KR101721527B1 - Electrical Cnnection Device for Safety Diagnosis of Reinforced Concrete Structure - Google Patents

Abstract

The present invention relates to a rebar connection apparatus to diagnose the safety of a reinforced concrete structure, measuring a corrosion degree of a rebar by using a potential difference, so as to diagnose the safety of a reinforced concrete structure. According to the present invention, the apparatus comprises: magnets (30, 32) attached to a surface of a rebar (20); holders (42, 44) in which the magnets (30, 32) are installed; a hollow sleeve (46) to allow the holders (42, 44) to be installed in upper and lower parts thereof; a hollow insulation bush (50) inserted into the sleeve (46); a conductive rod (60) inserted into the center of the insulation bush (50) to be guided in a direction closed to or separated from the rebar (20), and in comparison with the rebar (20) to be electrically connected; a spring seat (62) inserted into the conductive rod (60); and a spring (70) installed between the spring seat (62) and the sleeve (46), and applying elasticity to press the conductive rod (60) towards the rebar (20). Moreover, the apparatus comprises: a pair of locking grooves (64, 66) formed on an outer circumferential surface of the conductive rod (60) in parallel; and a U-shaped stopper (80) combined with the locking grooves (64, 66), and locked in the sleeve (46) to maintain a recessed state of the conductive rod (60).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reinforced concrete structure for reinforced concrete structures,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a technology used for diagnosing the safety of a reinforced concrete structure by measuring the corrosion degree of a reinforcing steel by using a potential difference, more specifically, The present invention relates to a reinforcing bar connecting device for safety diagnosis of a reinforced concrete structure capable of greatly reducing the amount of crushing of concrete.

Concrete is very high in alkalinity to protect steel from corrosion, but if penetration or neutralization of chlorine ions occurs, the corrosion of the reinforcing bars is destroyed and corrosion occurs.

It is very important to investigate the degree of corrosion of reinforcing bars in evaluating the condition of the structure because the corrosion of such reinforcing bars causes the cross-sectional loss of the reinforcing bars and the expansion cracks of the concrete, .

The corrosion of steel in concrete is proceeded by electrochemical phenomenon. By measuring the degree of active state of steel in steel reinforced concrete, it is possible to measure the corrosion of steel by non-destructive method.

In general, the electrochemical nondestructive test method for diagnosing the corrosion of the inner reinforcing bars of concrete is widely used, in which the corrosion potential of the reinforcing bars is judged by measuring the natural potential by the copper-copper sulfate counter electrode corresponding to the reference electrode.

This natural transfer method is to diagnose the possibility of corrosion of reinforcing bars at the time of irradiation and finds a place where the possibility of corrosion of the reinforcing steel is high in the inside of the structure. When the inner reinforcing steel is corroded and the concrete is cracked, It is effective to grasp the initial stage.

1, the positive lead wire 14a connected to the positive terminal of the electric potential meter 15 as shown in Fig. 1 is a schematic view of a natural power transfer method for measuring the corrosion degree of a reinforcing bar using copper- The negative electrode lead wire 14b connected to the negative terminal of the potential meter 15 is connected to the reinforcing bar 10 inside the structure 11 and connected to the copper bar 17 of the counter electrode 19 serving as the reference electrode The wet sponge 18 of the backing sheet 19 is brought into contact with the surface of the concrete structure 11 and the potential of the reinforcing bar 10 is read through the potential meter 15 to measure the degree of corrosion of the reinforcing bar 10. [ .

The copper-copper sulfate counter electrode 19 is filled in the insulating tube 18a made of an electrically non-conductive material so as not to react with copper or copper sulfate so as to maintain a constant oil level. The insulating tube 18a, A copper head 17b connected to the negative lead wire 14b connected to the minus terminal of the electric potential meter 15 is provided at the upper portion of the insulating tube 18a and a copper rod 17b 17 penetrate and are immersed in the copper sulfate solution 18b.

In addition, a ring-shaped copper bushing 17a is provided between the insulating tube 18a and the copper rod 17, and a plug 18c made of porous wood or synthetic resin, which is maintained in a wet state by the capillary phenomenon, A sponge 18 is provided on the outer side of the lower end of the insulating tube 18a so as to be in contact with the plug 18c and to be brought into contact with the surface neutralizing layer 16 of the concrete structure 11, .

2 and 3, in order to connect the positive lead wire 14a to the reinforcing bar 10 in the concrete structure 11 as described above, the portion where the reinforcing bar 10 is located is searched using a reinforcing bar navigator The concrete structure 11 is crushed to form a reinforcing bar exposed portion 12 and then the energizing tongue 13 to which the positive lead wire 14a is connected should be measured with the exposed reinforcing bar 10 being tapped.

However, in the prior art, since the entire cross section of the reinforcing bars 10 must be exposed to the exposed reinforcing bar 10 to hold the energizing tongs 13, there is a disadvantage that the concrete structure 11 has a large amount of crushing, which slows down the work.

Particularly, since the entire cross-section of the reinforcing bar 10 is exposed, not only the rigidity of the concrete structure 11 is reduced by that much, but also the cost and time in proportion to the amount of crushing are recovered There was an issue that was needed.

Korean Registered Utility Model No. 20-0447882 Korean Patent Registration No. 10-1212728

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and an object of the present invention is to provide a reinforcing bar connecting device for safety diagnosis of a reinforced concrete structure capable of being partially exposed without exposing the entire cross section of the reinforcing bars.

In order to accomplish the object of the present invention, there is provided a reinforcing bar connecting device for safety diagnosis of a reinforced concrete structure, comprising: a magnet; A holder in which a magnet is installed; A citron crown in which the holder is installed at upper and lower portions; A hollow sleeve formed at the center of the citrus tendon; A hollow insulated bush inserted into the sleeve; A conductive rod inserted into the center of the insulated bush and guided in a direction away from or close to the reinforcing bar and electrically connected to the reinforcing bar to be electrically energized; A spring seat which is fitted to the current-carrying bar; And a spring which is provided between the spring seat and the sleeve and exerts an elastic force so that the electrification rod is pressed toward the reinforcing bar, characterized in that: a pair of engaging grooves formed on the outer circumferential surface of the energizing rod in parallel with each other; And a U-shaped detent coupled to the latching groove and engaged with the sleeve to maintain the retracted state of the energizing rod.

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The present invention includes a conical portion formed at the tip of a current-carrying rod and contacting a reinforcing bar.

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Since the present invention as described above is constructed so as to be attracted to the reinforcing bars 20 by using the magnets 30 and 32, it is possible to connect the reinforcing bars 20 even if they are partially exposed without exposing the entire cross- 20 can be greatly reduced and the strength of the concrete structure 22 can be improved in proportion to the reduced crushing amount.

When the conical portion 68 is formed at the tip of the conductive rod 60, when the conical groove 21 is formed in the reinforcing bar 20 to contact the conical portion 68 of the conductive rod 60, 60 and the reinforcing bars 20 can be increased, so that the measurement accuracy can be improved due to the lowering of the contact resistance.

The contact resistance between the energizing rod 60 and the reinforcing bar 20 can be made constant because the energizing rod 60 is always subjected to a constant pressure toward the reinforcing bar 20 by the spring 70. Therefore, Can be improved.

The retracted state can be maintained by using the detent 80 in a state in which the energizing rod 60 is retracted before the magnet 30 (32) is attracted to the reinforcing bar 20, It is possible to prevent the interference between the magnets 30 and 32 and prevent the interference between the magnets 30 and 32 to the reinforcing bars 20.

The magnetic force is transmitted to the sleeve 46 through the sleeve 46 and the barbend 40 through the holders 42 and 44 and the magnet 30 and 32 through the insulating bushing 50 positioned between the sleeve 46 and the energizing rod 60. [ It is possible to improve the measurement accuracy since the current path is previously cut off.

The surface of the reinforcing bar 20 is polished and then the curved surface 90 of the energizing bar 60 is brought into contact with the curved surface 90 of the energizing bar 60 so that the energizing bar 60 and the reinforcing bars 20 It is possible to simplify the connecting operation of the display device.

Further, the present invention helps the conical portion 68 to come into close contact with the conical groove 21 when the conical cutting portion 69 is formed at the end of the conical portion 68 formed at the tip of the energizing rod 60, It is possible to prevent defects.

When the chamfered portions 92 and 94 are formed on both sides of the curved surface 90, the curved surface 90 forms a gap with the outer peripheral surface of the reinforcing bar 20, It is possible to expect an effect of helping to come into close contact with the outer peripheral surface of the housing.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a natural transfer method for measuring the corrosion degree of reinforcing steel using a general copper-copper sulfate bicarbonate paper
FIG. 2 is a cross-sectional view showing a reinforced concrete exposed portion formed in a concrete structure for connecting a positive lead to a conventional reinforcing bar;
FIG. 3 is a plan view showing the connection of the positive electrode lead through the conventional exposed reinforcing bar-
Fig. 4 is an exploded perspective view
Fig. 5 is a rear exploded perspective view of Fig. 4
Figure 6 is a cross-sectional view of a reinforced connecting device according to the present invention in a seated state,
7 is a cross-sectional view taken along line A-A '
8 is a perspective view showing that the reinforcing bar according to the present invention is adsorbed on a reinforcing bar;
9 is a side cross-sectional view showing that the reinforcing bar according to the present invention is adsorbed on a reinforcing bar;
10 is a plan view showing the reinforcing bars according to the present invention being adsorbed to the reinforcing bars
11 is a sectional view taken along the line B-B 'in Fig. 9
12 is a plan view showing another embodiment of the energizing rod according to the present invention
13 is a perspective view showing another embodiment of the energizing rod according to the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 4 to 13, the present invention includes a magnet 30 (32) adsorbed on a surface of a reinforcing bar (20); A holder (42) (44) on which the magnet (30) (32) is installed; And a grapefruit cage 40 in which the holders 42 and 44 are installed at upper and lower portions.

The holders 42 and 44 are formed with rectangular digging grooves 42g and 44g into which the magnets 30 and 32 are inserted as shown in FIG. The magnets 30 and 32 are inserted into the digging grooves 42g and 44g and the magnets 30 and 32 are attached to the holder 30 42 (44).

5 and 11, the magnets 30 and 32 are arranged in such a manner that the attracting surfaces of the magnets 30 and 32 are brought into contact with the outer peripheral surface of the reinforcing bar 20 and the outer peripheral surface of the reinforcing bar 20, It can be formed into a concave curved surface having the same radius of curvature and can be constituted by a pair of upper and lower parts to improve the attraction force.

The reinforcing ribs 48 and 49 may be formed along the edges of the citron crook 40 so as to reduce the weight of the crookbang 40 and improve the rigidity.

The present invention includes a hollow sleeve (46) formed at the center of the castor barb (40); A hollow insulated bushing 50 inserted into the sleeve 46; And a conductive rod 60 inserted into the center of the insulation bushing 50 and guided in a direction away from or approaching the reinforcing bar 20 and brought into contact with the reinforcing bar 20 to be electrically energized.

A through hole 46h through which the insulating bush 50 is inserted is formed in the center of the sleeve 46 and a flange 52 engaged with the end of the sleeve 46 is formed at one end of the insulating bush 50 And a hollow hole 54 is formed in the center of the insulator bushing 50, through which the energizing rod 60 is inserted and guided.

The insulating bushing 50 is used to maintain the electrically insulated state between the energizing rod 60 and the live barb 40 so that the energizing path is passed only through the energizing rod 60 to reduce the measurement error, This is to increase the reliability.

If the insulating bushing 50 is made of Teflon resin, the Teflon resin has self-lubrication property. Therefore, when the energizing bar 60 is rotated about the shaft 50, the bushing 50 can be made of Teflon resin, So that the guide can be guided more smoothly.

An adhesive is applied to the inner circumferential surface of the hole 46h and the outer circumferential surface of the insulating bush 50 to insert the insulating bush 50 into the sleeve 46h when the insulating bush 50 is inserted into the hole 46h formed in the sleeve 46 46 or by inserting the insulating bush 50 into the hole 46h of the sleeve 46 by another example.

The energizing rod 60 is formed by using an electrically conductive material such as brass or pure copper, aluminum alloy, iron, or the like, and is connected to a positive terminal of a potentiometer (not shown) The electrification forceps 100 provided at the end portion of the positive electrode lead wire 102 are inserted into the end portion of the electrification bar 60 and the positive electrode lead wire 102 and the electrification forceps 100 and the current- (20).

The present invention is characterized by comprising a spring seat (62) fitted to the energizing rod (60); And a spring 70 installed between the spring seat 62 and the sleeve 46 and exerting an elastic force so that the energizing rod 60 is pressed toward the reinforcing bar 20.

A hooking step 61 is formed on the outer circumferential surface of the energizing rod 60 to hook the spring seat 62. The spring seat 62 may be formed in a donut shape having a hole formed at the center thereof.

The spring 70 may be constituted by a compression coil spring formed by spirally winding a spring steel wire made of metal and repulsive between the spring seat 62 and the sleeve 46 so that the magnets 30, And presses the energizing bar 60 toward the reinforcing bars 20 in a state where the reinforcing bars 20 are attracted to the reinforcing bars 20.

The present invention includes a pair of engagement grooves (64) (66) formed parallel to each other on the outer peripheral surface of the energizing rod (60); And a U-shaped detent 80 coupled to the retaining grooves 64 and 66 and retaining the retracted state of the energizing bar 60 by being caught by the sleeve 46.

4, 5 and 7, the detent 80 may be formed in a horseshoe shape that is formed by bending a square bar into a U-shape, and the engaging groove 64) 66 can be formed on the upper and lower portions of the outer peripheral surface of the energizing rod 60.

6 and 7, when the detent 80 is inserted into the engaging grooves 64 and 66 while the spring 70 is being compressed, the magnets 30 and 32 are inserted into the reinforcing bars 20, The tip of the energizing rod 60 is spaced apart from the reinforcing bar 20, so that interference with the energizing rod 60 is not caused.

The present invention includes a conical portion (68) formed at the tip of the energizing rod (60) and contacting the reinforcing bar (20).

The conical portion 68 can be brought into contact with the conical groove 21 formed on the surface of the reinforcing bar 20. The conical portion 68 is formed by cutting the conical portion formed at the tip of the conical portion 68, , And the horn cutting portion 69 helps the conical portion 68 to come into close contact with the conical groove 21.

The present invention comprises a concave curved contact surface (90) formed at the tip of the energizing rod (60) and in close contact with an outer circumferential surface of the reinforcing bar (20); And a chamfered portion 92 and 94 formed at the left and right edges of the curved contact surface 90 and forming a gap with the outer peripheral surface of the reinforcing bar 20.

The curved contact surfaces 90 may be formed to have the same radius of curvature as the outer diameter of the reinforcing bars 20 so as to be in surface contact with the outer circumferential surface of the reinforcing bars 20. The beveled portions 92, And prevents the curved contact surface 90 from being lifted from the reinforcing bars 20 at the same time.

In the drawings, reference numeral 22 denotes a concrete structure, and reference numeral 24 denotes a reinforcing bar exposed portion.

Hereinafter, the operation according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 4 to 13, in order to measure the degree of corrosion of the reinforcing bars 20, first, a portion where the reinforcing bars 20 are located is searched from the outside of the concrete structure 22 using a reinforcing bar searcher (not shown) 6, 9 and 10, when the reinforcing bars 20 are crushed by using a concrete crushing tool such as a hammer drill, And the reinforcing bars 20 are exposed to the outside.

As described above, when forming the reinforcing bar exposed portion 24, only the area where the magnet 30 (32) is adsorbed to the reinforcing bar 20 and the contact of the energizing bar 60 is ensured, 20 is sufficient to partially expose the entire cross-section of the concrete structure 22, thereby greatly reducing the amount of concrete crushing and greatly reducing the strength of the concrete structure 22 due to crushing.

As shown in FIGS. 5 and 7, when the energizing rod 60 is retracted and the spring 70 is compressed, the engaging grooves 64 and 66 are exposed to the outside. When the detent 80 is engaged with the engaging groove 64, (64) and (66), the energizing rod (60) is maintained in a backward state.

Next, if the surface of the reinforcing bar 20 to be brought into contact with the energizing bar 60 is polished by using an abrasive tool such as sandpaper to remove foreign substances, the electrical resistance of the surface can be minimized and the measurement accuracy can be increased.

As shown in Fig. 6, when the magnets 30 and 32 provided in the holders 42 and 44 of the germanium claw 40 are moved toward the outer peripheral surface of the reinforcing bar 20, as shown in Figs. 8 and 9 The holders 42 and 44 and the barbuckle 40 are attracted to the reinforcing bars 20 by the attractive force of the magnets 30 and 32. [

At this time, when the detent 80 is separated from the engagement grooves 64 and 66 of the energizing bar 60, the energizing bar 60 is advanced by the elastic restoring force of the spring 70, Is brought into contact with the surface of the reinforcing bar (20).

In this state, water is sprayed to the measurement point of the reinforcing bar exposed portion 24 and the concrete structure 22 by using a sprayer or the like, and a sufficient amount of water is sprayed through the positive electrode lead wire 102 When the electrifying forceps 100 connected to the positive terminal is struck to the rear end of the energizing rod 60 and then a reversal paper (not shown) is brought into contact with the measurement point of the concrete structure 22, a potential difference of the reinforcing bar 20 is detected .

Since the insulator 50 is electrically insulated between the sleeve 46 and the electrifying bar 60, the sleeve 46 and the barbuckle 40, the holders 42 and 44, and the magnet 30 32) is cut off in advance to improve the measurement accuracy.

6, 9, and 10, when the conical portion 68 is formed at the tip of the energizing rod 60, the conductive rod 60 is brought into contact with the contact portion of the reinforcing bar 20 A conical groove 21 such as a twist drill bit, a center drill and a counter sink bit is machined in the reinforcing bar 20 using a cutting tool capable of machining a conical groove, (68) is brought into contact with the conical groove (21), a more reliable measurement becomes possible.

At this time, when the conical cutting portion 69 is formed at the end of the conical portion 68, the conical portion 68 helps to adhere to the conical groove 21 as shown in FIG.

12 and 13, when the curved contact surface 90 and the chamfered portions 92 and 94 are formed at the tip of the energizing bar 60, the reinforcing bar 60 20 are polished by using an abrasive tool such as sandpaper, and then the energizing bar 60 is brought into contact with the surface of the reinforcing bar 20, energization becomes possible.

At this time, since the chamfered portions 92 and 94 form a clearance with the outer peripheral surface of the reinforcing bar 20 as shown in FIG. 12, a sharp burr of the edge, which may occur when the curved contact surface 90 is cut And the curved contact surface 90 is brought into close contact with the outer peripheral surface of the reinforcing bar 20.

20: Rebar 21: Conical groove
22: concrete structure 24:
30,32: Magnetic 40: citron cantilever
42, 44: holder 42g, 44g:
46: sleeve 46h: hole
48, 49: reinforcing rib 50: insulating bush
52: flange 54: hollow hole
60: energizing rod 61:
62: spring seat 64, 66:
68: conical part 69: horn cutting part
70: spring 80: detent
90: a curved contact surface 92, 94:
100: energizing tongue 102: positive lead wire

Claims (4)

delete A magnet (30) (32) adsorbed on the surface of the reinforcing bar (20);
A holder (42) (44) on which the magnet (30) (32) is installed;
A citron cage 40 in which the holders 42 and 44 are installed at upper and lower portions;
A hollow sleeve 46 formed at the center of the castor bend 40;
A hollow insulated bushing 50 inserted into the sleeve 46;
A conductive rod 60 inserted into the center of the insulating bushing 50 and guided in a direction away from or close to the reinforcing bar 20 and brought into contact with the reinforcing bar 20 to be electrically energized;
A spring seat (62) fitted to the energizing rod (60);
A spring 70 installed between the spring seat 62 and the sleeve 46 and applying an elastic force to the electromotive bar 60 so as to be pressed toward the reinforcing bar 20;
The reinforcing bar for reinforced concrete structure safety diagnosis according to claim 1,

A pair of engagement grooves (64) (66) formed parallel to each other on an outer peripheral surface of the energizing rod (60);
A U-shaped detent 80 coupled to the retaining grooves 64 and 66 to retain the energizing bar 60 in a retracted state by being caught by the sleeve 46;
A reinforcing bar for reinforcing concrete structure safety diagnosis. The method of claim 2,
A conical portion (68) formed at the tip of the conductive rod (60) and contacting the reinforcing bar (20);
A reinforcing bar for reinforcing concrete structure safety diagnosis. delete

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