KR101166371B1 - Membrane accumulator - Google Patents

Abstract

PURPOSE: A membrane type accumulator is provided to stabilize hydraulic machinery by guiding a stable vertical movement of a membrane as the surface of the membrane is ruggedly embossed. CONSTITUTION: A membrane type accumulator comprises an upper case(10), a lower case(20), and a membrane(30). An embossed part(34) is formed on the surface of the membrane and a flange part(11) is formed in the outer periphery of the upper case. Anti-movement protrusions are formed at the bottom of the flange part. In a state where the flange part is placed on the outer periphery of the top of the lower case spirally coupled with the upper case, the anti-movement protrusions of the flange part are inserted in anti-movement grooves and coupling parts of the upper case and the lower case are fixed according to a vertical movement of the membrane.

Description

Membrane accumulator

The present invention relates to a membrane-type accumulator, and more particularly, by embossing the surface of the membrane to make it easy to bend at any point of the surface of the membrane even if the fluid and gas pressure magnitudes are applied to the membrane differently. It relates to a membrane-type accumulator capable of inducing a stable vertical movement of.

In general, when the hydraulic pressure is generated in the fluid by the operation of the hydraulic pump, such as a hydraulic generator, the fluid is delivered along the hydraulic line. By the way, the fluid moving along the hydraulic line is rapidly changed in the hydraulic pressure by the operation of the pulsating wave, the hydraulic pump or the control valve, such that the hydraulic pressure is rapidly changed, causing failure or breakage of the hydraulic device or hydraulic line.

In other words, when the kinetic energy to be transmitted to the hydraulic system changes the hydraulic pressure momentarily, this energy is changed to the pressure energy instantaneously. The sudden change in the hydraulic pressure of the fluid causes damage to the hydraulic system or the hydraulic line. Accumulators are constructed in hydraulic equipment to protect hydraulic lines and hydraulic devices in response to changes.

These accumulators are generally classified into spring loaded, gas oil, bladder and membrane types.

Here, the membrane-type accumulator is provided with a membrane having elasticity therein, and buffers the hydraulic change through the deformation of the membrane.

The prior art related to the membrane accumulator may be exemplified by Korean Patent Application Publication No. 10-2009-0010550.

The prior art includes an upper body in which an injection hole is formed, a lower body in which a fluid connector is formed and coupled to the upper body to seal the inside, and a membrane disposed between the upper body and the lower body, wherein the membrane is Formed from H-NBR material is the technical gist.

The membrane-type accumulator of the above-described configuration stabilizes the hydraulic device by vertically moving the membrane by the fluid and gas pressure and performing a buffer function.

When the membrane performs vertical motion with fluid and gas pressures, bending occurs at some point on the surface of the membrane, and when the fluid and gas pressure magnitudes are applied to the membrane differently, the bending part of the membrane is also different due to the pressure difference. Will occur in.

However, the structure of the conventional membrane is not improved so that the bending can occur easily at any point, there is a problem that can not perform a stable vertical movement of the membrane if the fluid and gas pressure size acts differently.

Prior art literature

Document 1: Korean Patent Office Publication No. 10-2009-0010550

An object of the present invention for solving the above problems is to emboss the surface of the membrane unevenly so that the membrane can be easily bent at any point of the membrane even if the fluid and gas pressure magnitudes are applied to the membrane differently. It is to provide a membrane-type accumulator that can induce a stable vertical movement of the.

Another technical problem to be achieved by the present invention is to provide a membrane-type accumulator which prevents the flow between the upper case and the low case due to the vertical movement of the membrane.

The present invention for achieving the above object is an upper case formed with a male thread along the outer circumferential surface, and an internal thread formed for screwing the male thread of the upper case along the inner circumferential surface is screwed to the upper case and screwed. In the membrane-type accumulator comprising a membrane that fits into the low case and the inner space of the low case and partitions the space between the upper case and the low case, the surface of the membrane to form an embossed portion, the outer surface of the upper case Protruding and forming a flow preventing projection at the bottom, characterized in that the flow preventing groove for the flow preventing projection is recessed formed in the upper end of the outer surface of the low case.

A lower end of the membrane is provided with a stopper fixed with a rivet, the stopper is preferably formed of a stainless material, the rivet is preferably formed of an aluminum material.

According to the present invention, the surface of the membrane is embossed unevenly, so that even if the fluid and gas pressure sizes are differently applied to the membrane, bending can easily occur at any point of the membrane to induce stable vertical movement of the membrane to stabilize the hydraulic device. Implement possible effects.

In addition, the present invention implements the effect of preventing the flow between the upper case and the low case due to the vertical movement of the membrane by further forming a flow preventing protrusion and the flow preventing groove on the contact surface of the upper case and the low case.

1 is an exploded three-dimensional view of the configuration of a membrane accumulator according to a preferred embodiment of the present invention.
FIG. 2 shows a cross section of FIG. 1; FIG.
3 and 4 are views showing the operating state of the vertical and vertical movement of the membrane by the fluid and gas pressure, respectively.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following description will be presented a representative embodiment in the present invention to achieve the above technical problem. And other embodiments which may be presented by the present invention are replaced by descriptions in the constitution of the present invention.
1 is a three-dimensional view showing the configuration of a membrane accumulator according to the present invention, Figure 2 is a view showing a cross section of the membrane accumulator shown in FIG.
As shown in FIG. 1 and FIG. 2, the membrane accumulator 100 of the present invention is provided with at least one on a fluid conduit (not shown). The upper case 10 and the low case 20 are largely installed. ) And the membrane 30.
The upper case 10 has a hemispherical shape and a space 12 is formed therein, and a lower end thereof is opened. The gas inlet 14 for injecting gas into the inner space 12 of the upper case 10 is formed at the center of the upper end of the upper case 10.
In addition, a male screw thread 16 is formed on the outer circumferential surface of the upper case 10, and the male screw thread 16 is screwed to the female screw thread 26 formed on the inner circumferential surface of the low case 20, and the upper case. 10 is fixed to the low case 20.
The lower case 20 is located below the upper case 10, and has a hemispherical shape with a space 22 formed therein, and an upper end thereof is opened. The fluid inlet 24 is formed at the center of the lower end of the low case 20 so that the fluid flowing through the fluid pipe may be injected into the inner space 22 of the low case 20.
A female thread 26 is formed on the inner circumferential surface of the low case 20, and the female thread 26 is screwed with the male screw thread 16 formed on the outer circumferential surface of the upper case 10. The case 10 and the row case 20 are fastened to each other to form one case.
The membrane 30 partitions the upper case 10 and the inner spaces 12 and 22 of the low case 20 which are fitted into the inner space 22 of the low case 20 and are fastened to each other by screwing. , Has a hemispherical shape and the outer surface is fixed to the locking groove 28 formed on the inner circumferential surface of the low case 20. The membrane 30 is formed of a rubber material to fluidize through the fluid inlet 24 of the low case 20 while partitioning the inner spaces 12 and 22 of the upper and the low cases 10 and 20. When the fluid flowing through the conduit is injected, it is deformed by the fluid pressure at this time and rises upward to the center portion to buffer the pressure of the fluid, and also the gas pressure injected through the gas inlet 14 of the upper case 10. The sinking operation is performed, and this series of operations (vertical movement) stabilizes the hydraulic device by maintaining a constant pressure of the fluid flowing through the fluid line.
On the other hand, the entire surface of the membrane 30 is preferably formed by forming the embossed portion 34 unevenly. That is, as shown in FIGS. 3 and 4, when the membrane 30 performs vertical movement with fluid and gas pressures, bending occurs at a surface of the membrane 30, where the membranes have different fluid and gas pressure sizes. When applied to (30), bending occurs accordingly accordingly.
In consideration of this, the present invention forms an embossed portion 34 on the entire surface of the membrane 30 to easily bend at any point of the surface of the membrane 30 even if the fluid and gas pressures act on the membrane 30 differently. It will be able to induce and perform a stable vertical movement.
A stopper 44 is installed at the lower center of the membrane 30. Specifically, a hole 36 is formed in the center of the lower end of the membrane 30, and the pin part 42 of the rivet 40 is fitted into the hole 36, and a rivet penetrating the hole 36 is formed. The stopper 44 is fitted to the pin portion 42 of the 40 to constitute a coupling. The stopper 44 is closed by the gas pressure when the central portion of the membrane 30 is closed, so that the stopper 44 blocks the fluid inlet 24 through which the fluid is injected, thereby preventing the fluid from leaking.
The stopper 44 is continuously buried in the process of the stopper 44 blocking the fluid inlet 24 according to the continuous vertical movement of the membrane 30, so that the stopper 44 may be damaged due to the impact. There is a concern that by molding the stopper 44 in consideration of durability to reduce the damage of the stopper 44 as possible. In addition, the rivet 40 fixing the stopper 44 to the membrane 30 is preferably formed of aluminum as it is not directly impacted.
On the other hand, the flange 11 is formed on the outer surface of the upper case 10 described above, The flow preventing protrusions 50 protrude from the lower end of the flange portion 11, and the flow preventing protrusions 50 are fitted to the upper end of the outer surface of the low case 20 fastened below the upper case 10. The flow preventing groove 52 is recessed. That is, the upper case 10 and the low case 20 which are first screwed together are vertically moved in the membrane 30 (that is, the membrane center portion rises or sinks down due to fluid and gas pressure). The upper case 10 and the low case 20 may be shaken and flow due to the impact of the upper case 10 and the lower case 20, and when the flow occurs continuously, the coupling portions of the upper and low cases 10 and 20 may be slipped and released. The flow preventing protrusion 50 and the flow preventing groove 52 fix the upper and the low cases 10 and 20 so that the upper and the low cases 50 and 52 are prevented from slipping. will be.

Hereinafter, the operation of the membrane accumulator according to the present invention will be described with reference to FIGS.
When assembling the membrane type accumulator according to the present invention, first, the upper case 10 and the low case 20 are separately formed, and then the membrane 30 is placed in the inner space 22 of the low case 20. Next, the outer surface 32 of the membrane 30 is inserted into the locking groove 28 formed on the inner circumferential surface of the low case 20.
Subsequently, the male screw thread 16 formed on the outer circumferential surface of the upper case 10 is screwed onto the female thread thread 26 formed on the inner circumferential surface of the lower case 20, and the upper case 10 is lowered. Fastening to the case 20 is fixed. At this time, the flow preventing protrusion 50 protruding from the bottom of the outer surface of the upper case 10 is fitted into the flow preventing groove 52 recessed and formed in the upper end of the outer surface of the low case 20 and the membrane 30. The upper case 10 and the low case 20 are fixed so as not to flow with each other due to the impact of the vertical movement of the).
That is, in the membrane-type accumulator 100 assembled in the above configuration, when the membrane 30 performs vertical movement under fluid and gas pressure, bending occurs at a certain point of the surface of the membrane 30. When the fluid and gas pressure magnitudes act on the membrane 30 differently through the embossed portion 34 formed on the entire surface of the 30, the membrane 30 is easily bent at any point of the surface of the membrane 30. It will lead to stable vertical movement.

10: upper case 16: male thread
20: low case 26: internal thread
30 membrane 34 embossing portion
40: rivet 44: stopper
50: flow preventing projection 52: flow preventing groove

Claims (2)

An upper case 10 having a male thread 16 formed along an outer circumferential surface thereof, and a female thread 26 for fastening a male thread 16 of the upper case 10 along a inner circumferential surface thereof are formed in the upper case. It fits into the low case 20 and the low case 20 inner space 22 which is screwed to the 10 and partitions the spaces 12 and 22 of the upper case 10 and the low case 20. In the membrane type accumulator comprising a membrane 30 to make,
The surface of the membrane (30) causes an embossed portion (34) to be formed;
An outer surface of the upper case 10 has a flange portion 11 formed therein, and a lower end of the flange portion 11 protrudes from a flow preventing protrusion 50;
The flow preventing protrusion 50 of the flange portion 11 is inserted into an upper end of the outer surface of the low case 20 which is screwed to the upper case 10 so that the flange portion 11 is settled. Recessed grooves 52 are formed to be recessed so that the coupling portions of the upper case 10 and the lower case 20 which are screwed together according to the vertical movement of the membrane 30 are fixed so as not to slip. Membrane accumulator, characterized in that.

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