KR101107299B1 - Seawater erosion fatigue testor - Google Patents

Abstract

A seawater corrosion fatigue tester is disclosed in which the specimens are fatigued only by the seawater and the seawater does not leak out of the tank, allowing precise testing.

Seawater corrosion fatigue tester according to the present invention, the water tank is accommodated; A lower connector supporting the tank by mounting the tank on an upper surface thereof; And a specimen through which the tank passes in a vertical direction and a lower portion thereof is fastened to the lower connector. Is formed, and a first fastening groove into which the first fastening protrusion is fitted is formed on an upper surface of the lower connector, and the water tank and the lower connector may be configured to be detachable.

By the above configuration, the present invention is that the load of the water tank and the sea water is applied to the lower connector, the specimen is fatigued only by the sea water, and the seawater does not leak from the tank as the airtight member is formed between the water tank and the specimen, You can make precise experiments.

Seawater Corrosion, Fatigue Test, Water Tank, Specimen, Connector, Actuator, Spring Member

Description

Seawater erosion fatigue testor

The present invention relates to a seawater corrosion fatigue tester, the seawater corrosion fatigue tester to be able to perform a precise experiment by the specimen is fatigued only by sea water and seawater does not leak out of the tank.

1 is a front view showing a seawater corrosion fatigue tester according to the prior art.

Referring to the drawings, the seawater corrosion fatigue tester includes a water tank 2 in which sea water 1 is accommodated, a specimen 3 installed through the water tank 2, and a support member to which the lower portion of the specimen 3 is fastened ( 4) is provided.

The seawater corrosion fatigue tester configured as described above is used in an experiment for observing the impact on the fracture surface of the specimen 3 by applying a fatigue stress when the specimen 3 is corroded by the seawater 1.

However, as the tank 2 is spaced apart from the lower support member 4 and installed on the specimen 3, the load of the tank 2 is applied to the specimen 3, and the tank 2 and the specimen ( 3) When seawater 1 leaks through a gap between them, there is a limit that precise experiments are not performed.

The present invention was devised to solve the above problems, and the object thereof is to provide a seawater corrosion fatigue tester that allows the specimen to be subjected to precise experiments by being fatigued only by seawater and not leaking from the tank. have.

Seawater corrosion fatigue tester according to a preferred embodiment of the present invention in order to achieve the above object, the water tank is accommodated; A lower connector supporting the tank by mounting the tank on an upper surface thereof; And a specimen through which the tank passes in a vertical direction and a lower portion thereof is fastened to the lower connector. Is formed, the upper surface of the lower connector is formed with a first fastening groove into which the first fastening protrusion is fitted, the water tank and the lower connector is configured to be detachable.

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In addition, the airtight member is preferably configured to be waterproof at the edge of the passage hole through which the specimen passes in the water tank.

And, the present invention, the upper connector is installed on the upper surface of the water tank is fastened to the upper portion of the specimen; A case having a lower frame on which the lower connector is installed and an upper frame disposed on an upper side of the upper connector, wherein the lower frame and the upper frame are connected and fixed; And an actuator configured to provide a fatigue stress to the specimen through the seawater while connecting the upper connector and the upper frame.

In addition, the present invention, the connecting member is provided radially from each of the upper connector and the lower connector, the slide hole is formed; And a slide bar installed in the case in a vertical direction so as to be inserted into the slide hole of the connection member so that the connection member can slide upward and downward.

In addition, the present invention may further include a spring member surrounding the slide bar between the connecting members spaced apart from each other so as to elastically support the connecting members respectively connected to the upper connector and the lower connector.

In addition, a second fastening protrusion protruding in one direction is formed on an upper surface of the water tank, and a second fastening groove is formed in the lower surface of the upper connector to which the second fastening protrusion is fitted, and the water tank and the upper connector are detachable. It is preferably configured to be possible.

On the other hand, the present invention, a jig mounted on the upper surface of the lower frame and the lower surface of the upper frame, further comprising; the lower connector for the lower frame, and the actuator for the upper frame is positioned by the jig It is preferable to be fixedly installed.

Further, it is more preferable that a plurality of fatigue test units including the lower connector, the specimen, the water tank, and the upper connector are stacked between the lower frame and the upper frame of the case.

In the seawater corrosion fatigue tester according to the present invention, the specimen is subjected to fatigue only by the seawater as the load of the tank and the seawater is applied to the lower connector, and the seawater does not leak from the tank as the airtight member is formed between the tank and the specimen. It has the effect of making precise experiments possible.

Figure 2 is a front view showing an embodiment of the seawater corrosion fatigue tester of the present invention, Figure 3 is a perspective view of one embodiment of the seawater corrosion fatigue tester of Figure 2, Figure 4 is another embodiment of the seawater corrosion fatigue tester of the present invention 5 is a perspective view showing that the seawater corrosion fatigue tester of FIG.

Referring to the drawings, the seawater corrosion fatigue tester of the present invention, the water tank 20, the lower connector 40 for supporting the water tank 20, and the specimen passing through the water tank 20 is accommodated (30).

The water tank 20 has a space formed therein to accommodate the sea water 1 used for the corrosion fatigue test.

The water tank 20 is formed with an inlet 20b through which the seawater 1 flows in one side, and an outlet 20c through which the seawater 1 is discharged.

As the seawater 1 is introduced into the water tank 20 through the inlet 20b by the pump (not shown) and discharged out of the water tank 20 through the outlet 20c, the seawater (in the water tank 20) 1) may flow and consequently may exert fatigue stress on the specimen (30).

In addition, the lower connector 40 supports the water tank 20 by mounting the water tank 20 on the upper surface.

That is, unlike the prior art, the water tank 20 is directly supported while contacting the lower connector 40, the total load of the water tank 20 and sea water 1 is applied to the lower connector 40.

Here, the lower connector 40 has a first fastening groove 41 is formed on the upper surface so that the water tank 20 seated on the upper surface is detachable.

In addition, of course, the tank 20 is provided with a first fastening protrusion 21 fitted into the first fastening groove 41.

That is, a first fastening protrusion 21 protruding in one direction is formed on a lower surface of the water tank 20, and a first fastening groove into which the first fastening protrusion 21 is fitted on an upper surface of the lower connector 40. 41 can be formed.

As described above, as the first fastening protrusion 21 is fitted into the first fastening groove 41 to fasten the water tank 20 to the lower connector 40, the fastening force of the water tank 20 to the lower connector 40. Becomes high.

In this case, a plurality of first fastening grooves 41 and first fastening protrusions 21 may be configured to correspond to each other to improve the fastening force.

In addition, the specimen 30 passes through the water tank 20 in the vertical direction and the lower portion is fastened to the lower connector 40.

Here, as the lower fixing hole 43 is formed in the lower connector 40, the specimen 30 is fitted into the lower fixing hole 43 and fixed in position.

In addition, a lower fitting hole 40a is formed in the lower connector 40, and as a coupling member such as a coupling pin is fitted into the lower fitting hole 40a and fits into the lower hole 30a of the specimen 30. The specimen 30 is firmly fixed to the lower connector 40.

As described above, the specimen 30 is fixed while forming a structure passing through the water tank 20. For this purpose, the water tank 20 has a through hole 20a formed on the upper and lower surfaces thereof.

Of course, the through hole 20a has a diameter equal to the diameter of the specimen 30, but a gap may occur between the specimen 30 and the through hole 20a due to an external force such as the flow of seawater 1. have.

The gap is a passage through which the sea water 1 in the water tank 20 leaks outward, and the specimen 30 is passed through the water tank 20 to prevent the sea water 1 from leaking through the gap. The airtight member 25 is comprised in the edge of the passage hole 20a so that waterproofing may be carried out.

Specifically, the airtight member 25 is disposed along the inner edge of the water tank 20 to form the through hole 20a, so that the specimen 30 pushes the airtight member 25 toward the water tank 20. Accordingly, the gap between the specimen 30 and the water tank 20 is airtight. This prevents the connector from being corroded by the leaked seawater 1 and at the same time enables precise experiments.

On the other hand, the present invention is the upper connector 50 is installed on the upper surface of the water tank 20, the case 80 having a lower frame 82 and the upper frame 84, and the upper connector 50 and the upper frame ( 84 may further include an actuator 60 for connecting.

The upper connector 50 is disposed on the upper surface of the water tank 20, the upper portion of the specimen 30 is fastened.

That is, similar to the fastening of the specimen 30 to the lower connector 40, the upper portion of the specimen 30 passed through the water tank 20 is fastened to the upper connector 50.

Here, as the upper fixing hole 53 is formed in the upper connector 50, the specimen 30 is fitted into the upper fixing hole 53 is fixed.

In addition, a lower fitting hole 40a is formed in the upper connector 50, and a coupling member such as a coupling pin is fitted into the upper fitting hole 50a and fitted into the upper hole 30b of the specimen 30. The specimen 30 is firmly fixed to the upper connector 50.

Preferably, the upper connector 50 has a second fastening groove 51 formed on the lower surface such that the water tank 20 in contact with the lower surface is detachable.

In addition, of course, the tank 20 is provided with a second fastening protrusion 22 fitted in the second fastening groove.

That is, a second fastening protrusion 22 protruding along one direction is formed on an upper surface of the water tank 20, and a second fastening groove into which the second fastening protrusion 22 is fitted on a lower surface of the upper connector 50. 51 may be formed.

On the other hand, the case 80 is provided with a lower frame 82, the lower connector 40 is installed on the upper surface, and an upper frame 84 disposed above the upper connector 50, such a lower frame 82 ) And the upper frame 84 is configured to be connected and fixed.

The case 80 serves to ensure that the lower connector 40, the water tank 20, and the upper connector 50 are firmly positioned on the ground.

The actuator 60 provides fatigue stress to the specimen 30 through the seawater 1 while connecting the upper connector 50 and the upper frame 84.

That is, the actuator 60 is positioned between the upper connector 50 and the upper frame 84 and fastened to both sides, and generates a movement such as vibration so that the specimen 30 is subjected to fatigue stress through the seawater 1. do.

In addition, the present invention, as shown in Figure 5, the connecting member 70 provided in the upper connector 50 and the lower connector 40, respectively, and the slide bar (fitted vertically to the connecting member 70) 86, and a spring member 88 surrounding the slide bar 86 may be further included.

The connecting member 70 is radially installed from each of the upper connector 50 and the lower connector 40, and a slide hole 70a is formed at an end thereof.

At this time, the slide bar 86 is fitted in the slide hole 70a of the connecting member 70 so that the connecting member 70 can slide up and down, and is installed in the case 80 in the vertical direction.

In addition, the spring member 88, the slide bar 86 between the spaced apart connecting member 70 to elastically support the connecting member 70 connected to the upper connector 50 and the lower connector 40, respectively. It is configured to surround.

Accordingly, the specimen 30 is not subjected to fatigue stress due to the flow of the seawater 1 by the pump and the external force rather than the vibration by the actuator 60.

That is, when external force is transmitted through the weight and the case 80 by components other than the specimen 30 such as a connector, the lower connector 40 and the upper connector 50 slide by the connecting member 70. The external force can be absorbed by the elastic force of the spring member 88 in the process of sliding up and down along the bar 86 and sliding.

In addition, a jig 99 may be mounted on an upper surface of the lower frame 82 and a lower surface of the upper frame 84, respectively.

This jig 99, the lower connector 40 for the lower frame 82, and the actuator 60 for the upper frame 84 is to be firmly fixed as it is fitted.

On the other hand, in the present invention, consisting of a lower connector 40, a specimen 30, the water tank 20 and the upper connector 50 disposed between the lower frame 82 and the upper frame 84 of the case 80 It is preferable that a plurality of fatigue test units 90 are stacked.

At this time, the lower fastening hole 42 of the lower connector 40 and the upper fastening hole 52 of the upper connector 50 are in line with each other, and a fastening member such as a fastening pin is inserted therein to the lower connector. 40 and the upper connector 50 is coupled to each other.

In addition, an insulating member (not shown) may be provided between the lower connector 40 of the one fatigue test unit 90 and the upper connector 50 of the other fatigue test unit 90 which is connected adjacent thereto. Thus, each of the specimens 30 may be insulated against, for example, the current from the actuator 60 and so on, so as not to affect the corrosion.

The plurality of fatigue test units 90 as described above enable precise experiments in the seawater corrosion fatigue test.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1 is a front view showing a seawater corrosion fatigue tester according to the prior art.

Figure 2 is a front view showing an embodiment of the seawater corrosion fatigue tester of the present invention.

3 is a perspective view of one embodiment of the seawater corrosion fatigue tester of FIG.

Figure 4 is a front view showing another embodiment of the seawater corrosion fatigue tester of the present invention.

5 is a perspective view showing that the seawater corrosion fatigue tester of FIG.

DESCRIPTION OF THE REFERENCE SYMBOLS

1: seawater 20: tank

21: first fastening protrusion 22: second fastening protrusion

20a: through hole 20b: inlet

20c: outlet 25: airtight member

30: test piece 30a: lower hole

30b: upper hole 40: lower connector

40a: lower fitting hole 41: first fastening groove

42: lower fastening hole 43: lower fixing hole

50: upper connector 50a: upper insertion hole

51: second fastening groove 52: upper fastening hole

53: upper fixing hole 60: actuator

70: connecting member 70a: slide hole

80: case 82: lower frame

84: upper frame 86: slide bar

88: spring member 90: fatigue test unit

99: jig

Claims (10)

A tank in which seawater is accommodated; A lower connector supporting the tank by mounting the tank on an upper surface thereof; And Specimens passing through the water tank in the vertical direction and the lower portion is fastened to the lower connector, the load of the water tank and sea water is applied to the lower connector, A first fastening protrusion protruding in one direction is formed on a lower surface of the water tank, and a first fastening groove is formed on the upper surface of the lower connector so that the first fastening protrusion is fitted, so that the water tank and the lower connector are detachable. Seawater corrosion fatigue tester, characterized in that the configuration. delete The method of claim 1, The seawater corrosion fatigue tester, characterized in that the airtight member is configured to be waterproof at the edge of the passage hole through which the specimen passes in the water tank. The method of claim 1, An upper connector installed on an upper surface of the tank and fastened to an upper portion of the specimen; A case having a lower frame on which the lower connector is installed and an upper frame disposed on an upper side of the upper connector, wherein the lower frame and the upper frame are connected and fixed; And An actuator configured to provide fatigue stress to the specimen through the seawater while connecting the upper connector and the upper frame; Seawater corrosion fatigue tester, characterized in that it further comprises. 5. The method of claim 4, A connecting member radially installed from each of the upper connector and the lower connector and having a slide hole; And A slide bar installed in the case in a vertical direction to be inserted into a slide hole of the connection member so that the connection member can slide up and down; Seawater corrosion fatigue tester, characterized in that it further comprises. The method of claim 5, A spring member surrounding the slide bar between the connecting members spaced apart from each other so as to elastically support the connecting members respectively connected to the upper connector and the lower connector; Seawater corrosion fatigue tester, characterized in that it further comprises. 5. The method of claim 4, On the upper surface of the tank is formed a second fastening protrusion protruding in one direction, On the lower surface of the upper connector is formed a second fastening groove into which the second fastening protrusion is fitted, The water tank and the upper connector is a seawater corrosion fatigue tester, characterized in that configured to be removable. 5. The method of claim 4, Further comprising: a jig mounted on the upper surface of the lower frame and the lower surface of the upper frame, respectively, The seawater corrosion fatigue tester, characterized in that the lower connector to the lower frame, and the actuator for the upper frame is fixedly installed by the jig. 5. The method of claim 4, Between the lower frame and the upper frame of the case, Seawater corrosion fatigue tester, characterized in that a plurality of fatigue test unit consisting of the lower connector, the specimen, the water tank and the upper connector is stacked. 10. The seawater corrosion fatigue tester according to claim 9, wherein an insulation member is provided between the lower connector of the fatigue test unit and the upper connector of another fatigue test unit connected adjacent thereto.

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