KR20160074863A - Dynamic Cone Penetration Tester - Google Patents

Abstract

A dynamic cone penetrometer for measuring the hardness of the ground according to the present invention comprises: a verticality maintaining unit (100) which maintains verticality between the dynamic cone penetrometer and the ground surface; an intrusive rod (300) which intrudes into the ground by driving a pile by a hammer (200) fallen from a predetermined height; an anvil (400) which is combined with the upper end of the intrusive rod (300) and enables the hammer (200) to drive a pile; and a hammer guide rod (500) which is combined with the anvil (400) at a lower end and guides the movement of the hammer (200). The verticality maintaining unit (100) includes: a horizontal plate (110) which is in contact with the ground surface; and a perpendicularity support (120) which is combined with the horizontal plate (110) in a perpendicular direction. In the dynamic cone penetrometer and the hardness measurement method provided by the present invention, a connection member (600) moving with the intrusive rod (300) in a single united body is guided by the perpendicularity support (120).

Description

Technical Field [0001] The present invention relates to a dynamic cone penetration tester,

TECHNICAL FIELD The present invention relates to a civil engineering field, and more particularly, to a dynamic cone penetration tester capable of measuring the rigidity of a ground and a method of measuring the rigidity of the ground using the same.

Dynamic Cone Penetration Test (DCPT) is an instrument for measuring the ground stiffness of the underfloor underground. It is used mainly in USA, Europe and Japan.

The dynamic cone tester is composed of simple equipment and it has advantages of high mobility and portability because it can be separated by parts. In addition, since the test method is not difficult, general field practitioners can easily use it, and it is possible to directly and indirectly estimate the physical properties of the ground layer through the relational formula proposed by existing researchers.

Fig. 1 shows a configuration of a conventional dynamic cone penetration tester. Referring to FIG. 1, a hammer is dropped through a top rod and freely dropped at a position of 50 cm, so that a hammer moves along an upper rod, and a free fall energy of a hammer is transmitted to a lower anvil formed at a lower rod.

The free fall energy transmitted to the lower anvil causes the lower rod to penetrate into the ground (penetrating the entire tester), so that the penetration depth of the lower rod due to one blow or the number of blows to be penetrated to a predetermined depth is calculated, Stiffness can be measured.

However, in the case of the conventional dynamic cone penetration tester, it is developed for the purpose of measuring the rigidity of the roadway so that the length of the lower rod is limited to 1 m. Therefore, it is difficult to measure the grounding rigidity for deep depths over the surface layer. Is limited to 8 kg, so that it is difficult to apply to the surface layer of soft ground where the rigidity is weak.

Also, since there is no standard that can accurately maintain the verticality of the surface of the dynamic cone penetration tester, which affects the test data, it is necessary to measure the accurate grounding stiffness There has also been a problem of difficulty.

It is an object of the present invention to provide a dynamic cone penetration tester capable of measuring the rigidity of the ground up to the depth of the depth allowing extension of the penetration rod, And a method of measuring the rigidity of the ground using the same.

Another object of the present invention is to provide a dynamic cone penetration tester which can be used in various kinds of relational and similar ground survey results proposed by existing researchers by varying the weight of the hammer according to the type and nature of the ground, And a method of measuring the stiffness of the stiffness sensor.

Another object of the present invention is to provide a dynamic cone penetration tester and a method of measuring the rigidity of a ground using the dynamic cone penetration tester and the ground by using the dynamic cone penetration tester and the ground surface.

According to an aspect of the present invention, there is provided a dynamic cone penetration tester for measuring the rigidity of a ground, the dynamic cone penetration tester including: a vertical cone penetration tester 100 for maintaining a vertical degree of a dynamic cone penetration tester and an earth surface; A penetration rod 300 which is hammered by a hammer 200 falling freely at a predetermined height and penetrates into the ground; An anvil 400 coupled to an upper end of the penetration rod 300 and hammering the hammer 200; And a hammer guide rod 500 coupled to the anvil 400 and guiding the motion of the hammer 200. The vertical guide 100 includes a horizontal plate 110); And a vertical support 120 coupled to the horizontal plate 110 in a vertical direction so that the handle 600 acting as an integral part of the penetration rod 300 is guided by the vertical support 120 A dynamic cone penetration tester is provided.

Here, the vertical support 120 may include a plurality of rods, and a vertical support fixing member 700 integrally holding the plurality of rods.

In addition, the vertical supporting member fixing member 700 may include an upper fixing member 710 formed at the upper end of the plurality of rods; And a lower fixing member 720 formed at a lower end of the plurality of rods.

Also, the anvil 400 may be a dynamic cone penetration tester, which is guided by the vertical support 120.

The horizontal plate 110 further includes a penetration hole 111 through which the penetration rod 300 passes, and a pipe penetration hole 800 extending from the bottom of the horizontal plate 110 and penetrating into the ground. And the inside of the tube inlet pipe 800 is connected to the through hole 111. In this case,

A dynamic cone penetration testing apparatus according to any one of the preceding claims, wherein a cone (900) is coupled to the lower end of the penetration rod (300), and the anvil (400) .

The knocking head 510 may be formed at the lower end of the hammer guide rod 500 to transmit the impact energy provided by the hammer 200 to the anvil 400.

The dynamic cone penetration testing apparatus further comprises a shear key 112 extending from the lower portion of the horizontal plate 110 toward the ground so that the horizontal plate 110 can be horizontally fixed to the ground surface. .

The hammer 200 is formed by a plurality of engraving members 210. The engraving member 210 includes a guide rod through hole 211 through which the hammer guide rod 500 passes, And a hammer engaging portion 212 for engaging with the other engaging member 210. The hammer engaging portion 212 includes a female screw portion 212b formed in the other engaging member 210, A portion 212a; And a male screw portion 212b inserted into the female screw portion 212a formed on the other engraving member 210. The dynamic cone penetration testing machine shown in FIG.

The engraving member 210 may be a dynamic cone penetration tester in which a handle insertion hole 230 for inserting the handle 220 is formed.

According to another aspect of the present invention, there is provided a method of measuring the rigidity of a ground using a dynamic cone penetration tester, the method comprising: a first step (S100) of dropping the hammer (200) ); And a second step (S200) of measuring the depth of the penetration rod (300) by using a scale (310) and a separate commercial steel shaker displayed on the penetration rod (300) A method of measuring stiffness is provided.

A third step (S300) of separating the intrusion rod (300) and the anvil (400) when the upper end of the intrusion rod (300) reaches the ground surface; And a fourth step S400 of coupling the upper end of the penetration rod 300 to the lower end of the other penetration rod 300a and coupling the anvil 400 to the upper end of the other penetration rod 300a, The method comprising the steps of:

According to the present invention, it is possible to measure the rigidity of the ground located at the depth of depth by allowing extension of the penetration rod.

According to the present invention, the weight of the hammer can be varied variously, so that it can be applied to the surface layer of the soft ground and various relational expressions suggested by the existing researchers can be utilized.

According to the present invention, it is possible to maintain a vertical degree of the dynamic cone penetration tester and the surface of the ground, thereby enabling accurate ground stiffness measurement.

1 is a view showing a configuration of a conventional dynamic cone penetration tester
2 is a perspective view of a dynamic cone penetration tester according to an embodiment of the present invention.
3 is a side view of a dynamic cone penetration tester according to an embodiment of the present invention
4 is an exploded view of a hammer formed of a piece member according to an embodiment of the present invention;
5 is an exploded view of a penetration rod, cone, and anvil in accordance with one embodiment of the present invention.
6 to 10 are views showing a method of measuring the rigidity of a ground using a dynamic cone penetration tester according to an embodiment of the present invention.

The dynamic cone penetration tester according to the present invention and the method of measuring the stiffness of the ground using the same will be described in detail with reference to the accompanying drawings and the same or corresponding components will be described in the same drawing And the description thereof will be omitted.

It is also to be understood that the terms first, second, etc. used hereinafter are merely reference numerals for distinguishing between identical or corresponding components, and the same or corresponding components are defined by terms such as first, second, no.

In addition, the term " coupled " is used not only in the case of direct physical contact between the respective constituent elements in the contact relation between the constituent elements, but also means that other constituent elements are interposed between the constituent elements, Use them as a concept to cover each contact.

The dynamic cone penetration tester according to an embodiment of the present invention is for measuring the rigidity of a ground, and basically includes a dynamic cone penetration tester and a verticality maintaining unit 100 for maintaining the verticality of the ground surface, An anvil 400 coupled to an upper end of the penetration rod 300 and coupled to the anvil 400 and a lower end coupled to the anvil 400, And a hammer guide rod 500 for guiding the behavior of the hammer 200 (Figs. 2 and 3).

The hammer 200 freely falls along the hammer guide rod 500 when the hammer 200 is freely dropped at a predetermined height (dropping 50 cm) in order to measure the rigidity of the ground, The impact energy is transmitted to the anvil 400 coupled with the free fall.

The impact energy transmitted to the anvil 400 is transmitted to the penetration rod 300 under the anvil 400 and the penetration rod 300 in contact with the surface of the cone 900 and in contact with the surface of the anvil 400, .

It is possible to calculate the penetration depth of the penetration rod 300 due to the one blow or to calculate the number of blows for the penetration of the penetration rod 300 to a predetermined depth to quantify the rigidity of the ground.

It is also possible to indirectly measure the stiffness of the ground by substituting the numerical values calculated in the various relational expressions proposed by existing researchers.

However, in this case, maintaining the verticality of the dynamic surface and the dynamic cone penetration tester in this case is an important factor in calculating the correct numerical value. Therefore, the dynamic cone penetration tester according to an embodiment of the present invention includes the verticality holding unit 100 (Figs. 1 and 2).

The vertical degree holding unit 100 includes a horizontal plate 110 and a vertical support 120 which are vertically coupled to the horizontal plate 110 and the horizontal plate 110, The connecting member 600 can be guided by the vertical support 120 (Figs. 1 and 2).

That is, the vertical support 120 is connected to the connecting member 600, which maintains a vertical degree with the ground surface by the horizontal board 110 and moves integrally with the penetrating rod 300 by the vertical support 120, So that the penetrating rod 300 can be penetrated in a direction perpendicular to the ground surface.

Since the intrusion rod 300, the hammer guide rod 500 and the anvil 400 are coupled to each other, the fact that the verticalness of the intrusion rod 300 is maintained means that the intrusion rod 300, the hammer guide rod 500, The vertical direction is maintained as one body.

In order to improve the vertical holding force and portability, the vertical support 120 may be formed of a plurality of bars, and may further include a vertical support member fixing member 700 that integrally restrains the plurality of bars 1 and 2).

The vertical support member fixing member 700 may include an upper fixing member 710 formed at the upper end of the plurality of rods and a lower fixing member 720 formed at the lower end of the plurality of rods (FIGS. 1 and 2).

The upper fixing member 710 is formed on the upper end of the plurality of rods and the lower fixing member 720 is formed on the lower end of the plurality of rods. The connection member 600 can be freely guided along the plurality of rods.

It is also possible to carry out the test by separating the vertical holding portion 100 when a test is performed on a ground where the vertical holding portion 100 is not applicable, such as an ultra soft ground or a slope.

The anvil 400 serves as an anvil for transmitting drop energy of the hammer 200 to the intrusion rod 300 in an impact energy form.

The anvil 400 may be guided by the vertical support 120 to contribute to the maintenance of the verticalness of the penetration rod 300. To this end, the anvil 400 may be provided with an anvil 400 through-hole through which one or more vertical supports 120 may pass (FIG. 1).

The dynamic cone penetration tester according to an embodiment of the present invention may further include a pipe inlet pipe 800 extending below the horizontal plate 110 and penetrating into the ground (FIGS. 1 and 2).

The inside of the tube 800 can be connected to the through hole 111 through which the penetration rod 300 formed in the horizontal plate 110 passes (FIG. 2). The penetration rod 300 passes through the through hole 111 and passes through the horizontal plate 110 and the penetration rod 300 passing through the horizontal plate 110 passes through the inside of the tube 800 As shown in FIG.

The pipe inlet pipe 800 penetrates the ground at a predetermined depth from the lower part of the horizontal plate 110 and the dynamic cone penetration tester and the surface of the ground surface So that the vertical degree can be stably maintained.

In addition, the tube 800 is coupled with the horizontal plate 110 to perform a function of maintaining verticality, a disturbance of the experimental surface layer is prevented, and a function of maintaining a cavity to minimize the influence of disturbance friction is performed.

The dynamic cone penetration tester according to an embodiment of the present invention may be configured such that the cone 900 is coupled to the lower end of the penetration rod 300 and the anvil 400 and the cone 900 can be separated from the penetration rod 300 (Fig. 5). The intruding rod 300 and the anvil 400 are separated from each other and the upper part of the other intruding rod 300 is connected to the anvil 400, When the lower portion of the penetration rod 300 is coupled with the upper portion of the penetration rod 300 penetrating the ground, the length of the penetration rod 300 can be extended (FIGS. 6 to 10).

The dynamic cone penetration tester according to the present invention is capable of measuring the rigidity of the ground by measuring the extension of the penetration rod 300 in comparison with the conventional dynamic cone penetration tester in which the rigidity of the ground can be measured only up to the depth corresponding to the length (100 cm) It is possible to measure the rigidity of the ground by penetrating the penetration rod 300 up to the depth of the ground to be measured by the tester.

The knocking head 510 may be formed at the lower end of the hammer guide rod 500 of the dynamic cone penetration tester according to an embodiment of the present invention to transfer the impact energy provided by the hammer 200 to the anvil 400 1 and 2).

The knocking head 510 should be formed to have a diameter that is larger than the diameter of the hammer guide rod 500 and a diameter that is larger than the diameter of the hammer guide rod through hole formed through the hammer 200.

Further, since the knocking head 510 directly hits the hammer 200, it is preferable that the knocking head 510 is formed of a member having high rigidity.

The dynamic cone penetration tester according to an embodiment of the present invention may further include a shear key 112 extending from the lower portion of the horizontal plate 110 toward the ground so that the horizontal plate 110 can be fixed horizontally to the ground surface (Figs. 1 and 2).

The hammer 200 of the dynamic cone penetration tester according to an embodiment of the present invention may be formed by a plurality of engraving members 210 (FIG. 4).

The engaging member 210 includes a guide rod through hole 211 through which a hammer guide rod 500 passes and a hammer engaging portion 212 for engaging with another engaging member 210, 212 may include a female screw portion 212a into which the male screw portion 212b formed in the other engaging member 210 is inserted and a male screw portion 212b inserted into the female screw portion 212a formed in the other engaging member 210 (Fig. 4).

The plurality of engraving members can be different weights. Since the relational expression proposed by existing researchers is a result using a hammer of different weights, it is possible to utilize various relational expressions by constructing a hammer (3, 5, 8 kg) corresponding to each relational expression by using a plurality of engraving members.

In addition, the engraving member 210 may be formed with a handle insertion hole 230 for inserting the handle 220 to facilitate penetration and withdrawal (FIG. 4).

The hammer 200 is configured to provide an impact force for the penetration of the penetration rod 300 and to provide a pulling force to extract the penetration rod 300 penetrated into the ground.

The hammers 200 provide an upward impact force to the connecting member 600 that moves integrally with the penetration rod 300. The hammering force is applied to the hammering member 300 in a state where the penetration rod 300 penetrates the ground, And the upward impact force provided to the connecting member 600 acts as a pulling force of the penetrating rod 300. Accordingly, the penetration rod 300 intruded into the ground can be easily pulled out.

The hammer 200 can be easily moved in the drawing process of the penetration rod 300 by inserting the handle into the engaging member 210.

Hereinafter, a method of measuring the rigidity of the ground using the dynamic cone penetration tester according to an embodiment of the present invention will be described.

A method of measuring the rigidity of a ground using a cone penetration tester according to an embodiment of the present invention includes a first step S100 of penetrating the penetration rod 300 into the ground by freely dropping the hammer 200, And a second step S200 of measuring the depth at which the penetration rod 300 is penetrated by using the scale 310 indicated in FIG.

A third step S300 of separating the intruding rod 300 and the anvil 400 when the upper end of the intrusion rod 300 reaches the ground surface and a third stage S300 of separating the intruding rod 300 and the anvil 400 at the lower end of the other intrusion rod 300a, And a fourth step S400 of coupling the anvil 400 to the upper end of the other penetration rod 300a.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100:
200: Hammer
300: Intrusion Rod
400: Anvil
500: hammer guide rod
600: connecting member
700: vertical support member fixing member
800: Pipeline
900: Cone

Claims (12)

A dynamic cone penetration tester for measuring rigidity of a ground,
A vertical degree holding unit 100 for maintaining a vertical degree of the dynamic cone penetration tester and the ground surface;
A penetration rod 300 which is hammered by a hammer 200 falling freely at a predetermined height and penetrates into the ground;
An anvil 400 coupled to an upper end of the penetration rod 300 and hammering the hammer 200; And
And a hammer guide rod (500) coupled to the anvil (400) at a lower end to guide the movement of the hammer (200)
The vertical-direction holding unit 100 includes:
A horizontal plate (110) contacting the ground surface; And
And a vertical support (120) vertically coupled to the horizontal plate (110)
Wherein a connecting member (600) acting as an integral part of the penetration rod (300) is guided by the vertical support (120). The method according to claim 1,
The vertical support 120 is formed of a plurality of rods,
A vertical support fixing member 700 integrally restraining the plurality of rods;
Wherein the dynamic cone penetration tester further comprises: 3. The method of claim 2,
The vertical support member fixing member 700 includes:
An upper fixing member 710 formed at the upper end of the plurality of rods; And
A lower fixing member 720 formed at a lower end of the plurality of rods;
And a dynamic cone penetration tester. The method according to claim 1,
Wherein the anvil (400) is guided by the vertical support (120). The method according to claim 1,
(800) extending from the lower portion of the horizontal plate (110) and penetrating into the ground,
A through hole 111 through which the penetration rod 300 passes is formed in the horizontal plate 110,
Wherein the through hole (111) is connected to the inside of the tube (800). The method according to claim 1,
A cone 900 is coupled to the lower end of the penetration rod 300,
Wherein the anvil (400) and the cone (900) are separable from the intrusion rod (300). The method according to claim 1,
Wherein a knocking head (510) for transmitting an impact energy provided by the hammer (200) to the anvil (400) is formed at a lower end of the hammer guide rod (500). The method according to claim 1,
A shear key 112 extending from the lower part of the water level plate 110 toward the ground so that the water leveling plate 110 can be fixed to the ground surface;
Wherein the dynamic cone penetration tester further comprises: The method according to claim 1,
The hammer 200 is formed by a plurality of engraving members 210,
The engraving member (210)
A guide rod through hole (211) through which the hammer guide rod (500) passes; And
And a hammer engagement portion (212) for engagement with another engaging member (210)
The hammer engaging portion (212)
A female screw portion 212a into which the male screw portion 212b formed in the other engaging member 210 is inserted; And
A male screw portion 212b inserted into the female screw portion 212a formed in the other engaging member 210;
And a dynamic cone penetration tester. 10. The method of claim 9,
Wherein the engaging member (210) is formed with a handle insertion hole (230) for inserting the handle (220). A method of measuring rigidity of a ground using the dynamic cone penetration tester of claim 1,
A first step (S100) of freezing the hammer (200) to penetrate the penetration rod (300) into the ground; And
A second step S200 of measuring the depth of the penetration rod 300 by using the scale 310 displayed on the penetration rod 300;
And measuring the stiffness of the ground. 12. The method of claim 11,
A third step (S300) of separating the intrusion rod (300) and the anvil (400) when the upper end of the intrusion rod (300) reaches the ground surface; And
A fourth step S400 of coupling the upper end of the penetration rod 300 to the lower end of the other penetration rod 300a and coupling the anvil 400 to the upper end of the other penetration rod 300a
And measuring the stiffness of the ground.

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