JPH09144928A - Solenoid operating valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lengthen and shorten a shim between a solenoid and a valve main body without removing the solenoid from the valve main body. SOLUTION: A pressure adjusting shim 41 is arranged between a valve main body 12 and a solenoid 1 by which a needle 3 is axially operated. The solenoid 1 is fixed to the valve main body 12 by bolts 14 inserted and passed from the solenoid 1 through the shim 41. The shim 41 is formed in an almost right-angled isosceles triangle in which the conventional square shim is divided into two along a diagonal line so as to correspond to one conventional shim by two divided shims which make a pair. When the shim 41 is lengthened and shortened for adjusting pressure, two bolts out of four bolts 14, which are inserted in bolt passing grooves of divided parts position on one diagonal line of the shim 41, are loosened to an extent that the solenoid 1 may not be removed from the valve main body 12, and two remaining bolts inserted to bolt passing holes positioned on the other diagonal line of the shim 41 are removed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic actuating valve such as an electromagnetic proportional relief valve, an electromagnetic proportional control valve and an electromagnetic switching valve.

[0002]

2. Description of the Related Art FIG. 2A shows an actual example of a conventional electromagnetic proportional relief valve. The structure is such that an electromagnetic proportional solenoid 1 is attached to an upper portion of a valve body 12, a needle 3 is arranged at a tip of a push rod 2 which is axially actuated by the solenoid 1, and a needle 3 is arranged inside the valve body 12 at a tip of the needle 3. The pilot stage seat part 5 of the fitted seat body 4 is arranged.

A main poppet 6 which is axially slidable in a valve body 12 is arranged below the seat body 4, and the main poppet 6 is pressed against a main seat portion 7 by a return spring 8. The main seat portion 7 is located between the inlet port 9 bored in the axial direction of the lower end portion of the valve body 12 and the tank port 10 bored in the radial direction.

An orifice 11 is provided at the center of the main poppet 6. Further, the seat body 4 is pressed and fixed by the adapter 13 screwed into the valve body 12. Adapter 13
Is also a guide for guiding the axial movement of the needle 3.

The solenoid 1 and the valve body 12 are fixed by screwing a bolt 14 fitted from above the solenoid 1 into the valve body 12. At that time, the solenoid 1 and the valve body 12 are fixed.
A shim 15 is sandwiched between 12 and 12, and the operating amount of the needle 3 relative to the operating amount of the push rod 2 is adjusted by increasing or decreasing the shim 15, and the set pressure is adjusted as described later.

Liquid tightness between the solenoid 1 and the valve body 12 is maintained by an O-ring 16 and the upper end of the adapter 13 is locked by a stop ring 17.

A through hole 18a is bored in the adapter 13 and a through hole 18b is bored in the valve body 12, and a space around the needle in the valve T is opened in the tank T through the through holes 18a, 18b. Communicate with the inside. An O-ring 19 is fitted on the outer peripheral surface of the valve body 12 fitted in the tank T to maintain liquid tightness.

The pressure supplied from the inlet port 9 through the orifice 11 to the spring chamber 20 in which the spring 8 is mounted acts on the tip of the needle 3 through the orifice of the seat body 4.

Next, the operating principle of this electromagnetic proportional relief valve will be described.

First, the solenoid 1 presses the needle 3 via the push rod 2 with a thrust force F ₁ proportional to the current value I (ampere).

Now, assume that the push rod 2 pushes the needle 3, and the tip of the needle 3 is pushed against the pilot stage seat portion 5 of the seat body 4. At this time, under the condition that the stroke of the push rod 2 is constant, It is assumed that the solenoid thrust F ₁ and the current value I are in the proportional relationship shown in FIG.

F ₁ = k ₁ · I (1) where k ₁ is a proportional constant.

The pressure receiving area at the tip of the needle 3 seated on the seat portion 5 of the seat body 4 is A _P, and the pressure receiving area upstream and downstream of the orifice 11 of the main poppet 6 are both Am. . Further, the preset load of the return spring 8 is F ₂ .

When the inlet pressure P _IN of the inlet port 9 is lower than F ₁ / A _P , since the seat portion 5 is closed, the inlet pressure P _IN and the pressure in the spring chamber 20 are balanced at the same pressure. Therefore, the main poppet 6 is pressed against the main seat portion 7 by the spring 8, and therefore the inlet port 9
And the tank port 10 are shut off from each other.

Next, the inlet pressure P _IN rises and P _IN = F ₁ /
When he became A _P ...... (2), the needle 3 is pushed upward, the seat portion 5 is opened, the orifice 11 from the inlet port 9, the spring chamber 20, the sheet body 4 orifice and through hole 18a
, 18b, the pilot flow rate Q ₁ flows into the tank T.

Here, assuming that the tank pressure is 0 for convenience, the flow rate Q ₁ is supplied to the orifice 11 built in the main poppet 6.
Flows, a differential pressure ΔP before and after the orifice 11 represented by the following equation (3) is generated.

Q ₁ = k ₂ · A ₃ · (ΔP) ^1/2 (3) where k ₂ is a constant and A ₃ is the opening cross-sectional area of the orifice 11.

Then, when F ₂ ≦ Am · ΔP with respect to the preset load F ₂ of the return spring 8, the main poppet 6 is pushed up, the inlet port 9 and the tank port 10 are electrically connected, and (2 ) The expression is retained. That is, the inlet pressure P _IN is arbitrarily set by the current value I from the equations (1) and (2).

At that time, the stroke and thrust of the push rod 2 at a certain constant current value have a relationship as shown in FIG. 3 (B), and therefore, a predetermined input current as shown in FIG. 3 (C). In order to obtain the relationship between the inlet pressure P _IN and the inlet pressure P _IN, it is necessary to adjust the stroke of the push rod 2 in the axial direction. Therefore, in this relief valve, the shim 15 is mounted on the mating surface between the valve body 12 and the solenoid 1. The inlet pressure P _IN with respect to the input current is adjusted by increasing or decreasing the shim 15.

[0020]

As shown in FIG. 2B, in the conventional electromagnetic proportional relief valve, the shim 15 is formed by a square thin plate, and the solenoid main body is fitted in the central portion thereof. A solenoid fitting hole 15a for drilling holes is drilled, and bolts are installed at four locations around the solenoid fitting hole 15a.
A bolt through hole 15b for inserting 14 is formed.

Each time the pressure is adjusted by increasing or decreasing the thin plate shim 15, the four bolts 14 are removed and the solenoid 1
Need to be removed from the valve body 12, work efficiency is poor, and if residual pressure remains in the relief valve, the solenoid 1
When the oil is removed from the valve body 12, there is a problem in that the internal oil is ejected to the outside and is applied to the operator.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an electromagnetically actuated valve capable of increasing and decreasing the shim without removing the solenoid from the valve body. is there.

[0023]

According to a first aspect of the present invention, a shim is provided between a valve body and a solenoid for axially operating the valve body in the valve body, and the shim is inserted from the solenoid. In an electromagnetically actuated valve in which a solenoid is fixed to the valve body with a bolt, one shim is divided into multiple pieces, and a bolt through hole for inserting a bolt is provided in the divided shim. This is a configuration in which a bolt through groove for inserting a bolt into the portion is provided.

When increasing or decreasing the shim, among the bolts for mounting the solenoid, the bolt inserted in the bolt through groove between the shims is loosened so that the solenoid does not come off from the valve body. Remove the remaining bolts inserted in the bolt through holes.

According to a second aspect of the invention, in the electromagnetically actuated valve according to the first aspect, a square shim is divided into two along a diagonal line, and a bolt through hole is provided at an undivided corner of each shim. A bolt through groove is provided at each of the divided corners.

When the number of shims is increased or decreased, two of the four bolts for mounting the solenoid are inserted between the bolt through grooves of the half-divided portion located on one diagonal line of the shim.
The bolts are loosened so that the solenoid does not come off the valve body, and the remaining two bolts inserted into the bolt through holes located on the other diagonal line of the shim are removed.

According to a third aspect of the present invention, in the electromagnetically actuated valve according to the first or second aspect, the shim between the valve body and the solenoid in the electromagnetic proportional relief valve is divided, and each divided shim is bolted. A through hole and a bolt through groove are provided.

The relative relationship between the input current to the solenoid and the inlet pressure (set pressure) is adjusted by increasing or decreasing the shim.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment in which the present invention is applied to an electromagnetic proportional relief valve will be described below with reference to FIG. The same parts as those of the conventional example shown in FIG. 2 are designated by the same reference numerals, and the description thereof will be omitted.

As shown in FIG. 1A, the adapter 13
On the central axis in the upper part of the needle 3 as a valve body
A needle guide portion 31 is provided which is closely fitted to the outer peripheral portion and guides the vertical movement of the needle 3.

Further, an inner peripheral surface portion 32 for positioning is formed by turning in the lower portion of the adapter 13 concentrically with the needle guide portion 31.

Further, a positioning outer peripheral surface portion which is closely fitted to the positioning inner peripheral surface portion 32 is provided on the outer peripheral portion of the sheet body 4.
33 is turned and formed concentrically with the seat portion 5 at the center.

Then, the outer peripheral portion of the needle 3 is closely fitted in the needle guide portion 31 of the adapter 13 to guide the axial movement, and the positioning inner peripheral surface portion 32 of the adapter 13 and the seat body 4 are guided. The positioning outer peripheral surface portion 33 is closely fitted.

In this way, the degree of coaxiality (error between shaft centers) between the inner diameter of the needle guide portion 31 of the adapter 13 and the inner diameter of the positioning inner peripheral surface portion 32 is kept to a minimum, and the positioning inner peripheral surface portion is minimized. By minimizing the gap between the 32 and the positioning outer peripheral surface portion 33, the coaxiality between the inner diameter of the needle guide portion 31 of the adapter 13 and the seat portion 5 can be sufficiently reduced.

As a result, the seat portion 5 at the tip of the needle
Therefore, it is possible to avoid pressure hunting and pressure rise failure due to a sheet defect due to the needle 3 being unevenly contacted.

Further, as shown in FIG. 1A, a conventional shim 15 is provided between the valve body 12 and the solenoid 1 for axially actuating the needle 3 provided in the valve body 12. A similar pressure adjusting shim 41 is provided, and the solenoid 1 is connected to the valve main body 12 by a bolt 14 inserted from the solenoid 1 into the shim 41.
Fixed to

As shown in FIG. 1 (B), the shim 41 sandwiched between the solenoid 1 and the valve body 12 is an isosceles right triangle formed by dividing a conventional square thin plate into two along a diagonal line. The shims 41a are formed in a shape so that one pair of shims 41a corresponds to one conventional shim.

For this reason, the solenoid fitting hole in the central portion for fitting the solenoid 1 in the conventional shim is a solenoid fitting groove 41b in a half-divided form, and the circumference of the solenoid fitting groove 41b. The bolt through hole of the solenoid mounting bolt 14 located at is a bolt through hole 41c similar to the conventional one at the undivided corner, but at the corner located on the divided diagonal line, it is a half-divided bolt through groove. 41
It is d.

In this way, a bolt through hole 41c for inserting the bolt 14 is provided in each of the divided shims 41a, and a semi-circle for inserting the bolt 14 into the opposite side portion of the divided shim 41a. A shaped bolt through groove 41d is provided.

When the number of the shims 41 is increased or decreased for the above-mentioned pressure adjustment by forming the shims 41 in such a shape, the shim of the four bolts 14 for mounting the solenoid is used.
41 Half-divided bolt through groove located on one diagonal of 41
The two bolts inserted between 41d are loosened so that the solenoid 1 does not come off the valve body 12, and the remaining two bolts inserted in the bolt through holes 41c located on the other diagonal line of the shim 41. Remove.

Then, the shim 41a is inserted or pulled out while the two bolts are inserted into the half-bolt-shaped bolt through groove 41d to increase or decrease the shim 41a in pairs, and then the shim 41a remains in the bolt through hole 41c. The solenoid 1 and the valve body 12 are fixed again by inserting two bolts and tightening all the bolts 14 of the bolt through hole 41c and the bolt through groove 41d at the half-divided portion.

As a result, the shim 41 can be easily attached and detached, the working efficiency is improved as compared with the conventional product, and the solenoid 1 is detached from the valve body 12 by the two bolts 14. Since this can be prevented, the ejection of oil due to the residual pressure in the valve body 12 can be prevented.

In the case of the electromagnetic proportional relief valve according to the embodiment, the relative relationship between the input current to the solenoid 1 and the inlet pressure (relief setting pressure) P _IN at the inlet port 9 is increased or decreased by increasing or decreasing the shim 41. Can be adjusted.

The invention described in claim 1 or 3 is not limited to the form of the divided shim and the number of sheets of one set shown. For example, when the bolts 14 for fixing the solenoid 1 to the valve body 12 are 6 bolts arranged at equal pitches, the shim should be divided into 3 parts at 3 bolt positions located at 120 ° intervals. By forming it, it is only necessary to loosen the three bolts at that position, and it is not necessary to remove it.

Further, the invention described in claim 1 or 2 is not limited to the electromagnetic proportional relief valve of the embodiment, and other electromagnetic proportional control valves as well as on / off actuated type electromagnetic switching valves. Such an electromagnetically actuated valve can also be used when adjusting the relative position of the needle, poppet, spool, or the like with respect to the valve body.

[0046]

According to the invention described in claim 1, when the number of shims is increased or decreased, among the bolts for mounting the solenoid, the bolts inserted in the bolt passing grooves between the shims need only be loosened. Since it is not necessary to remove the solenoid from the valve body each time the shim is increased or decreased, the shim can be adjusted easily, improving work efficiency compared to conventional products and
It is possible to prevent the ejection of oil due to the residual pressure.

According to the invention described in claim 2, it is possible to easily increase or decrease the shim only by loosening the two bolts and removing the two bolts.

According to the third aspect of the present invention, the relative relationship between the input current to the solenoid and the relief setting pressure can be easily adjusted by increasing or decreasing the shim.

[Brief description of the drawings]

FIG. 1A is a sectional view showing an embodiment of an electromagnetic proportional relief valve as an electromagnetically actuated valve according to the present invention, and FIG. 1B is a plan view showing its shim.

FIG. 2A is a sectional view showing a conventional electromagnetic proportional relief valve, and FIG. 2B is a plan view showing its shim.

FIG. 3 (A) is a characteristic diagram showing the relationship between the current value and thrust of the relief valve solenoid, FIG. 3 (B) is a characteristic diagram showing the relationship between push rod stroke and thrust, and FIG. It is a characteristic view which shows the relationship between an electric current and inlet pressure.

[Explanation of symbols]

 1 Solenoid 3 Needle as valve body 12 Valve body 14 Bolt 41 Shim 41c Bolt through hole 41d Bolt through groove

Claims (3)

[Claims] 1. An electromagnetically actuated valve, wherein a shim is provided between a valve body and a solenoid for axially operating a valve body in the valve body, and the solenoid is fixed to the valve body by a bolt through which the shim is inserted. A piece of shim is divided into multiple pieces, and a bolt through hole for inserting a bolt is provided in the divided shim, and a bolt through groove for inserting a bolt is formed on the opposite side between the divided shims. An electromagnetically operated valve characterized by being provided. 2. A square-shaped shim is divided into two along a diagonal line, and a bolt through hole is provided at a non-divided corner of each shim,
The solenoid operated valve according to claim 1, wherein a bolt passage groove is provided at each of the divided corner portions. 3. The electromagnetic proportional relief valve according to claim 1, wherein a shim between the valve body and the solenoid is divided, and each of the divided shims is provided with a bolt through hole and a bolt through groove. Solenoid operated valve.