KR100764491B1 - A bleed type variable force solenoid valve - Google Patents

Abstract

The present invention forms a side of the piston ring for the valve seat for maintaining the balance of the force between the electromagnetic force and the spring force of the drive unit against the hydraulic pressure of the valve unit by the fluid force reducing action to prevent the valve malfunction in the high temperature region in advance. Provides a bleed-type variable force solenoid valve.

Bleed Type, Variable Force Solenoid Valve, VFS, VBS, Conical, Round, Fluid

Description

Bleed Type Variable Force Solenoid Valve {A BLEED TYPE VARIABLE FORCE SOLENOID VALVE}

1 is a cross-sectional configuration of a bleed-type variable force solenoid valve according to the prior art.

FIG. 2 is an enlarged cross-sectional view of the main part of FIG. 1. FIG.

3 is a control pressure characteristic graph of a bleed-type variable force solenoid valve for explaining a problem of the prior art.

Figure 4 is a cross-sectional configuration of the bleed-type variable force solenoid valve according to an embodiment of the present invention.

5 is an enlarged cross-sectional view illustrating main parts of a bleed-type variable force solenoid valve according to an exemplary embodiment of the present invention.

6 is a cross-sectional view illustrating a configuration of a piston ring according to another embodiment of the present invention.

The present invention relates to a bleed type variable force solenoid valve, and more particularly, to a bleed type variable force solenoid valve which is applied to a valve body of a hydraulic control system such as an automatic transmission or a continuously variable transmission of a vehicle to variably control a flow path and its hydraulic pressure. (variable force solenoid valve).

In general, the main types of solenoid valves used in automatic transmission or continuously variable transmission include on / off type, pulse width modulation (PWM) type and variable force solenoid valve (VFS).

Normally, solenoid valves of on / off type and PWM type are controlled by on / off signals from the shift control unit, while the variable force solenoid valve outputs a duty control signal for driving the solenoid valve in the shift control unit. The driving unit also drives the solenoid valve by the amount of current proportional to the output duty, and generally refers to a three-way spool type proportional control solenoid valve, but recently, as shown in FIG. 1, a closed end (CE) The bleed type variable force solenoid valve is actively being developed as a new solenoid valve to be used for the next generation 6-speed automatic transmission by solving the flow consumption and residual pressure problems of the existing bleed type valve.

The configuration of the bleed-type variable force solenoid valve, as shown in Figure 1, is basically divided into a drive unit 1 and a valve unit 3, the drive unit 1 is a coil ( 13 is provided in a state of being wound around the bobbin 15, and inside the bobbin 15, an armature 17 and an armature spindle 19 operated by the electromagnetic force of the coil 13 are attached to the adjusting screw 21. It is provided in the axial direction to receive the elastic force of the adjustment spring 23 mounted by.

In the rear of the driving unit 1, a contact guide 25 having a contact fork 27 is provided.

The valve part 3 has a flange 31 having a supply port Ps through which a pump pressure is supplied, and a control port Pc and a discharge port Pe for supplying a control pressure to a flow path of a valve body (not shown). ) Is configured in front of the housing 11 of the drive unit 1 via the magnetic core 33.

The supply port Ps, the control port Pc, and the discharge port Pe are connected to each other therein along the center line SL of the flange 31 and at the same time on the center line SL of the flange 31. A valve needle 37, one end of which is supported by the amateur spindle 19 and guided in the axial direction by a needle bearing 35 configured in the magnetic core 33, is installed.

In addition, inside the control port Pc on the center line SL of the flange 31, as shown in FIG. 2, a check ball 39 is provided in contact control with the other end of the valve needle 37. The valve seat 41 is configured to penetrate the valve needle 37 on an inner side surface of the flange 31 corresponding to the discharge port Pe by the valve needle 37. The piston seat corresponds to the valve seat 41. A ring 43 is fitted to the valve needle 37.

Therefore, in the bleed-type variable force solenoid valve of the above-described configuration, as shown in FIG. 2, the hydraulic pressure in the line P supplied from the pump is controlled according to a control signal from a shift control unit (not shown). In proportion to the electromagnetic force and the spring force acting on the spindle 19, a fine gap adjustment operation of the piston ring 43 relative to the valve seat 41 maintains a pressure balance.

However, in the conventional bleed-type variable force solenoid valve as described above, a factor that is not considered in the pressure balancing operation of the piston ring 43 relative to the valve seat 41 is the fluid force in the high temperature region. The change in the flow force due to the physical force causes a malfunction of the valve by breaking the equilibrium of the force in response to the electromagnetic force and the spring force of the opposite drive unit 1 together with the hydraulic pressure in the valve unit 3.

That is, the fluid force is divided into a shear stress component acting in a tangential direction to the working surface and a pressure component acting in a direction perpendicular to the working surface. Shear stress is an ideal fluid neglecting viscosity as a frictional force due to the viscosity of the fluid. Although it does not appear under the assumption of, the most significant factor of the change in the fluid force in the high temperature region, in the case of non-ideal fluid, may be the change of frictional force due to the change in viscosity of the fluid.

In FIG. 3, the balance of the force between the electromagnetic force and the spring force of the drive unit 1 with respect to the hydraulic pressure in the valve unit 3 is broken by the influence of the change in the fluid force in the high temperature region, thereby causing the piston ring to the valve seat 41. Since the fine gap adjustment operation of (43) is not performed, it causes a problem of forming an open section in which the control pressure is detected in the section S reduced by about 0.5 to 2.0 kgf / cm 2 relative to the normal pressure.

Therefore, the cause of this problem is due to the fluid force in the high temperature region of the fluid, the present invention is to change the structure of the piston ring directly affected by the fluid force to reduce the influence of the fluid force, the valve seat It is conceived that the fine gap adjustment operation of the piston ring can be normally performed, and an object of the present invention is to provide a piston ring for a valve seat that maintains an equilibrium force between the electromagnetic force and the spring force of the drive unit against the hydraulic pressure of the valve unit. It is to provide a bleed-type variable force solenoid valve to form a side of the fluid force reducing action to prevent the valve malfunction in the high temperature region in advance.

The bleed-type variable force solenoid valve according to the characteristics of the present invention for solving the above problems is a drive unit provided in the housing in the axial direction so that the armature and the amateur spindle operating by the electromagnetic force of the coil is provided with an elastic force of the adjustment spring; A flange forming a supply port Ps, a control port Pc, and a discharge port Pe, which are connected to each other, is formed in front of the driving unit, and a valve needle having one end supported by the amateur spindle inside the flange; A check ball configured in the control port Pc to be in contact with and controlled to the other end of the valve needle, a valve seat configured to pass through the valve needle on an inner surface corresponding to the discharge port Pe, and the valve seat In the bleed-type variable force solenoid valve comprising a valve portion configured to be fitted with the piston ring corresponding to the valve needle,

The piston ring is formed by forming a fluid force reducing action portion on its front surface facing the valve seat.

The fluid force reducing action is characterized in that the front surface of the piston ring, consisting of a conical surface formed to form a circumferential circumference at a predetermined inclination angle to one side of the outer peripheral surface of the valve needle.

The conical surface is formed via a horizontal plane between the front surface of the piston ring.

The diameter of the horizontal plane is characterized in that it is formed smaller than the inner diameter of the valve seat.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can practice the present invention.

Figure 4 is a cross-sectional configuration of the bleed-type variable force solenoid valve according to an embodiment of the present invention, Figure 5 is an enlarged cross-sectional view of the main portion of the bleed-type variable force solenoid valve according to an embodiment of the present invention.

In the description of the configuration of the present invention, however, the same components as those in the prior art will be described with the same reference numerals.

As shown in FIG. 4, the bleed-type variable force solenoid valve according to the exemplary embodiment of the present invention is basically divided into a driving unit 1 and a valve unit 3, and the driving unit 1 of the housing 11 is formed. A coil 13 is provided inside the bobbin 15 in a state of being wound therein, and an inside of the bobbin 15 includes an armature 17 and an armature spindle 19 operated by an electromagnetic force of the coil 13. It is provided in the axial direction to receive the elastic force of the adjustment spring 23 mounted by (21).

In the rear of the driving unit 1, a contact guide 25 having a contact fork 27 is provided.

The valve part 3 has a flange 31 having a supply port Ps through which a pump pressure is supplied, and a control port Pc and a discharge port Pe for supplying a control pressure to a flow path of a valve body (not shown). ) Is configured in front of the housing 11 of the drive unit 1 via the magnetic core 33.

The supply port Ps, the control port Pc, and the discharge port Pe are connected to each other therein along the center line SL of the flange 31 and at the same time on the center line SL of the flange 31. A valve needle 37, one end of which is supported by the amateur spindle 19 and guided in the axial direction by a needle bearing 35 configured in the magnetic core 33, is installed.

In addition, inside the control port Pc on the center line SL of the flange 31, as shown in FIG. 5, a check ball 39 is provided in contact control with the other end of the valve needle 37. The valve seat 41 is configured to penetrate the valve needle 37 on an inner side surface of the flange 31 corresponding to the discharge port Pe by the valve needle 37. The piston seat corresponds to the valve seat 41. A ring 43 is fitted to the valve needle 37.

Here, the piston ring 43 according to a specific embodiment of the present invention has a technical feature to form a fluid force reducing action on the front surface facing the valve seat 41.

That is, the fluid force reducing action of the piston ring 43, as shown in Figure 6, may be variously configured through four examples divided into A, B, C, D type.

For example, the A-type fluid force reducing action of the piston ring 43 is a conical surface 50 is formed in the circumference of the conical shape at a predetermined inclination angle from the front surface of the piston ring 43 to one side of the outer peripheral surface of the valve needle 37 It is made of a.

In addition, the B-type fluid force reducing action of the piston ring 43 to the conical surface 50 is formed to form a circumferential circumference at a predetermined inclination angle from the front surface of the piston ring 43 to one side of the outer peripheral surface of the valve needle 37 Although made, the conical surface 50 is exemplarily formed through the horizontal surface 51 between the front surface of the piston ring 43.

Here, the diameter of the horizontal surface 51 is preferably formed smaller than the inner diameter of the valve seat 41.

In the example of FIG. 6, the C-type fluid force reducing action portion of the piston ring 43 is rounded so that the side cross-section is rounded around the circumference from the front surface of the piston ring 43 to one side of the outer peripheral surface of the valve needle 37. What is formed by the surface 60 is illustrated.

In addition, the D-type fluid force reducing action portion of the piston ring 43 from the front surface of the piston ring 43 to one side of the outer peripheral surface of the valve needle 37 to the rounded surface 60 so that the side cross-section is rounded around Although forming, the round surface 60 is exemplarily formed through a horizontal surface 61 between the front surface of the piston ring 43.

Of course, the diameter of the horizontal surface 61 is also preferably formed smaller than the inner diameter of the valve seat (41).

Therefore, the operation of the bleed-type variable force solenoid valve of the above-described configuration, as shown in Figure 5, the outer peripheral surface of the valve needle 37 on the front surface of the piston ring 43, which is the type A fluid force reducing action portion Referring to the example in which the conical surface 50 is formed to form a circumferential shape at a predetermined inclination angle to one side, the hydraulic pressure in the line (P) supplied from the pump in accordance with the control signal from the shift control unit (not shown) The pressure balance is maintained by the fine gap adjustment operation of the piston ring 43 with respect to the valve seat 41 in proportion to the electromagnetic force and the spring force acting on the spindle 19.

Of course, in the bleed-type variable force solenoid valve of the above-described configuration, during the pressure balancing operation of the piston ring 43 with respect to the valve seat 41, the fluid force in the high temperature region is equal to the hydraulic pressure in the valve portion 3. Together with the electromagnetic force and the spring force of the opposite side drive unit 1, the fluid force does not directly act on the conical surface 50 or the rounded surface 60, which is the respective fluid force reducing action of the piston ring, and acts at an angle. By minimizing the influence of the stamina, it will not work enough to break the equilibrium state of force, thereby preventing the malfunction of the valve.

Therefore, the bleed-type variable force solenoid valve of the present invention, despite the change in the fluid force in the high temperature region, the fine gap adjustment operation of the piston ring 43 with respect to the valve seat 41 is maintained in all sections, so that the control pressure is increased. You can keep it normally.

As described above, according to the bleed-type variable force solenoid valve according to the embodiment of the present invention, one side of the piston ring for the valve seat to maintain the balance of the force between the electromagnetic force and the spring force of the drive unit against the hydraulic pressure of the valve unit It is formed as a force reducing action part to minimize the influence of the fluid force in the high temperature region by changing the structure of the piston ring so that it is not directly affected by the fluid force in the high temperature region, thereby minimizing the piston ring to the valve seat There is an effect that the gap adjustment operation can be performed normally.

Claims (7)

delete delete A drive unit 1 provided in the housing 11 in the axial direction such that the armature 17 and the armature spindle 19 operated by the electromagnetic force of the coil are provided with the elastic force of the adjustment spring 21; A flange 31 forming a supply port Ps, a control port Pc, and a discharge port Pe, which are connected to each other, is formed in front of the driving unit, and one end of the flange is supported by the amateur spindle. A valve needle 37, a check ball 39 formed inside the control port Pc and controlled to contact the other end of the valve needle, and an inner surface corresponding to the discharge port Pe, In a bleed-type variable force solenoid valve comprising a valve seat 41 through which a needle passes, and a valve portion 3 formed by fitting a piston ring 43 to the valve needle corresponding to the valve seat, The piston ring 43 forms a fluid force reducing action formed of a conical surface 50 forming a circumferential circumference at a predetermined inclination angle from a front surface thereof facing the valve seat 41 to one side of the outer peripheral surface of the valve needle 37. , The conical surface 50 is a bleed-type variable force solenoid valve, characterized in that formed between the front surface of the piston ring (43) via a horizontal plane (51). The method of claim 3, Bleed-type variable force solenoid valve, characterized in that the diameter of the horizontal surface 51 is formed smaller than the inner diameter of the valve seat (41). delete  A drive unit 1 provided in the housing 11 in the axial direction such that the armature 17 and the armature spindle 19 operated by the electromagnetic force of the coil are provided with the elastic force of the adjustment spring 21; A flange 31 forming a supply port Ps, a control port Pc, and a discharge port Pe, which are connected to each other, is formed in front of the driving unit, and one end of the flange is supported by the amateur spindle. A valve needle 37, a check ball 39 formed inside the control port Pc and controlled to contact the other end of the valve needle, and an inner surface corresponding to the discharge port Pe, In a bleed-type variable force solenoid valve comprising a valve seat 41 through which a needle passes, and a valve portion 3 formed by fitting a piston ring 43 to the valve needle corresponding to the valve seat, The piston ring 43 has a fluid force reducing action portion formed as a round surface 60 so that the side cross-section is rounded around the outer surface of the valve needle 37 to one side from the front facing the valve seat 41 Form, The rounded surface (60) is a bleed-type variable force solenoid valve, characterized in that formed between the front surface of the piston ring (43) via a horizontal plane (61). The method of claim 6, Bleed-type variable force solenoid valve, characterized in that the diameter of the horizontal plane 61 is formed smaller than the inner diameter of the valve seat (41).

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