to each annular groove so as to selectively variable iris an annular groove which communicates with the output passage by axial displacement of the spool in an annular groove which communicates with the annular groove or drain passage communicating with the pressure oil supply passage A land is formed on the valve body, and the spool is displaced by being connected to the valve body.
A filled linear solenoid is provided, and the drain passage is
Outside the valve body above the internal space of the near solenoid
And an annular groove communicating with the drain passage and a solenoid
A drain oil passage communicating with the housing space is formed in the valve body.
It has been achieved .

The annular groove communicating with the drain passage communicates with the space of the solenoid housing only through a drain oil passage formed in the valve body. Further, in the case where the valve is installed at a position in the air above the oil level of the oil tank, it is preferable that the opening of the drain passage in the mounting portion of the valve body is located above the highest part of the electromagnetic spool valve.

[0013]

In the above-mentioned electromagnetic spool valve, the spool is displaced in the axial direction by the operation of the linear solenoid portion by the controlled exciting current, so that the pressure oil supply passage and the drain passage are shut off, and the output oil passage is supplied to the output passage. A variable throttle is selectively opened and closed between the passage and the drain passage to control the hydraulic pressure to the output passage.
At this time, the oil inside the linear solenoid portion is discharged through the annular groove through the drain oil passage along with the breathing action by the operation of the linear solenoid portion, and the internal space of the linear solenoid portion is removed.
It flows into and out of the drain passage opening outside the valve body above .

When oil mixed with iron powder or dust generated in the hydraulic operating device flows into the drain passage through the annular groove, the inside of the linear solenoid portion is formed in the annular groove in the axial direction on the spool valve portion. Oil from the hydraulically operated device to the drain passage when the oil inside and outside flows due to the respiration of the axially displaced portion of the linear solenoid and the respiration of the reciprocating spool. , Do not enter the linear solenoid. Also,
The liquid level filling the internal space of the near solenoid
Is maintained at the opening of the
Air will not enter or enter.

When the electromagnetic spool valve is installed at a position in the air above the oil level of the oil tank, the opening of the drain passage is located above the highest part of the electromagnetic spool valve. -Air does not enter the linear solenoid even if the oil level is slightly reduced due to expansion or leakage from other places.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An electromagnetic spool valve according to an embodiment of the present invention will be described with reference to the drawings. In addition, the left-right direction in the following description is the direction in FIG. The pressure control solenoid spool valve of the embodiment shown in FIG. 1 is used, for example, for an automatic transmission of an automobile.

The pressure control electromagnetic spool valve according to the embodiment comprises a spool valve portion 1 and a linear solenoid portion 2 which is coaxially operated to operate the spool valve portion. The spool valve portion 1 is fitted in a hollow horizontal hole h formed near the upper end of the upright wall portion H of the transmission housing (equipment), and has a linear solenoid portion 2 coaxial with the spool valve portion 1.
Has its base end fixed to the exposed end of the spool valve portion 1,
It projects into the air above the oil level in the oil tank T formed between the transmission housing and the transmission case.

In the spool valve section 1, a sliding hole 4 extends in the axial direction through a cylindrical spool housing 3 made of a nonmagnetic material and fitted in a hollow horizontal hole h of an upright wall H of a transmission housing (equipment). The sliding hole 4 is formed as
A spool 5 is slidably fitted in the axial direction. The rear end (right end) of the sliding hole 4 is hermetically closed by a lid plug 6 screwed into the sliding hole 4 in an adjustable manner.

On the inner peripheral surface of the sliding hole 4, a large-diameter hole portion 7, a first annular groove 9, and a second annular groove are sequentially provided from the linear solenoid portion 2 side.
11, a third annular groove 13, a fourth annular groove 15, a fifth annular groove 17, and a large-diameter hole 19 are formed. In addition, the fourth of the third annular groove 13
On the side of the annular groove 15, a concave notch of a small projection is formed.

The first annular groove 9 is a partial arc chamber 9a facing obliquely upward, and the third annular groove 13, the fourth annular groove 15, and the fifth annular groove 17 are a partial arc chamber 13a facing downward and a partial arc chamber. 15a and a partial arc chamber 17a respectively reach the outer peripheral surface of the spool housing 3. The fourth annular groove 15 reaches the outer peripheral surface of the spool housing 3 as a partial arc chamber 15b facing obliquely upward and out of phase with the partial arc chamber 9a separately from the partial arc chamber 15a. Apart from the partial arc chamber 17a, the partial arc chamber 9a reaches the outer peripheral surface of the spool housing 3 as a partial arc chamber 17b facing obliquely upward in the same phase as the partial arc chamber 9a. (See FIGS. 2 and 3)

An axial drain groove 20 and a feedback control pressure groove 21 which are circumferentially out of phase with each other are formed on the outer peripheral surface of the spool housing 3, and the drain groove 20 is a partial arc of the first annular groove 9. Chamber 9a and partial arc chamber 17b of fifth annular groove 17
One end of the feedback control pressure groove 21 communicates with the second annular groove 11 via the orifice 22, and the other end opens to the partial arc chamber 15 b of the fourth annular groove 15. I have. (See FIGS. 2 and 3)

A supply passage 23 connected to the pump P and an output passage 24 connected to the hydraulic operating portion A are formed in the hollow wall h in the fitting area of the spool valve portion of the upright wall H of the transmission housing. Further, the drain passage 25 communicating downward from the hollow horizontal hole h is turned in the horizontal direction on the way as shown in FIG. 3 and further turned in the upward direction, and particularly in the top surface of the upright wall H. The opening N communicates with the outside. The supply passage 23 is provided in the partial arc chamber 13a of the third annular groove 13, the output passage 24 is provided in the partial arc chamber 15a of the fourth annular groove 15, and the drain passage 25 is provided in the partial arc chamber 17a of the fifth annular groove 17. They communicate with each other. In addition, the large-diameter hole portion 19 is directly in open communication with the outside.

The spool 5 has a small-diameter tip portion 26, a first land portion 27, and a first
The annular groove 28, the second land 29, the second annular groove 30, and the third
Land portions 31 are sequentially formed. The diameter of the sliding hole 4 between the large-diameter hole 7 and the second annular groove 11 is smaller than that of the other portion by an appropriate amount. Therefore, the first land portion 27 of the spool 5 has a smaller diameter than the other land portions. It has become. That is, a step is formed between the first land portion 27 and the second land portion 29, and there is an area difference between both end surfaces of the first annular groove portion.

In the linear solenoid unit 2, a first solenoid housing 40 made of a magnetic material, which is a cylindrical member having a flange 41 formed on the base end side, is connected to the outer peripheral surface of the first solenoid housing 40 via a conducting wire 51 from an external power control unit. A solenoid 42 through which an exciting current flows is fitted, and a flange portion 41 is fixed to a flange portion (left end surface) at the tip of the spool housing 3. A second solenoid housing 44 made of a cylindrical magnetic body having an inward flange 43 covers the outer periphery of the solenoid 42, and its rim is formed by the flange 41 of the first solenoid housing 40 and the tip of the spool housing 3. It is fixed to the flange.

A non-magnetic valve stem 47 is slidably fitted in the hollow hole of the first solenoid housing 40 and the large-diameter hole portion 7 of the spool housing 3 via the spool 45 and the rolling bearings 46 in the axial direction. A magnetic plunger 48 is attached near the rear end (left end) of the valve stem 47, and the plunger 48 has a small gap in the center opening of the inward flange 43 of the second solenoid housing 44. The front end (right end) becomes a cylindrical front end portion 48a, which faces the yoke portion 40a which is a rear end small diameter portion of the first solenoid housing 40, and can be fitted with an appropriate gap. I have. A communication hole 49 is formed through the plunger 48, and the communication hole 49 is formed.
Contributes to the respiratory action in the reciprocating motion of the plunger 27.

A cover plate 50 is mounted on the outer end surface of the inward flange portion 43 of the second solenoid housing 44 so as to close the hollow hole.
Filled with oil. In the spool valve portion 1, between the outer end surface of the spool 5 and a spring insertion hole formed in the inner end surface of the lid plug 6, a compression coil spring 33 surrounding the rear end small diameter portion 32 is provided.
Is fitted.

Accordingly, the cap 6 is screwed into the adjusted predetermined screwing position, so that the compression coil spring 33 is given an initial spring force of a predetermined preload, and the spool 5 is compressed. It is biased and displaced by the initial spring force of the preload of the coil spring 33, and its tip is always in contact with the right end of the valve rod 47,
As a result, the tip (left end) of the valve stem 47 is biased and displaced toward the cover plate 50.

The space between the first annular groove 9 and the second annular groove 11, the space between the second annular groove 11 and the third annular groove 13, and the space between the fifth annular groove 17 and the large-diameter hole 19 of the spool housing 3, respectively. The first land portion 27, the second land portion 29, and the third land portion 31 of the spool 5 are always shut off.

The operation of the above-described pressure control electromagnetic spool valve will be described. The upper half of the spool 5 and the valve rod 47 in FIG. 1 shows a state in which the solenoid 42 is not excited, and the lower half shows a state in which an excitation current by a control signal is applied to the solenoid 42 via the conductor 51. Show. Therefore, when the solenoid 42 is not excited, the tip of the valve rod 47 is brought into contact with the cover plate 50, and the right end face of the plunger 48 is appropriately spaced from the yoke portion 40a of the first solenoid housing 40. Are facing each other.

When the solenoid 42 is not excited, the compression coil spring adjusted and set by adjusting the screwing of the cap 6
33 initial spring force Fs ₀ (= Kx ₀ ) acts on the spool 5,
The spool 5 moves to the left in FIG. 1 and is at the leftmost position where the tip of the valve rod 47 of the linear solenoid portion 2 protrudes until it comes into contact with the cover plate 50. The output passage 24, that is, the fourth annular groove 15 is The third land portion 31 communicates with the third annular groove 13, that is, the supply passage 23 at the maximum opening degree narrowed by the second land portion 29, and the fifth land portion 31
It is shut off from the annular groove 17, that is, the drain passage 25.

Accordingly, the pressure oil supplied from the pump P to the supply passage 27 passes through the third annular groove 13, the second annular groove 30, and the fourth annular groove 15 to the output passage 24, that is, to the hydraulic operating portion A. Is supplied and does not flow out to the oil tank T through the drain passage 25,
The hydraulic pressure of the hydraulic operating section A increases and reaches the maximum pressure.

When a controlled exciting current from an external control device is applied to the solenoid 42 via the conductor 51, a magnetic field line circuit constituted by the first solenoid housing 40, the second solenoid housing 44 and the plunger 48 is constructed. And an attractive force Fm corresponding to the magnitude of the exciting current.
Works between the yoke 40a and the plunger 48, and the valve stem 47
The spool 5 is pressed to compress the compression coil spring 33.

As a result, the spool 5 moves rightward in FIG.
The spring is displaced until the spring force Fs (= k (x ₀ + x)) of the compression coil spring 33 and the attraction force Fm of a magnitude corresponding to the magnitude of the exciting current are balanced, that is, x. In response to the increase of the exciting current, the communication between the output passage 24, that is, the fourth annular groove 15 and the third annular groove 13, that is, the supply passage 23, is gradually narrowed by the second land portion 29, and the output passage 24, that is, Fourth annular groove 15 and fifth
The communication with the annular groove 17, that is, the drain passage 25,
The output passage 24 is gradually opened by 31. Finally, the output passage 24 is cut off from the supply passage 23 and communicates with the drain passage 25 at the maximum opening.

In this case, the pressure oil supplied to the hydraulic operating section A is supplied to the fourth annular groove 15 in the operating range of the control by the exciting current.
From the feedback control pressure groove 21, the orifice 22 and the second
The hydraulic pressure p · ΔA, which is also supplied to the first annular groove portion 28 through the annular groove 11 and is obtained by multiplying the difference ΔA between the end faces of the first annular groove portion 18 by the feedback pressure p, provides the suction force Fm of the solenoid 42.
Work added to.

As a result, in the spool 5, the sum of the suction force Fm by the solenoid 42 and the feedback oil pressure p · ΔA is equal to the spring force Fs of the compression coil spring 33 (= K (x ₀ + x)).
And the supply passage 23, that is, the third annular groove 13
The throttle that communicates with the output passage 24, that is, the fourth annular groove 15, has an opening corresponding to the above-described equilibrium position set by the attraction force Fm of the solenoid 42, that is, the magnitude of the exciting current.

In the above operating range, when the hydraulic pressure of the hydraulic operating section A fluctuates according to the throttle set by the magnitude of the exciting current, the feedback pressure p fluctuates, whereby the spool 5 is displaced, The second land portion 29 has a third annular groove.
The communication relationship between 13 and the fourth annular groove 15, that is, the communication relationship between the supply passage 23 and the output passage 24 is fluctuated or cut off to absorb the fluctuation of the hydraulic pressure and set by the magnitude of the exciting current. Feedback control is performed so as to maintain the output oil pressure.

When the exciting current is at the maximum, the output passage 24 is cut off from the supply passage 23 and communicates with the drain passage 25 at the maximum degree of opening.
The fluid flows out through the fourth annular groove 15, the second annular groove 30, the fifth annular groove 17, and the drain passage 25. In the pressure control electromagnetic spool valve, the inflow and outflow by the respiratory operation of the axially displaced portion in the linear solenoid portion 2 and the respiratory operation of the first land portion 27 of the reciprocating spool 5 are performed by the first annular groove 9, the drain groove 20 and This is performed by the drain passage 25 through the fifth annular groove 17.

The hydraulic operating portion A is connected to the output passage 24, that is, the fifth annular groove adjacent to the fourth annular groove 15 via the second annular groove 30.
17, which is in communication with the drain passage 25, while the linear solenoid portion 2 is furthest from the fifth annular groove 17 through the drain groove 20 from the fifth annular groove 17 communicating with the drain passage 25. The first annular grooves 9 communicate with each other. Accordingly, when the oil from the hydraulic operating portion A flows out and in due to the respiratory operation of the axial displacement portion of the linear solenoid portion 2 and the respiratory operation of the first land portion 27 of the reciprocating spool 5, the linear solenoid portion There is no danger of intrusion into 2.

Moreover, since the drain passage 25 is open at the top surface of the upright wall H of the transmission housing (equipment),
That is, since the opening is provided only at a position above the entire space inside the pressure control electromagnetic spool valve including the drain passage 25, the oil filling the entire space inside the pressure control electromagnetic spool valve including the drain passage 25 is included. Is maintained at the opening of the drain passage 25. Therefore, air does not enter the oil in the pressure control electromagnetic spool valve internal space, which causes hydraulic vibration, that is, air does not enter the space.

The first movement caused by the axial movement of the spool 5 and the valve rod 47
Since the breathing of the space S including the annular groove 9 is performed by the oil in and out of the drain groove 20, the oil from the hydraulic operating portion A does not enter the space S. Further, the breathing in the space U in which the plunger 48 moves axially is performed by the oil in and out of the space S, so that the oil from the hydraulic operating part A is
There is no risk of intrusion into

[0041]

In the electromagnetic spool valve according to the present invention, when the hydraulic oil of the hydraulic device flows out to the drain passage through the output passage spool valve portion, the linear solenoid is operated in accordance with the breathing action by the operation of the linear solenoid portion. The oil inside the part is also higher than the internal space of the linear solenoid part.
The oil flows into and out of the drain oil passage toward the annular groove that communicates with the drain passage that opens to the outside of the valve body, but inside the linear solenoid portion, a drain oil passage formed in the spool valve portion in the axial direction is formed in the annular groove. Since it is away from the hydraulic solenoid, oil from the hydraulically operated device into which the dust passage is mixed into the drain passage does not enter the linear solenoid portion. Accordingly, it is possible to prevent the operation of the linear solenoid unit from being hindered due to the entry of iron powder, dust, and the like into the oil filled in the linear solenoid unit.
Also, the entire space inside the linear solenoid is full.
Oil level is maintained at the drain passage opening,
Air in the oil of the linear solenoid that causes vibration
No contamination or intrusion occurs.

When the solenoid spool valve is installed at a position in the air above the oil level of the oil tank, the opening of the drain passage is located above the highest part of the solenoid spool valve. -Air does not enter the linear solenoid even if the oil level is slightly reduced due to expansion or leakage from other places. Therefore, the vibration absorbing action by the oil in the operation of the electromagnetic spool valve is not hindered by the air mixed into the oil.

[Brief description of the drawings]

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

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

FIG. 3 is a sectional view taken along line III-III in FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Spool valve part 2 Linear solenoid part 3 Spool housing 4 Sliding hole 5 Spool 6 Lid 7 Large-diameter hole part 9 1st annular groove 11 2nd annular groove 13 3rd annular groove 15 4th annular groove 17 5th annular groove 9a , 13a, 15a, 15b, 17a, 17b Partial arc chamber 19 Large diameter hole 20 Drain groove 21 Feedback control pressure groove 22 Orifice 23 Supply passage 24 Output passage 25 Drain passage 26 Tip small diameter portion 27 First land 28 First ring Groove part 29 Second land part 30 Second annular groove part 31 Third land part 32 Rear end small diameter part 33 Compression coil spring 41 Flange part 40 First solenoid housing 40a Yoke part 42 Solenoid 43 Inward flange part 44 Second solenoid housing 45 Sleeve 46 Rolling bearing 47 Valve stem 48 Plunger 48a Cylindrical tip 49 Communication hole 50 Cover plate 51 Conductor C Transmission case H Upright wall h Hollow horizontal hole N Opening A Hydraulic actuator P Amp T oil tank

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-2-129483 (JP, A) JP-A-4-175587 (JP, A) JP-A-3-32268 (JP, U) JP-A-3-129 117178 (JP, U) Japanese Utility Model Application Hei 5-30663 (JP, U) Japanese Utility Model Application Utility Model 4-117967 (JP, U) Japanese Utility Model Application Utility Model 4-80904 (JP, U) (58) Field surveyed (Int. ⁶ , DB name) F16K 31/00-31/124 F16K 11/00-11/07 F16K 3/00-3/36

Claims (2)

(57) [Scope of request for utility model registration] 1. A valve body having a pressure oil supply passage and a sliding hole having respective annular grooves communicating with a drain passage and an output passage.
And a spool is slidably inserted in the sliding hole in the axial direction.
The annular groove communicating with the output passage by the axial displacement of the spool is selectively variably throttled to the annular groove communicating with the pressure oil supply passage or the annular groove communicating with the drain passage. To form a land on the spool,
The spool is displaced by being connected to the valve body and
A linear solenoid filled with oil is provided between
Pass the valve valve above the internal space of the linear solenoid
An annular groove that opens to the outside of the body and communicates with the drain passage
Drain oil passage communicating with the space in the solenoid housing is valved.
An electromagnetic spool valve formed on the main body . 2. The electromagnetic solenoid according to claim 1, wherein the solenoid valve is installed at a position in the air above the oil level of the oil tank, and the opening of the drain passage in the mounting portion of the valve body is located above the highest part of the electromagnetic spool valve. Spool valve.