KR20110011769U - appratus for dynamic pile load test - Google Patents

Abstract

The present invention can minimize the overall size and maintain a stable installation, but can be easily installed, and a new type of pile rod that enables the load test without the use of equipment such as a separate crane. It relates to a test apparatus.
To this end, the present invention is located on the upper side of the pile drop hammer hitting the pile by a selective free fall; A pile seating portion including a lower support plate mounted on an upper surface of the pile and a plurality of pile support guides protruding from the bottom of the lower support plate along the upper circumferential surface of the pile; The upper support plate is fixed to the upper surface of the lower support plate constituting the pile seat portion and a plurality of hammer support guides that are formed to protrude along the vertical direction from the upper surface of the upper support plate to guide the fall of the drop hammer in place A hammer support; A hammer operating part which moves the drop hammer upward and free-falls the drop hammer; And, the load analysis device for analyzing the received from the measuring gauges installed in the piles received by the drop hammer when the impact of the impact applied to the piles received measurement data: dynamic load test apparatus characterized in that it comprises a configuration do.

Description

Apparatus for dynamic pile load test

The present invention relates to a pile load test device, more specifically, to minimize the overall size and to maintain a stable installation state can be made easy to install, using a separate crane-like equipment It relates to a new type of pile loading test device which enables the loading test without the need.

In general, the load test device is a device to determine the static bearing capacity of piles, to measure the behavior of piles and grounds during pile driving, and to verify the performance of the driving equipment.

1 is a schematic view showing a structure of a conventional general loading test apparatus, and as can be seen from the drawing, a conventional general loading test apparatus includes a drop hammer 10, a main frame 20, and a driving analyzer ( 50).

Here, the main frame 20 is a series of configurations to guide the drop path of the drop hammer 10 while being installed to surround the head portion of the pile 1 along the periphery of the ground on which the pile 1 is installed, The drop hammer 10 is a series of configurations to drive the pile (1) while being selectively dropped by the crane (2) in a state located on the top of the main frame (20), the drive analysis analyzer (50) Is a device that analyzes after receiving the measurement data through the measuring gauge (3) embedded in the pile (1).

The load test apparatus as described above freely falls the drop hammer 10 lifted by the crane 2 to hit the pile 1, and the impact of the hit of the pile 1 causes the measurement gauge 3 to fall. By being provided to the drive analyzer 50 through the analysis, it is possible to obtain the magnitude of the load that can be supported within the limit load or allowable settlement of the pile (1).

The conventional dynamic load test apparatus as described above has been provided in various structures such as Korean Patent Publication No. 10-0779486 and Korean Utility Model Publication No. 20-0142328.

However, in the conventional load-bearing test apparatus described above, when the main frame 20 is installed on the ground while the ground is not firm, the heavy drop hammer 10 falls along the main frame 20. There is a possibility that the main frame 20 is inclined during the fall, thereby causing a fall eccentricity has a problem that the accurate load test does not proceed.

In particular, in order to stably install the main frame 20 on the ground, the overall structure is inevitably increased, and a separate structure (for example, a ground fixing wire) for preventing the main frame 20 from tilting is provided. There is a problem that it is additionally necessary.

In addition, the load-bearing test apparatus according to the prior art described above should be formed so that the height of the entire main frame 20 reaches the height of the height of the pile 1 plus the reference drop height of the drop hammer 10 is added. This is not easy and has a problem that construction is difficult for installation.

In addition, the load-bearing test apparatus according to the prior art described above is to increase the cost due to the use of the equipment and equipment for the installation of the crane (2) equipment as additional equipment should be provided for the lifting of the drop hammer (10) There is a problem that an increase in working time is inevitably caused.

The present invention has been devised to solve the various problems according to the prior art described above, an object of the present invention to prevent the tilting of the main frame when the drop hammer falls, so that the exact load test can be carried out, It is to provide a new type pile loading test device that can be installed and transported by minimizing the overall height, and to be able to test loads without using equipment such as a separate crane.

According to the dynamic load test apparatus of the present invention for achieving the above object, a drop hammer positioned on the upper side of the pile and hitting the pile by a selective free fall; A pile seating portion including a lower support plate mounted on an upper surface of the pile and a plurality of pile support guides protruding from the bottom of the lower support plate along the upper circumferential surface of the pile; The upper support plate is fixed to the upper surface of the lower support plate constituting the pile seat portion and a plurality of hammer support guides that are formed to protrude along the vertical direction from the upper surface of the upper support plate to guide the fall of the drop hammer in place A hammer support; A hammer operating part which moves the drop hammer upward and free-falls the drop hammer; And, it is characterized in that it is configured to include a drive analysis analyzer for receiving and analyzing the measurement data according to the impact applied to the pile when hitting the pile by the drop hammer from the measuring gauge installed in the pile.

Here, the drop hammer comprises a ram formed by stacking a plurality of iron plates, and a plurality of coupling brackets are fixed while being formed along the stacking direction of each iron plate on each circumferential surface of the ram, the ram is a plurality While being provided as being stacked with each other, the upper end and the lower end of each coupling bracket is characterized in that it is gradually formed outwardly inclined toward the top.

In addition, each pile support guide constituting the pile seat is characterized in that one or two or more H-beams are formed in a continuous radial direction from the outer peripheral surface of the pile.

In addition, the length of each pile support guide constituting the pile seat is characterized in that it is formed to have a length that does not reach to the installation height of the measuring gauge is buried in the pile.

In addition, the lower end of each support guide for the pile forming the pile seat is characterized in that it is gradually inclined outward toward the bottom.

In addition, the hammer support guide constituting the hammer support portion is formed to be bent to form the same shape as the corner shape of the drop hammer so as to surround each corner of the drop hammer, the drop hammer on the outer surface of the support guide for each hammer The free fall of the hammer is characterized in that it further comprises a guide frame for preventing the bending of the support guide for the hammer.

In addition, between the lower support plate constituting the pile seat and the upper support plate constituting the hammer seat is characterized in that it is configured to be selectively coupled or separated through the bolt fastening.

In addition, an upper portion of the drop hammer protrudes a ring portion through which a locking hole is formed, and the hammer operation portion is installed at an upper end of the hammer support portion, is drawn out toward the drop direction of the drop hammer, and a bottom of the drop hammer It is configured to include a main cylinder having a main rod formed with an accommodating portion for accommodating the annular portion, and a coupling portion which is installed at the end of the main rod and coupled to each other when the annular portion of the drop hammer is accommodated in the accommodating portion of the main rod. It features.

In addition, the coupling part is an auxiliary cylinder which is fixed to the end circumferential wall of the main rod, and the auxiliary rod for sequentially coupling through the receiving portion of the main rod and the ring portion of the drop hammer by the drive of the auxiliary cylinder to be coupled to each other Characterized in that configured to include.

As described above, the load-bearing test apparatus of the present invention is configured so that the structure supporting the free fall of the drop hammer can be directly installed on the top of the pile, thereby minimizing the overall size of the load-bearing test apparatus and the stable installation state. It is possible to maintain the installation can be made easily.

In particular, in the dynamic load test apparatus of the present invention, by configuring the hammer operating part for free fall of the drop hammer in a cylinder structure, the dynamic load test is possible without using a separate crane-like equipment, and it is possible to reduce the working time as accurately as possible. Has the added effect.

1 is a structural diagram showing to explain a conventional common load test apparatus
Figure 2 is a structural diagram showing to explain the loading test apparatus according to a preferred embodiment of the present invention
Figure 3 is a configuration diagram showing in more detail to explain the structure of the drop hammer of the load tester according to a preferred embodiment of the present invention
Figure 4 is a block diagram showing in more detail to explain the structure of the pile seat portion and the hammer support of the load tester according to a preferred embodiment of the present invention
5 and 6 is a bottom view showing to explain the structure of the pile seat portion and the use example of the load tester according to a preferred embodiment of the present invention
Figure 7 is a plan view showing to explain the structure of the hammer support of the load tester according to a preferred embodiment of the present invention
8 to 11 is a block diagram showing the structure and operation state of another embodiment of the hammer operation unit of the load tester according to a preferred embodiment of the present invention

Hereinafter, a preferred embodiment of the dynamic load tester of the present invention will be described with reference to FIGS. 2 to 11.

Prior to the description of the structure of the embodiment, the dynamic load test apparatus of the present invention is a device for the dynamic load test of the pile (1) embedded in the ground, wherein the pile (1) to measure the impact applied to the pile hitting The measuring gauge 3 is buried.

As shown in FIG. 2, the load test apparatus according to the embodiment of the present invention has a large drop hammer 100, a pile seating part 200, a hammer support part 300, a hammer operating part 400, and It is configured to include a drive analyzer 500.

This will be explained in more detail for each configuration.

First, the drop hammer 100 is a series of configurations for hitting the pile (1), located on the upper side of the pile (1) constructed on the ground and configured to hit the pile (1) by a selective free fall do.

The drop hammer 100 is a ram 110 formed by stacking a plurality of iron plate as shown in Figure 3, and is fixed while being formed along the lamination direction of each iron plate on each circumferential surface of the ram 110 It is configured to include a plurality of coupling brackets (120).

In this case, the RAM 110 is provided in plurality to be stacked on each other to form the drop hammer 100.

In particular, the upper end and the lower end of each coupling bracket 120 constituting the drop hammer 100 is preferably formed to be inclined outward gradually toward the top. This is to ensure that the position of each ram 110 can be exactly matched by the structural features of the coupling bracket 120 in the process of stacking each ram 110 with each other.

In addition, the upper portion of the ram 110, which is located on the uppermost side of each of the rams 110 forming the drop hammer 100 is formed with a protruding portion 111, the hook portion 111 in the engaging hole ( 112 is formed through. At this time, the structure of the ring portion 111 is configured to be smoothly connected to the hammer operation unit 400 to be described later.

Next, the pile seat 200 is configured as a series of coupling fixed to the pile 1, it is composed of a lower support plate 210 and the support guide 220 for the pile as shown in FIG.

Here, the lower support plate 210 is a portion that is placed on the upper surface of the pile 1, it is formed of a flat metal plate.

In addition, the pile support guide 220 is provided as a series of configurations to support while surrounding the upper periphery of the pile (1), each of which is provided with a plurality of each of the pile (1) from the bottom of the lower support plate 210 It is formed to protrude so as to be in close contact along the circumferential surface of the top side.

Particularly, in the embodiment of the present invention, the support guides 220 for each pile are provided while forming a double row along the radial direction from the outer circumferential surface of the pile 1 and each of them is formed as an H-beam. Additionally. Such a structure is intended to enable common use regardless of the diameter of the pile (1) subject to the load test.

That is, in the case of the copper loading test for the pile 1 having a relatively large diameter as shown in FIG. 5, the pile support guides 220 forming the outer row are in close contact with the outer circumferential surface of the pile 1. ) Is configured to wrap, and when the load test for the relatively small diameter pile (1) as shown in Figure 6 attached to each pile support guide 220 forming an inner row in close contact with the outer peripheral surface of the pile (1) Will be configured to wrap the pile (1).

At this time, the support guides 220 for the piles of each row are configured to be selectively coupled or separated by bolting or the like.

In addition, the length of each of the pile support guides 220 is formed to have a length not to reach the installation height of the measuring gauge (3) buried in the pile (1).

In addition, the lower end of each of the pile support guides 220 is formed to be inclined outward gradually toward the bottom. Such a structure can be accurately guided to the inside of each of the pile support guides 220 by the inclined portion in the process of installing the support guides 220 for each pile to the pile (1). It is to ensure that.

Next, the hammer support portion 300 is a series of configurations for supporting to guide the fall of the drop hammer 100 in place.

The hammer support 300 is composed of an upper support plate 310 and the support guide for the hammer 320 as shown in Figure 4 and 7 attached.

Here, the upper support plate 310 is a series of components that are fixed to the upper surface of the lower support plate 210 forming the pile seat 200, the hammer support guide 320 is the upper surface of the upper support plate 310 It is a series of configuration to support to guide the drop in place of the drop hammer 100 while being formed to protrude along the vertical direction from.

In this case, the upper support plate 310 is preferably configured to be selectively coupled or separated through the lower support plate 210 and the bolt fastening. This structure is configured to minimize the height during transportation by being configured to be separated between the pile seat 200 and the hammer support 300.

In addition, the hammer support guide 320 is provided in plurality so as to support the four corner portions of the drop hammer 100 are respectively installed on the four corner portions of the upper surface of the upper support plate 310, each of the hammer The support guides 320 are formed to be bent to surround the edge of the drop hammer 100.

In addition, the outer surface of each of the hammer support guide 320 is configured to further include a guide frame 330, the guide frame 330 wraps the hammer support guide 320 in a horizontal direction By configuring so that the free fall of the drop hammer 100 to prevent the bending of the support guide for each hammer (320).

Next, the hammer operation unit 400 is a series of configurations for freely falling while moving the drop hammer 100 upward.

In the present invention, the hammer operation part 400 is an example of a conventional crane.

At this time, the crane is operated to lift or drop freely the drop hammer 100 using the ring portion 111 formed on the upper surface of the drop hammer 100.

Next, the drive analyzer 500 measures the measurement data according to the impact applied to the pile (1) when the pile hit by the drop hammer 100 from the measuring gauge (3) buried in the pile (1) A series of configurations that are provided and analyzed.

At this time, the anti-taking analyzer 500 may be a conventional PDA (PDA) terminal.

In the following, it will be described in more detail with respect to the dynamic load test process using the dynamic load test apparatus according to an embodiment of the present invention configured as described above.

First, the measuring gauge 3 is embedded in the pile 1 and the drive analyzer 500 is connected to the measuring gauge 3.

In this state, the pile mounting portion 200 is coupled to the pile 1 by placing it on the upper end of the pile 1 to surround the plurality of pile support guides 220 constituting the pile mounting portion 200. In this case, the upper circumferential surface of the pile 1 is in close contact with the inner wall surface of the support guide 220 for each pile can be prevented from flowing of the pile seat 200.

If the pile 1 is a pile having a large diameter standard, the above-described process is performed after removing the pile support guide of the inner row of the pile support guides 220 formed of a double row as shown in FIG. 5. At this time, the removal of the support guides for the piles in the inner row is to release the fastening of the bolts coupling the support guides for the piles in each row.

In addition, the lower end of each pile support guide 220 constituting the pile seating portion 200 inclined outward gradually toward the bottom in the process of mounting the pile seating portion 200 to the top of the pile 1 as described above Considering that it is formed, although the position of the support guide for the pile 220 and the top position of the pile 1 does not exactly match each other, the position of the pile support guide 220 as the coupling progresses with each other is the pile (1) Are matched to match the position of.

And, as described above, when the coupling of the pile seat 200 to the pile 1 is completed, the hammer support 300 is fixed to the upper surface of the pile seat 200.

At this time, the coupling of the hammer support part 300 by coupling the upper support plate 310 constituting the hammer support part 300 on the upper surface of the lower support plate 210 of the pile seat 200 by fastening and coupling with each other. Is done.

Next, a drop hammer 100 is provided into the hammer support guide 320 of the hammer support part 300.

Subsequently, when the drop hammer 100 releases its restraint while being positioned at the top of the hammer support 300, the drop hammer 100 hits the top of the pile while falling freely by its own weight. In this case, since the drop hammer 100 is guided in the falling direction by the hammer support guides 320, the drop hammer 100 may hit the exact hitting point of the pile 10.

Then, the impact force is measured through the measurement gauge (3) embedded in the pile (1) by the impact of the pile (1) in accordance with the free fall of the drop hammer 100, the measured data Is provided to the anti-analysis analyzer 500 and then provided as information desired by the user through the anti-analysis analyzer 500.

As a result, the dynamic load test apparatus according to the embodiment of the present invention as described above can reduce the overall height of the test apparatus by configuring the structure supporting the drop of the drop hammer 100 is installed directly on the pile (1). As a result, the advantages of transportation can be obtained.

On the other hand, of each component constituting the dynamic load test apparatus according to an embodiment of the present invention, the hammer operation unit 400 is not necessarily to be configured only as a crane as in the above-described embodiment.

That is, when the hammer operation unit 400 is configured only with a crane, the cost of the test is increased due to an increase in time for use of the equipment, as well as the crane and the drop hammer 100. There is a drawback that the work takes a long time as the work for the connection between the two works manually.

Accordingly, in another embodiment of the present invention proposes that the hammer operation unit 400 is composed of a structure using a hydraulic cylinder.

This will be described in more detail with reference to FIGS. 8 to 11 as follows.

First, the hammer operation unit 400 according to the embodiment of the present invention is largely configured to include the main cylinder 410 and the coupling portion 420.

Here, the main cylinder 410 is installed at the upper end of the hammer support guide 320 constituting the hammer support portion 300, is drawn out toward the falling direction of the drop hammer 100 and the drop hammer on the bottom It is configured to include a main rod 412 is formed with a receiving portion 411 is accommodated in the ring portion 111 of (100).

In addition, when the coupling portion 420 is installed at the end of the main rod 412, the ring portion 111 of the drop hammer 100 is accommodated in the receiving portion 411 of the main rod 412 It is a series of configurations that combine with each other.

At this time, the coupling part 420 according to the embodiment of the present invention is the auxiliary cylinder 421 is fixed to the end peripheral wall surface of the main rod 412, the main rod 412 by the driving of the auxiliary cylinder 421 It is proposed to include an auxiliary rod 422 to sequentially pass through the receiving portion 411 and the ring portion 111 of the drop hammer 100 to each other. That is, the coupling between the main rod 412 and the ring portion 111 and the release is configured to be made by automatic operation rather than manual operation by the operator.

Hereinafter, a free fall process of the drop hammer 100 using the hammer operation unit 400 having the above-described structure will be described with reference to FIGS. 5 to 7.

First, the initial state is maintained in a state in which the drop hammer 100 is placed on the upper surface of the lower support plate 210 constituting the pile seat 200 is the upper end of the pile (1).

In this state, when the manipulation for the dynamic load test is generated, the main rod 412 is driven downward while the main cylinder 410 is driven.

In addition, when the ring portion 111 of the drop hammer 100 is received by the accommodation portion 411 of the main rod 412 by the above process, the driving of the main cylinder 410 is stopped and an auxiliary cylinder ( 421 is driven.

As such, when the auxiliary cylinder 421 is driven, the auxiliary rod 422 is protruded and sequentially moved to the receiving portion 411 of the main rod 412 and the ring portion 111 of the drop hammer 100. The main rod 412 and the drop hammer 100 are coupled to each other by the auxiliary rod 422.

Subsequently, the main rod 412 is moved upward while the main cylinder 410 is operated again, and the drop hammer 100 gradually moves upward with the main rod 412. .

Subsequently, when the position of the drop hammer 100 reaches a predetermined height, driving of the main cylinder 410 is stopped and the auxiliary cylinder 421 is driven to retreat its auxiliary rod 422.

Thus, the coupling between the main rod 412 and the ring 111 is released momentarily, the drop hammer 100 hits the upper end of the pile 1 while performing the free fall according to the release of the coupling. .

Subsequently, the impact force is measured through the measurement gauge 3 which is installed in the pile 1 by the impact of the pile 1 according to the free fall of the drop hammer 100, the measured data Is provided to the anti-analysis analyzer 500 and then provided as information desired by the user through the anti-analysis analyzer 500.

As a result, due to the structure of the hammer operation unit 400 according to another embodiment of the present invention as described above, it is possible to minimize the use of the crane and to shorten the time required for the dynamic load test as much as possible. .

100.Hammer 110. Ram
111. Hook 112. Hook hole
120. Coupling bracket 200. Pile seat
210. Lower support plate 220. Support guide for piles
300. Hammer support 310. Upper support plate
320. Guide for hammer 330. Guide frame
400. Hammer operation unit 410. Main cylinder
411. Receptacle 412. Main Road
420. Coupling Part 421. Auxiliary Cylinder
422. Auxiliary Load 500. Drive Analyzer

Claims (9)

A drop hammer positioned above the pile and striking the pile by a selective free fall;
A pile seating portion including a lower support plate mounted on an upper surface of the pile and a plurality of pile support guides protruding from the bottom of the lower support plate along the upper circumferential surface of the pile;
The upper support plate is fixed to the upper surface of the lower support plate constituting the pile seat portion and a plurality of hammer support guides that are formed to protrude along the vertical direction from the upper surface of the upper support plate to guide the fall of the drop hammer in place A hammer support;
A hammer operating part which moves the drop hammer upward and free-falls the drop hammer; And,
Dynamic load test apparatus comprising: a driving analyzer for analyzing and receiving the measurement data according to the impact applied to the pile when hitting the pile by the drop hammer from the measuring gauge installed in the pile. The method of claim 1,
The drop hammer
A ram formed by stacking a plurality of iron plates,
Comprising a plurality of coupling brackets are fixed to each circumferential surface of the ram formed along the stacking direction of each iron plate,
The ram is provided with a plurality of stacking each other, and the upper end and the lower end of each coupling bracket is characterized in that it is gradually inclined outwards toward the top is characterized in that the same load. The method of claim 1,
Each pile support guide constituting the pile seat is provided while forming a double row in the radial direction from the outer circumferential surface of the pile and each of them is formed of an H-beam (H-beam). The method of claim 1,
The length of the support guide for each pile forming the pile seat
Dynamic load test apparatus, characterized in that formed to have a length so as not to reach the installation height of the measuring gauge buried in the pile. The method of claim 1,
The lower end of each pile support guide constituting the pile seating portion is characterized in that it gradually formed outwardly inclined toward the bottom. The method of claim 1,
Each hammer support guide constituting the hammer support is formed to be bent to form the same shape as the corner shape of the drop hammer to surround each corner of the drop hammer,
The outer surface of each of the hammer support guide is a dynamic load test device, characterized in that it further comprises a guide frame for preventing the bending of the support guide for each hammer in the free fall of the drop hammer. The method of claim 1,
Between the lower support plate constituting the pile seat and the upper support plate constituting the hammer seating portion is a dynamic load test device, characterized in that configured to be selectively coupled or separated through the bolt fastening. The method according to any one of claims 1 to 7,
The upper surface of the drop hammer is formed with a protruding ring portion through which the engaging hole is formed,
The hammer operation unit
A main cylinder installed at an upper end of the hammer support part, the main cylinder having a main rod formed at a lower side thereof and drawn out toward the falling direction of the drop hammer, and having an accommodating part for accommodating a ring part of the drop hammer;
When installed at the end of the main rod is the load test device, characterized in that it comprises a coupling portion for coupling each other when the ring portion of the drop hammer is received in the receiving portion of the main rod. The method of claim 8,
The coupling portion
An auxiliary cylinder fixed to an end circumferential wall of the main rod,
And an auxiliary rod configured to sequentially penetrate through the receiving portion of the main rod and the annular portion of the drop hammer by driving of the auxiliary cylinder.

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