JP6284401B2 - Reservoir tank and brake system using the same - Google Patents

Description

The present invention relates to a technical field of a reservoir tank for storing hydraulic fluid and a brake system using the hydraulic reservoir, which is used in a hydraulic actuator using hydraulic pressure such as hydraulic pressure.

In a vehicle such as an automobile, a hydraulic actuator using hydraulic pressure is used. This hydraulic pressure operating device has a reservoir tank that stores hydraulic fluid supplied to a master cylinder that generates hydraulic pressure.

Conventionally, there is a reservoir tank that ejects from an inflow / outflow port that communicates with a master cylinder. In such a reservoir tank, the cap of the injection port is removed in order to attach the brake fluid injection device and the brake fluid can to the reservoir tank at the time of air bleeding work such as replacement of various brake parts. The brake pedal may be operated. At this time, as described above, when the liquid injection port is positioned above the inflow / outflow port and the inflow / outflow port and the liquid injection port are on substantially the same axis, the working fluid from the master cylinder is suddenly introduced into the reservoir tank. Returning and ejecting, the ejected working fluid may jump out of the injection port. The hydraulic fluid that has jumped out of the liquid injection port may fall on the clothes of the worker or enter the eyes of the worker, leading to deterioration of the work environment and health problems.

In order to solve such a problem, even if the hydraulic fluid suddenly returns to the reservoir tank and spouts toward the liquid injection port, the hydraulic fluid can be ejected from the open liquid injection port by regulating the jet direction of the hydraulic fluid. A technique for preventing this is disclosed (see Patent Document 1).

JP 2005-88772 A

However, in the reservoir tank of the embodiment described in FIGS. 1 to 8 of Patent Document 1, a new member must be put in the inside in advance, and the lower half 2 and the upper half 3 must be thermally welded, Since the number of parts and the assembly process increase, it takes time and effort and increases the cost. In addition, to obtain this structure using a mold, the structure becomes complicated and the cost becomes high. Moreover, since the reservoir tank of the embodiment described in FIG. 9 of Patent Document 1 supports the plate surface of the regulating plate at one end, the strength is low, and the operator presses the pressure feeding gun for injecting the working fluid. There was a risk of damage.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a reservoir tank capable of regulating the ejection direction of hydraulic fluid with a simple structure and a brake system using the same. It is.

In order to solve the above-described problem, a reservoir tank according to an embodiment of the present invention includes:
A lower half having a lower surface including a hydraulic fluid supply unit for supplying hydraulic fluid to the outside and a side surface connected to the lower surface and opened upward;
An upper half including a top surface including an inlet into which the working fluid is injected, and an upper half having a side surface which is connected to the top surface and is open at the bottom;
With
A reservoir tank in which an upper end of a side surface of the lower half body and a lower end of a side surface of the upper half body are welded to form a hydraulic fluid reservoir inside;
A base disposed so as to cover an upper side of the supply port of the hydraulic fluid supply unit, a connection unit extending outward from the base, a holding unit connected to the outer ends of at least two of the connection units and held by the injection port; And a restricting portion having a wall portion disposed below the base portion.

In the reservoir tank according to one embodiment of the present invention,
The axis of the wall is formed to be inclined with respect to the axis of the supply port.

In the reservoir tank according to one embodiment of the present invention,
The wall is formed with a slit extending in the longitudinal direction.

In the reservoir tank according to one embodiment of the present invention,
The injection port has a small diameter portion,
The holding part has a side part that connects the connecting part along the shape of the small-diameter part, and a projecting part that is formed from the upper end of the side part toward the outer periphery and is caught by the small-diameter part.

In the reservoir tank according to one embodiment of the present invention,
The connecting portion is formed in an elongated shape and extends radially from the base portion.

In the reservoir tank according to one embodiment of the present invention,
The restricting portion is integrally formed.

In the reservoir tank according to one embodiment of the present invention,
The wall portion is formed integrally with the lower half so as to extend upward from the periphery of the supply port of the lower half.

Furthermore, the brake system according to one embodiment of the present invention includes:
A brake pedal,
A brake booster that boosts and outputs the pedal effort of the brake pedal;
A master cylinder that operates with the output of the brake booster to generate hydraulic pressure;
The reservoir tank for supplying hydraulic fluid to the master cylinder;
A brake cylinder that generates a braking force with a hydraulic pressure generated in the master cylinder and brakes the wheel;
It is characterized by providing.

A reservoir tank according to an embodiment of the present invention is:
A lower half having a lower surface including a hydraulic fluid supply unit for supplying hydraulic fluid to the outside and a side surface connected to the lower surface and opened upward;
An upper half including a top surface including an inlet into which the working fluid is injected, and an upper half having a side surface which is connected to the top surface and is open at the bottom;
With
A reservoir tank in which an upper end of a side surface of the lower half body and a lower end of a side surface of the upper half body are welded to form a hydraulic fluid reservoir inside;
A base disposed so as to cover an upper side of the supply port of the hydraulic fluid supply unit, a connection unit extending outward from the base, a holding unit connected to the outer ends of at least two of the connection units and held by the injection port; And a restriction part having a wall part arranged below the base part,
It becomes possible to regulate the ejection direction of the hydraulic fluid with a simple structure.

In the reservoir tank according to one embodiment of the present invention,
Since the axis of the wall is formed to be inclined with respect to the axis of the supply port,
It is possible to make the hydraulic fluid that has suddenly returned to the supply port collide with the wall portion, and to further restrict the hydraulic fluid from jumping out of the injection port.

In the reservoir tank according to one embodiment of the present invention,
Since the wall portion is formed with a slit extending in the longitudinal direction,
The air in the wall portion can be easily removed to the outside, and the air can be prevented from staying in the wall portion.

In the reservoir tank according to one embodiment of the present invention,
The injection port has a small diameter portion,
Since the holding part has a side part that connects the connecting part along the shape of the small diameter part and a protruding part that is formed from the upper end of the side part toward the outer periphery and is hooked on the small diameter part,
It becomes possible to easily attach the restricting portion to the inlet.

In the reservoir tank according to one embodiment of the present invention,
Since the connecting portion is formed in an elongated shape and extends radially from the base portion,
It becomes possible to make the hydraulic fluid flow smoothly from the inlet.

In the reservoir tank according to one embodiment of the present invention,
Since the restricting portion is integrally formed,
It can be easily formed with few steps.

In the reservoir tank according to one embodiment of the present invention,
Since the wall portion is integrally formed with the lower half so as to extend upward from the periphery of the supply port of the lower half,
The hydraulic fluid that has suddenly returned to the supply port can be accurately collided by the regulating portion, and the hydraulic fluid can be regulated so as not to jump out of the injection port.

Furthermore, the brake system according to one embodiment of the present invention includes:
A brake pedal,
A brake booster that boosts and outputs the pedal effort of the brake pedal;
A master cylinder that operates with the output of the brake booster to generate hydraulic pressure;
The reservoir tank for supplying hydraulic fluid to the master cylinder;
A brake cylinder that generates a braking force with a hydraulic pressure generated in the master cylinder and brakes the wheel;
So that
It is possible to provide a brake system that can accurately change the liquid level in the float chamber of the reservoir tank, reduce the amount of unnecessary liquid only for controlling the liquid level, and reduce the cost.

The reservoir tank of a 1st embodiment is shown. It is the figure which looked at the reservoir tank of a 1st embodiment from the upper part. It is a cross-sectional arrow view of the AA line of FIG. It is the figure which looked at the upper half of the reservoir tank of a 1st embodiment from the lower part. It is a VV cross-sectional arrow view of FIG. It is a cross-sectional arrow view corresponding to FIG. 3 of the reservoir tank of the second embodiment. A brake system as an example in which the reservoir tank of this embodiment is used is shown typically.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  First, the first embodiment will be described.

FIG. 1 shows a reservoir tank 1 of the first embodiment. FIG. 2 is a view of the reservoir tank 1 of the first embodiment as viewed from above. 3 is a cross-sectional view taken along line AA in FIG. FIG.
It is the figure which looked at the upper half 3 of the reservoir tank 1 of 1st Embodiment from the downward direction. FIG. 5 shows V in FIG.
FIG.

The reservoir tank 1 of the first embodiment has a lower surface 21 and a side surface 22, has a container-like lower half body 2 that opens upward, an upper surface 31, and a side surface 32, and an upper end 2 a of the lower half body 2. And a lid-like upper half 3 that closes the lid. The upper end 2a of the lower half 2 and the lower end 3a of the upper half 3 are thermally welded to store the working fluid inside.

The lower half body 2 is formed on the bottom surface and is provided with a float chamber 23 that is partitioned by a partition wall that houses a float that detects the liquid level, and a hydraulic fluid supply that is formed on the bottom surface and supplies the hydraulic fluid to the master cylinder of the brake system. A portion 24 and a connection port 25 formed on the side surface 22 and connected to a master cylinder or the like of the clutch system via a hose or the like (not shown) are formed.

The hydraulic fluid supply unit 24 includes a first hydraulic fluid supply unit 24a connected to a first master cylinder of a brake system (not shown) and a second hydraulic fluid supply unit 24b connected to a second master cylinder.

The upper half 3 is formed with a cylindrical inlet 33 formed in the upper part. The hydraulic fluid is injected into the reservoir tank 1 by opening a cap (not shown) that is detachably attached to the upper end of the injection port 33. The reservoir tank 1 stores the injected hydraulic fluid, and the hydraulic fluid supply unit 24
The hydraulic fluid is supplied from the connection port 25 to the brake system and the clutch system, respectively.

The reservoir tank 1 according to the first embodiment includes a restricting portion 1 that extends downward from the inlet 33 of the upper half 3.
0 is provided. The restricting portion 10 includes a base portion 11 and a connecting portion 12 extending outward from the base portion 11.
And a holding portion 13 held at the injection port and a cylindrical wall portion 14 extending downward from the base portion 11. The restricting portion 10 of the first embodiment is integrally formed.

The base portion 11 is a plate-like portion having a smaller diameter than the injection port 33, and as shown in FIG. 2, at least a part of the supply port 24 b ₁ at a position including the center C of the injection port 33 as viewed from above. It is preferable that it is arranged so as to cover. The connecting portion 12 is a long portion that connects the base portion 11 to the holding portion 13. The connecting portion 12 is formed in a radial shape in the first embodiment, but may have other shapes.

The holding part 13 has a side part 13a that connects the outer ends of at least two connecting parts 12 along the shape of the injection port 33, and a protruding part 13b that is formed from the upper end of the side part 13a toward the outer periphery. And the control part 10 is hold | maintained at the injection port 33 because the protrusion part 13b is hooked by the small diameter part 33a formed in the injection port 33. FIG.

Wall 14 extends downwardly from the base 11 to immediately above the feed opening 24b _1. Although the wall part 14 of 1st Embodiment is formed in the cylinder shape, another shape may be sufficient. The wall 14 has 9 with respect to the axis.
A slit 14a extending in the longitudinal direction is formed every 0 °. The axis C1 of the wall 14
Is preferably inclined with respect to the axis C2 of the supply port 24b ₁ .

When the restricting portion 10 is attached to the injection port 33, as shown in FIG. 2, the base portion 11 is disposed so as to cover the upper side of the supply port 24 b ₁ including the central axis C of the injection port 33 as viewed from above. The
The wall portion 14 extending from the base 11 downward, as shown in FIG. 3, arranged around at least one upper feed opening 24b ₁ formed in the second hydraulic fluid supply portion 24b of the hydraulic fluid supply portion 24 Is done.

In such a reservoir tank 1 of the first embodiment, the working fluid passes through the inlet 33 and is injected from the gap of the connecting portion 12 of the restricting portion 10. Therefore, the regulating part 10 does not obstruct the flow of the hydraulic fluid at the time of injection. Further, even if the hydraulic fluid suddenly returns to the reservoir tank 1 and is ejected from the supply port 24 b ₁ of the hydraulic fluid supply unit 24, it can be prevented from being ejected from the injection port 33 because it hits the base 11 and the wall portion 14. It becomes. That is, it becomes possible to regulate the direction of ejection of the hydraulic fluid with a simple structure.

  Next, a second embodiment will be described.

  FIG. 6 is a cross-sectional arrow view corresponding to FIG. 3 of the reservoir tank 1 of the second embodiment.

In the reservoir tank 1 of the second embodiment, the regulating portion 10 is divided, the base portion 11, the connecting portion 12, and the holding portion 13 are provided in the upper half body 1, and the wall portion 14 is formed integrally with the lower half body 2. It is a thing.

The restricting portion 10 includes a base portion 11, a connecting portion 12 that extends outward from the base portion 11, a holding portion 13 that is held by the injection port 33, and a cylindrical wall portion 14 that extends below the base portion 11.

The base 11 is a plate-like portion having a smaller diameter than the injection port 33, and in the same manner as in the first embodiment shown in FIG. 2, at the position including the center C of the injection port 33 as viewed from above, the supply port It is preferable that it is arranged so as to cover at least a part of 24b ₁ . The connecting portion 12 is a long portion that connects the base portion 11 to the holding portion 13. The connecting portion 12 is formed in a radial shape in the second embodiment, but may have another shape.

The holding part 13 has a side part 13a that connects the outer ends of at least two connecting parts 12 along the shape of the injection port 33, and a protruding part 13b that is formed from the upper end of the side part 13a toward the outer periphery. And the control part 10 is hold | maintained at the injection port 33 because the protrusion part 13b is hooked by the small diameter part 33a formed in the injection port 33. FIG.

The wall portion 14 extends upward from the periphery of the supply port 24b ₁ to just below the base portion 11. Although the wall part 14 of 2nd Embodiment is formed in the cylinder shape, another shape may be sufficient. The wall portion 14 is formed with slits 14a extending in the longitudinal direction every 90 ° with respect to the axis. Further, the axis C1 of the wall portion 14 is preferably formed to be inclined with respect to the axis C2 of the supply port 24b _1.

When the restricting portion 10 is attached to the injection port 33, as in the first embodiment shown in FIG.
When viewed from above, the base 11 includes the central axis C of the injection port 33 and is disposed so as to cover the upper side of the supply port 24b ₁ . And at least one second hydraulic fluid supply unit 24b of the hydraulic fluid supply unit 24
As shown in FIG. 6, the wall portion 14 extending upward from the periphery of the supply port 24b ₁ formed in the base portion extends to just below the base portion 11.

In such a reservoir tank 1 of the first embodiment, the working fluid passes through the inlet 33 and is injected from the gap of the connecting portion 12 of the restricting portion 10. Therefore, the regulating part 10 does not obstruct the flow of the hydraulic fluid at the time of injection. Further, even if the hydraulic fluid suddenly returns to the reservoir tank 1 and is ejected from the supply port 24 b ₁ of the hydraulic fluid supply unit 24, it can be prevented from being ejected from the injection port 33 because it hits the base 11 and the wall portion 14. It becomes. That is, it becomes possible to regulate the direction of ejection of the hydraulic fluid with a simple structure.

In the restricting portion 10 of the present embodiment, the four connecting portions 12 are 90 from the base portion 11 in the circumferential direction.
Although it is formed radially at every °, the number and angle may be set in any way. Further, four slits 14a are formed in the wall portion 14 every 90 ° in the circumferential direction, but the number and angle may be set in any manner.

Thus, the reservoir tank 1 of the present embodiment includes a lower surface 21 including a hydraulic fluid supply unit 24 that supplies hydraulic fluid to the outside, and a lower half body 2 that is connected to the lower surface 21 and has a side surface 22 that opens upward.
An upper surface 31 including an injection port 33 into which hydraulic fluid is injected and an upper half 3 having an upper surface connected to the upper surface 31 and having a side surface 32 opened at the lower side, and an upper end 2a of the side surface 22 of the lower half 2 the lower end 3a of the side surface 32 of the half 3 a reservoir tank 1 the hydraulic fluid reservoir to the inside by welding is formed, the base portion being arranged to cover the upper side of the supply port 24b ₁ of the hydraulic fluid supply portion 24 11, base 11
A connecting portion 12 that extends outward from the connecting portion 12, a holding portion 13 that connects the outer ends of at least two connecting portions 12 and is held by the injection port 33, and a regulating portion 10 that has a wall portion 14 disposed below the base portion 11. Therefore, it is possible to restrict the hydraulic fluid that has suddenly returned to the supply port 24 b ₁ to collide with the regulating portion 10 so that the hydraulic fluid does not jump out of the inlet 33.

Further, the reservoir tank 1 of this embodiment, the axis C1 of the wall portion 14, so formed is inclined with respect to the axis C2 of the supply port 24b _1, the wall portion of the hydraulic fluid returned rapidly to the supply port 24b ₁ 14 and can be further controlled so that the hydraulic fluid does not jump out of the injection port 33.

Moreover, in the reservoir tank 1 of this embodiment, the wall part 14 is the slit 1 extended in a longitudinal direction.
Since 4a is formed, the air in the wall portion 14 can be easily escaped to the outside.
It is possible to prevent air from staying inside.

Moreover, in the reservoir tank 1 of this embodiment, the injection port 33 has the small diameter part 33a, and the holding | maintenance part 13 connects the side part 13a and the side part 1 which connect the connection part 12 along the shape of the small diameter part 33a.
Since it has the protrusion part 13b formed toward the outer periphery from the upper end of 3a, it becomes possible to attach the control part 10 to the injection port 33 easily.

Further, in the reservoir tank 1 of the present embodiment, the connecting portion 12 is formed in an elongated shape, and the base 1
Since it extends radially from 1, the hydraulic fluid can be smoothly flowed from the inlet 33.

Moreover, in the reservoir tank 1 of this embodiment, since the control part 10 is formed integrally, it becomes possible to form easily with few processes.

Further, in the reservoir tank 1 of the present embodiment, the wall portion 14 is formed integrally with the lower half 3 so as to extend upward from the periphery of the supply port 24b ₁ of the lower half 2, so the supply port 24b ₁ The hydraulic fluid that has suddenly returned to the position can be accurately collided by the restricting portion 10, and the hydraulic fluid can be regulated so as not to jump out of the inlet 33.

Next, the operation when the reservoir tank 1 of this example is used as the reservoir tank 1 of the brake system will be described.

FIG. 7 shows a brake system 5 as an example in which the reservoir tank 1 of the present embodiment is used.
0 is shown schematically.

As shown in FIG. 7, the hydraulic brake system 50 in this example is basically the same as a conventionally known two-system brake system. That is, the brake system 50 includes a reservoir tank 1, a brake pedal 51, a booster 52, a tandem master cylinder 53, and a brake cylinder 54.

When the driver depresses the brake pedal 21, the booster 52 operates to boost and output the pedal depression force with a predetermined servo ratio. The primary piston of the tandem master cylinder 53 is operated by the output of the booster 52 to supply the hydraulic fluid in the primary hydraulic fluid chamber to the brake cylinder 54 of one system, and the secondary piston is operated to activate the secondary hydraulic fluid chamber. Is supplied to the brake cylinder 54 of the other system. When the loss stroke of each brake system disappears, the tandem master cylinder 53 generates hydraulic pressure. The hydraulic pressure of the tandem master cylinder 53 is transmitted to each brake cylinder 54, and each brake cylinder 54
Generates a braking force, and each wheel 55 is braked. The reservoir tank 1 supplies hydraulic fluid to the tandem master cylinder 53.

The reservoir tank 1 according to the present invention is not limited to a brake device, and any hydraulic device can be used as long as it generates hydraulic pressure in a hydraulic chamber of a piston , including a clutch device. Can be applied.

Although various embodiments of the present invention have been described above, the present invention is not limited only to these embodiments, and the configurations of the respective embodiments and the configurations appropriately changed without departing from the scope of the invention. Embodiments having a configuration in which the configurations of the embodiments are appropriately combined also fall within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Reservoir tank, 10 ... Control part, 11 ... Base part, 12 ... Connection part, 13 ... Holding part, 13a
... side part, 13b ... projecting part, 14 ... wall part, 14a ... slit, 2 ... lower half, 21 ... lower surface,
22 ... side, 23 ... float chamber, 24 ... hydraulic fluid supply portion, 24b ₁ ... supply port, 25 ... connecting port, 3 ... upper half, 31 ... upper surface 32 ... side, 33 ... inlet, 33a ... small-diameter portion , 50 ... Brake system, 51 ... Brake pedal, 52 ... Booster, 53 ... Tandem master cylinder, 54 ... Brake cylinder, 55 ... Wheel

Claims (8)

A lower half having a lower surface including a hydraulic fluid supply unit for supplying hydraulic fluid to the outside and a side surface connected to the lower surface and opened upward;
An upper surface including an inlet through which the working fluid is injected and an upper half having a side surface connected to the upper surface and opened at the bottom; and
A reservoir tank in which an upper end of a side surface of the lower half body and a lower end of a side surface of the upper half body are welded to form a hydraulic fluid reservoir inside;
A base disposed so as to cover an upper side of the supply port of the hydraulic fluid supply unit, a connection unit extending outward from the base, a holding unit connected to the outer ends of at least two of the connection units and held by the injection port; And a reservoir tank having a wall portion disposed below the base portion. The reservoir tank according to claim 1, wherein the axis of the wall portion is formed to be inclined with respect to the axis of the supply port. The reservoir tank according to claim 1 or 2, wherein the wall portion is formed with a slit extending in a longitudinal direction. The injection port has a small diameter portion,
The holding part includes a side part that connects the connecting part along the shape of the small-diameter part, and a projecting part that is formed from the upper end of the side part toward the outer periphery and is caught by the small-diameter part. The reservoir tank according to any one of 1 to 3. The reservoir tank according to any one of claims 1 to 4, wherein the connecting portion is formed in an elongated shape and extends radially from the base portion. The reservoir tank according to any one of claims 1 to 5, wherein the restricting portion is integrally formed. The said wall part is integrally formed in the said lower half body so that it may extend upwards from the circumference | surroundings of the said supply port of the said lower half body. The Claim 1 thru | or 5 characterized by the above-mentioned. Reservoir tank. A brake pedal,
A brake booster that boosts and outputs the pedal effort of the brake pedal;
A master cylinder that operates with the output of the brake booster to generate hydraulic pressure;
The reservoir tank according to any one of claims 1 to 7 , wherein hydraulic fluid is supplied to the master cylinder.
A brake cylinder that generates a braking force with a hydraulic pressure generated in the master cylinder and brakes the wheel.

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