KR20080103174A - Accumulator for line pressure - Google Patents

Abstract

An accumulator for the line pressure is provided to reduce the spring force of accumulator using the most high pulley pressure of CVT. The accumulator(10) is used for the line pressure pulsation decrease of the CVT(Continuously Variable Transmission). The accumulator for the line pressure reduces the pulsating of the line pressure of CVT of the high pressure by reducing the spring force. The accumulator receives the pressure which is high between the first pulley(31) and the second pulley(32) through the backend in which the spring(11) is mounted. The line pressure of CVT is 4bar ~ 50bar range.

Description

Accumulator for line pressure

1 is a diagram illustrating a high first pulley pressure flow flowing in an accumulator according to an exemplary embodiment of the present invention.

2 is a diagram illustrating a high second pulley pressure flow flowing in an accumulator according to an exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

1: oil pump 3: line regulator valve

10: accumulator 11: spring

21: race control valve 22: secondary valve

30: Arrangement Direction Valve 31: First Pulley

32: second pulley

The present invention relates to an accumulator for line pressure, and more particularly, to an accumulator for line pressure that sends a high pressure to the accumulator by using the highest pulley pressure of the CVT to reduce the spring force required for the accumulator.

In general, line pressure receives the flow rate discharged from the oil pump from the line regulator valve to create a reference pressure required for continuously variable transmission (CVT).

However, this line pressure (Pressure fluctuation) occurs due to the characteristics of the oil pump, the basic way to solve this is to install an accumulator (Accumulator).

Line pressure for the CVT is typically controlled over a high and wide pressure range of 4 bar to 50 bar. However, the design of accumulators operating over this wide pressure control range is practically impossible.

For example, if you design an accumulator running at 50 bar, the spring force on the accumulator is:

F _spring = A _accum × P _accum

Where F _spring Is the spring force, A _accum is the accumulator's hydraulic area (assuming A _accum used in the existing clutch), and P _accum is the actual accumulator's operating pressure.

When calculating the result of the spring force of the above equation, the spring design is virtually impossible at about 307.8 Kgf, and therefore, there is a problem that the design of the high-pressure accumulator is difficult.

The present invention is to solve the above problems, an object of the present invention is to provide an accumulator for line pressure using the highest pulley pressure of the CVT to reduce the spring force of the accumulator in order to implement a high-pressure accumulator for the actual CVT will be.

In order to achieve the above object, the present invention is an accumulator used for reducing the line pressure pulsation of CVT (Continuously Variable Transmission), the high pressure of the pressure of the first pulley and the second pulley of the CVT to the spring-loaded rear end Provided is an accumulator for line pressure, characterized in that the pulsation of the line pressure of the CVT of high pressure is reduced by receiving the spring force by the pressure received.

And a high pressure of the first pulley pressure and the second pulley pressure of the CVT is transmitted to the rear end of the spring by an anneal direction valve to which the first pulley and the second pulley of the CVT are connected.

The line pressure of the CVT is characterized in that the range of 4bar ~ 50bar.

Hereinafter, an accumulator for line pressure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view illustrating a flow of a high first pulley pressure flowing in an accumulator according to an embodiment of the present invention, and FIG. 2 is a view of a flow of a high second pulley pressure flowing in an accumulator according to an embodiment of the present invention. Figure is shown.

As shown in Figs. 1 and 2, in general, the line pressure causes the flow rate discharged from the oil pump 1 to make a reference pressure necessary for continuously variable transmission (CVT, not shown). do.

Due to the characteristics of the oil pump 1, the line pressure is shaken, and an accumulator 10 is installed to catch the shake, that is, the pressure pulsation.

In the line regulator valve 3, the flow rate discharged from the oil pump 1 is linearly controlled by the LCSV (Line Control Solenoid Valve, LCSV) to control the pressure linearly in the range of 4 bar to 50 bar. Will be sent).

In other words, the line regulator valve 3 is linearly controlled by the LCSV. If the pressure of the LCSV is high, the pressure of the line regulator valve 3 is also high, and if the pressure of the LCSV is low, the line regulator valve 3 The pressure of is also lowered accordingly. This will create the line pressure required for the CVT.

The line pressure in the CVT is controlled according to the higher of the pulley pressures. Accordingly, in the present invention, an accumulator direction valve 30 is connected to the accumulator 10 to use the pulley control pressure, which is the highest pressure in the CVT, to implement the high pressure accumulator 10.

In this case, the line pressure is controlled by adding a margin amount to a higher pressure of the first pulley pressure and the second pulley pressure, and the margin amount is a value set by electronic control. Generally, the value is set between 1 bar and 5 bar.

The first pulley 31 is installed in connection with a ratio control valve 21 to be controlled by the raceway control valve 21, and the second pulley 32 is a secondary valve, It is connected to the 22 and is controlled by the secondary valve (22).

In addition, the installation direction valve 30 connected to the accumulator 10 to send a high pulley pressure has a first pulley 31 and a second pulley 32 installed at both sides thereof. do.

The first pulley 31 is connected to the B side shown in the drawing of the anchor direction valve 30, and the second pulley 32 is connected to the A side of the arrest direction valve 30.

In the mounting direction valve 30, the pressure of the first pulley 31 received from the race control valve 21 and the secondary valve 22, which controls the first pulley 31 and the second pulley 32, and The high pressure of the second pulley 32 pressure is determined and sent to the accumulator 10. That is, as will be described later, when the pressures of the first pulley 31 and the second pulley 32 are respectively applied to the arrest direction valve 30, the arrest direction valve 30 moves to the lower side and at the same time, The high pressure of the first pulley 31 and the second pulley 32 is sent to the accumulator 10.

The high pressure sent from the anchor direction valve 30 is sent to the rear end of the accumulator 10, i.e. to the portion on which the spring 11 is mounted.

At this time, looking at the spring force of the spring of the high-pressure accumulator 10 to catch the pressure pulsation,

F _spring + High pulley pressure × A _accum = A _accum × P _accum

F _spring = A _accum × P _accum High pulley pressure × A _accum

Where F _spring Is the spring force, A _accum is the pressure area of the accumulator (assuming A _accum used in the existing clutch), and P _accum is the actual working pressure of the accumulator.

Since the spring force of the accumulator 10 subtracts the high pulley pressure value, the spring force is much lower than the spring force required for the conventional accumulator, and the present invention reduces the spring force to design the accumulator for line pressure in a high and wide pressure range. You can do

In the accumulator implementation according to the present invention configured as described above, the pressure flow according to the pressure comparison between the first pulley and the second pulley is as follows.

As shown in FIG. 1, when the first pulley pressure flowing in the accumulator is high, it is as follows.

In the installation direction valve 30, the pressure of the first pulley 31 and the pressure of the second pulley 32 are determined to be high, and the first pulley 31 receives a pressure higher than the pressure of the second pulley 32. When the arrangement direction valve 30 is moved in the direction A connected with the second pulley 32 having a low pressure, the pressure of the accumulator 10 having the spring 11 mounted on the first pulley 31 having the high pressure is moved. Send it to the end.

Due to the high pressure of the first pulley 31, the spring force required for the spring 11 mounted on the accumulator 10 is reduced, so that the accumulator 10 catches the high pressure pressure pulsation.

As shown in FIG. 2, when the second pulley pressure flowing in the accumulator is high is as follows.

In the attachment direction valve 30, a high pressure is determined between the pressure of the first pulley 31 and the pressure of the second pulley 32, and the pressure of the second pulley 32 higher than the pressure of the first pulley 31 is determined. When received, the displacement direction valve 30 moves in the B direction connected to the first pulley 31 having a low pressure, and the accumulator 10 having the spring 11 mounted on the second pulley 32 having a high pressure. Send to the end of.

Due to the high pressure of the second pulley 32, the spring force required for the spring 11 mounted on the accumulator 10 is reduced, so that the accumulator 10 catches the high pressure pressure pulsation.

On the other hand, the present invention is not limited to the above-described embodiment, and those skilled in the art to which the present invention pertains without departing from the gist of the invention claimed in the claims can be variously modified. Of course, such changes are intended to be within the scope of the claims set forth.

As described above, the line pressure accumulator according to the embodiment of the present invention catches the pressure pulsation of the line pressure of the CVT controlled in the range of 4bar ~ 50bar by reducing the required spring force by using the pulley pressure which is the high pressure of the CVT There are advantages to give.

Claims (3)

An accumulator (10) used for reducing line pressure pulsation of CVT (Continuously Variable Transmission), The pulsation of the line pressure of the CVT of the high pressure by receiving the high pressure of the pressure of the first pulley 31 and the second pulley 32 of the CVT to the rear end equipped with the spring 11 and reducing the spring force to the pressure Accumulator for line pressure, characterized in that to reduce. The method of claim 1, The high pressure of the first pulley 31 and the second pulley 32 of the CVT is controlled by an anchoring direction valve 30 connected to the first pulley 31 and the second pulley 32 of the CVT. Accumulator for line pressure, characterized in that receiving the spring 11 is mounted to the rear end. The method according to claim 1 or 2, Line pressure of the CVT accumulator for line pressure, characterized in that the range of 4bar ~ 50bar.

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