DE202015104365U1 - Bicycle hydraulic operating system - Google Patents

Abstract

A bicycle hydraulic operating system, comprising: a hydraulic operating device; a hydraulically operated device fluidly connected to the hydraulic control device via a hydraulic line; and a control mechanism that regulates an internal volume of the hydraulic line depending on the temperature.

Description

TECHNICAL AREA

The subject matter of the present utility model relates to a bicycle hydraulic operating system.

BACKGROUND

In the field of bicycles, various hydraulic control systems have been proposed and implemented. An example of a widely used hydraulic control system is a hydraulic brake system. In the hydraulic brake system, a piston is moved in a hydraulic cylinder in response to pivoting of a brake lever. The movement of the piston expels fluid (eg, mineral oil) from the hydraulic cylinder. A hydraulic hose connecting the hydraulic cylinder to a caliper delivers the fluid to the caliper. The fluid drives a piston in the caliper. As a result, the caliper generates a braking force.

SUMMARY

In the hydraulic brake system, a change in the temperature of a hydraulic line containing fluid may, for example, change the position of the brake lever or change the distance from a friction element of the caliper to a rotor or a wheel rim.

It is an object of the subject matter of the present utility model to provide a bicycle hydraulic operating system that improves the operational stability with respect to changes in the temperature of a hydraulic line.

One aspect of the subject matter of the present utility model is a bicycle hydraulic operating system including a hydraulic operating device, a hydraulically operated device fluidly connected to the hydraulic operating device via a hydraulic line, and a regulating mechanism that regulates an internal volume of the hydraulic line depending on the temperature.

In a preferred embodiment, the control mechanism comprises a variable volume chamber located in the hydraulic line.

In a preferred embodiment, the variable volume chamber is defined by a cylinder and a piston which is movable in the cylinder.

In a preferred embodiment, the control mechanism includes a detector that detects information regarding the temperature of the bicycle hydraulic operating system, a drive that drives the piston, and a controller that controls the drive based on the detection of the detector.

In a preferred embodiment, the detector detects a temperature of the fluid, an ambient temperature about the hydraulic line, a temperature of the hydraulic control device, a temperature of the hydraulically operated device, or any combination thereof.

In a preferred embodiment, the controller includes a memory that stores information regarding positions of the piston corresponding to the detections of the detector and a processor that controls the drive based on the detection of the detector and information regarding the position of the piston.

In a preferred embodiment, the variable volume chamber includes an expandable portion which expands and contracts in response to the temperature of the fluid.

In a preferred embodiment, the expandable portion is configured to receive the fluid.

In a preferred embodiment, the expandable portion is dome shaped.

In a preferred embodiment, the variable volume chamber is defined by a cylinder and a piston movable in the cylinder, and the expandable portion is adapted to support the piston in the cylinder.

Another aspect of the subject matter of the present utility model is a bicycle hydraulic operating system including a hydraulic operating device, a hydraulically operated device fluidly connected to the hydraulic operating device via a hydraulic line, and a regulating mechanism having an internal volume of the hydraulic line depending on the pressure of the fluid regulated in the hydraulic line. The control mechanism includes a detector that detects pressure of the hydraulic line, a drive that drives a piston, and a controller that controls the drive based on the detection of the detector. The control device is configured to vary the volume of a variable volume chamber with the piston and the drive, so that the pressure of the hydraulic line is kept at a set value when the Hydraulic operating device is not operated and thus is in a state of rest.

In a preferred embodiment, the bicycle hydraulic operating system is of a closed type that is free of a fluid container.

Other aspects and advantages of the subject matter of the present invention will become apparent from the following description when taken in conjunction with the accompanying drawings which exemplify the subject matter of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter of the present invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments, taken in conjunction with the accompanying drawings, in which:

1 Fig. 12 is a schematic diagram showing an embodiment of a bicycle hydraulic operating system;

2 a schematic diagram of a control mechanism is;

3 Fig. 12 is a schematic diagram showing a control mechanism in a first modification; and

4 Fig. 10 is a schematic diagram showing a control mechanism in a second modification.

DESCRIPTION OF THE EMBODIMENTS

A bicycle hydraulic operating system according to an embodiment of the subject matter of the present invention will now be described. If you take reference 1 includes the bicycle hydraulic operating system 10 a hydraulic operating device 20 , a hydraulically operated device 30 and a control mechanism 50 , A hydraulic line R, through which a fluid is circulated, connects the hydraulic operating device 20 and the hydraulically operated device 30 , The regulatory mechanism 50 Regulates the internal volume of the hydraulic line R as a function of the temperature of the hydraulic line R.

In general, a change in the temperature of a hydraulic line may alter the operating profile of the hydraulic control system. More specifically, the temperature and / or operation of the hydraulic control system changes the temperature of the hydraulic line, which in turn varies the volume of the fluid. This may change the operating profile of the hydraulic control system.

Thus, in the bicycle hydraulic operating system 10 of the present embodiment, to substantially compensate for the changes in the operating profile caused by changes in the temperature of the hydraulic line R, the control mechanism 50 designed to vary the internal volume of the hydraulic line R as a function of the temperature of the hydraulic line R. The regulatory mechanism 50 reduces or prevents changes to the operating profile of the bicycle hydraulic operating system 10 that would be caused by changes in the temperature of the hydraulic line R. The regulatory mechanism 50 contributes to the operational stability of the bicycle hydraulic operating system 10 in terms of changes in the temperature of the hydraulic line R to improve.

Each element of the bicycle hydraulic control system 10 will now be described. That in the 1 shown bicycle hydraulic control system 10 is a bicycle hydraulic disc brake system.

The hydraulic operating device 20 , which is a so-called brake lever device is attached to a handlebar HB, which is fixed to a bicycle stem. The handlebar HB can be a racing handlebar or another type of handlebar. The hydraulic operating device 20 includes a lever 22 , a hydraulic cylinder 24 , a piston 26 and a connecting element 28 , The hydraulic operating device 20 does not have a fluid container. Accordingly, the bicycle hydraulic operating system 10 of a so-called closed type.

The lever 22 is through a swivel axle 29 is mounted and pivoted about a lever pivot axis X1 between a rest position P1 and a operated position P2. The lever 22 can be a cam surface 22a include. The cam surface 22a may be a section of a separate component that works with the lever 22 connected is.

The hydraulic cylinder 24 includes a hole 24a , The piston 26 (Main piston) is in the hole 24a of the hydraulic cylinder 24 arranged and is moved between a starting position and an actuating position. A piston return spring 26a urges the piston 26 to the starting position. The piston return spring 26a For example, a compression spring that is connected to the piston 26 and the hydraulic cylinders 24 engaged or connected and engaged in the bore 24a located.

The connecting element 28 connects the lever 22 (eg a cam surface 22a ) and the piston 26 so that the piston 26 is moved from the home position to the operating position when the lever 22 is pivoted from the rest position P1 in the operated position P2. The connecting element 28 is at the lever 22 pivotally coupled about the pivot axis X2. The connecting element 28 includes a length adjustment structure 28a covering the entire length of the connecting element 28 established. When the bicycle hydraulic control system 10 is of a closed type, the entire length of the connecting element becomes 28 adjusted to the position or the angle of play of the lever 22 adjust. The hydraulic operating device 20 may include a known range adjustment structure in the bicycle hydraulic brake.

The hydraulic hose 40 connects the hydraulic control device 20 fluidic with the hydraulically operated device 30 ,

The hydraulically operated device 30 is a so-called caliper (here a disc brake caliper) and includes at least one piston 32 (Secondary piston), which is on a brake body 36 suppressed. The piston 32 is in the hydraulic cylinder bore 34 the hydraulically operated device 30 arranged. When the hydraulic operating device 20 is operated, the piston presses 32 the brake body 36 which is a friction member against a disc rotor DR. Accordingly, the hydraulically operated device generates 30 a braking force. In this embodiment, the hydraulically operated device comprises 30 two pistons 32 ,

The hydraulic operating device 20 , the hydraulically operated device 30 and the hydraulic hose 40 are known in the art and will not be described in detail. In the present embodiment, the hydraulic pipe R is defined as a portion through which fluid circulates from the piston 26 to the piston 32 to be led.

The regulatory mechanism 50 will now be referring to 2 described.

The regulatory mechanism 50 includes a chamber 52 with variable volume, located in the hydraulic hose 40 the hydraulic line R is located. The chamber 52 with variable volume is through a cylinder 52a and a piston 52b defined in the cylinder 52a is mobile. The regulatory mechanism 50 includes a detector 54 , the information relating to the temperature of the bicycle hydraulic operating system 10 detected, a drive 56 that the piston 52b drives, and a control device 58 that the drive 56 based on the detection of the detector 54 controls.

The chamber 52 variable volume is located between the hydraulic cylinder 24 the hydraulic operating device 20 and the hydraulic cylinder bore 34 the hydraulically operated device 30 , The chamber 52 with variable volume located in the hydraulic hose 40 as in the 1 and 2 shown. Furthermore, the chamber 52 variable volume ones, one or more fluid passages, which allow fluid in and out of the chamber 52 flows. A chamber 52 variable volume, which includes a plurality of fluid passages is, for example, in an intermediate portion of the hydraulic hose 40 , A chamber 52 With variable volume, which includes a single fluid passage can be retrofitted in the hydraulic line R, for example, by a three-way valve at an intermediate portion of the hydraulic hose 40 is connected. The chamber 52 Variable volume does not have to be in the hydraulic hose 40 are located. The variable volume chamber 52 may be located in a connector that houses the hydraulic hose 40 and the hydraulic operating device 20 connects, or in a connecting element, the hydraulic hose 40 and the hydraulically operated device 30 combines.

The detector 54 includes a temperature sensor that includes a detector that directly or indirectly determines the temperature of the bicycle hydraulic handling system 10 detected. The detector 54 measures or monitors the temperature of the fluid, the ambient temperature around the hydraulic line R, the temperature of the hydraulic control device 20 , the temperature of the hydraulically operated device 30 or any combination thereof, to detect a temperature with respect to the hydraulic line R. There is no particular limitation on where and how the detector 54 the temperature detected. The detector 54 supplies the control device 58 with a detection signal indicating the detection.

The control device 58 includes a memory 58a , the information relating to positions of the piston 52b according to the detections of the detector 54 stores, and a processor 58b that the drive 56 based on the detection of the detector 54 and information regarding the position of the piston 52b controls. The control device 58 is with the detector 54 and the drive 56 connected via a wired connection or a wireless connection. The location of the control device 58 is not particularly limited.

The memory 58a can be a table, an illustration or an arithmetic expression saved in advance by experiments or simulations. It is preferred that the table, map or arithmetic expression be based on thermal changes in the operating profile of the hydraulic control system, which are measured in advance by experiments or simulations. If the thermal distortion of mechanical components relative to changes in the volume of the fluid is negligible and thus ignorable, the table, map, or arithmetic expression may be based on thermal volume changes of the fluid, measured in advance by experiment or simulation. The processor 58b generates a control signal in response to the detection signal of the detector 54 and supplies the control signal to the drive 56 ,

Under the control of the control device 58 varies the drive 56 forcibly the internal volume of the hydraulic line R as a function of the temperature with respect to the hydraulic line R. For example, as the temperature of the hydraulic line R increases, the drive moves 56 the piston 52b to the volume of the chamber 52 to increase with variable volume. The drive 56 includes a motor 56a and a gearbox 56b that the engine 56a and the piston 52b effectively connects. The gear 56b is for example a ball screw. However, the drive is 56 not limited to such a structure and may be a linear actuator.

• (1) Der Regelmechanismus 50 reguliert das interne Volumen der Hydraulikleitung R in Abhängigkeit von der Temperatur in Bezug auf die Hydraulikleitung R. Dies verringert oder beseitigt den Einfluss der Wärmeausdehnung und der Wärmekontraktion bei dem Fahrrad-Hydraulikbedienungssystem 10. Beispielsweise werden Veränderungen bei dem Abstand zwischen dem Bremskörper 36 und dem Scheibenrotor DR, die durch Veränderungen der Temperatur der Hydraulikleitung R bewirkt würden, verringert oder vermieden. Ferner werden Veränderungen bei der Position oder dem Spielwinkel des Hebels 22, die durch Veränderungen der Temperatur der Hydraulikleitung R bewirkt würden, verringert oder vermieden. Dementsprechend werden Veränderung beim durch den Fahrer wahrgenommenen Bedienungsgefühl, die durch Veränderungen der Temperatur der Hydraulikleitung R bewirkt werden, verringert oder vermieden.

The advantages of the bicycle hydraulic operating system 10 will now be described.

• (1) The regulatory mechanism 50 regulates the internal volume of the hydraulic line R as a function of the temperature with respect to the hydraulic line R. This reduces or eliminates the influence of the thermal expansion and the thermal contraction in the bicycle hydraulic operating system 10 , For example, changes in the distance between the brake body 36 and the disc rotor DR, which would be caused by changes in the temperature of the hydraulic line R, reduced or avoided. Further, changes in the position or the angle of play of the lever 22 that would be caused by changes in the temperature of the hydraulic line R, reduced or avoided. Accordingly, changes in the operating feeling perceived by the driver caused by changes in the temperature of the hydraulic pipe R are reduced or avoided.

• (2) Der Regelmechanismus 50 umfasst die Kammer 52 mit variablem Volumen, die sich in der Hydraulikleitung R befindet. Bei dieser Struktur verändert sich das Volumen der Kammer 52 mit variablem Volumen in Abhängigkeit von der Temperatur in Bezug auf die Hydraulikleitung R. Dies verringert oder kompensiert wärmebedingte Veränderungen am Betriebsprofil des Fahrrad-Hydraulikbedienungssystems 10. Dementsprechend kann die Betriebsstabilität des Fahrrad-Hydraulikbedienungssystems 10 verbessert werden.
• (3) Die Kammer 52 mit variablem Volumen wird durch den Zylinder 52a und den Kolben 52b definiert, der in dem Zylinder 52a beweglich ist. Bei dieser Struktur bewegt sich der Kolben 52b in Abhängigkeit von der Temperatur in Bezug auf die Hydraulikleitung R, um das Volumen der Kammer 52 mit variablem Volumen zu variieren.
• (4) Der Regelmechanismus 50 umfasst den Detektor 54, der Information bezüglich der Temperatur des Fahrrad-Hydraulikbedienungssystems 10 detektiert, den Antrieb 56, der den Kolben 52b antreibt, und die Steuervorrichtung 58, die den Antrieb 56 basierend auf dem Detektionsergebnis des Detektors 54 steuert. Bei dieser Struktur bewegt der Antrieb 56 den Kolben 52b zwangsweise unter der Steuerung der Steuervorrichtung 58. Dies erlaubt es, dass wärmebedingte Veränderungen am Betriebsprofil des Fahrrad-Hydraulikbedienungssystems 10 verringert oder ausgeglichen werden.
• (5) Der Detektor 54 detektiert die Temperatur des Fluids, die Umgebungstemperatur um die Hydraulikleitung R, die Temperatur der Hydraulikbedienungsvorrichtung 20, die Temperatur der hydraulisch bedienten Vorrichtung 30 oder irgendeine Kombination davon. Bei dieser Struktur variiert die Steuervorrichtung 58 das Volumen der Kammer 52 mit variablem Volumen in Abhängigkeit von der Temperatur, die durch den Detektor 54 detektiert wird. Dies erlaubt es, dass wärmebedingte Veränderungen am Betriebsprofil des Fahrrad-Hydraulikbedienungssystems 10 im Wesentlichen ausgeglichen werden.
• (6) Der Speicher 58a der Steuervorrichtung 58 speichert Information in Bezug auf Positionen des Kolbens 52b entsprechend den Detektionen des Detektors 54. Der Prozessor 58b steuert der Antrieb 56 basierend auf der Detektion des Detektors 54 und der Information in Bezug auf die Position des Kolbens 52b. Bei dieser Struktur kann der Speicher 58a Information speichern, die im Vorhinein beispielsweise durch Experimente oder Simulationen erzeugt und für das Fahrrad-Hydraulikbedienungssystem 10 optimiert wurden. Dementsprechend kann die Steuervorrichtung 58 den Kolben 52b um einen Bewegungsbetrag bewegen, der optimiert ist, um wärmebedingte Veränderungen am Betriebsprofil des Fahrrad-Hydraulikbedienungssystems 10 im Wesentlichen auszugleichen.

The bicycle hydraulic control system 10 that is the regulatory mechanism 50 includes, provides the driver with a quick and linear brake response when operating the lever 22 ready. The bicycle hydraulic control system 10 is particularly desirable for a driver who is sensitive to lever operation 22 performs.

• (2) The regulatory mechanism 50 includes the chamber 52 with variable volume, which is located in the hydraulic line R. With this structure, the volume of the chamber changes 52 with variable volume as a function of temperature with respect to the hydraulic line R. This reduces or compensates for thermal changes in the operating profile of the bicycle hydraulic operating system 10 , Accordingly, the operational stability of the bicycle hydraulic operating system 10 be improved.
• (3) The Chamber 52 with variable volume is through the cylinder 52a and the piston 52b defined in the cylinder 52a is mobile. In this structure, the piston moves 52b as a function of the temperature with respect to the hydraulic line R, to the volume of the chamber 52 to vary with variable volume.
• (4) The regulatory mechanism 50 includes the detector 54 , the information relating to the temperature of the bicycle hydraulic operating system 10 detected, the drive 56 that the piston 52b drives, and the control device 58 that the drive 56 based on the detection result of the detector 54 controls. In this structure, the drive moves 56 the piston 52b forcibly under the control of the control device 58 , This allows thermal changes to the operating profile of the bicycle hydraulic operating system 10 be reduced or compensated.
• (5) The detector 54 detects the temperature of the fluid, the ambient temperature around the hydraulic line R, the temperature of the hydraulic control device 20 , the temperature of the hydraulically operated device 30 or any combination thereof. In this structure, the control device varies 58 the volume of the chamber 52 variable volume depending on the temperature generated by the detector 54 is detected. This allows thermal changes to the operating profile of the bicycle hydraulic operating system 10 be substantially balanced.
• (6) The memory 58a the control device 58 stores information regarding positions of the piston 52b according to the detections of the detector 54 , The processor 58b controls the drive 56 based on the detection of the detector 54 and the information relating to the position of the piston 52b , With this structure, the memory can 58a Store information generated in advance, for example, by experiments or simulations, and for the bicycle hydraulic control system 10 were optimized. Accordingly, the control device 58 the piston 52b by an amount of movement Optimized for thermal changes in the operating profile of the bicycle hydraulic operating system 10 substantially equalize.

The subject matter of the present invention is not limited to the above embodiment and can be modified as described below.

3 shows a control mechanism 50a in a first modified example. The chamber 52 with variable volume of the regulating mechanism 50a includes an expandable section 52c which expands and contracts depending on the temperature of the fluid. The expandable section 52c which is adapted to receive the fluid is dome-shaped. The chamber 52 Variable volume can have a non-expandable section 52d include the expandable section 52c carries and with the hydraulic hose 40 connected is.

When the temperature of the fluid becomes higher than a reference temperature (eg, 25 ° C), the expandable portion expands 52c and increases the volume of the chamber 52 with variable volume.

The expandable section 52c For example, it is formed of a material having a linear expansion coefficient with respect to heat. The material is, for example, an aluminum alloy or the like. The thickness of the expandable section 52c is set so that the expandable section 52c can be expanded and contracted depending on the temperature of the fluid, but can not be expanded and contracted by the pressure of the hydraulic line R.

In the first modified example, the expandable section expands 52c spontaneously depending on the temperature of the fluid and contracts and varies the volume of the chamber 52 with variable volume without electricity. Accordingly, thermal changes may be made to the operating profile of the bicycle hydraulic operating system 10 be reduced or substantially compensated without electric current.

The expandable section 52c out 3 does not have to be dome-shaped and may have a different shape. For example, the expandable section 52c have the shape of a membrane or a bellows.

4 shows a control mechanism 50b in a second modified example. The chamber 52 with variable volume of the regulating mechanism 50b is through a cylinder 52e and a piston 52f defined in the cylinder 52e is mobile. The piston 52f is made by an expandable section 52g in the cylinder 52e carried. The expandable section 52g Expands depending on the temperature of the fluid and contracts.

As well as the expandable section 52c out 3 is the expandable section 52g For example, formed from a material having a linear expansion coefficient with respect to heat. When the temperature of the fluid becomes higher than a reference temperature (eg, 25 ° C), the expandable portion expands 52c and increases the volume of the chamber 52 with variable volume.

In the second modified example, the expandable portion expands 52g spontaneously depending on the temperature of the fluid and contracts and varies the volume of the chamber 52 with variable volume without electricity. Accordingly, thermal changes may be made to the operating profile of the bicycle hydraulic operating system 10 be reduced or substantially compensated without electric current.

The expandable section 52g out 4 does not have to be rod-shaped and may have any shape. The expandable section 52g out 4 can the piston 52f and the cylinder 52e connect directly. However, a non-expandable portion between the expandable portion 52g and the piston 52f and / or between the expandable section 52g and the inner surface of the cylinder 52e be arranged.

Instead of or in addition to a temperature sensor, the detector 54 out 2 be configured to detect a physical quantity other than the temperature, which correlates with the temperature of the bicycle hydraulic operating system 10 having. In the bicycle hydraulic control system 10 , which is of a closed type, a change in the temperature of the hydraulic line R can change the pressure of the hydraulic line R. Thus, the detector can 54 a pressure sensor that detects the pressure of the hydraulic line R. In this case, the control device 58 trained, the volume of the chamber 52 with variable volume with the piston 52b and the drive 56 to vary so that the pressure of the hydraulic line R is maintained at a set value when the hydraulic operating device 20 is not operated and thus is in a state of rest. In this case, the memory stores 58a the control device 58 Information relating to positions of the piston 52b according to the detections of the pressure sensor.

The shape, structure and type of the hydraulic operating device and the hydraulically operated device are not limited to the illustrations and may be changed as necessary. For example, the bicycle hydraulic operating system 10 is not limited to a hydraulic disc brake system, and may be formed as a hydraulic rims brake system. Further, instead of a hydraulic brake system, the bicycle hydraulic operating system 10 for example, in a hydraulic transmission system, a hydraulic suspension system, an adjustable hydraulic seat post or the like. In each of these examples is the use of the regulatory mechanism 50 particularly advantageous when the bicycle hydraulic control system 10 is of a closed type, which does not include a fluid container in the hydraulic control device.

It should be apparent to those skilled in the art that the subject matter of the present invention may be embodied in many other specific forms without departing from the scope of the appended claims. For example, some of the components disclosed in the embodiments may be omitted or combined. Therefore, the present examples and embodiments are to be considered as illustrative and not restrictive, and the subject matter of the present invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.

Claims (12)

Bicycle hydraulic operating system comprising: a hydraulic operating device; a hydraulically operated device fluidly connected to the hydraulic control device via a hydraulic line; and a control mechanism that regulates an internal volume of the hydraulic line as a function of the temperature. The bicycle hydraulic operating system according to claim 1, wherein the control mechanism comprises a variable volume chamber located in the hydraulic line. The bicycle hydraulic operating system according to claim 2, wherein the variable volume chamber is defined by a cylinder and a piston movable in the cylinder. The bicycle hydraulic operating system according to claim 3, wherein the control mechanism comprises: a detector that detects information regarding the temperature of the bicycle hydraulic operating system, a drive that drives the piston, and a controller that controls the drive based on the detection of the detector. The bicycle hydraulic control system of claim 4, wherein the detector detects a temperature of the fluid, an ambient temperature around the hydraulic line, a temperature of the hydraulic control device, a temperature of the hydraulically-operated device, or any combination thereof. A bicycle hydraulic operating system according to claim 4 or 5, wherein the control device comprises: a memory storing information relating to positions of the piston in accordance with the detections of the detector, and a processor that controls the drive based on the detection of the detector and information regarding the position of the piston. A bicycle hydraulic operating system according to any one of claims 2 to 6, wherein the variable volume chamber includes an expandable portion which expands and contracts in response to the temperature of the fluid. The bicycle hydraulic operating system of claim 7, wherein the expandable portion is configured to receive the fluid. The bicycle hydraulic operating system according to claim 8, wherein the expandable portion is dome-shaped. A bicycle hydraulic operating system according to any one of claims 7 to 9, wherein the variable volume chamber is defined by a cylinder and a piston movable in the cylinder, and the expandable portion is set to support the piston in the cylinder. A bicycle hydraulic operating system, comprising: a hydraulic operating device; a hydraulically operated device fluidly connected to the hydraulic control device via a hydraulic line; and a control mechanism that controls an internal volume of the hydraulic line in response to the pressure of the fluid in the hydraulic line, the control mechanism comprising a detector that detects pressure of the hydraulic line, a drive that drives a piston, and a controller that controls the drive based on the detection of the detector, wherein the controller is configured to vary the volume of a variable volume chamber with the piston and the driver so that the pressure of the hydraulic line is maintained at a set value the hydraulic operating device is not operated and thus is in a state of rest. A bicycle hydraulic operating system according to any one of claims 1 to 11, wherein the bicycle hydraulic operating system is of a closed type which is free of a fluid container.

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