DE69724925T2 - Master cylinder with a two-part sealing ring - Google Patents

Description

This invention relates to a master cylinder, in the sealing device for sealing the outer circumference a piston is a double-structured sealing ring (i.e., a double seal ring) deals with an inner peripheral seal ring and an outer peripheral seal ring on the outer circumference of the inner sealing ring. In other words, this invention relates refer to a process that is generally based on a master cylinder for a brake or a clutch and applied specifically to a master cylinder can be where an opening Part of one in a cylinder housing formed relief opening according to the movement of the piston blocked or interrupted by a sealing ring becomes. In particular, this invention relates to a method that is for the application in a tandem master cylinder is suitable for an anti-lock braking system.

The idea itself, to seal the outer periphery a piston with an inner circumferential sealing ring and an outer circumferential sealing ring existing double sealing ring is already known. The disclosed Japanese patent publication No. 219263/1994 or USP 5,168,791 which is a hydraulic pressure booster device shows a method in which to seal the outer circumference the servo piston an O-ring and a resin ring in a groove in the outer circumference of the Servo pistons are inserted, the former on the inner Peripheral side and the latter is located on the outer peripheral side. The inner circumferential sealing ring made of rubber or the like is used for sealing a space between the piston and the cylinder housing and a space between the outer peripheral seal ring and the cylinder housing due to its own elastic deformation. Furthermore acts on the outer circumferential sealing ring an elastic force of the inner peripheral seal ring, so that he a space between the inner circumference of the cylinder housing and seals the piston. Because the outer circumferential sealing ring is smaller and has a lower sliding resistance than the inner one Circumferential rubber o-ring, the smooth movement of the movable Enables piston.

Bearing in mind that the double sealing ring is hardly susceptible is on "biting by seal "(a phenomenon in which the lip part of the sealing ring through the opening of the in the cylinder housing formed relief opening pinched and damaged) the present inventors recently proposed a method where the double sealing ring is applied to a master cylinder becomes. As one of these suggestions Japanese patent application filed on November 16, 1995 discloses No. 321190/1995 (published on May 27, 1997 under number 136639/1997 Assessment disclosed) a process in which a sealing ring with double sealing ring structure on the outer peripheral surface of a Piston is formed, a connection path for connecting a working fluid container with a hydraulic pressure chamber is formed in a piston to a Additional liquid to promote the hydraulic pressure chamber and an additional valve is arranged in the connection path. Also revealed Japanese Patent Application No. 198487/1996 filed on July 9, 1996 another method in which a sealing ring with a double sealing ring structure to the outer perimeter the piston is shaped and a small piston movable in the piston is arranged so that when the pressure in the hydraulic pressure chamber becomes negative and between the ambient pressure on the side of the working fluid container and a pressure difference occurs in the pressure in the hydraulic pressure chamber, this pressure difference leads to that the small piston is moved, increasing the volume of the hydraulic pressure chamber is reduced. A volume reduction device that the includes small pistons and an auxiliary device that the auxiliary valve includes, serve as a supplement a plate sealing ring without additional feed function.

The use of a double sealing ring in a master cylinder is also known from WO 95/13206, where a Sealing device is disclosed with a first seal from relative hard material that can slide on the inside wall of the cylinder and a relatively compliant inner second seal that so is arranged between the sealing surfaces of the piston and the first Seal works. The sealing device is in a groove, the one on an outside diameter of the piston is formed. The groove has a tapered wall part and the arrangement is such that when pressure builds up in the pressure chamber the resilient inner seal is deformed against the tapered wall and a force radially outwards exerts so that the outer seal is loaded so that it comes into contact with the inner wall of the cylinder.

In these preceding methods, whether known or not, a groove for the sealing ring to be inserted therein is formed in the outer periphery of the piston and the O-ring and resin ring forming the double seal are arranged in the same groove so that their enlarged diameter sections over the adjacent web parts protrude from the piston. If the double sealing ring is arranged in the groove formed in the outer circumference of the piston, the O-ring can be easily elastically deformed on the inner circumference and the configuration of the inner circumferential O-ring thus deformed quickly returns to its initial configuration. The outer circumferential resin ring, however, which is harder than the O-ring, is difficult to deform elastically. In addition, the outer peripheral resin ring, after being deformed, is not easily returned to its original configuration. For this This is why a special tool is required to insert the resin ring. In addition, the resin ring must be left unchanged for a long time until it has returned to its original state. Even if it has returned to its original state, the resin ring, which cannot be easily elastically deformed, does not correctly return to its original state. This can lead to inadequate sealing performance and deteriorated sliding properties. In the conventional master cylinder with a plate sealing ring, the use of a return spring as a device for supporting the plate sealing ring is known (USP 4,437,310).

There is also the master cylinder with a double sealing ring in addition to the problem with assembly of such a resin ring the inconvenience that when the web part of the piston, just before the piston reaches its return position, an opening one relief opening on the side of the cylinder housing opposite, one formed between the inner wall of the cylinder housing and the land part Space has a throttling effect, which causes the liquid to return in the container interrupts. This happens for the following reason: Around the double sealing ring reliable to hold or the piston in the area of the fastening groove has sufficient mechanical strength, there must be an axial distance of the web part have a prescribed length from the fastening groove. On the other hand, the end of the double seal ring to the game (i.e. the invalid one Stroke), if possible close to the opening the relief opening. In view of such a design principle, the web part of the Piston of the opening the relief opening opposed, what the previously mentioned Throttling effect.

The first object of the present invention is hence in a method of improving assemblability to provide a double seal ring.

Another purpose of the present The invention consists in providing a method with which an outer peripheral sealing ring made of hard material such as resin or the like a piston can be attached without the diameter of the outer circumferential sealing ring be enlarged got to.

Another purpose of the present Invention is to provide a method that one Double sealing ring enables to have excellent sealing and sliding properties after assembly.

Yet another purpose of the present invention is to provide a method in a master cylinder with double sealing ring, the even return of a liquid from can ensure a hydraulic pressure chamber to a container itself if a piston is right in front of the return position.

The first concern of the present Invention is an idea where, given a difference in the ease with which the inner and outer peripheral sealing rings are elastic can be deformed the inner circumferential sealing ring, which deform slightly elastically leaves, is attached to the piston and can be deformed elastically, the outer circumferential sealing ring however, which is difficult to deform elastically, is attached to the piston, without being elastically deformed.

Based on this first idea, the present invention provides a master cylinder having a cylinder housing with a cylinder bore extending in the axial direction thereof, a piston slidably inserted into the cylinder bore formed in the cylinder housing, the piston being one with the cylinder housing Hydraulic pressure chamber in the cylinder bore, a return spring to bias the piston axially in a direction opposite to the hydraulic pressure chamber in a rest position, a relief opening formed in a side circumference of the cylinder housing, one end of the relief opening being connected to the hydraulic pressure chamber when the piston in the Rest position and the other end of the relief opening is connected to a working fluid container, and a double sealing ring placed around an outer periphery of the piston to the relief opening in response to a stroke of the piston in To block direction of the hydraulic pressure chamber, wherein the double sealing ring comprises an inner circumferential sealing ring made of elastic material and an outer circumferential sealing ring made of harder material than the inner circumferential sealing ring and the outer circumferential sealing ring is located on an outer circumference of the inner sealing ring, wherein the piston has a ring holding part with an outer diameter L0 for holding the double sealing ring, a first web part adjacent to the ring holding part and having an outer diameter L1 (wherein L1> L0), characterized in that the piston also comprises a second web part adjacent to an opposite side of the ring holding part on the first web part and the second web part Outer diameter L2 (where L2 <L1), the outer diameter L2 of the second web part is equal to or smaller than an inner diameter of the outer circumferential sealing ring, a side surface of the outer circumferential sealing ring on de r side of the second web part of a retaining ring attached to this piston ( 80 . 80 ' . 80 '' ) is supported.

By the outer diameter L2 of the web part the piston is selected to be equal to or smaller than an inner diameter of the outer circumferential sealing ring, the outer circumferential sealing ring on an outer peripheral side the inner circumferential sealing ring of the ring holder, radial without the outer circumferential sealing ring to expand.

Although the inner and outer peripheral sealing ring can be held by also on the other side surface of the piston on the side the first web is provided with a holding member, the other side surface on the side of the first web part, preferably through a side wall supported the first web part. As for the first page surface on the side of the second On the other hand, not only the outer circumferential sealing ring but also can also the inner circumferential sealing ring are supported by the retaining ring. Alternatively, it can be arranged so that only the side surface of the outer seal ring supported by the retaining ring and the inner peripheral sealing ring from the side wall of the second web portion of the piston is supported. If ever one side surface of the inner and outer circumferential sealing ring are held by the retaining ring, the outer diameter L0 of the ring holding part preferably equal to the outside diameter L2 of the second web part selected. If only one side the outer circumferential sealing ring supported by the retaining ring In contrast, a part with a reduced size is preferably used Diameter with the same diameter as the outer diameter of the second Web part in an area near the ring holding part of the first Provided part of the web. This allows both the outer circumferential sealing ring from the second web part as well as from the part with reduced diameter supported become. So the outer circumferential sealing ring more stable supported become.

The second concern of the present Invention is another idea where part is provided which has a role as a tool for plays the piston itself, so that the ability of the double sealing ring especially the outer circumferential ring, that is difficult to deform can be improved.

• A) der Außendurchmesser des eingesetzten Endteils (X) des Kolbenkörpers (132) ist kleiner als der Innendurchmesser des äußeren Umfangsdichtungsrings (55) und die Außendurchmesser des ersten und zweiten Stegteils (2310, 2320) angrenzend an die Befestigungsnut (2300) sind größer als der Innendurchmesser des äußeren Umfangsdichtungsrings (55); und
• B) zwischen dem eingesetzten Endteil (X) und der Befestigungsnut (2300) des Kolbenkörpers (132) befindet sich ein verjüngter Teil (280), dessen Außendurchmesser vom eingesetzten Endteil (X) zur Befestigungsnut (2300) hin allmählich zunimmt.

Based on this second idea, the present invention provides a master cylinder having a cylinder housing in which there is a cylinder bore extending in the axial direction thereof, a piston slidably inserted into the cylinder bore formed in the cylinder housing, the piston being one with the cylinder housing Hydraulic pressure chamber in the cylinder bore, a return spring to axially bias the piston axially in a direction opposite to the hydraulic pressure chamber in a rest position, a relief opening formed in a side circumference of the cylinder housing, one end of which is connected to the hydraulic pressure chamber when the piston is in the rest position and the other end of which is connected to a working fluid container and a double sealing ring placed around an outer periphery of the piston to close the relief opening in response to a stroke of the piston toward the hydraulic pressure chamber block, wherein the double sealing ring comprises an inner circumferential sealing ring made of elastic material and an outer circumferential sealing ring made of harder material than the inner circumferential sealing ring and the outer circumferential sealing ring is located on an outer circumference of the inner sealing ring, characterized in that the piston has a piston body with an inserted (X ) End part, which is opposite the hydraulic pressure chamber and serves as an inserted inlet opening when the double sealing ring is installed, a fastening groove, which is remote from the inserted end part (X) of the piston body in a direction opposite the hydraulic pressure chamber and into which the double sealing ring is inserted, a first web part adjacent to the Fastening groove and with respect to the fastening groove lying opposite the inserted end part (X) and a second web part, with respect to the fastening groove on the opposite side adjoining the first web part, which is on the same side as the inserted end part (X), the master cylinder fulfilling the following conditions A and B:

• A) the outer diameter of the inserted end part (X) of the piston body ( 132 ) is smaller than the inner diameter of the outer circumferential sealing ring ( 55 ) and the outer diameter of the first and second web part ( 2310 . 2320 ) adjacent to the mounting groove ( 2300 ) are larger than the inner diameter of the outer circumferential sealing ring ( 55 ); and
• B) between the inserted end part (X) and the fastening groove ( 2300 ) of the piston body ( 132 ) there is a tapered part ( 280 ), whose outer diameter from the inserted end part (X) to the fastening groove ( 2300 ) gradually increases.

If a piston with the properties mentioned above for example as part of a master cylinder, corresponds to the end part of the piston body used one of the hydraulic pressure chamber opposite Part.

The first and second webs, adjacent to the fastening groove, can have the same outer diameter (outer diameter of the part with the largest diameter). However, it is preferable that the outer diameter of the second web part on the same side as the inserted end part, which serves as the inserted opening, is chosen to be smaller than the outer diameter of the first web part on the opposite side. This allows the outer circumferential sealing ring to be easily installed. Although it is good enough if the tapered part is provided to improve the assembling ability at least in part of the area from the inserted end part to the fastening groove, it is preferable that the tapered part is provided over the entire area from the inserted end part to the fastening groove. This is the easiest way to install the sealing ring. If Although the double sealing ring is less damaged, the double sealing ring itself normally has no auxiliary liquid feed function. For this reason, the main ring, including the double sealing ring, must comprise an additional feed device with an additional valve or a volume reduction device with a small piston, as disclosed in the above-mentioned application. The auxiliary feed device or the volume reduction device enables an additional feed of a liquid to the hydraulic pressure chamber or reduces the volume of the hydraulic pressure chamber, so that the piston can quickly return to a non-releasing position, even if the master cylinder is actuated abruptly.

• C. Der zweite Stegteil des Kolbens umfasst einen verjüngten Teil an einem Bereich, der der Öffnung der Entlastungsöffnung in der Seite des Zylindergehäuses gegenüberliegt und der Außendurchmesser dieses verjüngten Teils wird vom eingesetzten Endteil des Kolbenkörpers zur Befestigungsnut hin allmählich vergrößert.

It is also preferable that by changing the configuration of the land portions of the piston adjacent to the mounting groove, the throttling function in the area of the opening of the relief opening is eliminated. From the foregoing point of view, the present invention has the following feature C:

• C. The second land portion of the piston includes a tapered portion at an area opposite to the relief port opening in the cylinder housing side, and the outer diameter of this tapered portion is gradually increased from the inserted end portion of the piston body toward the mounting groove.

Considered the piston of the master cylinder is the rejuvenated Part of this feature C is the same as the tapered part of the above Feature B. Because the tapered Part of feature C, however, is designed to control flow resistance the working fluid between the hydraulic pressure chamber and the relief opening reduce, this tapered Part of the opening the relief opening are opposite. In this regard, the tapered portion of feature B includes those the not the opening one Part of the relief opening are opposite. Therefore, a tapered one Part of at least the opening the relief opening opposite, for example a rejuvenated Part that is about the entire area from the inserted end part to the fastening groove of the piston body extends, meet the requirements of characteristics B and C and is therefore preferable.

With the double sealing ring is the inner circumferential sealing ring preferably an O-ring made of elastic molecular elastomer based on ethylene propylene terpolymer or ethylene propylene rubber. These materials are oil-resistant against not petroleum brake fluid for motor vehicles and heat resistant to over 120 ° C. on the other hand there is preferably the outer peripheral sealing ring a resin material, particularly preferably a material with a low sliding resistance between the cylinder housing and the outer peripheral sealing ring and more particularly preferably made of ethylene tetrafluoride resin (Trade name: Teflon). The whole outer sealing ring can be here also be made of the same material. It is also permissible that the outer circumferential sealing ring is made of another resin material or metal material, insofar as the sliding surface is coated with a resin with low sliding resistance.

In addition, the present Invention also for Single or tandem master cylinders can be used. In particular can do it with significant effect for a tandem master cylinder for a brake be used in an anti-lock braking system.

SHORT DESCRIPTION THE DRAWINGS

1 Fig. 12 is a sectional view showing an overall construction of an embodiment of a tandem master cylinder according to the present invention;

2 Fig. 3 is an enlarged sectional view showing an important part of 1 shows;

3 Fig. 12 is an enlarged sectional view of an important part showing another supporting example of a retaining ring;

4 is similar to an enlarged sectional view of an important part 3 ;

5 is similar to an enlarged sectional view of an important part 3 and 4 ;

6 (A) - 6 (B) are views showing yet another supporting example of a retaining ring, 6 (A) is similar to a sectional view 3 to 5 and 6 (B) Figure 6 is a sectional view on line 6-6 in 6 (A) ;

7 (A) - 7 (B) are similar views 6 (A) - (B) . 7 (A) is a sectional view and 7 (B) is a sectional view on the line 7-7 in 7 (A) ;

8th Fig. 12 is a sectional view of an important part showing another supporting example of a double seal ring;

9 Fig. 12 is a sectional view of an essential part showing another example of an auxiliary feeding device;

10 Fig. 12 is a sectional view of an important part showing an example of a volume reduction device;

11 Fig. 14 is a sectional view showing an overall construction of another embodiment of a tandem master cylinder according to the present invention;

12 Fig. 3 is an enlarged sectional view showing an important part of 11 shows;

13 Fig. 12 is an enlarged sectional view showing another example of a tapered part;

14 (A) and 14 (B) Fig. 14 are enlarged sectional views of an important part showing the behavior of a double seal ring;

15 is a graph showing a relationship between shows stroke and sliding resistance; and

16 (A) - 16 (B) Fig. 14 are enlarged sectional views showing the resin ring skew preventing device.

1 Fig. 12 shows an overall sectional structure of a tandem master cylinder for use in a brake to which the present invention is applied 2 Fig. 12 is a partially enlarged view showing an end part and the vicinity of a primary piston of a master cylinder.

A tandem cylinder 10 includes a cylinder housing 12 with a cylinder bore 14 that extends along an axis thereof. On an upper part of the cylinder housing 12 are ledges 16a . 16b provided with the cylinder bore 14 are communicatively connected. A working fluid container 18 sits on the cylinder housing 12 , with its joint parts 18a . 18b in the ledges 16a respectively. 16b stuck. The cylinder bore 14 in the cylinder housing 12 is on the side of the cylinder bottom 12b on the left of 1 closed and on the side of a cylinder head 12h open on the right. The inner circumference of the cylinder bore 14 has a constant diameter. Inside the cylinder bore 14 there is a return spring 22 , a secondary piston 32 , another return spring 21 and a primary piston 31 that from the side of the cylinder bottom 12b to the side of the cylinder head 112h are arranged in an orderly manner.

The primary piston 31 and the secondary piston 32 have sealing rings at two points on their outer circumference 51 . 61 ; 52 . 62 , To the piston 31 . 32 are the sealing rings 61 . 62 that of the pistons 31 . 32 held sealing rings closer to the side of the cylinder head 12h lie, plate sealing rings, while the sealing rings 51 . 52 that are closer to the side of the cylinder bottom 12b are the double sealing rings that are at issue here. In the cylinder bore 14 are through these sealing rings 51 . 61 ; 52 . 62 a second hydraulic pressure chamber 42 in the innermost end and a first hydraulic pressure chamber 41 between the pistons 32 . 31 educated. The pistons are in a normal operating state in which there is no braking 32 and 31 through the return springs 22 respectively. 21 to the side of the cylinder head 12h pressed. Therefore, the first and second hydraulic pressure chambers are in the normal state 41 . 42 over on the side of the cylinder housing 12 relief openings formed 71 . 72 with the inside of the working fluid container 18 connected. When an operator operates the brake, the primary piston overcomes first 31 the preload force of the return spring 21 , then the secondary piston overcomes 32 the preload force of the return spring corresponding to the movement on the primary side 22 and moves to the side of the cylinder bottom 12b to. Then the double sealing rings close 51 . 52 the relief openings 71 . 72 , The pistons 31 . 32 move forward and generate hydraulic pressure in the first and second hydraulic pressure chambers 41 . 42 ,

The master cylinder 10 uses a double seal as sealing rings according to an embodiment of the present invention 51 . 52 for opening and closing the relief openings 71 . 72 , The double seal includes an O-ring 53 on the inner circumferential side of the master cylinder 10 and a resin ring on the outer peripheral side. As already mentioned, the double sealing ring has the advantage on the one hand that the seal is less damaged, but on the other hand the disadvantage that the requirement for an additional supply of liquid has to be met. Here are the pistons 31 . 32 plate sealing rings at their end parts 65 so that working fluid from the side of the working fluid container 18 into the hydraulic pressure chambers 41 . 42 can be fed. The pistons 31 . 32 and their perimeters have connecting paths 90 to the hydraulic pressure chambers 41 . 42 with the inside of the working fluid container 18 connect to. An opening part of the connecting routes 90 is through plate sealing rings 65 locked. If, therefore, by abrupt braking or anti-lock control within the hydraulic pressure chambers 41 . 42 negative pressure is generated on a front and a rear portion of a lip of each plate seal ring 65 a pressure difference. Due to the effect of this pressure difference, the lip collapses, causing working fluid from the side of the working fluid container 18 into the hydraulic pressure chambers 41 . 42 is fed. The communication routes 90 each include a room 94 on the side circumference of each piston 31 . 32 and one in addition to that in each flask 31 . 32 formed relief opening 92 in the cylinder housing 12 additional hole formed 96 ,

In the first embodiment of the present invention, there is a feature in the supporting structure of the double seal rings 51 . 52 , The primary side and the secondary side have this feature in common. How out 2 , which shows the primary side in a partially enlarged scale, can be seen better, is in the master cylinder 10 , although the diameter of a first web part 310 adjacent to a ring holding part 300 to hold the double sealing ring 51 ( 52 ) is large, the diameter of a second web part 320 near the face of the piston 31 ( 32 ) equal to that of the ring holding part 300 , That is, if the outer diameter of the ring holding part 300 , of the first web part 310 and the second web part 320 are represented by L0, L1 and L2, L2 = L0 and also L0 <L1. The difference between L1 and L0 becomes equal to the thickness of that on the master cylinder 10 attached double sealing ring 51 ( 52 ). So, since the diameter L2 of the second web part 320 equal to the diameter L0 of the ring holding part 300 is not just the O-ring 53 comprehensive inner circumferential sealing ring, but also that of the resin ring 55 comprehensive outer circumferential sealing ring slightly on the ring holding part 300 be attached. In particular, since the outer peripheral resin ring 55 can be attached without significant elastic deformation, do not wait for its restoration. The one on the ring holding part 300 attached double sealing ring 51 ( 52 ) is on one side surface of the same from the side wall of the first web part 310 supported and on the other side surface by a retaining ring 80 ,

The retaining ring 80 also serves as a spring retainer for one of the return springs 21 ( 22 ) and can also only by the spring force of the return spring 21 ( 22 ) on the end face part of the piston 31 ( 32 ) being held. The retaining ring is on the primary side 80 but by tightening a screw 28 attached to a cage spring. The retaining ring 80 is produced by press molding. The retaining ring 80 includes a center hole formed in a central part thereof 82 in which the screw 28 is recorded, a flange part formed on the outer peripheral part 84 to support the side surface of the double sealing ring 51 and a part pressed up 86 which in the radial direction on an intermediate part of the retaining ring 80 is shaped. The part pressed up 66 has an upward pressed element that serves to support the retaining spring 21 contribute. A hole caused by the pressing process upwards serves as a relief opening for the hydraulic pressure chamber 41 , An outer diameter of the on the outer circumference of the retaining ring 80 formed flange part 84 is slightly smaller than the diameter of the first web part 310 of the piston 31 , Thanks to this arrangement, this surface has to be the outer peripheral surface of the flange part 84 not with the inner peripheral wall of the cylinder housing 12 in contact, cannot be processed precisely, for example with a high-gloss polish or the like. The retaining ring 80 has two curved parts 881 . 882 that are in an area near the flange part 83 are shaped. A sheet metal part 88 to connect the two curved parts 881 . 882 is parallel to the axes of the piston 31 and the cylinder bore 14 , The retaining ring 80 is from the piston 31 supported, the sheet metal part 88 in the second part of the bridge 320 intervenes. Hence the retaining ring 80 using the screw 28 for firmly attaching the retaining ring 80 on the piston 31 firmly in the piston 31 integrated. For this reason, the function of the retaining ring 80 to support the side surface of the double sealing ring 51 very stable.

More supportive Example of the retaining ring

Regarding the support of the retaining ring 80 , especially a retaining ring 80 ' on the secondary side, not by the screw 28 various devices can be used to hold it in place. 3 to 7 (A) to 7 (B) show such examples. In 3 is a rubber 88r on the inner circumference of the sheet metal part 88 of the retaining ring 80 ' welded so that the retaining ring 80 ' the secondary piston 32 like a tensioned spring. In 4 is on an inner circumference of the sheet metal part 88 a head start 88t formed so that the projection 88t in one in the outer circumference of the second web part 320 formed groove or depression 320d is used. 5 is a modification of 4 , in which an element pressed upwards 88s as a projection on the inner circumference of the sheet metal part 88 is used. In 6 becomes a middle part of the retaining ring 80 ' from an e-ring 89 supported. In 7 is a nose 88n on the inner circumference of the sheet metal part 88 formed and on the outer circumference of a web part 320 out 2 is a groove 320e to pick up the nose 88n formed so that the retaining ring 80 ' on the side of the piston 32 is attached.

More supportive Example of a double sealing ring

In 8th is an O-ring 53 comprehensive inner circumferential sealing ring in one in a ring holding part 300 formed groove 300d used and only one resin ring 55 comprehensive outer circumferential sealing ring is from the retaining ring 80 supported. In the example in

8th is not only the diameter L1 of a first web part 310 but also the diameter L2 of a second web part 320 larger than the diameter L0 of the ring holding part 300 and the ratio L1> L2 is established. In an area near the ring holding part 300 there is a part 3100 with a reduced diameter, which is generally equal to the outer diameter L2 of the second web part 320 is. The Harzring 55 on the outer circumferential side is from the inside of the diameter through the second web part 320 and the reduced diameter part 3100 supported. Here, too, is the diameter L2 of the web part 320 on the piston 31 chosen larger than the inner diameter of the O-ring 53 on the inner circumferential side but equal to or smaller than the inner diameter of the resin ring 55 on the outer circumferential side. Thanks to this arrangement, the diameter of the resin ring 55 , although the diameter of the O-ring 53 , which can be deformed easily elastically and easily returns to its initial state, is likely to be stretched, not enlarged, so that it is in this state (with an enlarged diameter) on the piston 31 can be attached. At the in 8th Support form shown is the resin ring 55 on the outer circumferential side on the parts 320 . 3100 supported and receives a radially outward force by the O-ring 53 , Therefore, the resin ring 55 be supported on the outer peripheral side in a stable manner and the piston 31 can be moved more evenly.

Another example of a Additional feeder

In 9 is an additional hole 92 ' inside the piston 31 educated. Near the outer circumference of the piston 31 is, however, an opening part of the additional hole 92 ' arranged. The opening part of the additional hole 92 ' is from a lip part 532 , the part of a deformed inner circumferential sealing ring 530 is open and closed. That means it has two functions; as an additional valve for the additional feed device and as an inner circumferential sealing ring.

An example as a volume reduction device

10 shows an example with a small piston 290 as a device for reducing the volume. The little piston 290 is in one in the middle of the piston 32 formed depression 320 and is axially within the recess 320 movable. A sleeve-like link 292 is on the outer circumference of the small piston 290 placed. With this arrangement, one becomes between the outer periphery of the small piston 290 and the inner circumference of the recess 320 formed space sealed. The little piston 290 is by the spring 294 with a small preload in one of the retaining rings 80 '' biased in the opposite direction. In a normal state, one end touches the small piston 290 the bottom of the depression 320 , The deepening 320 is against the hydraulic pressure chamber 42 open. A connecting path 92 ' for connecting the well 320 with the working fluid container 18 is against deepening 320 open. Thanks to this arrangement, one end of the small piston is subject 290 the pressure from the hydraulic pressure chamber 42 and the other end thereof is subjected to the pressure from the working fluid container 18 , The little piston 290 moves on the retaining ring 80 '' too, so that when a pressure difference occurs, the pressure in the hydraulic pressure chamber 42 the volume of the hydraulic pressure chamber becomes negative compared to the container side under ambient pressure 42 downsized and the feather 294 is elastically deformed.

[Second execution]

11 Fig. 12 shows an overall sectional construction of another embodiment of a tandem master cylinder used for a brake, to which the present invention is applied. 12 Fig. 12 is a partially enlarged view showing an end part and the adjoining portion of a second piston of the master cylinder. The numbers representing the various components are essentially the same as in the first embodiment, and components that correspond to one another are essentially identified by identical numbers.

A tandem master cylinder 210 includes a cylinder housing 12 with a cylinder bore 14 that extends axially therein. On an upper part of the cylinder housing 12 there are protrusions 16a . 16b that with the cylinder bore 14 stay in contact. An integrated joint link 18 with joint parts 18a . 18b will on the protrusion parts 16a . 16b supported. In this example, a working fluid container (not shown) for storing a working fluid is separate from the cylinder housing 12 placed and stands over hoses (not shown) attached to the joint parts 18a . 18b are connected to the inside of the cylinder housing 12 in connection. The cylinder bore in the cylinder housing 12 is on the side of the cylinder bottom 12b left in 11 closed and on the side of the cylinder head 12h open on the right. The cylinder bore 14 has an inner circumference with a constant diameter. Within the cylinder bore thus constructed 14 there is a secondary piston 32 by a return spring 22 near the cylinder bottom 12b is held, another return spring 21 and a primary piston 31 all in order to the cylinder head 12h are arranged.

The primary piston 31 and the secondary piston 32 have sealing rings at two points on their outer circumference 51 . 61 ; 52 . 62 , Looking at the pistons 31 . 32 individually, are the sealing rings 51 . 61 of the primary piston 31 Disc sealing rings and O-rings. The sealing ring 62 of the secondary piston is also a plate sealing ring. These rings are single sealing rings (not double sealing rings). In contrast, the other sealing ring is the secondary piston 32 , ie the bottom of the cylinder 12b closest sealing ring 52 the double sealing ring that is at issue here. Through these sealing rings 51 . 61 ; 52 . 62 become a second hydraulic pressure chamber 42 at an innermost position within the cylinder bore 14 and a first hydraulic pressure chamber 41 between the pistons 32 . 31 educated. The pistons are in a normal state in which there is no braking 32 . 31 through the return springs 22 . 21 each in the direction of the cylinder head 12h biased. Therefore, the first and second hydraulic pressure chambers 41 . 42 in the normal state via relief openings 71 . 72 that are on the side of the cylinder housing 12 are formed in communication with the inside of an external container, which is not shown. When an operator operates the brake, the primary piston overcomes first 31 the preload force of the return spring 21 , then the secondary piston overcomes the biasing force of the return spring according to the movement on the primary side 22 and moves to the side of the cylinder bottom 12b to. Then close the plate sealing ring 51 and the double seal ring 52 the relief opening 71 respectively. 72 , The pistons 31 . 32 move forward and generate hydraulic pressure in the first and second hy draulikdruckkammer 41 . 42 ,

The master cylinder 210 According to the second embodiment of the present invention uses a double sealing ring as a sealing ring 52 for opening and closing the relief opening 72 on the secondary side. The double seal ring includes an O-ring 53 on the inner circumferential side of the master cylinder 210 and a resin ring 55 on the outer circumferential side. As already mentioned, the double sealing ring has the advantage on the one hand that it is less damaged, but on the other hand the disadvantage that the requirement for an additional liquid supply has to be met. Here is the secondary piston 32 on an end face part of the piston body 132 a disc seal ring 65 , so that working fluid from the side of the working fluid container into the second hydraulic pressure chamber 42 can be fed. The piston body 132 and the circumference of the secondary piston 32 have a connection path in addition to a groove in the end face 90 to the hydraulic pressure chamber 42 with the inside of the joint part 18 to connect. An opening part of the connecting path 90 is through the disc sealing ring 65 sealed. If, therefore, a negative pressure in the hydraulic pressure chamber due to an abrupt braking operation or an anti-lock control 42 is generated on a front and rear lip part of the plate sealing ring 65 a pressure difference, like in the plate sealing ring 51 of the primary piston 31 , Due to the effect of this pressure difference, the lip collapses, so that working fluid from the side of the working fluid container through the joint part 18b and the connecting path 90 into the hydraulic pressure chamber 42 is fed. The connection path 90 includes a room 94 on the lateral circumference of the piston body 132 and one in the cylinder housing 12 additional hole formed 96 , in addition to that in the piston body 132 of the secondary piston 32 formed relief opening 92 , The plate sealing ring 65 is used as an additional valve through the retaining ring 28 which also acts as a spring retainer for the return spring 22 serves to prevent loosening.

The second embodiment of the present invention is characterized in that the piston body 132 even a prescribed tapered part 280 has to the assembly ability of the double sealing ring 52 to improve that of the secondary piston 32 includes. How out 12 , which shows the secondary side in a partially enlarged scale, is more recognizable, is in the master cylinder 210 , although an outer configuration of the first web 2310 adjacent to a mounting groove 2300 into which the double sealing ring 52 can be used, parallel to the axis of the piston body 132 is the configuration of the outer periphery of the other second land part 2320 near the face of the piston body 132 a tapered part, the outer diameter of an inserted end part X, which serves as an inserted opening when the sealing ring in the mounting groove 2300 is used, gradually increases. In addition, the outside diameter of the tapered part 230 on the side of the second web part 2320 near the mounting groove 2300 the biggest. However, this largest diameter is slightly smaller than the outer diameter of the first web part 2310 , Regarding the ratio to the inner diameter of the resin ring 55 as the outer circumferential sealing ring, is the outer diameter of the mounting groove 2300 smaller than the inner diameter of the resin ring 55 and the outer diameter of the first web part 2310 is larger than the inner diameter of the resin ring 55 , In contrast, when looking at the tapered part 280 of the second web part 2310 the outer diameter at the end part X used is smaller than the inner diameter of the resin ring 55 , while the outer diameter of a part near the mounting groove 2300 is larger than the inner diameter of the resin ring 55 , Therefore, the tapered part 280 of the inserted end part X to the fastening groove 2300 can be used effectively as a tool for the uniform fastening of not only the inner circumferential sealing ring, which is the O-ring 53 includes, but also the outer circumferential sealing ring that the resin ring 55 includes, in the mounting groove 2300 to support. For this reason, besides the piston body 132 no other special tools required. The double sealing ring can easily be installed with it. Especially when the outside diameter of the tapered part 280 of the second web part 2320 in an area near the mounting groove 2300 is chosen smaller than the outer diameter of the first web part 2310 , the resin ring 55 are easier to assemble. It can also adjust the flow resistance in an area near the opening part of the relief opening 72 on the side of the cylinder housing 12 reduce so that fluid is more even from the hydraulic pressure chamber 42 flows back to the side of the container. In other words, the tapered part supports 280 as a whole, the simple assembly of the sealing ring. In addition, the second bridge part 2320 the advantage (advantage resulting from the elimination of the throttle function) that part of the tapered part 280 close to the mounting groove 2300 not only supports the simple assembly, but also the smooth flow of the liquid that flows back into the working liquid container.

Another example of the tapered Part

13 shows an example in which a region of the second web part 2320 from the inserted end part X to the fastening groove 2300 is partially tapered. Consider the second part of the bridge 2320 at the end part X used with reference to 13 , has the second bridge part 2320 a smaller outer diameter than the first web part 2310 from the inserted end part X to a location X 'in the middle between the used end part X and the mounting groove 2300 , However, the configuration of the outer periphery of the tapered part is parallel to the axis of the piston body 132 , as with the first bridge section 2310 , The area or part of the central position X 'of the second web 2320 to the fastening groove 2300 , ie the area or part of the second web part 2320 near the mounting groove 2300 is partially rejuvenated 2800 , The outside diameter of this tapered part 2800 takes from the side of the inserted end part X (or center position (X) to the fastening groove 2300 gradually, as in the aforementioned tapered part 280 , The tapered part 2800 is located in an area that corresponds to the opening of the relief opening 72 on the side of the cylinder housing 12 opposite, so that a gap path between the inner wall of the cylinder housing 12 and the second web part 2320 is enlarged. This causes the flow resistance between the relief opening 72 and the second hydraulic pressure chamber 42 reduced, so that the backflow of fluid from the second hydraulic pressure chamber 42 to the working oil tank takes place evenly. In this other example, the second web part is used 2320 including the tapered part 2800 as a tool for fastening the sealing ring, since the outer diameter of the end part X used is also selected to be smaller than the inner diameter of the resin ring 55 as an outer circumferential sealing ring.

During the study of the behavior of the double sealing ring or the sealing mechanism, we sometimes encounter the phenomenon that the sealing ring of the outer circumference is temporarily inclined and increases the sliding resistance. This phenomenon is illustrated by the 14 (A) - 14 (B) and 15 clarified. 14 (A) and 14 (B) are partial sectional views showing the states of the double seal ring 52 on the outer circumference of the piston 32 show where 14 (A) the double sealing ring 52 shows when it is attached and 14 (B) the double sealing ring 52 shows when exposed to hydraulic pressure. The piston 32 has a fastening groove on its outer circumference 2300 , An o-ring 53 is attached to a lower part, that is, the inner peripheral side of the mounting groove 2300 and a resin ring 55 is on the outer peripheral side of the mounting groove 2300 appropriate. The o-ring 53 as an inner circumferential sealing ring has a round cross-section before fastening, which, however, becomes rectangular after fastening. In 14 (A) is the hydraulic pressure chamber 42 in the cylinder housing 12 via the relief opening 72 opened against the side of the working fluid container. As in 14 (A) the cross-section of the O-ring is shown 53 rectangular when it is on the piston 32 is attached and the width of the O-ring 53 is slightly larger than that of the resin ring 55 , In contrast, the O-ring 53 and the resin ring 55 in 14 (B) almost the same width. 14 (B) shows a state of the double seal ring 52 in which the double sealing ring 52 itself as a sealing part over the other end of the relief opening 72 extends out and so the connection between the hydraulic pressure chamber 42 and the working fluid container via the relief opening 72 blocked. For this reason, the hydraulic pressure in the hydraulic pressure chamber 42 increased and the double sealing ring 52 is the effect of the hydraulic pressure from the hydraulic pressure chamber 42 exposed. As a result, the O-ring 53 , which can be easily elastically deformed by the hydraulic pressure from the hydraulic pressure chamber 42 pushed away, reducing the width of the ring. As a result, the outer peripheral resin ring 55 with increased force from the O-ring 53 forced. However, observations have shown that the outer perimeter resin ring 55 through the power of the O-ring 53 is tilted clockwise or tends to fall.

15 is a graph showing a relationship between stroke and sliding resistance, the stroke (ie the pressure path) of the piston 32 along the abscissa and that on the piston 32 acting sliding resistance is plotted along the ordinate. Like the dashed line in 15 shows, there is a part Y in which the sliding resistance is temporarily increased at an initial stage of the printing process. This part Y arises due to the inclination of the resin ring 55 and affects the smooth movement of the piston 32 or the double sealing ring 52 , Such an increase in sliding resistance (or interruption) leads to a temporary delay in the increase in hydraulic pressure in the initial stage of actuation or is perceived as a malfunction in operation. If the resin ring 55 as the outer sealing ring in the first stage of the printing process and the piston 32 the piston returns to this inclined state 32 not enough and there is a fear that the hydraulic pressure cannot be reduced sufficiently.

The inner circumferential sealing ring 53 is an O-ring made of either elastic molecular elastomer based on ethylene propylene terpolymer or ethylene propylene rubber. These materials are oil-resistant to non-petroleum brake fluid for motor vehicles and heat-resistant up to over 120 ° C. On the other hand, there is the outer circumferential sealing ring 55 made of ethylene tetrafluoride resin and is harder than the inner circumferential sealing ring 53 , The Shore hardness of the outer peripheral seal ring 55 is Hs 80 to ms 90 , Inner and outer circumferential seal ring configurations 53 . 55 are known per se. The inner circumferential sealing ring 53 as an O-ring has a circular cross-section before, as mentioned before, in the mounting groove 2300 is attached. After being in the mounting groove 2300 attached or inserted therein, its cross section is rectangular. When the hydraulic pressure came in the hydraulic pressure mer 42 increases, its width is relatively reduced. The O-ring used here has a Shore hardness of Hs 55 to ms 65 and preferably from ms 60 , This O-ring is compared to conventional O-rings with Shore hardness from Hs 65 to ms 75 less hard. The O-ring can be reduced by reducing the hardness 53 easier on the mounting groove 2300 Fasten. It also becomes the outer peripheral seal ring in the first stage of operation 55 not slanted. Experiments have confirmed that the part Y (see dashed line) in which the sliding resistance is temporarily increased is eliminated.

As a method for eliminating the part Y in which the sliding resistance is temporarily increased, as in 16 (A) shown the side surface 2300A (Side surface on the of the hydraulic pressure chamber 42 far side) of the mounting groove 2300 and the side surface 55a of the outer circumferential sealing ring which touches this side surface can be made rougher, for example with 100 Dm, or that of the hydraulic pressure chamber 42 removed side surface 2300A can, as in 16 (B) shown with a graduated part 2330 be provided. This in 16 (A) - 16 (B) The methods shown use a support device against the force that causes the outer circumferential sealing ring 55 is inclined. The shore hardness itself of the O-ring 53 as an inner circumferential sealing ring, Hs 55 to ms 65 or ms 65 to ms 75 be. The graduated part 2330 is designed so that it is perpendicular to the side surface 2300A the mounting groove 2300 is (ie parallel to the axes of the cylinder bore 14 and the cylinder housing 12 ). It is also preferred that an angled part 553 the lower part of the outer peripheral sealing ring 55 that is placed on the stepped part is not beveled, or that the bevel is reduced, prevents the inclination more reliably.

Although the inner wall of the cylinder bore 14 of the cylinder body made of an aluminum alloy 12 is subjected to an anodic oxidation treatment and the outer circumferential sealing ring 55 is made from a material with low frictional resistance, it is preferable that the insufficient return of the primary and secondary pistons 31 . 32 , especially the secondary piston 32 , thereby reliably preventing that through the sealing rings of the primary and secondary pistons 31 . 32 caused sliding resistance is made even. For this purpose, it is preferable that the pressure force of the disc seal ring 51 on the primary side against the cylinder housing 12 is chosen smaller than the pressure force of the sealing ring 52 on the secondary side against the cylinder housing 12 , For example, it is preferable that the span is on the plate sealing ring 51 comprehensive primary side is set to 0.6 mm to 1.0 mm, while the span on the secondary side comprising the double sealing ring is set to 0.1 to 0.35 mm.

The piston 32 includes a conical tapered part 280 between that of the hydraulic pressure chamber 42 opposite end face and the fastening groove 2300 , The diameter of the tapered part 280 takes from the face to the mounting groove 2300 gradually towards. Its on the mounting groove 2300 adjacent part 280a is a web that is parallel to the axes of the cylinder bore 14 and the cylinder housing 12 is (see 16 (A) - 16 (B) ).

Claims (22)

Master cylinder with a cylinder housing ( 12 ) in which there is a cylinder bore ( 14 ), which extends in its axial direction, a piston ( 31 . 32 ), which slidably in the in the cylinder housing ( 12 ) shaped cylinder bore ( 14 ) is inserted, the piston with the cylinder housing a hydraulic pressure chamber ( 41 . 42 ) in the cylinder bore ( 14 ) forms a return spring ( 21 . 22 ) to the piston ( 31 . 32 ) axially into one of the hydraulic pressure chambers ( 41 . 42 ) to bias in the opposite direction to a rest position, one in a side circumference of the cylinder housing ( 12 ) formed relief opening ( 71 . 72 ), one end of the relief opening with the hydraulic pressure chamber ( 41 . 42 ) is connected when the piston is in the rest position and the other end of the relief opening is connected to a working fluid container and one around an outer circumference of the piston ( 31 . 32 ) placed double sealing ring ( 51 . 52 ) to the relief opening ( 71 . 72 ) in response to a stroke of the piston ( 31 . 32 ) towards the hydraulic pressure chamber ( 41 . 42 ) with the double sealing ring ( 51 . 52 ) an inner circumferential sealing ring ( 53 ) made of elastic material and an outer circumferential sealing ring ( 55 ) made of harder material than the inner circumferential sealing ring ( 53 ) and the outer circumferential sealing ring ( 55 ) on an outer circumference of the inner sealing ring ( 53 ) with the piston ( 31 . 32 ) a ring holding part ( 300 ) with an outer diameter L0 to hold the double sealing ring ( 51 . 52 ), a first web part ( 310 ) adjacent to the ring holding part ( 300 ) and with an outer diameter L1 (wherein L1> L0), characterized in that the piston also has a second web part ( 320 ) adjacent to an opposite side of the ring holding part ( 300 ) on the first part of the web ( 310 ) and the second part of the web ( 320 ) has an outer diameter L2 (where L2 <L1), the outer diameter L2 of the second web part ( 320 ) is equal to or smaller than an inner diameter of the outer circumferential sealing ring ( 55 ), a side surface of the outer peripheral seal ring ( 55 ) on the side of the second web part ( 320 ) from one to the its piston ( 31 . 32 ) attached retaining ring ( 80 . 80 ' . 80 '' ) is supported. Master cylinder according to claim 1, wherein the piston ( 31 . 32 ) a connecting path ( 90 ) for connecting the working fluid container to the hydraulic pressure chamber ( 41 . 42 ) and an additional valve ( 65 ) for feeding an additional working fluid from the working fluid container through the connecting path ( 90 ) includes. Master cylinder according to claim 1, wherein the piston ( 31 . 32 ) a small flask ( 290 ) carries one end of pressure from the hydraulic pressure chamber ( 41 . 42 ) and the other end of which is exposed to pressure from the working fluid container, and if a pressure difference occurs, the pressure of the hydraulic pressure chamber ( 41 . 42 ) becomes negative with regard to a working fluid container with ambient pressure, the small piston ( 290 ) moves so that the volume of the hydraulic pressure chamber ( 41 . 42 ) is reduced. Master cylinder according to one of claims 1 to 3, wherein the inner and outer peripheral sealing ring ( 53 . 55 ) on the side surfaces on the side of the first web part ( 310 ) through a side wall of the first web part ( 310 ) are supported. Master cylinder according to one of claims 1 to 4, wherein the outer diameter L2 of the second web part ( 320 ) is equal to the outer diameter L0 of the ring holding part ( 300 ) and the retaining ring ( 80 ) the side surface of the inner circumferential sealing ring ( 53 ) on the side of the second web part ( 320 ) together with the outer circumferential sealing ring ( 55 ) supports. Master cylinder according to one of claims 1 to 4, wherein a ratio L2> L0 is established and the side surface of the inner peripheral sealing ring ( 53 ) on the side of the second web part ( 320 ) from a side wall of the second web part ( 320 ) is supported. Master cylinder according to one of the preceding claims, wherein the Shore hardness of the inner circumferential sealing ring ( 53 ) Hs 55 to Hs 65 and the Shore hardness of the outer circumferential sealing ring ( 55 ) Hs 80 to Hs 90. Master cylinder according to one of the preceding claims, wherein a material of the inner circumferential sealing ring ( 53 ) is an elastic molecular elastomer based on ethylene propylene terpolymer or ethylene propylene rubber and is a material of the outer circumferential sealing ring ( 55 ) Is ethylene tetrafluoride resin. Master cylinder according to one of the preceding claims, wherein a material of the cylinder housing ( 12 ) is an aluminum alloy and a seal sliding surface of the cylinder bore ( 14 ) on which the double sealing ring ( 51 . 52 ) can slide, is coated with an anodic oxide film. Master cylinder according to one of the preceding claims, wherein the master cylinder is a tandem master cylinder and the cylinder bore ( 14 ) in an axial direction from a head side ( 12h ) to a bottom side ( 12b ) extends, the cylinder a primary piston ( 31 ) inside the cylinder bore on the head side ( 12h ) and a secondary piston ( 32 ) inside the cylinder bore on the bottom side ( 12h ), the pistons ( 31 . 32 ) a front and a rear sealing ring on a front and a rear part of the same ( 51 . 52 ; 61 . 62 ) with the pistons ( 31 . 32 ) a first hydraulic pressure chamber ( 41 ) between the primary piston ( 31 ) and the secondary piston ( 32 ), a second hydraulic pressure chamber ( 42 ) between the front sealing ring ( 52 ) of the secondary piston ( 32 ) and the underside of the cylinder housing ( 12 ) and in the side surfaces of the primary and secondary pistons ( 31 . 32 ) shaped liquid addition chambers ( 94 ) between the front sealing ring ( 51 . 52 ) and the rear sealing ring ( 61 . 62 ), the liquid addition chambers ( 94 ) through a wall surface of the cylinder housing ( 12 ) extending additional hole ( 96 ) are connected to a working fluid container, whereby the front sealing ring ( 52 ) of the secondary piston ( 32 ) includes the double sealing ring and the secondary piston encompasses the piston. Master cylinder according to claim 10, wherein the front sealing ring ( 51 ) of the primary piston ( 31 ) is a plate sealing ring and one through this plate sealing ring onto an inner wall of the cylinder housing ( 12 ) the compressive force exerted is small compared to that exerted by the double sealing ring ( 52 ) on the inner wall of the cylinder housing ( 12 ) pressure applied. Master cylinder with a cylinder housing ( 12 ) in which there is a cylinder bore ( 14 ), which extends in its axial direction, a piston ( 31 . 32 ), which slidably in the in the cylinder housing ( 12 ) shaped cylinder bore ( 14 ) is inserted, the piston with the cylinder housing a hydraulic pressure chamber ( 41 . 42 ) in the cylinder bore ( 14 ) forms a return spring ( 21 . 22 ) to the piston ( 31 . 32 ) axially into one of the hydraulic pressure chambers ( 41 . 42 ) to bias in the opposite direction to a rest position, one in a side circumference of the cylinder housing ( 12 ) formed relief opening ( 71 ), ( 72 ), one end of which is connected to the hydraulic pressure chamber ( 41 . 42 ) is connected when the piston is in the rest position and the other res end is connected to a working fluid container, and one around an outer periphery of the piston ( 31 . 32 ) placed double sealing ring around the relief opening ( 71 . 72 ) in response to a stroke of the piston ( 31 . 32 ) towards the hydraulic pressure chamber ( 41 . 42 ) to block, the double sealing ring an inner peripheral sealing ring ( 53 ) made of elastic material and an outer circumferential sealing ring ( 55 ) made of harder material than the inner circumferential sealing ring ( 53 ) and the outer circumferential sealing ring ( 55 ) on an outer circumference of the inner sealing ring ( 53 ), characterized in that the piston ( 32 ) a piston body ( 132 ) with an inserted (X) end part, which is the hydraulic pressure chamber ( 42 ) is opposite and serves as an inserted input if the double sealing ring ( 52 ) is mounted, one of the inserted end part (X) of the piston body ( 132 ) in one of the hydraulic pressure chambers ( 42 ) opposite fastening groove ( 2300 ) into which the double sealing ring ( 52 ) is used, a first web part ( 2310 ) adjacent to the mounting groove ( 2300 ) and the mounting groove ( 2300 ) lying opposite the inserted end part (X) and a second web part ( 2320 ), regarding the mounting groove ( 2300 ) on the opposite side to the first web part ( 2310 ) adjacent, which is on the same side as the inserted end part (X), the master cylinder fulfilling the following conditions A and B: A) the outer diameter of the inserted end part (X) of the piston body ( 132 ) is smaller than the inner diameter of the outer circumferential sealing ring ( 55 ) and the outer diameter of the first and second web part ( 2310 . 2320 ) adjacent to the mounting groove ( 2300 ) are larger than the inner diameter of the outer circumferential sealing ring ( 55 ); and B) between the inserted end part (X) and the fastening groove ( 2300 ) of the piston body ( 132 ) there is a tapered part ( 280 ), whose outer diameter from the inserted end part (X) to the fastening groove ( 2300 ) gradually increases. Master cylinder according to claim 12, wherein the piston ( 32 ) a connecting path ( 90 ) for connecting the working fluid container to the hydraulic pressure chamber ( 42 ) and an additional valve ( 65 ) for feeding an additional working fluid from the working fluid container through the connecting path ( 90 ) includes. Master cylinder according to claim 12, wherein the piston ( 32 ) a small flask ( 290 ) carries one end of pressure from the hydraulic pressure chamber ( 42 ) and the other end of which is exposed to pressure from the working fluid container, and if a pressure difference occurs, the pressure of the hydraulic pressure chamber ( 42 ) becomes negative with regard to a working fluid container with ambient pressure, the small piston ( 290 ) moves so that the volume of the hydraulic pressure chamber ( 42 ) is reduced. Master cylinder according to one of claims 12 to 14, wherein the outer diameter of the second web part ( 2320 ) on the same side as the inserted end part (X) is smaller than the outer diameter of the first web part ( 2310 ). Master cylinder according to one of claims 12 to 15, wherein the tapered part ( 280 ) over the entire length from the inserted end part (X) to the fastening groove ( 2300 ) extends. Master cylinder according to one of claims 12 to 14, wherein the tapered part ( 280 ) at least on one of the openings of the relief opening ( 72 ) on the side of the cylinder housing ( 12 ) opposite part when the piston is in the rest position, so that the flow resistance of a working fluid between the hydraulic pressure chamber ( 42 ) and the relief opening ( 72 ) can be reduced. Master cylinder according to one of claims 12 to 17, wherein a Shore hardness of the inner circumferential sealing ring ( 53 ) Hs is 55 to 65 and a Shore hardness of the outer circumferential sealing ring ( 55 ) Hs 80 to Hs 90. Master cylinder according to one of claims 12 to 18, wherein a material of the inner circumferential sealing ring ( 53 ) is an elastic molecular elastomer based on ethylene propylene terpolymer or ethylene propylene rubber and is a material of the outer circumferential sealing ring ( 55 ) Is ethylene tetrafluoride resin. Master cylinder according to one of claims 12 to 19, wherein a material of the cylinder housing ( 12 ) is an aluminum alloy and a seal sliding surface of the cylinder bore ( 14 ) on which the double sealing ring ( 52 ) can slide, is coated with an anodic oxide film. Master cylinder according to one of claims 12 to 20, wherein the master cylinder is a tandem master cylinder in which the cylinder bore ( 14 ) in an axial direction from a head side ( 12h ) to a bottom side ( 12b ) extends, the cylinder a primary piston ( 31 ) on the head side ( 12h ) within this in the cylinder housing ( 12 ) shaped cylinder bore ( 14 ) and a secondary piston ( 32 ) on the bottom side ( 12b ) within this in the cylinder housing ( 12 ) shaped cylinder bore ( 14 ), the pistons ( 31 . 32 ) hold a front and a rear sealing ring on a front and a rear part thereof, the Piston ( 31 . 32 ) a first hydraulic pressure chamber ( 41 ) between the primary piston ( 31 ) and the secondary piston ( 32 ), a second hydraulic pressure chamber ( 42 ) between the front sealing ring ( 52 ) of the secondary piston ( 32 ) and the bottom side ( 12b ) of the cylinder housing ( 12 ) and in the side surfaces of the primary and secondary pistons ( 31 . 32 ) between the front sealing ring ( 51 . 52 ) and the rear sealing ring ( 61 . 62 ) liquid addition chambers formed ( 94 ), the liquid addition chambers ( 94 ) through a wall surface of the cylinder housing ( 12 ) extending additional hole ( 96 ) are connected to a working fluid container, whereby the front sealing ring ( 52 ) of the secondary piston ( 32 ) includes the double sealing ring and the secondary piston encompasses the piston. A master cylinder according to claim 21, wherein the front seal ring ( 51 ) of the primary piston ( 31 ) is a plate sealing ring and one through the plate sealing ring onto an inner wall of the cylinder housing ( 12 ) the compressive force exerted is small compared to that exerted by the double sealing ring ( 52 ) on the inner wall of the cylinder housing ( 12 ) pressure applied.