KR101740045B1 - Adjustable Connection Jack of Steel Pipe Strut - Google Patents

Abstract

The present invention relates to an interval-adjustable steel pipe strut connection jack, capable of efficiently transferring and distributing load between a steel pipe strut and a furring strip. According to the present invention, the connection jack comprises: a connection plate connected to the furring strip; a repulsive plate installed by being spaced apart from the connection plate as much as a first interval; a maximum load support strut installed by being spaced apart from the repulsive plate as much as a second interval and to support axial load when the maximum load is applied; multiple steel rods connected to the connection plate, penetrating the repulsive place, and having a length capable of touching the maximum load strut upon the maximum load, so as to distribute the axial load applied to the connection plate and transfers the distributed axial load to the repulsive plate; a first nut fastened to the steel rod between the connection and repulsive plates to adjust the interval between the connection and repulsive plates; and a second nut fastened to the steel rod between the repulsive and maximum load strut to fixate the steel rod to the repulsive plate. A radial groove part is formed in upper and lower parts of one end fastened to the connection plate between both ends of the steel rod. A radial protrusion groove with a size and a position corresponding to those of the radial groove part is formed in upper and lower parts of a fastening hole of the connection plate connected to the steel rod. The radial groove part and the radial protrusion groove are formed with a size complementary to each other, so as to from one circle together when the steel rod is fastened to the fastening hole. Moreover, since a tap screw is fastened to the circle formed by the radial groove part and the radial protrusion groove, the fastening hole of the connection plate can be combined with the steel rod by the tap screw.

Description

{Adjustable Connection Jack of Steel Pipe Strut}

The present invention relates to a gap-adjustable steel pipe strut connection jack used for a wrist strap construction of an underground structure.

Recently, as the need for expansion of social overhead facilities has increased, underground excavation work has been under way in the city center. The characteristics of underground excavation work are maximum spatial excavation and great excavation excavation to maximize the use of limited space and underground construction where subway, overpass, underground structure, office space and ground structure for residential space are close to each other have.

Especially, underground excavation works for constructing underground structures in large urban areas in a limited space in urban areas should be considered as a top priority for stabilization of surrounding grounds. It is an important part. The retention method can be divided into two methods as a method to utilize the temporary earth retaining structure and a method to construct an underground structure in parallel with the excavation and earthwork as the main structural body acts as an earth retaining wall in response to earth pressure and water pressure. There is a risk of collapse of the retaining structure due to the possibility of civil complication and stability of the surrounding ground. In addition, there are many cases where complaints are generated due to the displacement of surrounding grounds and compensation for construction interruption or civil complaints.

In the present earthwork, the steel culverts are used for the clay, and the cast-in-place wall (CIP) and the soil cement wall (SCW) are used. Earth Anchor, Soil Nailing, Rock Bolt, and top-down construction methods.

In the case of using the hypothetical Strut, there is a high possibility of inducing the change of surrounding ground during the installation and dismantling process of the installation and dismantling. However, compared to the top-down method, It has the advantage of reducing the cross section of the slab and is now widely used.

Instead of the H-Pile, which is required to be reinforced with respect to the weak axis in the buckling design with respect to the compressive load transmitted from the earth wall through the wedge in the presence of the weak axis and the strong axis, Rectangular cross-section pipes are widely used.

In the case of using the above-mentioned round steel pipe or square pipe as a strut, the design of the connection structure for the connection between the strut and the strut plays an important role in the behavior of the wrist strap structure. In addition, a connection jack is commonly used for connecting the steel pipe to the wrist strap.

Conventional connection jacks have a problem in that the reaction plate is in direct contact with the steel pipe and is not efficient in transmitting loads between the steel pipe and the wale. Therefore, there has been a problem that sufficient rigidity of the connection structure can not be secured against lateral loads such as earth pressure and water pressure. The lack of stiffness of such a connection structure ultimately manifests itself as a deformation of a steel pipe strut, which in turn reduces the recovery rate of the steel pipe strut and its connection structure which must be recycled, thereby causing economic loss.

Therefore, there is a demand for a method for preventing the deformation of the steel pipe strut so that the rigidity of the steel pipe strut can be secured.

The stiffness of the steel pipe strut is secured because the steel pipe strut is not a permanent structure but a visibility product, so it is very important from the viewpoint of the recovery rate of the members that the steel pipe strut should be dismantled and recycled after completion of the underground sandwich construction.

On the other hand, in order to increase the load that can be received by the connection jack, it is necessary that the steel rod receives a larger force in the axial direction, and in particular, the compression load performance of the steel rod is improved A connection structure is required which can be more easily separated from the connection plate between the connection jack and the wrist strap when the steel bar is damaged.

Korean Registered Patent No. 10-1129017 Korean Registered Patent No. 10-1601166

An object of the present invention is to provide a connecting jack capable of effectively transmitting and distributing loads between a steel pipe strut and a wrist strap.

Particularly, since the connection jack between the wrist strap and the steel pipe is divided into two chambers (the space of the maximum load supporting plate-reaction plate and the space of the reaction plate-connection plate) and the reaction plate is divided between the two chambers, It is possible to compress or extend the connecting jack according to the load by adjusting the distance between the connecting plates so that the steel rod itself is not rotated and the steel pipe strut is connected to the connecting jack by welding or bolt to transmit and distribute the load to the steel strut strut. So as to provide a connection jack which is easier to handle.

In addition, it is possible to improve the performance against axial load (compression load) of a plurality of steel rods dispersing the axial load applied to the connecting plate and to transmit the axial load to the reaction plate, and to easily separate And to provide a connection structure of a steel bar and a connecting plate that can easily connect a new steel bar.

According to another aspect of the present invention, there is provided a spark plug connection jack comprising: a connecting plate connected to a wale; A reaction plate disposed apart from the connection plate by a first distance; A maximum load supporting plate installed to be spaced apart from the reaction plate by a second distance and supporting an axial load when a maximum load is applied; A plurality of steel rods connected to the connection plate and passing through the reaction force plate and having a length that can contact the maximum load support plate at a maximum load, and distributing the axial load applied to the connection plate to the reaction force plate; A first nut fastened to the steel rod between the connecting plate and the reaction force plate to adjust a distance between the connecting plate and the reaction force plate; And a second nut fastened to the steel bar between the reaction force plate and the maximum load support plate to fix the steel bar to the reaction plate; A radial groove portion is formed at both ends of one end of the steel bar and connected to the connecting plate at an upper portion and a lower portion; A radial protruding groove having a size corresponding to a position corresponding to the radial grooved portion is formed at an upper portion and a lower portion of a fastening hole of the connecting plate to which the steel bar is fastened; The radial grooves and the radial protruding grooves are formed to have a size complementary to each other so that when the steel rods are fastened to the fastening holes, one circle can be formed together; A tab thread is fastened to the circle formed by the radial grooved portion and the radial projection groove, so that the fastening hole of the coupling plate and the steel rod can be coupled by the tap screw.

In the steel pipe strut connection jack according to the present invention, the threads of the steel rods are formed in a quadrangle shape. In order to prevent the loosening of the nut due to the lowering of the frictional force of the rectangular threads and to strengthen the fastening force, And can be fastened to the steel rod in a state in which they are opposed to each other.

According to the present invention, in the steel pipe strut connection jack capable of adjusting the gap, a thread corresponding to the thread of the tap thread may be formed in the radial groove portion and the radial projection groove.

In the steel pipe strut connection jack according to the present invention, one end of the steel rod may have a support portion formed from a thread, and a protrusion protruding from the support portion and inserted into the fastening hole of the connection plate, A two-step structure; When the steel bar is connected to the fastening hole, the supporting portion may contact the outer wall of the connecting plate outside the fastening hole to serve as a stopper.

In the steel pipe strut connection jack according to the present invention, the connecting plate may be provided with a cruciform load distribution plate for dispersing the load transmitted from the wale band.

The first distance between the connecting plate and the reaction force plate can be adjusted according to the magnitude of the axial load, and the second distance between the reaction force plate and the load supporting plate can be adjusted by adjusting the distance Do not vary according to the magnitude of the axial load; Adjusting the position of the first nut and the second nut to move the steel bar through the reaction force plate toward the maximum load supporting plate to reduce the first distance, wherein the axial load is a maximum load The length of the steel bar can be determined such that the length of the steel bar can contact the maximum load supporting plate.

In the steel pipe strut connection jack according to the present invention, the connecting plate may be bolted to the wale band.

In the steel pipe strut connection jack according to the present invention, a load transmitted to the reaction force plate is distributed between the reaction force plate and the maximum load support plate, and the load is transmitted to the maximum load support plate, A load distribution plate may be formed to prevent buckling.

According to another aspect of the present invention, there is provided a steel pipe strut connection jack capable of adjusting a gap, wherein a separate support plate is formed between the steel pipe strut and the maximum load support plate to isolate the connection jack structure and the steel strut strut.

The connection structure according to the present invention can provide a connection structure that can effectively exert both the vertical load and the horizontal load.

Further, the axial load transmitted from the wale can be transmitted to the steel pipe strut through the connecting plate, the reaction plate, the maximum load supporting plate, and the supporting plate.

Further, the steel rods can be detachably fixed to the connecting plate without welding using the connecting plate and the nut by the fastening structure between the radial grooves of the steel rods and the radial protruding grooves of the connecting plate, so that when the steel rods are damaged, Therefore, the problem of replacing the connecting plate and the steel bar with each other can be solved. Further, the connecting rod (tap screw) is fastened to the fastening structure between the radial groove of the steel bar and the radial projecting groove of the connecting plate, so that the steel bar is not rotatably connected to the connecting plate.

In addition, even if the thread of the steel bar is formed in a square shape, it is advantageous for the transmission of the axial load, and the steel rod can be easily separated from the connecting plate even when the hand is damaged. This helps to improve the recovery rate.

Further, since the leading end of the steel bar connected to the connecting plate has a two-stage structure, when the connecting rod is connected to the connecting plate, the supporting portion of the steel rod functions as a stopper, It is possible to expect a double improvement effect that the compression force transmission performance is improved.

In addition, when the steel bar is connected to the reaction plate between the reaction plate and the connecting plate, the use of two nuts increases the overlap of the threads between the nut and the steel bar and prevents the loosening of the nut due to interference between the nuts.

In addition, the threads of the steel rods are formed in a square or rectangular shape, so that the support performance (compression load) of the steel rods is improved.

This increases the rigidity of the connection structure of the steel pipe strut, and ultimately improves the recovery rate of the steel pipe strut connection structure.

Of course, the advantageous effects of the present invention are not limited to those described above, and other advantageous effects that can be expected by those skilled in the art from the constitution disclosed in the present invention should be recognized as the effects of the present invention.

1 is an exploded perspective view of an embodiment of the present invention.
2 is a cross-sectional view showing a characteristic connecting structure of a steel bar and a connecting plate in an embodiment of the present invention.
3 is a front view showing a compression state of the connection jack at the time of maximum load in the embodiment of the present invention.
4 is a front view showing an extension state of a connection jack at a minimum load in the embodiment of the present invention.
5 is a cross-sectional view taken along line AA in Fig.
6 is a view showing the relationship between the radial grooves of the ends of the steel rods of the present invention and the radial projection holes of the connecting plate and the tap threads.
7 is a view showing an embodiment of a load distribution plate of the present invention.
8 is a view showing another embodiment of the load distribution plate of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

In the present invention, the distinction between the left and right direction and the up and down direction is based on the direction in which the drawing is viewed in each drawing, and the horizontal and vertical distinctions are defined as horizontal direction parallel to the longitudinal direction of the steel pipe strut, do.

An exemplary embodiment of the present invention will be described with reference to Figs. 1 to 8. Fig.

The gap-adjustable steel pipe strut connection jack according to the present invention is a connection jack used in a process of installing a wrist strap support structure used in an underground earth retaining work, and is adjusted to a stretched state or a compressed state to adjust a gap between a wrist strap and a steel wire strut And releasing the load applied to the steel pipe strut.

The connection jack of the present invention comprises a connection plate 10 connected to the wrist strap 2, a reaction force plate 11 installed at a distance from the connection plate 10 by a first distance, The maximum load supporting plate 12 is connected to the steel pipe strut 1 through a supporting plate 16 and is supported by the supporting plate 16 and the maximum load supporting plate 12, (12) are connected by bolting or welding. The maximum load supporting plate 16 is brought into contact with the steel bar 15 at the time of maximum compression of the connecting jack.

The supporting plate 16 structurally isolates the structure of the connecting jack composed of the connecting plate 10, the reaction plate 11 and the maximum load supporting plate 12 from the steel pipe strut 1, So that if one is damaged, the other can be easily separated, and even if the connection jack is damaged by deformation, it is prevented from being transferred to the steel pipe strut or vice versa.

More specifically, referring to FIG. 1, the connecting jack of the present invention includes a connecting plate 10, a reaction plate 11, a maximum load supporting plate 12, a reinforcing plate 13 covering upper and lower portions thereof, The connecting jack is structured so as to be isolated from the steel pipe strut 1 and the support plate 16 and the reinforcing plate 13 covering the steel pipe bracket 1 and the support plate 16 . In this respect, although the upper reinforcing plate 13 itself is shown as an integral member in FIG. 1 and the like, in reality, the reinforcing plate covering the connection jack, the steel pipe brace, and the reinforcing plate covering the supporting plate can be installed as separate members have.

The connecting plate 10 is connected to the reaction force plate 11 and has a length that can pass through the reaction force plate 11 and come into contact with the maximum load supporting plate 12 at a maximum load. A plurality of steel bars 15 distributed to the reaction force plate 11 and connected to the reaction force plate 11 and the maximum load support plate 12 and the support plate 16 at upper and lower portions thereof, (1), which are respectively provided at upper and lower portions so as to abut against the upper and lower support plates (1), (2), and the load transmitted to the reaction force plate (11), the maximum load support plate (13).

The steel pipe strut 1 is welded to the support plate 16 and the support plate 16 is connected to the maximum load support plate 12 by means of bolts a and n, 1 is formed as a structure separate from the maximum load supporting plate 12 constituting the connection jack. Of course, the maximum load supporting plate 12 and the supporting plate 16 may be welded.

In the accompanying drawings, four steel rods 15 are used.

The steel pipe strut 1 is inserted and connected to a space formed by the reinforcing plate 13 and the support plate 16.

The wrist strap 2 and the connecting plate 10 are generally fastened by bolts a and n. Although the connection plate 10 and the wale band 2 may be connected by a forced connection such as welding, in this case, the damage of the member may be increased during the process of disassembling the steel pipe strut used as the visibility member, .

As shown in FIG. 1, an H-file member is generally used as the wale band 2, and the flange of the wand 2 is bolted to the connecting plate 10.

The connecting plate 10, the reaction plate 11 and the maximum load supporting plate 12 are spaced apart from each other by a predetermined distance. Thus, the connecting jack of the present invention comprises two plates 10, 11 and 12, Is formed. Specifically, the first distance between the connecting plate 10 and the reaction force plate 11 is a variable distance according to the elongation and compression of the connecting jack, and at the time of maximum compression as shown in FIG. 3, The connecting plate 10 is brought into close contact with the reaction plate 11 so that only a space corresponding to the spacing distance is generated.

Since the connecting rod 10, the reaction force plate 11 and the maximum load supporting plate 12 are generally formed in a rectangular shape, the steel rods 15 are arranged in a symmetrical manner around each corner, It does not.

Further, the steel bar 15 extends continuously from the connecting plate 10 to the maximum load supporting plate 12. [

3, the steel bar 15 can contact the maximum load supporting plate 12 at a time when the connecting rod is compressed to the maximum, And when the minimum load as shown in Fig. 4, i.e., when the connection jack is extended to the maximum, the first distance is the maximum.

The reaction plate 11 and the maximum load supporting plate 12 are connected to the upper and lower reinforcing plates 13. The axial load transmitted to the reaction force plate 11 and the maximum load support plate 12 through the wale band 2 and the connecting plate 10 is transmitted to the steel pipe 12 through the reinforcing plate 13 and the support plate 16, Can be transmitted to the strut (1).

In the present invention, as shown in FIGS. 1 and 2, the steel rod 15 is formed in a square or rectangular shape so that the steel rod 15 can transmit a large force in the axial direction. On the other hand, when the thread of the steel bar 15 is formed as a square or a rectangle, the friction is reduced as compared with a case where the thread is formed into a triangle. That is, in the case of using a square screw, the strength (transfer performance) of the steel bar 15 is improved with respect to the axial load entering in the axial direction, but the frictional coefficient is relatively decreased and the frictional force with the nut is lowered, It becomes more important than triangular threads. To this end, in the present invention, as shown in FIG. 4, two nuts 21 and 23 connected between the reaction plate 11 and the steel bar 15 are connected together in parallel. If the two nuts 21 and 23 are connected together in this manner, the overlapping of the threads between the nuts 21 and 23 and the steel bar 15 is increased, so that the load that the steel bar 15 can receive is increased, 21, and 23 can be prevented from being released from the steel rod 15. Also, since the nuts 21 and 23 connected to each other interfere with each other, it is possible to prevent mutual loosening. Of course, three or more nuts can be used and are not necessarily limited to two or more, but may vary depending on the size of the steel rods, the shape of the threads, the length of the steel rods, the first separation distance, or the design load to be transferred by the steel rods.

The nuts 21 and 23 can be used to determine the position of the steel bar 15 to adjust the distance between the connecting plate 10 and the reaction plate 11. The nut 22 is fixed to the reaction plate 11 (Not shown).

As described below, in the present invention, the steel bar 15 is not coupled to the connection plate 10 in a semi-permanent manner such as welding, but is connected to the connection plate 10 And more specifically, to the fastening hole 500 of the connecting plate 10 so as to be detachable. Therefore, a separate nut for securing the welding area for welding to the connection plate 10 is not required. In this case, since the steel bar is not directly inserted into the connecting plate, the connecting hole 500 of the connecting plate 10 is not inserted into the steel bar (not shown) The connecting force is lowered as compared with the case where the protruding portion 153 of the protruding portion 15 is directly inserted. In the present invention, the steel bar 15 can be freely separated from the connecting plate 10 and the connecting force with the connecting plate 10 can be improved.

The tap screw 300 may be twisted into the fastening hole 500 and a screw thread may be formed in the tap screw 300 and the radial grooves 151 and the radial protrusions 200 It is possible.

On the other hand, a method of connecting the steel rod 15 to the connecting plate 10 will be described. One end (that is, the right end in the drawing) connected to the connection plate 10 in the steel rod 15 includes a support portion 152 extending from the thread of the steel bar 15 as shown in FIG. 2, And a protrusion 153 protruding from the rotor 152 and inserted into the fastening hole 500 formed in the connecting plate 10. The supporting part 152 and the protrusion 153 are formed so that the supporting part 152 contacts the connecting plate 10 when the steel rod 15 is inserted into the fastening hole 500, And a load transmitted from the wale band 2 to the steel bar 15 is transmitted to the steel bar 15 through the support portion 152 The supporting portion 152 of the steel rod 15 is wider than the projection 153 to increase the cross-sectional area of the steel rod 15, thereby enhancing the supporting performance of the steel rod 15 during axial load.

Radial grooves 151 are formed at the upper and lower ends of the distal end of the protruding portion 153 of the steel bar 15 so that the radial grooves 151 are formed in the fastening holes 500 of the connecting plate 10 as shown in Figures 1 and 6, A protrusion hole 200 is formed. The radial grooves 151 and the radial projection holes 200 are complementary to each other and are each formed to have a radius of the tab thread 300 to form a circle corresponding to the diameter of the tab thread as a whole. The radial grooves 151 and the radial projection holes 200 form a circle into which the tab threads 300 can be inserted and a thread corresponding to the threads of the tab threads 300 is inserted into the radial grooves 151 and the radial protrusion hole 200 so that the tab thread 300 can be rotated to be coupled to the circle formed by the radial grooves 151 and the radial protrusion holes 200.

The use of the reference numerals 151, 153, 300 and the like in the description of the fastening holes 500 in FIGS. 1, 4, and 6 indicates that the radial grooves 151, the protrusions 153, To indicate a point. The radial grooves 151 formed in the protruding portions 153 of the steel rods 15 are formed in the fastening holes 500 in the same manner as the radial grooves 151 formed in the fastening holes 500 And the radial projection hole 200 is formed with a circle in which the tab thread 300 is engaged.

In the steel bar 15, two nuts 21 and 23 are fastened to a portion of the reaction plate 11 projecting toward the connecting plate 10 and the nut 22 is fastened to the reaction plate 11 side. In the present invention, all the nuts 21, 22, and 23 are nuts for fixing the position of the steel bar 15 to the reaction force plate while moving the steel bar 15 along the thread. In the present invention, It is not necessary to use a nut for fixing the connection plate 10 by welding or the like.

Further, the position of the steel bar 15 is adjusted through the nuts 21, 22, and 23 to determine the degree of extension / compression of the connecting jack. The fastening force between the reaction plate 11 and the steel bar 15 is also enhanced by fastening the nuts 21, 22, and 23 to the front and rear of the reaction force plate 11. As described above, the double nuts 21 and 23 are fastened to the right side of the reaction plate 11 to strengthen the axial load performance of the steel bar 15, and even when the steel bar 15 is a square screw, Can be prevented. That is, the two nuts 21 and 23 interfere with each other to prevent loosening.

In addition, the load applied to the steel bar 15 is transmitted to the reaction plate 11 through the nuts 21 and 23. Further, the load applied to the steel bar 15 is transmitted to the maximum load supporting plate 12 through the clamping nut 22 when the load is maximum. The load transmitted to the maximum load supporting plate 12 is transmitted to the steel pipe strut 1 connected to the connecting jack.

Since the steel rod 15 can only contact the maximum load supporting plate 12 when it is near the maximum load supporting plate 12 and can not penetrate through the maximum load supporting plate 12, It is possible to visually confirm the length of the steel rod 15 that has been passed over.

The connecting plate 10 moves in the arrow direction from the maximum load state of FIG. 3 to the minimum load state of FIG.

As can be seen from FIGS. 3 to 4, the installation position of the fastening hole 500 and the connection position of the bolt (a) between the wale band 2 and the connecting plate 10 do not conflict with each other.

6, a cross-shaped reinforcing plate 400 may be installed on the connecting plate 10 to distribute a load applied to the connecting plate 10 from the wristband 2, And the shear force of the sheath is reinforced. The thickness of the cruciform reinforcing plate 400 formed on the connecting plate 10 is determined in consideration of the minimum value of the first distance between the reaction plate 11 and the connecting plate 10 at the time of maximum compression as shown in FIG. It is below the minimum value.

7 and 8, a load distribution for transmitting the axial load acting on the reaction force plate 11 to the maximum load support plate 12 is provided between the reaction force plate 11 and the maximum load support plate 12, The plates 121 and 122 can be additionally provided. The load distribution plates 121 and 122 distribute the load acting on the reaction force plate 11 to transfer the load to the maximum load support plate 12 and suppress the plate buckling of the reaction force plate 11 and the maximum load support plate 12, Can be performed. As shown in FIG. 7, the load distribution plates 121 and 122 may be cross-shaped for efficient load distribution, and a ribbon-type load distribution plate 121 as shown in FIG. 8 may be used.

It is general that the load distribution plate is disposed in parallel to the reinforcing plate 13 along the center line of the reaction force plate 11 and the maximum load supporting plate 12 and has a width corresponding to the diameter of the steel pipe strut 1 .

While the present invention has been particularly shown and described with reference to certain preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It should be understood that various changes and modifications may be made by those skilled in the art. In addition, the accompanying drawings are shown not to scale but to partially enlarge and reduce in order to explain the technical idea of the present invention.

Particularly, not only each of the embodiments of Figs. 1 to 6 of the present invention but also arbitrary combinations of them are included in the protection scope of the present invention.

1: Steel pipe bracket
2: wale
10: Connection plate
11: Reaction plate
12: Maximum load supporting plate
13: reinforced plate
15: steel rods
16: Support plate
121, 122: load distribution plate
150: Threaded
151: Radius groove
152:
153: protrusion
200: Radius protruding hole
300: Tap screw
400: Cross-
500: fastening hole
a: Bolt
b: Nut
c: Bolt hole

Claims (9)

A connection plate connected to the wrist strap,
A reaction plate that is spaced apart from the connection plate by a first distance,
A maximum load support plate installed at a second distance from the reaction plate and supporting an axial load when a maximum load is applied,
A plurality of steel rods connected to the connection plate and passing through the reaction force plate and formed to have a length that can contact the maximum load support plate at the time of maximum load and disperse the axial load applied to the connection plate and transmit the dispersion load to the reaction force plate,
A first nut fastened to the steel bar between the connection plate and the reaction force plate to adjust an interval between the connection plate and the reaction force plate,
And a second nut fastened to the steel bar between the reaction force plate and the maximum load support plate to fix the steel bar to the reaction plate,
A radial groove portion is formed at an upper portion and a lower portion of one end of the steel bar,
A radial protruding groove having a size corresponding to a position corresponding to the radial grooved portion is formed at an upper portion and a lower portion of a fastening hole of the connecting plate to which the steel bar is fastened,
Wherein the radial grooves and the radial protruding grooves are formed to have a size complementary to each other so that when the steel rods are fastened to the fastening holes,
The radial grooves and the radial protruding grooves formed in the circle are engaged with tab threads so that the fastening holes of the connecting plate and the steel rods can be engaged with the tab threads,
Wherein the threads of the steel rods are formed in a rectangular shape,
The first nut is fastened to the steel bar in a state where two or more of the first nut are in contact with each other to prevent the nut from loosening due to the lowering of the frictional force of the rectangular thread,
Wherein the radial grooves and the radial projection grooves are formed with threads corresponding to the threads of the tap threads,
Wherein one end of the steel rod is formed in a two-step structure of a support portion formed by extending from a thread and a protrusion protruding from the support portion and inserted into the fastening hole of the connection plate and formed with a width smaller than that of the support portion,
Wherein when the steel bar is connected to the fastening hole, the supporting portion abuts against an outer wall of the connecting plate outside the fastening hole to serve as a stopper. delete delete delete The method according to claim 1,
Wherein the connection plate is provided with a cruciform load distribution plate for dispersing a load transmitted from the wale band. The method according to claim 1,
The first distance between the connecting plate and the reaction force plate can be adjusted according to the magnitude of the axial load and the second distance between the reaction force plate and the load support plate does not vary according to the magnitude of the axial load,
Adjusting the position of the first nut and the second nut to move the steel bar through the reaction force plate toward the maximum load supporting plate to reduce the first distance, wherein the axial load is a maximum load Wherein the length of the steel bar is determined such that the length of the steel bar can be in contact with the maximum load supporting plate. The method according to claim 1,
Wherein the connecting plate is bolted to the wale band. The method according to claim 1,
And a load distribution plate is formed between the reaction force plate and the maximum load support plate to disperse a load transmitted to the reaction force plate and transmit the load to the maximum load support plate to prevent plate buckling of the reaction plate and the maximum load support plate. Spaced adjustable steel strut connection jack. The method according to claim 1,
Wherein a separate support plate is formed between the steel pipe strut and the maximum load supporting plate to isolate the connection jack structure and the steel pipe strut.

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