JP3046128U - Rod puller - Google Patents

Abstract

(57) [Summary] [Problem] A rod puller for pulling out a rod used in a test called a Swedish sounding test, which is used to determine the hardness of a soil, the tightness of the soil, and the composition of a soil layer, from the soil. It is an object of the present invention to make it possible to pull out a rod straight without eccentricity while utilizing the principle of leverage, and to significantly improve the work efficiency as compared with the conventional method as described above. . SOLUTION: One end side is a force point portion 3a, and the other end side is an action point portion 3b.
The force applying body 3 functioning as a rotatable member is rotatably connected to the column 1, and a rod holding body 8 holding the rod 20 is rotatably connected to the action point 3 b of the force applying body 3. It is characterized by being connected so as to be able to hang down from the point 3b.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention provides a rod puller, more specifically, a rod used for a test to determine the hardness and tightness of the soil and the composition of the soil layer, which is called the Swedish sounding test. Related to a rod puller.

[0002]

[Prior art]

 Generally, when conducting a ground survey, a test called the Swedish sounding test is performed.

[0003] This test is a test for determining the hardness of the soil, the tightness of the soil, and the configuration of the soil layer. The rods are rotationally inserted into the soil to determine the configuration of the soil layer. is there.

[0004] In such a test method, it is necessary to repeatedly use the rod inserted in the soil, and thus it is necessary to pull out the rod inserted in the soil.

Conventionally, as a method for pulling out such a rod, a method using a tripod and a chain block, a method using a hydraulic jack, a method using a chuck and a lever, and the like have been adopted.

[0006]

[Problems to be solved by the invention]

 As shown in FIG. 7, a method of using a tripod and a chain block is a method of suspending a chain block 26 on a tripod 25, connecting the rod 20 to the chain block 26, and pulling out.

[0007] However, in this method, the base material such as the tripod 25 is heavy, it is not easy to carry, and the work efficiency is poor.

As shown in FIG. 8, a method of using a hydraulic jack is a method of attaching a fastener 27 to a rod 20 and pulling it out with a jack 28 installed on the ground surface. This method was also inefficient because it could only be pulled out.

Further, in the method using a chuck and a lever, the rod 20 is pulled out by attaching the fastener 29 to the rod 20 and moving the rod member 30 up and down to pull out the rod 20. The pulling force against acts reasonably.

However, once the rod 20 is lifted, the fastener 29 does not lower, so that the worker must lower the fastener 29 after raising the rod 20, and therefore, even with this method, the working efficiency is poor. Had become.

In this method, since the rod 20 is pulled out by the leverage of one rod member 30, the fulcrum of the rotation of the rod member 30 may be eccentric, and as a result, the rod 20 may be pulled straight out. However, there was a problem that the drawing force was reduced.

The present invention has been made in order to solve the above-mentioned problems, and it is possible to pull out a rod straight without eccentricity while utilizing the principle of leverage, and to reduce the work efficiency. It is an object of the present invention to significantly improve the method as compared with the conventional method as described above.

[0013]

[Means for Solving the Problems]

 The present invention has been made in order to solve such a problem, and means for solving the problem is that the force applying body 3 having one end functioning as a force point portion 3a and the other end functioning as an action point portion 3b includes a support column. 1 and a rod holder 8 for holding a rod 20 is rotatably connected to an application point 3b of the force applying member 3 so that the rod holder 8 can be suspended from the application point 3b. It is to be connected.

When such a rod puller is used, first, the rod 20 is held by the rod holder 8, and in this state, the power point 3 a of the force applying body 3 is pushed down.

As a result, while the force applying body 3 rotates, a so-called leverage action occurs with the connecting portion between the force applying body 3 and the column 1 serving as a fulcrum, and the rod holder 8 is pulled up.

The rod 20 is pulled out of the soil by pulling up the rod holder 8.

In this case, the rod holder 8 is rotatably connected to the action point 3b of the force applying body 3 so as to be able to hang down from the action point 3b. Even if is rotated, the rod holding body 8 will be pulled upward in a hanging state.

Therefore, the rod 20 is pulled straight without eccentricity, and the pulling force acts on the rod 20 appropriately.

When the force applying portion 3 a side of the force applying body 3 is formed in a cylindrical shape into which the manual pipe 21 can be inserted, the pipe 21 is connected to the cylinder on the force applying point 3 a side of the force applying body 3. The force body 3 is rotated by inserting the pipe 21 into the cylindrical portion and depressing the pipe 21, so that the same operation as described above can be obtained.

Further, a long hole 14 is formed in the column, and a rotating shaft 13 serving as a rotation fulcrum of the force applying member 3 is inserted into the long hole 14 so that the force applying member 3 is rotatable on the column 1. When the force-applying members 3 are connected, when the force-applying body 3 rotates, the position of the rotation shaft 13 also shifts appropriately, and the force-applying body 3 turns without drawing the same orbit. It is possible to more suitably generate an upward force with respect to 20.

It is also possible to form a box 9 in the rod holder 8 and house a rod holder 15 for holding a rod 20 in the box 9.

As a form of the rod holder 15, for example, wing pieces 18, 18 are rotatably connected to both sides of the holder body 16, and a gap between the wing pieces 18, 18 is formed by an insertion portion of the rod 20. There is something like 19 formed.

In this case, when the locking portions 22, 22 for locking the wing pieces 18, 18 of the rod holder 15 are formed in the box 9 of the rod holding body 8, the wing pieces 18, 18 are formed. The rod 18 is locked to the locking portions 22 and 22 to prevent the rod holder 15 from rattling in the box 9 of the rod holder 8 when the force applying body 3 rotates.

[0024]

[Embodiment of the invention]

 Hereinafter, embodiments of the present invention will be described.

In FIG. 1 and FIG. 2, reference numerals 1 and 1 denote a pair of columns, which are erected on mounts 2 and 2 that can be placed on the ground.

Reference numeral 3 denotes a force applying member having one end functioning as a force point portion 3a and the other end functioning as an action point portion 3b. The force point portion 3a is constituted by a tubular portion 4 into which a pipe can be inserted. The side surface is constituted by a U-shaped part 5 formed in a substantially U-shape.

The U-shaped portion 5 is formed by a central bulging portion 6 serving as a fulcrum of rotation of the force applying body 3, and side rods 7, 7 projecting from the central bulging portion 6 on both sides. I have.

Reference numeral 8 denotes a rod holder for holding a rod 20, a box 9 for storing a rod holder 15 described later, and a pair of projecting rods 10, 10 protruding upward from the box 9. And a support plate 11 for supporting the protruding rods 10, 10 on the back side.

The protruding rods 10 of the rod holding body 8 and the side rods 7 of the force-applying body 3 are pivotally connected by pivot pins 12, 12. The rod holder 8 is connected to the action point 3b of the body 3 so as to be rotatable and to be able to hang down from the action point 3b.

Reference numeral 13 denotes a rotation shaft serving as a rotation fulcrum of the force applying body 3. The rotation shaft 13 is fixedly inserted into the central bulging portion 6, and is formed in an elongated hole formed in the upper portion of the columns 1 and 1. Inserted at 14,14.

As a result, the force applying body 3 is rotatably connected to the columns 1, 1.

Reference numeral 15 denotes a rod holder housed in the box 9 of the rod holder 8. Wing pieces 18, 18 are provided on both sides of a holder body 15 having a substantially rectangular front surface via pins 17, 17. It is connected to the rotation itself.

The gap between the two wing pieces 18 is formed as a rod insertion portion 19.

In the box 9 of the rod holder 8, locking portions 22, 22 to which the wing pieces 18, 18 of the rod holder 15 are locked are formed.

Next, the case of using the rod puller having the above configuration will be described. First, as shown in FIG. 4, the rod 20 is held in the box 9 of the rod holder 8. It is inserted into the insertion portion 19 of the tool 15.

Next, as shown in FIG. 5, a pipe 21 is inserted into the hole of the cylindrical portion 4, and the pipe 21 is pushed down while rotating in the direction of arrow a as shown in FIG. The cylindrical portion 4 and the side rod 7 also rotate in the same direction, whereby the distal end of the side rod 7, which is the application point 3b of the force applying member 3, rises as shown in the direction of arrow B in FIG. Thus, the rod holder 8 is pulled up.

When the holding body 8 is pulled up, the rod 20 is pulled out of the soil as shown in FIG.

As described above, by rotating the force applying body in which the cylindrical portion 4 and the side rod 7 are integrally formed in the direction of the arrow A in FIG. 5, a so-called leverage action is generated with the rotating shaft 13 as a fulcrum, An upward force is applied to the action point portion 3b of the force applying body 3 and thus to the rod holder 8.

The rod holder 8 is rotatably connected to the side rod 7 of the force applying member 3 by pivot pins 12, 12, and has an action point 3 b on the tip end side of the side rod 7. The rod holder 8 is pulled up in the suspended state despite the rotation of the force-applying body 3 because it is linked so that the rod holder 8 can be hung down.

Accordingly, the rod holder 15 accommodated in the box 9 of the rod holder 8 is similarly pulled upward, and the rod 20 held by the rod holder 15 is not displaced, It will be pulled straight out.

Moreover, since the locking portions 22 for locking the wings 18 of the rod holder 15 are formed in the box 9 of the rod holding body 8, the wings 18, 18 are formed. Are locked by the locking portions 22, 22 to prevent the rod holder 15 from rattling in the box 9 of the rod holder 8 during rotation of the force applying body 3.

The rotation shaft 13 serving as a fulcrum of the rotation of the force applying member 3 is inserted into the long holes 14, 14 formed in the upper portions of the columns 1, 1, so that At the time of rotation, the position of the rotation shaft 13 also shifts moderately, and as a result, the force applying body 3 rotates without drawing the completely same trajectory. Can be generated more suitably.

Then, as shown in FIG. 6, the pulled-out rod 20 rotates the wing pieces 18, 18 of the rod holder 15 in the directions indicated by arrows D and E, respectively, so that the rod 20 in the direction shown in FIG. By pulling it upward, it can be removed from the rod holder 15.

In the above-described embodiment, the pipe 20 is inserted into the cylindrical portion 4 of the load body 3, and the load body 3 is rotated by pushing down the pipe 20. The insertion is not an indispensable condition for the present invention, and it is also possible to directly grip and rotate the force applying portion 3a side of the force applying body 3.

However, in order to exert the leverage rationally, the force applying body 3 needs to be formed to have a certain size. In this case, the separate pipe 20 must be connected as in the above embodiment. It is advantageous that the pipe 20 can be inserted into the cylindrical portion 4 of the force applying body 3 so that the pipe 20 can be separated, which is convenient for transportation and handling.

In this embodiment, the force applying member 3 is constituted by the cylindrical portion 4 and the U-shaped portion 5, but the structure of the force applying member 3 is not limited to this. What is necessary is just to be configured so that one end side functions as the power point section 3a and the other end side functions as the action point section 3b.

Further, in the present embodiment, the rotation shaft serving as the rotation fulcrum of the force applying body 3 is inserted into the long holes 14, 14 formed in the upper portions of the columns 1, 1, and the force applying body 3 Is preferably rotatably mounted on the columns 1 and 1, so that the above-described advantageous effects can be obtained. However, the insertion into the slots 14 and 14 is not an essential condition of the present invention. The point is that the force applying member 3 only needs to be rotatably connected to the columns 1 and 1.

Further, in the above-described embodiment, the rod 20 is held by the rod holder 15 accommodated in the box 9 of the rod holder 8, but is not limited thereto, and the rod 20 is directly held by the holder 8. May be formed, and the rod 20 may be held at that portion.

That is, regardless of whether the rod 20 is indirect or direct via the rod holder 15, the rod 20 may be held by the rod holder 8.

[0050]

[Effect of the invention]

 As described above, according to the present invention, a load member having one end functioning as a force point portion and the other end functioning as an action point portion is rotatably connected to the column, and the force point portion of the force member has: Since the rod holding body that holds the rod is rotatably connected so as to be able to hang down from the point of application, the rod holding body holds the rod, and in this state, the power point of the force applying body is pushed down. When it is rotated, the lever portion acts as a fulcrum at the connecting portion between the load body and the support, and the rod holder is pulled up, and the rod is pulled out of the soil.

Thus, the lever operation facilitates the pull-out operation of the rod. Although the same lever operation is used, the attachment and detachment of the fastener is performed in the same manner as in the conventional method using a chuck and a lever. There is no need to perform this, and work efficiency can be significantly improved. Further, the working efficiency is improved as compared with other conventional methods.

Further, since the rod holding member is rotatably connected to the application point of the force applying member so as to be able to hang down from the application point, even if the force applying member rotates, The rod holder is lifted upward in a suspended state, and as a result, the rod is pulled straight without being displaced, which has an effect that the pulling force on the rod acts properly. .

[Brief description of the drawings]

FIG. 1 is a front view of a rod puller as one embodiment.

FIG. 2 is a side view of the same.

3A and 3B show a rod holder held by a rod holder, wherein FIG. 3A is a schematic front view, and FIG. 3B is a schematic plan view.

FIG. 4 is a side view showing a state where a rod is held by a rod holder and a pipe is inserted into a tubular portion.

FIG. 5 is a front view showing a state in which the rod is pulled out of the soil by rotating the force applying body.

FIG. 6 is a schematic front view showing a state where a rod is removed from a rod holder.

FIG. 7 is a schematic perspective view showing one conventional example.

FIG. 8 is a partial cross-sectional schematic front view of another conventional example.

FIG. 9 is a partial cross-sectional schematic front view showing still another conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Support column 3 ... Force body 3a ... Power point part 3b ... Point of action 8 ... Rod holder 9 ... Box 13 ... Rotating shaft 14 ... Long hole 15 ... Rod holder 16 ... Holder body 18 ... Wing piece 19 ... Insertion part 20… Rod 22… Locking part

Claims (6)

[Utility model registration claims] 1. One end is a force point (3a), and the other end is an action point.
A force member (3) functioning as (3b) is rotatably connected to the column (1), and a rod (20) is held at an action point (3b) of the force member (3). A rod holder (8), which is rotatably connected so as to be able to hang down from said action point (3b). 2. The force applying portion (3a) side of the force applying body (3) is formed in a cylindrical shape into which a manual pipe (21) can be inserted.
Rod extractor as described. 3. A strut is provided with a slot (14) formed therein, and a turning shaft (13) serving as a turning fulcrum of a force applying body (3) is formed in the slot.
When inserted into (14), the load (3)
The rod puller according to claim 1, wherein the rod puller is rotatably connected to the rod. 4. A rod (9) is formed in said rod holder (8), and a rod holder (15) for holding a rod (20) is housed in said box (9). Rod extractor as described. 5. The rod holder (15) is connected to a holder body (1).
The wing pieces (18), (18) are rotatably connected to both sides of the wing piece (6), and the gap between the wing pieces (18), (18) is formed by the insertion portion (1) of the rod (20).
The rod puller according to claim 4, formed as 9). 6. Boxes (9) of said rod holder (8) are provided with locking portions (22), (18) to which wings (18), (18) of a rod holder (15) are locked. 22. The rod puller according to claim 5, wherein the rod is formed.