JP3475340B2 - Accumulator with check valve - Google Patents

Description

Description: BACKGROUND OF THE INVENTION [0001] 1. Field of the Invention [0002] The present invention relates to an accumulator for use in accumulating energies, absorbing shock, absorbing pulsation, shock absorbers, and the like. 2. Description of the Related Art A conventional accumulator contains a gas bag inside a pressure-resistant container provided with a double valve cylinder at the bottom and inside.
Due to the inflating action of the gas bag, the pulsation of the high-pressure liquid sent from one valve cylinder into the pressure vessel is removed, and the pulsation is sent from the other valve body to the outside. [0003] Then, the inner valve cylinder is formed in an elbow shape having substantially the same cross-sectional area as the pipe, and the lower end thereof is directly passed through one of the pipes.
The outer valve cylinder is directly connected to the other pipe at the same or symmetrical position as the inner valve cylinder, and a valve element is disposed at a portion where the inner and outer double valve cylinders open into the pressure vessel. [0004] The conventional accumulator has the following problems. (1) If the accumulator gas filling pressure is higher than the circuit pressure, the separating member presses the valve body against the valve seat and closes the valve. Therefore, since the flow of the circuit is stopped, the passage on the entrance side and the exit side is not completely partitioned, and the through hole is formed. However, since this through hole is open even when the valve body of the accumulator is open, pulsation partially passes through this through hole, and good results cannot be obtained. (2) When the valve body of the accumulator is open, a malfunction occurs in the drive source, and when a large volume of liquid flows, a large force acts on the valve body of the accumulator due to a pressure difference. At this time, if the through hole is small, the pressure difference does not decrease, so the valve body is damaged.
Cannot absorb pulsation. (3) In the accumulator provided between the drive source and the actuator, when an abnormally high pressure is generated on the actuator side, the high-pressure liquid flows to the drive source side through the through-hole, and drives the drive source such as a pump. May cause damage. (4) The liquid that has flowed into the liquid chamber from the inner valve cylinder may immediately flow out of the outer valve cylinder without sufficiently entering the liquid chamber. Therefore, the function of the accumulator such as pulsation absorption may not be exhibited. The present invention has been made in view of the above circumstances, and has as its object to enable the function of an accumulator to be sufficiently performed and to prevent the occurrence of a breakage accident. Another object is to enable the hydraulic circuit to be used with a liquid pressure lower than the gas charging pressure of the accumulator. According to the present invention, there is provided an accumulator in which the interior of a container is partitioned into a gas chamber and a liquid chamber by a separating member, and the liquid chamber communicates with a fluid passage through a connecting passage; a check valve is provided in the fluid passage. is, the connecting passage consists of a inlet side connecting passage and the outlet-side connecting path away from each other, said input
The mouth side connection path is connected to the primary side of the check valve, and the outlet
The side connection passage is connected to the secondary side of the check valve, and
The check valve is configured to control the pressure on the primary side of the fluid passage and the secondary side.
Pressure does not reach the check valve cracking pressure.
Is closed, the check valve cracks.
The valve opens when the pressure reaches the
撃波 a accumulator, with check valve, wherein Rukoto such a closed state if occurs. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A separating member, for example, a diaphragm, a bladder, a rigid piston, or a metal bellows formed of an elastic material, forms a partitioning gas chamber and a liquid chamber inside a container portion of an accumulator. [0011] The accumulator is connected to the liquid passage through a connection passage. A check valve is provided in the liquid passage. The primary side of the check valve communicates with the liquid chamber via an inlet-side connection path, and the secondary side communicates with the liquid chamber via an outlet-side connection path. The two communication passages are separately formed at intervals, but the number, shape, diameter, position, and the like are appropriately selected as necessary. A valve body for protecting the separation member, for example, a poppet valve may be provided on the liquid chamber side of both connection paths. In this case, it is not always necessary to provide both connecting paths,
You may provide in either one. A drain hole may be formed near the valve seat of the valve body to prevent liquid from being sealed. The drain holes need not necessarily be provided over the entire circumference in the vicinity of both valve seats. For example, a plurality of drain holes may be provided in the vicinity of one of the valve seats at intervals in the circumferential direction. Embodiment 1 A first embodiment of the present invention will be described with reference to FIG. The accumulator ACC is a container unit 1 provided on the base B.
, A separating member 4, and a lid 2 for closing the container 1. A fluid passage W is provided in the base B, and a check valve 9 is provided in the fluid passage W. The cracking pressure of the check valve 9, that is, the pressure at which the check valve 9 opens is set, for example, to 0.7 to 5 kg / cm ² . At both ends of the liquid passage W, connection means, for example, screws SC are provided. The check valve 9 includes a truncated cone-shaped head 9A having a through hole 9a, a cylindrical spring chamber 9B accommodating a coil spring 10, and a spring stopper 11. The check valve 9 is not limited to this type, and other valves such as a ball valve and a butterfly valve may be used. The primary side of the liquid passage W, ie, the diameter d1 on the inlet 13 side, is formed smaller than the secondary side, ie, the diameter d2 on the outlet side 12, but these diameters d1, d2 may be changed as required. Selected as appropriate. The primary side 14 of the fluid passage W communicates with the liquid chamber 6 via the inlet side connection path 7, and the secondary side 15 communicates with the liquid chamber 6 via the outlet side connection path 8. Entrance side connection road 7
A plurality of outlet-side connection paths 8 are provided at intervals. The intervals, the number, the shape, the diameter, etc. of the connecting paths 7, 8 are appropriately selected as necessary. For example, seven inlet-side connecting paths 7 and outlet-side connecting paths 8 are provided with equal diameters.
The interval LM between the inner entrance-side communication path 7a and the inner exit-side communication path 8a may be made wider than the interval LN between the other communication paths. The diaphragm 4 constituting the separating member is made of natural rubber or the like, and its flange 4a is sandwiched between the container 1 and the lid 2. The interior of the container 1 is partitioned into a gas chamber 5 and a liquid chamber 6 by the diaphragm 4.
Gas is sealed in the gas chamber 5 through the air supply plug 3 at a predetermined pressure. Next, the operation of this embodiment will be described.
When the pressure liquid A is supplied to the liquid passage W from a pump (not shown), if the pressure of the pressure liquid A is higher than the gas pressure of the gas chamber 5, the inlet-side communication path 7 that has flowed into the inlet 13 of the fluid path W is connected. Then, it flows into the liquid chamber 6, receives an action such as pulsation absorption, and is directed to the outlet side communication path 8. Thereafter, the liquid A is discharged through the outlet side communication path 8 to the secondary side 15 with a pressure loss, and is supplied to an actuator (not shown). At this time, if the difference between the primary pressure and the secondary pressure of the fluid passage W does not reach the cracking pressure of the check valve 9, the check valve 9 is kept closed. Therefore, all of the liquid A flowing in the liquid passage W passes through the liquid chamber 6 of the accumulator ACC and is sufficiently supplied with an action such as pulsation absorption and then supplied to an actuator or the like. On the other hand, when the difference between the pressure on the primary side and the pressure on the secondary side of the fluid passage W reaches the cracking pressure of the check valve 9, the check valve 9 is pushed to the outlet 12 side and opens. The pressure liquid A on the primary side 14 directly flows out to the secondary side 15 through the through hole 9a. Therefore, the pressure liquid A on the primary side
Is supplied to the secondary side separately into a system flowing through the inlet-side connection path 7, the liquid chamber 6, and the outlet-side connection path 8, and a system flowing through the through hole 9a. Even if it flows, an appropriate amount of fluid flows in the accumulator and does not become abnormally high pressure, so that there is no breakage accident. If the gas filling pressure of the accumulator is set higher than the cracking pressure of the check valve, the check valve opens and flows directly to the secondary side even if a liquid having a pressure smaller than the filling pressure flows to the primary side. Therefore, a low-pressure liquid can be used without using an accumulator. Further, when a shock wave is generated on the actuator side, the secondary-side pressure liquid of the accumulator pushes the check valve 9 in the valve closing direction, that is, the primary side 14, and closes the liquid passage W. And the shock wave is not transmitted. For this reason, it is possible to prevent damage to the primary pump and the like. Embodiment 2 A second embodiment of the present invention will be described with reference to FIG. 2. The difference between this embodiment and the first embodiment is as follows. (1) The separating member is a pleated bladder formed in a bag shape by an elastic member such as rubber or synthetic resin, and has a plurality of pressure portions extending in the axial direction at intervals in the circumferential direction.
It should be easy to fold. (2) Inlet side connecting path 27 and outlet side connecting path 2
8 are formed one by one, and a valve body for protecting the bladder 24, for example, a poppet valve 21 is provided on the liquid chamber 26 side. This poppet valve 21
Need not necessarily be provided on both connecting paths 7 and 8, and may be provided on one of them, for example. (3) The liquid drain hole 23 is provided near the valve seat 25 of the poppet valve 21 and the cushion cup 29 is provided on the poppet valve 21. This liquid draining hole 23 prevents liquid from remaining in the liquid chamber 6 when the valve is closed, and its installation position can be appropriately selected as necessary. A plurality of seats 25 may be provided at intervals in the circumferential direction. The cushion cup 29 is for preventing the liquid drain hole 23 from being closed, that is, for forming a gap between the bottom surface 6a of the liquid chamber 6 and the bladder 24, and is made of an elastic material such as rubber. It is formed of plastic or the like. The shape and the like are appropriately selected as needed. Third Embodiment A third embodiment of the present invention will be described with reference to FIG. The difference between this embodiment and the second embodiment is as follows. (1) The separating member is a metal bellows 30.
One end of the fold wall 37 of the bellows 30 is a bellows lid 31.
, And the other end is sealed with a lid 32 having an air supply plug 33. The bellows 30 partitions the inside of the container 34 into a gas chamber 35 and a liquid chamber 36. (2) No drain hole for removing residual liquid is formed near the valve seat 25 of the poppet valve 21. However, it is a matter of course that a liquid draining hole may be provided in this embodiment as in the previous embodiment. Fourth Embodiment A fourth embodiment of the present invention will be described with reference to FIG. The difference between this embodiment and the second embodiment is as follows. (1) The separating member is the piston 44 formed on the base B, and the container is the cylinder 41. (2) Inlet side passage 47 and outlet side passage 48 on the liquid chamber 46 side
That no poppet valve is provided. The present invention has the following remarkable effects. (1) Since a check valve is provided in the liquid passage, if an unexpected flow rate flows on the primary side, the check valve opens, and a part of the primary-side pressure liquid passes through the accumulator, and the other part is directly on the secondary side. Drain. For this reason, an appropriate amount of liquid can be passed through the accumulator, so that the accumulator is not damaged. (2) When a shock wave is generated on the secondary side, the check valve is closed, and at the same time, it flows into the accumulator and flows to the primary side, so that the shock wave is not transmitted to the primary side. Therefore, there is no possibility that abnormally high pressure is applied to the drive source on the primary side or the like, so that there is no damage. (3) If the gas charging pressure of the accumulator is set higher than the cracking pressure of the check valve, the check valve opens and the liquid flows directly to the secondary side even if a liquid having a pressure lower than the sealing pressure flows to the primary side. I do. Therefore, a low-pressure liquid can be used without using an accumulator. (4) The connecting path comprises an inlet-side connecting path and an outlet-side connecting path which are separated from each other, an inlet-side connecting path is connected to the primary side of the check valve, and an outlet-side connecting path is connected to the secondary side. Therefore, the pressure liquid that has flowed into the liquid chamber from the inlet-side connection path sufficiently absorbs the pulsation while flowing through the liquid chamber, and is then discharged from the outlet-side connection path to the secondary side. For that reason,
Since an effect such as pulsation absorption can be sufficiently obtained as compared with the conventional example, an efficient accumulator can be obtained.

[Brief description of the drawings] FIG. 1 is a longitudinal sectional view showing a first embodiment of the present invention. FIG. 2 is a longitudinal sectional view showing a second embodiment of the present invention. FIG. 3 is a longitudinal sectional view showing a third embodiment of the present invention. FIG. 4 is a longitudinal sectional view showing a fourth embodiment of the present invention. [Explanation of symbols] 1 container part 4 Diaphragm 5 gas chamber 6 liquid chamber 7 Entrance side connection road 8 Exit side connection road 9 Check valve Exit 12 13 entrance 14 Primary side 15 Secondary side 21 Poppet valve 23 Drain hole 24 bladder 30 Bellows B base

Continuation of the front page (56) References JP-A-3-88982 (JP, A) JP-A-3-234922 (JP, A) JP-A-61-6401 (JP, A) JP-A-63-141301 (JP) , U) Fully open sho 61-157703 (JP, U) Fully open sho 60-127101 (JP, U) Real open hei 7-34280 (JP, U) Special table 10-505692 (JP, A) (58) Field surveyed (Int.Cl. ⁷ , DB name) F15B 21/11 F15B 1/08 F16K 15/02

Claims (1)

(57) [Claim 1] In an accumulator in which the interior of the container is partitioned into a gas chamber and a liquid chamber by a separating member, and the liquid chamber communicates with a fluid passage through a connection path; check valve is provided in the fluid passage, the connecting passage consists of a inlet side connecting passage and the outlet-side connecting path away from each other, the inlet-side connecting path is connected to the primary side of the check valve, the
The outlet connection passage is connected to the secondary side of the check valve .
The check valve is connected to the pressure on the primary side of the fluid passage and the secondary side.
The difference with the pressure on the side reaches the cracking pressure of the check valve
If not, the valve will be closed and the check valve will be cracked.
The valve opens when the operating pressure reaches the
An accumulator with a check valve, which is closed when a shock wave is generated .