JPH0692212A - Fluid pressure control device - Google Patents

Abstract

PURPOSE:To reduce the size of a device by providing a plunger and a spool with a first pressure receiving surface where the fluid pressure of an output port is applied toward the fixed core side and with a second pressure receiving surface where the fluid pressure is applied to the opposite side to the fixed core, which has a wider pressure receiving area than the first pressure receiving surface. CONSTITUTION:When a plunger 13, that is, a spool 161 is sucked to the fixed core 12 side, liquid pressure is applied from an output port 291 to a braking device 5. The reaction force produced by fluid pressure of the output port 291 according to a pressure receiving area difference between a first pressure receiving surface 301 and a second pressure receiving surface 311 is applied to the spool 161. Accordingly, the electromagnetic force generated by a linear solenoid 61 is held down comparatively to the minimum. A second guide cylinder 10 is integrated with a valve housing 151 and the plunger 13 is integrated with the spool 161, so that the linear solenoid 61 and a control valve 71 can be made in a compact size. As a release port 231 is provided on the fixed core 12, the length of the valve housing 151 is reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to coaxial first and second guide cylinders with a non-magnetic portion interposed in the middle, a coil surrounding the first and second guide cylinders, and a first guide. And a plunger housed in the first and second guide cylinders that can move toward and away from the fixed core provided on the cylinder side, and the axial electromagnetic force corresponding to the amount of electricity input to the coil is applied to the plunger. First and second linear solenoids for
A spool, which is interlocked with and connected to the plunger, slides in a sliding hole of the valve housing that is coaxial with the guide cylinder to enable switching between communication and cutoff between the fluid pressure device and the fluid pressure supply source and the reservoir. And a control valve which is movably fitted to the control valve.

[0002]

2. Description of the Related Art Conventionally, such an apparatus is disclosed in, for example, Japanese Patent Laid-Open No.
It is known from JP-A-136963.

[0003]

However, in the above-mentioned prior art, the housing of the linear solenoid is coupled to the valve housing with the fixed core on the valve housing side, and the plunger movably penetrates through the fixed core and the control valve. And the spool in the above are coaxially linked and connected to each other as a separate body, and the valve housing is provided with a port leading to a fluid pressure device, a port leading to a fluid pressure supply source, and a port leading to a reservoir. There is. Therefore, the axial length of the fluid pressure control device must be relatively long. Moreover, since the fluid pressure of the fluid pressure device acts on the entire surface of the cross section of the spool to thereby generate a reaction force that opposes the force applied from the linear solenoid to the spool, the reaction force is relatively small. Since the electromagnetic force generated by the linear solenoid is relatively large, the size of the linear solenoid is inevitably increased, which also increases the size of the fluid pressure control device.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a fluid pressure control device which can be miniaturized.

[0005]

In order to achieve the above object, according to the present invention, the second guide cylinder portion is integrally provided in the valve housing with its inner surface being coaxially connected to the sliding hole. ,
A plunger penetrating the second guide cylinder portion fluid-tightly and movably is integrally connected to the spool, and the valve housing is
An input port leading to a fluid pressure source and one of an output port leading to a fluid pressure device and a release port leading to a reservoir are provided, and the fixed core is provided with the other of the output port and the release port, and a plunger and a spool. Include a first pressure receiving surface on which the fluid pressure of the output port acts toward the fixed core side, and a fluid pressure of the output port acting on the opposite side to the fixed core, and a pressure receiving surface more than the first pressure receiving surface. A second pressure receiving surface having a large area is provided.

[0006]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a first embodiment of the present invention. A reaction force generating means 3 is connected to a brake pedal 1 via a pedal force sensor 2 for detecting a braking operation amount. The fluid pressure control device 4 configured according to the present invention determines the braking fluid pressure according to the braking operation amount detected by the pedal effort sensor 2.
₁ to the brake device 5 as a fluid pressure device.

Fluid pressure control device 4₁Is a linear solenoid
6₁And control valve 7₁It consists of So Rini
As solenoid 6₁Means that the void 8 as the non-magnetic portion is formed in the middle portion.
Coaxial first and second guide cylinder portions 9 and 10 interposed between
And a coil surrounding the first and second guide cylinders 9 and 10.
11 to the fixed core 12 provided on the side of the first guide tube portion 9
The first and second guide tube portions 9, which can be moved toward and away from each other,
And a plunger 13 housed in the carp 10.
Plunge the electromagnetic force in the axial direction according to the amount of electricity input to
It is given to the user 13. Control valve 7₁Is the first
And a sliding hole 14 which is coaxial with the second guide tube portions 9 and 10.₁To
Valve housing 15₁And sliding hole 14 ₁Slidable on
Spool 16 fitted to₁And the spool 16
₁Is a brake device 5, a fluid pressure source 17 and a reservoir.
It is possible to switch between communication and disconnection with the server 18.

The second guide cylinder portion 10 has a valve housing 15₁To
It is provided integrally. In addition, the second guide cylinder portion 1 is provided through the gap 8.
At one end of the first guide tube portion 9 that is coaxially opposed to 0, a fixed coil is provided.
A 12 is provided integrally with the fixed core 12.
The collar portion 19 that projects outward in the radial direction is integrally provided,
At the outer edge of the collar portion 19, the first and second guide tube portions 9, 1 are provided.
An outer cylinder 20 that is coaxial with 0 is continuously provided. Thus, the outer cylinder 20
But the valve housing 15 ₁Are integrally connected to. Moreover,
The first and second guide cylinders 9 and 10 are made of a non-magnetic material.
Which are fitted to both ends of the connecting cylinder 21.
The coil 11 surrounding the collar 19 and the valve housing 1
5₁Sandwiched between.

A first release chamber 22 is formed between the fixed core 12 and the plunger 13.
The release chamber 22 is the release port 2 provided in the fixed core 12.
It communicates with the reservoir 18 via a 3 _1. Moreover, the return spring 24 that exerts a spring force in the direction of separating the plunger 13 from the fixed core 12 is housed in the first release chamber 22.

Control valve 7₁At the valve housing 15₁
Slide hole 14 provided in₁Is the linear solenoid 6₁To
Is formed to have a larger diameter than the inner surface of the second guide tube portion 10
The sliding hole 14₁One end of the second guide tube portion 10
It is coaxially connected to the inner surface of the through a step. Thus, the sliding hole 14
₁Spool 16 slidably fitted to₁At one end of
The second guide tube portion 10 is fluid-tightly and movably supported.
The plunger 13 is integrally connected,
Ja 13 and spool 16₁Are stepped from each other
It will be installed in series. Also, the sliding hole 14₂The other end of the valve
Housing 15 ₁Closed by a plug 25 that is screwed into
The plug 25 and the spool 16₁Formed between the other ends of
The second release chamber 26 is a valve housing 15₁Was drilled in
It communicates with the first release chamber 22 via the communication passage 27.

An annular output chamber 28 is formed between the outer surface of the continuous portion of the spool 16 ₁ and the plunger 13, and the inner surface of the second guide cylinder 10 and the inner surface of the sliding hole 14 ₁ .
The output chamber 28 communicates with the brake device 5 through an output port 29 ₁ formed in the valve housing 15 ₁ .
Moreover, the fluid pressure in the output chamber 28, that is, the output port 29 ₁ , is applied to the plunger 13 and the spool 16 ₁ by the fixed core 1.
The annular first pressure receiving surface 30 ₁ acting toward the second side and the fluid pressure of the output chamber 28, that is, the output port 29 ₁ acts toward the side opposite to the fixed core 12 and the first pressure receiving surface 30 ₁ Also, an annular second pressure receiving surface 31 ₁ having a wide pressure receiving area is provided so as to face each other.

The fluid pressure source 17 includes a pump 32 for pumping fluid pressure from the reservoir 18, an accumulator 33 connected to the discharge port of the pump 32, and a pressure switch 34 for controlling the operation of the pump 32. The fluid pressure supply source 17 is provided and is connected to an input port 35 ₁ provided in the valve housing 15 ₁ .

Sliding hole 14₁Input port 35 on the inside
₁To the annular groove 36 communicating with the communication passage 27, and the first release
Release port 23 through chamber 22₁With an annular groove 37 leading to
Are provided at intervals in the axial direction, and the spool 1
6₁An annular recess 38 communicating with the output chamber 28 is provided on the outer surface of the
To be Then spool 16₁Is a linear solenoid 6 ₁
When moved to the side, the annular recess 38 is inserted into the annular groove 36.
The spool 16₁Is a linear solenoid 6₁Keep away from
The annular recess 38 is inserted into the annular groove 37.
As shown in FIG.
The pair position is set.

Further, the detection signal of the pedal effort sensor 2 is inputted to the control means 39, and the control means 39 energizes the coil 11 with an electric quantity corresponding to the braking operation quantity detected by the pedal effort sensor 2. .

The operation of the first embodiment will now be described. When the coil 11 is excited, the plunger 1
3, that is, the spool 16 ₁ is sucked toward the fixed core 12 side, and the annular groove 37 communicates with the annular recess 38, whereby the fluid pressure from the fluid pressure supply source 17 acts on the brake device 5 from the output port 29 _1. . At this time, the linear solenoid ₆₁ is intended to provide an axial electromagnetic force according to the input electrical quantity to the plunger 13 i.e. the spool 16 _1, the spool 16 _1, the first pressure receiving surface 30 ₁ and the second
The reaction force due to the fluid pressure of the output chamber 28, that is, the output port 29 ₁ according to the pressure receiving area difference of the pressure receiving surface 31 ₁ acts against the electromagnetic force of the linear solenoid 6 ₁ . Therefore, the fluid pressure in the reaction force chamber 29, that is, the output port 29 ₁ , is
It corresponds to the amount of electricity input to 1.

[0017] In such a fluid pressure control apparatus 4 _1,
The second guide cylinder portion 10 of the linear solenoid 6 ₁ has the control valve 7
Provided integrally on _one of the valve housing 15 _1, the plunger 1 which passes through the second guide tube portion 10 to freely close and transfer fluid
Since 3 is integrally coupled to the spool 16 ₁ , the linear solenoid 6 ₁ and the control valve 7 ₁ can be compactly configured.

[0018] The valve housing 15 _1, the input port 35 ₁ and output port 29 ₁ is provided, fixed core 1
Since the release port 23 ₁ is provided in 2,
The axial length of the valve housing 15 ₁ can be shortened as compared with the conventional one in which three ports are provided in the valve housing.

Further, the plunger 13 and the spool 1
6₁Output port 29₁Fluid pressure is fixed core 12 side
First pressure receiving surface 30 acting toward₁And output port 29
₁Fluid pressure acts toward the side opposite to the fixed core 12
And the first pressure receiving surface 30 ₁With a wider pressure receiving area than
2 Pressure receiving surface 31₁And are provided, the linear solenoid
6₁The reaction force against the electromagnetic force of the first pressure receiving surface 30₁And
And the second pressure receiving surface 31₁Output port 29 to the pressure receiving area difference of₁of
Can be relatively small obtained by multiplying the fluid pressure
Yes, therefore linear solenoid 6₁Should be generated in
Since it is possible to keep the magnetic force relatively small,
As solenoid 6₁Can be miniaturized.

In this way, the linear solenoid 6 ₁ and the control valve 7 ₁ are constructed compactly, the axial length of the valve housing 15 ₁ is shortened, and the linear solenoid 6 ₁ is further miniaturized. makes it possible to reduce the size of the fluid pressure control apparatus 4 _1.

FIG. 2 shows a second embodiment of the present invention, in which parts corresponding to those in the first embodiment are designated by the same reference numerals.

The fluid pressure controller 4 ₂ comprises a linear solenoid 6 ₂ and a control valve 7 ₂ . Thus, the second guide cylinder portion 10 of the linear solenoid 6 ₂ is provided integrally with the valve housing 15 ₂ of the control valve 7 ₂ . Also the first
An output chamber 40 is formed between the fixed core 12 and the plunger 13 provided at one end of the guide tube portion 9,
The output chamber 40 communicates with the brake device 5 via an output port 29 ₂ provided in the fixed core 12. Moreover, the output chamber 40 accommodates the return spring 24 that exerts a spring force in the direction of separating the plunger 13 from the fixed core 12.

In the control valve 7 ₂ , the valve housing 15 ₂
Sliding hole 14 ₂ provided is intended to be formed smaller in diameter than the inner surface of the second guide tube portion 10 in the linear solenoid 6 _2, one end of the slide hole 14 _2, the second guide tube portion 10
It is coaxially connected to the inner surface of the through a step. Thus, the sliding hole 14
_At one end of the spool 16 ₂ slidably fitted in ₂ ,
A plunger 13 movably supported in a fluid-tight manner by the second guide cylinder portion 10 is integrally coupled. In addition, the sliding hole 14 ₂
The other end is closed by a plug 25 screwed into the valve housing 15 _2, reaction chamber 41 formed between the other end of the plug body 25 and the spool 16 _2, coaxial to the plunger 13 and the spool 16 ₂ It is communicated with the output chamber 40 through a communication passage 42 formed in the.

A first pressure receiving surface 30 ₂ for receiving the fluid pressure of the reaction chamber 41, that is, the fluid pressure of the output chamber 40 is formed at the end of the spool 16 ₂ facing the reaction chamber 41, and the plunger facing the output chamber 40 is formed. A second pressure receiving surface 31 ₂ that receives the fluid pressure of the output chamber 40 is formed at the end of 13. Moreover, the plunger 1
3 has a larger diameter than the spool 16 ₂ and has a second pressure receiving surface 31
₂ of the pressure receiving area larger than the pressure receiving area of the first pressure receiving surface 30 _2.

The fluid pressure source 17 is a valve housing 15 ₂
Connected to the input port 35 ₂ provided on the
8 is a release port 23 provided in the valve housing 15 _2.
Connected to ₂ . Thus, on the inner surface of the sliding hole 14 ₂ , the annular groove 43 communicating with the input port 35 ₂ and the release port 23 _{2 are formed.}
An annular groove 45 communicating with the output chamber 40 is provided on the outer surface of the spool 16 _{2 so} as to communicate with the output chamber 40 via the communication passage 42. When the spool 16 ₂ moves to the linear solenoid 6 ₂ side, the annular recess 45 communicates with the annular groove 43, and the spool 1
6 ₂ annular recess 45 when moved to the side away from the linear solenoid 6 ₂ so as to communicate with the annular groove 44, the relative position of the annular groove 43, 44 and an annular recess 45 is set.

Also in the second embodiment, as in the first embodiment, the linear solenoid 6 ₂ and the control valve 7 ₂ are compactly integrated, and the axial length of the valve housing 15 ₂ is shortened. Further, by further downsizing the linear solenoid 6 ₂ , it is possible to downsize the fluid pressure control device 4 ₂ .

Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above embodiments, and various small design changes can be made without departing from the present invention described in the claims. It is possible to

[0028]

As described above, according to the present invention, the second guide cylinder portion is integrally provided in the valve housing with its inner surface being coaxially connected to the sliding hole, and the second guide cylinder portion is fluidized. A tightly and movably penetrating plunger is integrally coupled to the spool and the valve housing is provided with an input port leading to a fluid pressure source and one of an output port leading to fluid pressure equipment and a release port leading to a reservoir. The fixed core is provided with the other of the output port and the release port, and the plunger and the spool have a first pressure receiving surface on which the fluid pressure of the output port acts toward the fixed core and a fluid of the output port. Since the pressure acts toward the side opposite to the fixed core and the second pressure receiving surface having a wider pressure receiving area than the first pressure receiving surface is provided, the linear solenoid and the control valve can be compactly assembled. Configured, also shortens the axial length of the valve housing, can be further miniaturized linear solenoid, it becomes possible to reduce the size of the fluid pressure control device as a whole.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of a first embodiment.

FIG. 2 is a vertical sectional view of a second embodiment.

[Explanation of symbols]

4 ₁ , 4 ₂ Fluid Pressure Control Device 5 Brake Device as Fluid Pressure Device 6 ₁ , 6 ₂ Linear Solenoid 7 ₁ , 7 ₂ Control Valve 8 Void as Non-Magnetic Part 9 First Guide Cylindrical Section 10 Second Guide Cylindrical Section 11 coil 12 fixed core 13 plunger 14 ₁ and 14 ₂ sliding hole 15 ₁ and 15 ₂ valve housing 16 ₁ and 16 ₂ spool 17 fluid pressure supply source 18 reservoir 23 ₁ and 23 ₂ release port 29 ₁ and 29 ₂ output port 30 ₁ , 30 ₂ 1st pressure receiving surface 31 ₁ , 31 ₂ 2nd pressure receiving surface 35 ₁ , 35 ₂ Input port

[Procedure amendment]

[Submission date] December 25, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0011

[Correction method] Change

[Correction content]

Control valve 7₁At the valve housing 15₁
Slide hole 14 provided in₁Is the linear solenoid 6₁To
Is formed to have a larger diameter than the inner surface of the second guide tube portion 10
The sliding hole 14₁One end of the second guide tube portion 10
It is coaxially connected to the inner surface of the through a step. Thus, the sliding hole 14
₁Spool 16 slidably fitted to₁At one end of
The second guide tube portion 10 is fluid-tightly and movably supported.
The plunger 13 is integrally connected,
Ja 13 and spool 16₁Are stepped from each other
It will be installed in series. Also, the sliding hole 14 ₁ The other end of the valve
Housing 15 ₁Closed by a plug 25 that is screwed into
The plug 25 and the spool 16₁Formed between the other ends of
The second release chamber 26 is a valve housing 15₁Was drilled in
It communicates with the first release chamber 22 via the communication passage 27.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0016

[Correction method] Change

[Correction content]

The operation of the first embodiment will now be described. When the coil 11 is excited, the plunger 1
3, that is, the spool 16 ₁ is sucked toward the fixed core 12 side, and the annular groove 37 communicates with the annular recess 38, whereby the fluid pressure from the fluid pressure supply source 17 acts on the brake device 5 from the output port 29 _1. . At this time, the linear solenoid ₆₁ is intended to provide an axial electromagnetic force according to the input electrical quantity to the plunger 13 i.e. the spool 16 _1, the spool 16 _1, the first pressure receiving surface 30 ₁ and the second
The reaction force due to the fluid pressure of the output chamber 28, that is, the output port 29 ₁ according to the pressure receiving area difference of the pressure receiving surface 31 ₁ acts against the electromagnetic force of the linear solenoid 6 ₁ . Therefore output
The fluid pressure in the chamber 28, that is, the output port 29 ₁ , is
It corresponds to the amount of electricity input to 1.

Claims (1)

[Claims] 1. A non-magnetic part (8) is interposed in the middle part of the same.
The first and second guide tube portions (9, 10) of the shaft,
And a coil (11) surrounding the second guide cylinder (9, 10)
And a fixed core (1 provided on the side of the first guide cylinder (9)
First and second guide cylinders that can be moved toward and away from 2)
The plunger (13) housed in the part (9, 10)
Axial direction according to the amount of electricity input to the coil (11)
A linear solenoid that applies an electromagnetic force to the plunger (13).
Nooid (6₁, 6₂) And; first and second guide cylinders
A valve housing (15) coaxial with (9, 10)₁, 15
₂) Sliding hole (14₁, 14₂) To the plunger
A spool (16) that is linked and linked to (13)₁, 1
6₂) Is a fluid pressure device (5) and a fluid pressure supply source (17)
It is possible to switch between communication and disconnection with the reservoir (18)
Control valve (7₁, 7₂)
And a fluid pressure control device including;
0) has a sliding hole (14₁, 14₂) Coaxially
Valve housing (15₁, 15₂) Integrated with
The second guide cylinder part (10) is fluid-tight and movable.
Plunger (13) that penetrates through the spool (16₁, 1
6₂) And a valve housing (15₁, 15
₂) Is an input port leading to a fluid pressure supply (17)
(35₁, 35₂) And the output leading to the fluid pressure device (5)
Port (29 ₁, 29₂) And reservoir (18)
Open port (23₁, 23₂) One side (29₁，
23₂) And the fixed core (12)
Power port (29₁, 29₂) And release port (2
Three₁, 23₂) The other (23₁, 29₂) Is provided,
Plunger (13) and spool (16₁, 16₂)
The output port (29₁, 29₂) Fluid pressure is
The first pressure receiving surface (3 that acts toward the constant core (12) side
0₁, 30₂) And the output port (29₁, 29₂)
Body pressure acts toward the side opposite to the fixed core (12)
And the first pressure receiving surface (30₁, 30₂) Than the pressure receiving surface
The second pressure receiving surface (31₁, 31₂) And
A fluid pressure control device characterized by the above.