JP6975688B2 - Cylinder device - Google Patents

Description

The present invention relates to a cylinder device suitably used for buffering vibration of, for example, an automobile, a railroad vehicle, or the like.

Generally, a vehicle such as an automobile is provided with a cylinder device represented by a hydraulic shock absorber between the vehicle body (upper spring) side and each wheel (unsprung) side. A cylinder device of this type is known to have a configuration in which the generated damping force is variably controlled by applying an electric field due to a high voltage in a state where an electrorheological fluid is sealed in the cylinder (for example, a patent). See Document 1).

Japanese Unexamined Patent Publication No. 6-241265

By the way, in Patent Document 1, for example, when the wire harness (ground wire) on the minus side connected to the outer cylinder is broken, the electrical connection from the cylinder device to the ground side may be cut off.

An object of the present invention is to provide a cylinder device capable of ensuring an electrical connection from the cylinder device to the vehicle body side, which is the ground, even if the wire harness on the minus side connected to the outer cylinder is broken. be.

In order to solve the above-mentioned problems, the cylinder device of the present invention slides in two chambers with an inner cylinder in which an electrorheological fluid whose properties change due to an electric potential is enclosed. A piston, a rod whose one end side protrudes to the outside of the inner cylinder and abuts on the vehicle body and whose other end side is connected to the piston, an outer cylinder provided on the outside of the inner cylinder, and the inner cylinder and the outer cylinder. An electrode provided between the two, an intermediate cylinder forming a passage through which the electrorheological fluid flows between the inner cylinder, and an intermediate cylinder provided at each end of the inner cylinder and the intermediate cylinder. A spacer that closes and insulates between the inner cylinder and the intermediate cylinder, a reservoir chamber formed between the intermediate cylinder and the outer cylinder and in which the electrorheological fluid and the working gas are sealed, and the inner cylinder. And a closing member provided so as to close one end of the outer cylinder and supporting the rod, and a body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber. A cylinder device having a positive potential applied to the intermediate cylinder and a negative potential applied to the outer cylinder from the voltage supply unit, wherein the cylinder device is applied to the inner cylinder and the inner cylinder. It is characterized in that a conductor member is provided between the piston that comes into contact with the piston or between the rod and the closing member that comes into contact with the rod.

Further, in the cylinder device of the present invention, an inner cylinder in which an electrically viscous fluid whose properties change due to an electric potential is enclosed, a piston in which the inner cylinder is defined into two chambers and slides, and one end side is the inner cylinder. A rod that protrudes to the outside of the cylinder and comes into contact with the vehicle body, the other end of which is connected to the piston, an outer cylinder provided on the outside of the inner cylinder, and an electrode provided between the inner cylinder and the outer cylinder. An intermediate cylinder that forms a passage through which the electroviscous fluid flows between the inner cylinder and the inner cylinder, and the inner cylinder and the intermediate cylinder are provided at the respective ends of the inner cylinder and the intermediate cylinder. A spacer that closes and insulates the space, a reservoir chamber that is formed between the intermediate cylinder and the outer cylinder and is filled with the electrically viscous fluid and the working gas, and one end of the inner cylinder and the outer cylinder. A closing member provided to close the rod and supporting the rod, a body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber, and a positive potential from the voltage supply unit. Is applied to the intermediate cylinder and a negative potential is applied to the outer cylinder, and the cylinder device is provided at the other end of the rod in contact with the inner cylinder. It is characterized by having a conductive member to be used.

According to the present invention, even if the wire harness on the minus side connected to the outer cylinder is broken, the electrical connection from the cylinder device to the vehicle body side, which is the ground, can be secured.

It is a vertical sectional view which shows the shock absorber as a cylinder device by 1st Embodiment of this invention. FIG. 3 is an enlarged cross-sectional view showing a piston and a conductor member in FIG. 1. It is a circuit diagram which shows the electric circuit of a cylinder device. It is sectional drawing which shows the case where the conductor member by 2nd Embodiment of this invention is provided in the inner circumference of the closing member. It is the same cross-sectional view as FIG. 2 which shows the conductor member by 1st modification of this invention. It is the same cross-sectional view as FIG. 2 which shows the conductor member by the 2nd modification of this invention.

Hereinafter, a case where the cylinder device according to the embodiment of the present invention is applied to a shock absorber provided in a vehicle such as a four-wheeled vehicle will be described as an example, and will be described with reference to the accompanying drawings.

In FIG. 1, the shock absorber 1 as a cylinder device is configured as a damping force adjusting type hydraulic shock absorber (semi-active damper) using an electrorheological fluid 21 enclosed therein. The shock absorber 1 constitutes a suspension device for a vehicle together with a suspension spring (not shown) including, for example, a coil spring. In the following description, one end side in the axial direction of the shock absorber 1 will be referred to as the "upper end" side, and the other end side in the axial direction will be referred to as the "lower end" side.

The shock absorber 1 includes an inner cylinder 2, an outer cylinder 3, a piston 5, a piston rod 8, an intermediate cylinder 18, and the like. The inner cylinder 2 is formed as a cylindrical cylinder extending in the axial direction, and an electrorheological fluid 21 whose properties change due to an electric field is enclosed therein. A piston rod 8 to be described later is inserted inside the inner cylinder 2, and the outer cylinder 3 is provided coaxially on the outer side in the radial direction of the inner cylinder 2.

The outer cylinder 3 forms the outer shell of the shock absorber 1 and is formed as a cylindrical body. The outer cylinder 3 is provided on the outside of the inner cylinder 2, and the lower end side thereof is a closed end closed by a bottom cap 4 using a welding means or the like. The bottom cap 4 constitutes a base member together with the valve body 14 of the bottom valve 13, which will be described later. The upper end side of the outer cylinder 3 is an open end, and the crimped portion 3A is formed by bending inward in the radial direction on the open end side. The caulking portion 3A holds the outer peripheral side of the annular plate body 11A of the sealing member 11 in a retaining state. Further, in the outer cylinder 3, a mounting hole 3B to which a high voltage driver 23 described later is mounted is formed as a radial lateral hole (through hole).

On the other hand, the inner cylinder 2 is provided in the outer cylinder 3 coaxially with the outer cylinder 3. The lower end side of the inner cylinder 2 is fitted and attached to the valve body 14 of the bottom valve 13, and the upper end side is fitted and attached to the rod guide 10. The inner cylinder 2 is formed with a plurality (for example, 4 to 8) oil holes 2A that are always in communication with the passage 19 described later, as lateral holes in the radial direction, separated in the circumferential direction. The rod-side oil chamber B in the inner cylinder 2 communicates with the passage 19 by the oil hole 2A.

The inner cylinder 2 constitutes a cylinder together with the outer cylinder 3, and an electrorheological fluid 21 (ERF: Electro Rheological Fluid) made of a liquid is sealed (filled) in the cylinder. In each figure, the enclosed electrorheological fluid 21 is colorless and transparent.

The electrorheological fluid 21 is a kind of functional fluid whose properties change by an external stimulus, and is a fluid whose viscosity (characteristics) changes by an increase or decrease in voltage (strength or weakness of an electric field). That is, the electrorheological fluid 21 has a flow resistance (damping force) that changes according to the applied voltage (electric field strength). The electrorheological fluid 21 is composed of a base oil (base oil) made of, for example, silicon oil, and particles (urethane particles) whose viscosity is variable according to changes in the electric field mixed (dispersed) in the base oil. ing. The shock absorber 1 is configured to control (adjust) the generated damping force by generating a potential difference in the passage 19 described later and variably controlling the viscosity of the electrorheological fluid 21 passing through the passage 19. ..

An annular reservoir chamber A is formed between the inner cylinder 2 (intermediate cylinder 18 described later) and the outer cylinder 3. The reservoir chamber A is filled with a gas that becomes a working gas together with the liquid electrorheological fluid 21. This gas may be air in an atmospheric pressure state, or a gas such as compressed nitrogen gas may be used. The gas in the reservoir chamber A is compressed to compensate for the approaching volume of the piston rod 8 when the piston rod 8 is contracted (contraction stroke).

The piston 5 defines the inside of the inner cylinder 2 into two chambers, a rod-side oil chamber B and a bottom-side oil chamber C, and slides in the inner cylinder 2 via a conductor member 28 described later. The piston 5 is made of a conductor such as a metal material, and a plurality of oil passages 5A and 5B that allow communication between the rod side oil chamber B and the bottom side oil chamber C are formed so as to be separated from each other in the circumferential direction. There is. Here, the shock absorber 1 according to the embodiment has a uniflow structure. Therefore, the electrically viscous fluid 21 in the inner cylinder 2 is directed from the rod-side oil chamber B (that is, the oil hole 2A of the inner cylinder 2) toward the passage 19 in both the contraction stroke and the expansion stroke of the piston rod 8. It always circulates in one direction (that is, the direction of the arrow F indicated by the two-dot chain line in FIG. 1).

In order to realize such a uniflow structure, a valve is opened on the upper end surface of the piston 5 when the piston 5 slides downward in the inner cylinder 2 in the contraction stroke (shrinkage stroke) of the piston rod 8. A check valve 6 on the contraction side that closes the valve at other times is provided. The contraction side check valve 6 allows the liquid (electrorheological fluid 21) in the bottom side oil chamber C to flow in each oil passage 5A toward the rod side oil chamber B, and the liquid in the opposite direction. Prevents the flow.

A disc valve 7 on the extension side is provided on the lower end surface of the piston 5. In the extension side disc valve 7, the pressure in the rod side oil chamber B exceeds the relief set pressure when the piston 5 slides upward in the inner cylinder 2 in the extension stroke (extension stroke) of the piston rod 8. And the pressure at this time is relieved to the bottom side oil chamber C side via each oil passage 5B.

The piston rod 8 as a rod extends in the inner cylinder 2 in the axial direction (the same direction as the central axis of the inner cylinder 2 and the outer cylinder 3, and extends in the upper and lower directions in FIG. 1). The piston rod 8 is made of a conductor such as a metal material, and the upper end side (one end side) protrudes to the outside of the inner cylinder 2 and the outer cylinder 3 which are cylinders, and the lower end side (the other end side) is inside the inner cylinder 2. It is connected (fixed) to the piston 5. In this case, the piston 5 is fixed (fixed) to the lower end side of the piston rod 8 by using a nut 8A or the like. On the other hand, the upper end side of the piston rod 8 projects to the outside via the rod guide 10 and is in contact with the vehicle body G (ground) in a conductive state (electrically connected state). In addition, both rods may be formed by further extending the lower end of the piston rod 8 so as to project outward from the bottom portion (for example, the bottom cap 4) side.

The closing member 9 is provided on the upper end side (one end side) of the inner cylinder 2 and the outer cylinder 3, and closes the upper end side of the inner cylinder 2 and the outer cylinder 3. The closing member 9 supports a piston rod 8 that is displaced in the axial direction on the upper end side of the inner cylinder 2 and the outer cylinder 3. The closing member 9 is composed of a stepped cylindrical rod guide 10 and an annular seal member 11.

The rod guide 10 supports the piston rod 8, and is formed as a tubular body having a predetermined shape by subjecting a conductor such as a metal material to a forming process, a cutting process, or the like. The rod guide 10 positions the upper portion of the inner cylinder 2 and the upper portion of the intermediate cylinder 18 described later in the center of the outer cylinder 3. At the same time, the rod guide 10 guides (guides) the piston rod 8 so as to be slidable in the axial direction on the inner peripheral side thereof.

Here, the rod guide 10 is located on the upper side and is located on the inner peripheral side of the outer cylinder 3 and is inserted into the inner peripheral side of the annular large diameter portion 10A, and is located on the lower side of the large diameter portion 10A and is inside the inner cylinder 2. It is formed in a stepped cylindrical shape by a short tubular small diameter portion 10B inserted on the peripheral side. A guide portion 10C that guides the piston rod 8 so as to be slidable in the axial direction is provided on the inner peripheral side of the small diameter portion 10B of the rod guide 10. The guide portion 10C is formed, for example, by applying an ethylene tetrafluoride coating to the inner peripheral surface of the metal cylinder.

An annular sealing member 11 is provided between the large diameter portion 10A of the rod guide 10 and the caulking portion 3A of the outer cylinder 3. The seal member 11 is made of a metallic annular plate 11A having a hole through which the piston rod 8 is inserted in the center, and an elastic material such as rubber fixed to the annular plate 11A by means such as seizure. It is configured to include an elastic body 11B. The inner circumference of the elastic body 11B is in sliding contact with the outer peripheral side of the piston rod 8, so that the seal member 11 is liquid-tightly and airtightly sealed with the piston rod 8.

On the other hand, an annular holding member 12 is fitted and attached between the large diameter portion 10A and the small diameter portion 10B on the outer peripheral side of the rod guide 10. The holding member 12 constitutes the spacer of the present invention, is provided at the upper end of the inner cylinder 2 and the intermediate cylinder 18 described later, and closes and insulates between the inner cylinder 2 and the intermediate cylinder 18. .. The holding member 12 holds the intermediate cylinder 18 in a state where the upper end side is positioned in the axial direction. The holding member 12 is formed of, for example, an electrically insulating material, and keeps the inner cylinder 2 and the rod guide 10 and the intermediate cylinder 18 electrically insulated from each other.

A bottom valve 13 is provided on the lower end side (the other end side) of the inner cylinder 2 so as to be located between the inner cylinder 2 and the bottom cap 4. The bottom valve 13 includes a valve body 14, an extension check valve 16, and a disc valve 17. The valve body 14 constitutes the body of the present invention, is provided at the other end (lower end) of the inner cylinder 2, and defines the inside of the inner cylinder 2 and the reservoir chamber A. That is, the valve body 14 defines the reservoir chamber A and the bottom side oil chamber C between the bottom cap 4 and the inner cylinder 2. The valve body 14 is formed with oil passages 14A and 14B that allow the reservoir chamber A and the bottom side oil chamber C to communicate with each other at intervals in the circumferential direction.

A step portion 14C is formed on the outer peripheral side of the valve body 14, and the lower end inner peripheral side of the inner cylinder 2 is fitted and fixed to the step portion 14C. Further, an annular holding member 15 is fitted and attached to the step portion 14C on the outer peripheral side of the inner cylinder 2. The holding member 15 constitutes the spacer of the present invention, is provided at the lower end of the inner cylinder 2 and the intermediate cylinder 18, and closes and insulates between the inner cylinder 2 and the intermediate cylinder 18. The holding member 15 holds the lower end side of the intermediate cylinder 18 in a state of being positioned in the axial direction. The holding member 15 is formed of, for example, an electrically insulating material, and keeps the inner cylinder 2 and the valve body 14 and the intermediate cylinder 18 electrically insulated from each other. Further, the holding member 15 is formed with a plurality of oil passages 15A for communicating the passage 19 described later with the reservoir chamber A.

The extension side check valve 16 is provided, for example, on the upper surface side of the valve body 14. The extension-side check valve 16 opens when the piston 5 slides and displaces upward in the extension stroke of the piston rod 8, and closes at other times. The extension-side check valve 16 allows the electrorheological fluid 21 in the reservoir chamber A to flow in each oil passage 14A toward the bottom-side oil chamber C, and prevents the liquid from flowing in the opposite direction. do.

The disc valve 17 on the reduction side is provided on the lower surface side of the valve body 14. The disc valve 17 on the reduction side opens when the pressure in the oil chamber C on the bottom side exceeds the relief set pressure when the piston 5 slides and displaces downward in the reduction stroke of the piston rod 8, and the pressure at this time. Is relieved to the reservoir chamber A side via each oil passage 14B.

An intermediate cylinder 18 made of a pressure pipe extending in the axial direction is provided between the inner cylinder 2 and the outer cylinder 3. The intermediate cylinder 18 is formed by using a conductive material, and constitutes a tubular electrode to which a high voltage (electric field) is applied from the battery 22 (high voltage driver 23) described later. The intermediate cylinder 18 forms a passage 19 in which the electrorheological fluid 21 flows from the upper end side to the lower end side in the axial direction by advancing and retreating the piston rod 8 with the inner cylinder 2.

That is, the intermediate cylinder 18 is attached to the outer peripheral side of the inner cylinder 2 via the holding members 12 and 15. The holding members 12 and 15 are provided apart from each other in the axial direction (vertical direction) on the outer peripheral side of the inner cylinder 2. In this case, the upper end side of the intermediate cylinder 18 cannot rotate relative to the outer cylinder 3 via the holding member 12 and the rod guide 10. The lower end side of the intermediate cylinder 18 cannot rotate relative to the outer cylinder 3 via the holding member 15, the valve body 14, and the bottom cap 4. The intermediate cylinder 18 surrounds the outer peripheral side of the inner cylinder 2 over the entire circumference, so that an annular flow path, that is, an electrorheological fluid 21 flows between the inner peripheral side of the intermediate cylinder 18 and the outer peripheral side of the inner cylinder 2. The passage 19 is formed. Further, the positive electrode 26A of the high voltage output line 26, which will be described later, is in contact with the outer periphery of the intermediate cylinder 18.

The passage 19 always communicates with the rod-side oil chamber B by an oil hole 2A formed as a radial lateral hole in the inner cylinder 2. In the shock absorber 1, the electrorheological fluid 21 flows from the rod-side oil chamber B into the passage 19 through the oil hole 2A in both the contraction stroke and the expansion stroke of the piston 5. When the piston rod 8 moves back and forth in the inner cylinder 2 (that is, while repeating the contraction stroke and the expansion stroke), the electrorheological fluid 21 that has flowed into the passage 19 moves to the upper end of the passage 19 in the axial direction. It flows from the side to the lower end side. That is, the electrorheological fluid 21 flows in the direction indicated by the arrow F in FIG.

The electrorheological fluid 21 that has flowed into the passage 19 flows out from the lower end side of the intermediate cylinder 18 to the reservoir chamber A through the oil passage 14A of the holding member 15. At this time, the pressure of the electrorheological fluid 21 is highest on the upstream side (that is, the oil hole 2A side) of the passage 19, and gradually decreases because it receives the flow path (passage) resistance while flowing through the passage 19. Therefore, the electrorheological fluid 21 in the passage 19 has the lowest pressure when flowing through the downstream side of the passage 19 (that is, the oil passage 14A of the holding member 15).

A partition wall member 20 for partitioning a passage 19 through which the electrorheological fluid 21 flows (to guide the flow of the electrorheological fluid 21) is provided between the outer circumference of the inner cylinder 2 and the inner circumference of the intermediate cylinder 18. The partition wall member 20 is formed of an electrically insulating material and is attached so as not to rotate relative to the outer peripheral surface of the inner cylinder 2 and the inner peripheral surface of the intermediate cylinder 18. The partition wall member 20 is a flow path forming member that guides the electrorheological fluid 21 between the inner cylinder 2 and the intermediate cylinder 18 not only in the axial direction but also in the circumferential direction. Thereby, the passage 19 through which the electrorheological fluid 21 flows can be made into one or a plurality of spiral or meandering passages (flow passages) having a portion extending in the circumferential direction. In this case, the total length of the passage 19 (the length of the flow path from the oil hole 2A to the oil passage 14A) can be made longer than that of the passage extending linearly in the axial direction.

The passage 19 imparts resistance to the electrorheological fluid 21 that flows through the sliding of the piston 5 in the outer cylinder 3 and the inner cylinder 2. Therefore, the intermediate cylinder 18 is connected to the positive electrode of the battery 22 as a power source via, for example, a high voltage driver 23 that generates a high voltage. That is, the intermediate cylinder 18 serves as an electrode (electrode) for applying an electric field to the electrorheological fluid 21 flowing in the passage 19.

Here, both ends of the intermediate cylinder 18 are electrically insulated from the rod guide 10 and the valve body 14 (bottom cap 4) via the holding members 12 and 15. On the other hand, the inner cylinder 2 is connected to the negative electrode (ground) via the rod guide 10, the bottom valve 13 (valve body 14), the bottom cap 4, the outer cylinder 3, the high voltage driver 23, and the like.

The battery 22 serves as a power source for applying to the intermediate cylinder 18. The battery 22 is connected to the shock absorber 1 (intermediate cylinder 18 and outer cylinder 3) via a high voltage driver 23, which is also called a high voltage box (HV-Box). As the battery 22, for example, in the case of a hybrid vehicle or an electric vehicle equipped with an electric motor (drive motor) for traveling, a large-capacity battery (not shown) for driving the vehicle can also be used. The battery 22 constitutes the voltage supply unit (electric field supply unit) of the present invention together with the high voltage driver 23.

The high voltage driver 23 is mounted in the mounting hole 3B of the outer cylinder 3. The high voltage driver 23 is configured to include a booster circuit 23A and the like, and a DC voltage output from the battery 22 is transmitted by the booster circuit 23A based on a command signal (high voltage command) output from a controller (not shown). Boost. As a result, the high voltage driver 23 generates a high voltage (for example, 5 kV) applied to the electrorheological fluid 21. For this purpose, the high voltage driver 23 is connected to the battery 22 as a power source via the battery line 24 and the ground line 25 constituting the (low voltage) DC power line.

Further, the high voltage driver 23 is connected to the shock absorber 1 (intermediate cylinder 18 and outer cylinder 3) via the high voltage output line 26 and the ground line 27 constituting the (high voltage) DC power line. The contact portion between the high voltage output line 26 and the intermediate cylinder 18 is a positive electrode 26A that applies a positive potential to the intermediate cylinder 18. On the other hand, the contact portion between the ground wire 27 and the outer cylinder 3 is a negative electrode 27A that applies a negative potential to the outer cylinder 3. The positive electrode 26A and the negative electrode 27A constitute the imparting portion of the present invention.

As a result, a potential difference is generated between the inner cylinder 2 and the intermediate cylinder 18, in other words, in the passage 19 according to the high voltage applied to the intermediate cylinder 18, and the viscosity of the electrorheological fluid 21 changes. .. In this case, the shock absorber 1 has a characteristic of the generated damping force (damping force characteristic) according to the high voltage applied to the intermediate cylinder 18, a hard characteristic (hard characteristic) and a soft characteristic (Soft characteristic). It can be continuously adjusted with the soft property). The shock absorber 1 may be capable of adjusting the damping force characteristics in two stages or a plurality of stages even if the damping force characteristics are not continuous. Further, in the present embodiment, the voltage boosted by the high voltage driver is a DC voltage, but it may be an AC voltage.

Next, the conductor member 28 provided on the outer periphery of the piston 5 will be described.

The conductor member 28 is provided between the inner cylinder 2 and the piston 5 that abuts on the inner cylinder 2. The conductor member 28 is provided on the outer periphery of the piston 5 and is in contact with the inner cylinder 2 (sliding contact). That is, the conductor member 28 is provided between the inner cylinder 2 and the piston rod 8 via the piston 5. The conductor member 28 is a band wound around the outer periphery of the piston 5 by, for example, graphite or ceramics. As a result, the inner cylinder 2 and the vehicle body G, which is the ground, are electrically connected to each other via the conductor member 28, the piston 5, and the piston rod 8. In this case, the inner cylinder 2 and the vehicle body G are conducted with a resistance value sufficiently lower than the human body resistance W (for example, 7.9 Ω or less).

Therefore, in the shock absorber 1, the outer cylinder 3 is conducted by the ground wires 25 and 27 to the vehicle body G which is the ground via the battery 22, and the inner cylinder 2 is the conductor member 28, the piston 5, and the piston rod 8. It is conducted to the vehicle body G which is the ground through. That is, the shock absorber 1 is electrically connected to the vehicle body G whose negative side is ground by two systems. As a result, for example, even if the ground wire 27 connecting between the battery 22 and the high voltage driver 23 is disconnected, the ground wire 27 from the inner cylinder 2 on the minus side is grounded via the conductor member 28, the piston 5, and the piston rod 8. It is possible to secure an electrical connection to the vehicle body G side.

The shock absorber 1 according to the first embodiment has the above-mentioned configuration, and its operation will be described next.

When mounting the shock absorber 1 on a vehicle such as an automobile, for example, the upper end side of the piston rod 8 is attached to the vehicle body G side, and the lower end side (bottom cap 4 side) of the outer cylinder 3 is on the wheel side (axle side). Install. When the vehicle travels, when vibrations in the upward and downward directions occur due to unevenness of the road surface and the like, the piston rod 8 is displaced so as to extend and contract from the outer cylinder 3. At this time, a potential difference based on the damping force command from the controller is generated between the inner cylinder 2 and the intermediate cylinder 18, an electric field is applied to the passage 19, and the viscosity of the electrorheological fluid 21 passing through the passage 19 is increased. By controlling, the generated damping force of the shock absorber 1 is variably adjusted.

In this case, during the extension stroke of the piston rod 8, the check valve 6 on the contraction side of the piston 5 is closed by the movement of the piston 5 in the inner cylinder 2. Before the disc valve 7 of the piston 5 is opened, the electrorheological fluid 21 in the oil chamber B on the rod side is pressurized and flows into the passage 19 through the oil hole 2A of the inner cylinder 2. At this time, the electrorheological fluid 21 to which the piston 5 has moved flows from the reservoir chamber A into the bottom side oil chamber C by opening the extension side check valve 16 of the bottom valve 13.

On the other hand, during the contraction stroke of the piston rod 8, the contraction side check valve 6 of the piston 5 opens due to the movement of the piston 5 in the inner cylinder 2, and the extension side check valve 16 of the bottom valve 13 closes. Before opening the bottom valve 13 (disc valve 17), the liquid in the bottom side oil chamber C flows into the rod side oil chamber B. At the same time, the liquid corresponding to the amount of the piston rod 8 infiltrated into the inner cylinder 2 flows from the rod side oil chamber B into the passage 19 through the oil hole 2A of the inner cylinder 2.

In either case (both expansion and contraction strokes), the electrorheological fluid 21 flowing into the passage 19 has a viscosity corresponding to the electric field strength of the passage 19 (potential difference between the inner cylinder 2 and the intermediate cylinder 18). It flows through the inside of 19 toward the outlet side (lower side), and flows from the passage 19 to the reservoir chamber A through the oil passage 14A of the holding member 15. At this time, the shock absorber 1 generates a damping force according to the viscosity of the electrorheological fluid 21 passing through the passage 19, and can buffer (damp) the vertical vibration of the vehicle.

By the way, in the above-mentioned conventional technique, when the wire harness (ground wire) on the minus side connected to the outer cylinder is broken or the like, the electrical connection from the cylinder device to the ground side is cut off. In this state, if the worker comes into contact with the shock absorber and the vehicle body at the same time, a current may flow to the worker side.

Therefore, in the present embodiment, in addition to the ground wire 27 connected to the outer cylinder 3, the inner cylinder 2 on the minus side and the vehicle body G which is the ground are electrically connected via the piston rod 8. Specifically, the upper end side of the piston rod 8 formed of the conductor is electrically connected to the vehicle body G. A conductor member 28 having a sealing property and a slidable property with the inner cylinder 2 is provided on the outer peripheral side of the piston 5 formed of the conductor. In this case, the inner cylinder 2 and the vehicle body G are electrically connected via the conductor member 28, the piston 5, and the piston rod 8 with a resistance value sufficiently lower than the human body resistance W (for example, 7.9 Ω or less). Has been done.

As a result, when the ground wire 27 connecting the battery 22 and the intermediate cylinder 18 is disconnected, it is assumed that the operator simultaneously contacts the shock absorber 1 and the vehicle body G as shown by the dotted line in FIG. Also, as shown by the arrow D in FIG. 3, most of the current flows from the inner cylinder 2 toward the vehicle body G. Therefore, the current flowing from the shock absorber 1 indicated by the arrow E in FIG. 3 to the vehicle body G via the operator may be set to a value smaller than the current that the operator can feel (for example, 5.2 mA or less). can. As a result, the workability of the work when maintaining the shock absorber 1 can be improved.

Next, FIG. 4 shows a second embodiment of the present invention. The feature of the second embodiment is that the conductor member 31 is provided on the inner peripheral side of the rod guide 10 constituting the closing member 9. In the second embodiment, the same components as those in the first embodiment described above are designated by the same reference numerals, and the description thereof will be omitted.

The conductor member 31 is provided between the piston rod 8 and the closing member 9 that comes into contact with the piston rod 8. Specifically, the conductor member 31 is provided on the inner circumference of the rod guide 10 constituting the closing member 9. The conductor member 31 is formed of, for example, graphite, ceramics, or the like in a ring shape through which the piston rod 8 penetrates (sliding) on the inner peripheral side. In this case, the rod guide 10 is formed of a conductor and is in contact with the inner cylinder 2 and the outer cylinder 3 on the minus side.

As a result, the inner cylinder 2 and the outer cylinder 3 and the vehicle body G which is the ground are electrically connected to each other via the rod guide 10, the conductor member 31, and the piston rod 8. In this case, the inner cylinder 2 and the outer cylinder 3 and the vehicle body G are conducted with a resistance value sufficiently lower than the human body resistance W (for example, 7.9 Ω or less).

Therefore, in the shock absorber 1, the outer cylinder 3 is conducted by the ground wires 25 and 27 to the vehicle body G which is the ground via the battery 22, and the outer cylinder 3 and the inner cylinder 2 are the rod guide 10 and the conductor member 31. , And is conducted to the vehicle body G, which is the ground, via the piston rod 8. That is, the shock absorber 1 is electrically connected to the vehicle body G whose negative side is ground by two systems. As a result, for example, even if the ground wire 27 connecting between the battery 22 and the high voltage driver 23 is disconnected, the rod guide 10, the conductor member 31, and the piston rod are connected to the outer cylinder 3 and the inner cylinder 2 on the negative side. It is possible to secure an electrical connection to the vehicle body G side, which is the ground, via 8.

Therefore, even if the operator comes into contact with the shock absorber 1 and the vehicle body G at the same time when the ground wire 27 connecting the battery 22 and the intermediate cylinder 18 is disconnected, the inner cylinder 2 and the outer cylinder 3 can be used. Most of the current flows toward the vehicle body G. Therefore, the current flowing from the shock absorber 1 to the vehicle body G via the operator can be set to a value smaller than the current that the operator can feel (for example, 5.2 mA or less). As a result, the workability of the work when maintaining the shock absorber 1 can be improved.

In the first embodiment described above, the case where the conductor member 28 is provided over the entire circumference of the piston 5 has been described as an example. However, the present invention is not limited to this, and the conductor member 42 may be provided on a part of the insulator 41 provided on the outer periphery of the piston 5, as in the first modification shown in FIG. 5, for example.

Further, in the above-mentioned first embodiment, the case where the conductor member 28 is provided over the entire circumference of the piston 5 has been described as an example. However, the present invention is not limited to this, and for example, as in the second modification shown in FIG. 6, a conductor member 51 made of a band in contact with the inner cylinder 2 is provided at the other end (lower end) of the piston rod 8. You may. The band may be formed by forming a part of the band that slides on the inner peripheral surface of the inner cylinder 2 as a conductor.

Further, in the second embodiment described above, the case where the conductor member 31 is provided on the inner peripheral side of the rod guide 10 has been described as an example. However, the present invention is not limited to this, and for example, the guide portion 10C of the rod guide 10 may be formed of a conductive material. In this case, the entire guide portion 10C may be formed of a conductive material, or the conductive material that contacts the small diameter portion 10B of the rod guide 10 and the piston rod 8 may be formed in a part of the guide portion 10C.

Further, in the second embodiment described above, the case where the conductor member 31 is provided on the inner peripheral side of the rod guide 10 has been described as an example. However, the present invention is not limited to this, and for example, the seal member 11 constituting the closing member 9 may be formed of a conductive material. In this case, the entire sealing member 11 may be formed of a conductive material, or the conductive material that contacts the piston rod 8 and the rod guide 10 may be formed on a part of the sealing member 11.

Further, in the embodiment, a case where the shock absorber 1 as a cylinder device is used for a four-wheeled vehicle has been described as an example. However, the present invention is not limited to this, and for example, a shock absorber used for a two-wheeled vehicle, a shock absorber used for a railroad vehicle, a shock absorber used for various mechanical devices including general industrial equipment, a shock absorber used for a building, and the like. It can be widely used as various shock absorbers (cylinder devices) for buffering objects to be buffered.

As the cylinder device based on the embodiment described above, for example, the one described below can be considered.

As the first aspect of the cylinder device, an inner cylinder in which an electrorheological fluid whose properties change due to an electric potential is enclosed, a piston in which the inner cylinder is defined into two chambers and slides, and one end side is said. A rod that protrudes to the outside of the inner cylinder and abuts on the vehicle body, and the other end side is connected to the piston, an outer cylinder provided on the outside of the inner cylinder, and an electrode provided between the inner cylinder and the outer cylinder. An intermediate cylinder that forms a passage through which the electrorheological fluid flows between the inner cylinder and the inner cylinder and the intermediate cylinder are provided at the respective ends of the inner cylinder and the intermediate cylinder. A spacer that closes and insulates between the two, a reservoir chamber that is formed between the intermediate cylinder and the outer cylinder and is filled with the electrorheological fluid and the working gas, and the inner cylinder and the outer cylinder. A closing member provided so as to close one end and supporting the rod, a body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber, and a plus from the voltage supply unit. A cylinder device having an imparting portion in which a potential is applied to the intermediate cylinder and a negative potential is applied to the outer cylinder, wherein the cylinder device comprises the inner cylinder and the piston abutting on the inner cylinder. It is characterized in that a conductor member is provided between the rod or between the rod and the closing member that comes into contact with the rod. As a result, even if the wire harness on the minus side connected to the outer cylinder is broken, the electrical connection from the cylinder device to the vehicle body side, which is the ground, can be secured.

As a second aspect of the cylinder device, an inner cylinder in which an electroviscous fluid whose properties change due to an electric potential is enclosed, a piston in which the inside of the inner cylinder is defined into two chambers and slides, and one end side is said. A rod that protrudes to the outside of the inner cylinder and abuts on the vehicle body, and the other end side is connected to the piston, an outer cylinder provided on the outside of the inner cylinder, and an electrode provided between the inner cylinder and the outer cylinder. An intermediate cylinder that forms a passage through which the electroviscous fluid flows between the inner cylinder and the inner cylinder, and the inner cylinder and the intermediate cylinder are provided at the respective ends of the inner cylinder and the intermediate cylinder. A spacer that closes and insulates between the two, a reservoir chamber that is formed between the intermediate cylinder and the outer cylinder and is filled with the electrically viscous fluid and the working gas, and the inner cylinder and the outer cylinder. A closing member provided so as to close one end and supporting the rod, a body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber, and a plus from the voltage supply unit. A cylinder device having an imparting portion in which a potential is applied to the intermediate cylinder and a negative potential is applied to the outer cylinder, and the cylinder device abuts on the inner cylinder and is attached to the other end of the rod. It is characterized by having a provided conductive member. As a result, even if the wire harness on the minus side connected to the outer cylinder is broken, the electrical connection from the cylinder device to the vehicle body side, which is the ground, can be secured.

1 Buffer (cylinder device)
2 Inner cylinder 3 Outer cylinder 5 Piston 8 Piston rod (rod)
9 Closing member 12,15 Holding member (spacer)
14 Valve body (body)
18 Intermediate cylinder 19 Passage 21 Electrorheological fluid 22 Battery (voltage supply unit)
23 High voltage driver (voltage supply unit)
26 High voltage output line 26A Plus electrode (giving part)
27 Ground wire 27A Negative electrode (giving part)
28, 31, 42, 51 Conductor member A Reservoir chamber B Rod side oil chamber C Bottom side oil chamber

Claims (2)

An inner cylinder in which an electrorheological fluid whose properties change due to an electric field is enclosed,
A piston that slides in two chambers in the inner cylinder,
A rod whose one end side protrudes to the outside of the inner cylinder and comes into contact with the vehicle body, and the other end side is connected to the piston.
An outer cylinder provided on the outside of the inner cylinder and
An electrode provided between the inner cylinder and the outer cylinder, which is an intermediate cylinder that forms a passage through which the electrorheological fluid flows between the inner cylinder and the inner cylinder.
A spacer provided at each end of the inner cylinder and the intermediate cylinder to close and insulate between the inner cylinder and the intermediate cylinder,
A reservoir chamber formed between the intermediate cylinder and the outer cylinder and filled with the electrorheological fluid and the working gas.
A closing member provided so as to close one end of the inner cylinder and the outer cylinder and supporting the rod, and a closing member.
A body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber.
A positive potential is applied to the intermediate cylinder from the voltage supply unit, and a negative potential is applied to the outer cylinder.
It is a cylinder device having
The cylinder device is characterized in that a conductor member is provided between the inner cylinder and the piston that abuts on the inner cylinder, or between the rod and the closing member that abuts on the rod. Cylinder device. An inner cylinder in which an electrorheological fluid whose properties change due to an electric field is enclosed,
A piston that slides in two chambers in the inner cylinder,
A rod whose one end side protrudes to the outside of the inner cylinder and comes into contact with the vehicle body, and the other end side is connected to the piston.
An outer cylinder provided on the outside of the inner cylinder and
An electrode provided between the inner cylinder and the outer cylinder, which is an intermediate cylinder that forms a passage through which the electrorheological fluid flows between the inner cylinder and the inner cylinder.
A spacer provided at each end of the inner cylinder and the intermediate cylinder to close and insulate between the inner cylinder and the intermediate cylinder,
A reservoir chamber formed between the intermediate cylinder and the outer cylinder and filled with the electrorheological fluid and the working gas.
A closing member provided so as to close one end of the inner cylinder and the outer cylinder and supporting the rod, and a closing member.
A body provided at the other end of the inner cylinder and defining the inside of the inner cylinder and the reservoir chamber.
A positive potential is applied to the intermediate cylinder from the voltage supply unit, and a negative potential is applied to the outer cylinder.
It is a cylinder device having
The cylinder device is a cylinder device that comes into contact with the inner cylinder and has a conductor member provided at the other end of the rod.

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