KR102192458B1 - Concrete ultrasonic measuring aids - Google Patents

Abstract

The present invention relates to an ultrasonic measurement aid device for concrete which can accurately measure a crack depth of a concrete structure by minimizing space on a contact surface of the concrete structure, a reception probe, and a transmission probe even if coming in contact with an uneven surface. The ultrasonic measurement aid device for concrete comprises: a transmitter adapter to accommodate the transmission probe; a receiver adapter which is horizontally separated from the transmitter adapter, and accommodates the reception probe; a distance adjustment unit to which the transmitter adapter and the receiver adapter are coupled in a sliding manner; and a support connected to the distance adjustment unit to be gripped by a worker. The outer diameters of the transmission probe and the reception probe are smaller than the inner diameters of the transmitter adapter and the receiver adapter, respectively.

Description

Concrete ultrasonic measuring aids{CONCRETE ULTRASONIC MEASURING AIDS}

The present invention relates to a concrete ultrasonic measurement aid, and more particularly, to a concrete ultrasonic measurement aid that can quickly and efficiently inspect the strength and cracks of a concrete structure.

In general, in order to inspect the construction condition, in-use condition, safety condition, and whether or not it continues to be used after a fire, the strength and cracks of the concrete structure should be inspected.

For this purpose, the method of inspecting by destroying a part of a concrete structure is the most accurate, but depending on the surrounding conditions, measurement by destruction may not be possible, and the condition of the concrete structure may deteriorate due to damage, or a lot of time and cost are incurred.

Therefore, for measurement of concrete structures, non-destructive testing is mainly performed in order to preserve the concrete structure in an undamaged state and not to damage the exterior.

Such non-destructive inspection methods include visual inspection, radiographic inspection, self-examination, ultrasonic inspection, leakage inspection, and impact echo inspection.

Of these inspection methods, ultrasonic inspection is the most accurate and simple to work with, and can quantify the result of the measured value.

The ultrasonic inspection includes a transmitting transducer and a receiving transducer contacting the surface of a concrete structure, and an ultrasonic measuring body connected to the transducers by a cable.

For example, in the ultrasonic inspection, first, measuring points of about 10 cm intervals are marked along the horizontal and vertical directions using a chalk and a ruler to indicate the measurement position of the surface of the concrete structure.

Subsequently, when grease is applied to a measurement point marked on the surface of the concrete structure, and then the transmitting and receiving transducers are brought into contact with each other, the measurement signal of each transducer is transmitted to the ultrasonic measuring body, so that the measurement result can be known.

In this ultrasonic test, since the transmitting and receiving transducers are generally separated, the distance between the transducers must be measured individually.

And, for ultrasonic measurement of the next measurement point displayed on the surface of the concrete structure, one of the transmitting or receiving transducers is left as it is, and the other transducers are moved to the next measurement point and contacted to perform ultrasonic measurement.

As such a process of carrying a transducer is required, there is a disadvantage in that a large amount of error occurs in the crack depth measurement result of the concrete structure, and it is cumbersome and inconvenient in the operation, and it takes too long a measurement time.

For the above reasons, in the relevant field, a method for efficiently inspecting the strength and cracks of concrete structures in a short time has been sought, but satisfactory results have not been obtained until now.

The present invention is to solve the above-described problems, and to provide a concrete ultrasonic measurement aid that can quickly and efficiently inspect the strength and cracks of a concrete structure.

A concrete ultrasonic measurement aid according to an embodiment of the present invention includes: a transmitter adapter accommodating the transmission transducer; A receiver adapter horizontally spaced apart from the sender adapter and receiving the receiver probe; A distance adjusting unit in which the sender adapter and the receiver adapter are coupled in a sliding manner; And a support that is connected to the distance control unit and can be gripped by an operator, wherein outer diameters of the transmitting probe and the receiving probe are smaller than the inner diameters of the sender adapter and the receiver adapter, respectively.

The sender adapter and the receiver adapter may include: a sliding unit having one end and the other end in a direction orthogonal to a direction in which the transmitting probe and the receiving probe are accommodated and coupled to the distance adjusting unit in a sliding manner; And a transducer accommodating unit having a space formed therein to accommodate the transmitting transducer and the receiving transducer, respectively.

The sliding unit comprises a body, and a sliding housing in which the distance adjusting unit is slidably coupled therein; A movement adjustment member for controlling movement in the horizontal direction from the distance adjustment unit; And a pressing member configured as a pair and supporting inclination of the transmitting transducer and the receiving transducer in contact with the surface of the concrete.

The distance adjusting unit may include a body portion to which the sliding unit is coupled in a sliding manner; And a plurality of locking grooves arranged at equal intervals along the horizontal direction of the other surface opposite to the direction in which the concrete structure is disposed in the body portion, and into which the movement control member is selectively inserted.

The sliding housing may include a movement control groove through which the movement control member penetrates through an area overlapping the distance control unit on the other surface opposite to the direction in which the concrete structure is disposed; And a pair of pressing grooves through which the pressing member penetrates through an area overlapping the transmitting probe or the receiving probe on the other surface opposite to the direction in which the collet structure is disposed.

The pair of pressing grooves are formed on both sides based on the center of the sliding housing.

The movement control member is formed in a cylindrical shape, one side is in communication with the outside, the other side is sealed, a bolt member one end is inserted into the movement control groove; A bearing ball disposed on one surface of the bolt member and selectively inserted into the locking groove; A first elastic member disposed inside the bolt member to elastically support the bearing ball in one surface direction; And a fixing nut disposed on the other surface of the sliding housing and coupled to the other end direction of the bolt member in a screwing manner to fix the bolt member to the sliding housing.

The pressing member may include a pressing needle inserted into the pressing groove and having one end in contact with the other surfaces of the transmitting and receiving probes; Consisting of a first support member extending along an outer circumference of the pressure needle and a second support member formed in a size corresponding to the circumference of the first support member at a position corresponding to the first support member on the inner peripheral surface of the pressing groove Support; And a second elastic member inserted into the pressure needle and having one end in contact with the first support member and the other end in contact with the second support member.

A scale is formed on the other surface of the body, and the center of the body has a dimension of 0, and the dimension increases as it is arranged in a horizontal direction based on the dimension 0.

The scale is formed at the same interval as the arrangement interval of the locking grooves.

The sender adapter and the receiver adapter slide in a horizontal direction based on the scale of zero.

The transducer receiving unit comprises: a fixed socket constituting a body, wherein the transmitting transducer and the receiving transducer are respectively accommodated; A stopper formed on the other surface opposite to the direction in which the concrete structure is arranged in the fixed socket to seal a part of the fixed socket and to limit excessive movement of the transmitting or receiving transducer to the other end; And an elastic ring disposed between the transmission transducer and the fixing socket and made of an elastic material.

The elastic ring has a length shorter than the depth of the fixing socket, and is disposed at an end of the transmission transducer and the fixing socket in a direction in which a concrete structure is disposed.

A cut-out groove is formed to vertically communicate the side surface of the sliding unit and the transducer receiving unit from the side of the transducer receiving unit and the sliding unit to the center of the other surface of the transducer receiving unit.

The cut-out groove is formed of an oblique line on the other surface of the sliding part.

A handle part is fixed in the center of the support, and the handle part is disposed at each of the gripping part gripped by the operator, the support part supporting the lower arm of the worker, and both ends of the gripping part and the support part, and the gripping part and the support part It consists of connecting parts that connect to each other.

The support part is inclined from the connection part.

In the concrete ultrasonic measurement auxiliary device according to the present invention, when the transmitting transducer and the receiving transducer come into contact with the surface of the concrete structure and the transmitting transducer is inclined inside the transducer receiving unit, the pressure needle contacting the other surface of the transmitting transducer is elastically supported, thereby transmitting By keeping the probe and the surface of the concrete structure parallel to each other, even when the measurement aid is tilted by the operator's wrist bending, or when measuring a concrete structure with an uneven surface, accurate crack depth measurement results of the concrete structure can be obtained. There is an effect.

In addition, since the inner diameter of the fixed socket is formed larger than the outer diameter of the transmitting probe, there is an effect that the transmitting probe accommodated in the transducer receiving unit can be easily inclined from the transducer receiving unit.

1 is a perspective view showing a concrete ultrasonic measurement aid according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a sender adapter according to an embodiment of the present invention.
FIG. 3 is an enlarged view of “A” shown in FIG. 2;
Figure 4 is an operation diagram showing the operating state of the movement control member according to an embodiment of the present invention.
Figure 5 is an operation diagram showing the operating state of the pressing member according to an embodiment of the present invention.
6 and 7 are plan views showing an operating state of the ultrasonic concrete measurement aid according to an embodiment of the present invention.
8 is a cross-sectional view showing a cross-section of a pressing member according to an embodiment of the present invention.
9 is a front view showing an incision according to another embodiment of the present invention.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms different from each other, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to the possessor, and the invention is defined by the description of the claims. Meanwhile, terms used in the present specification are for explaining embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used herein, "comprises" or "comprising" refers to the presence of one or more other components, steps, actions and/or elements other than the recited elements, steps, actions and/or elements, or Does not rule out addition.

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

On the other hand, the ultrasonic measuring aid for concrete according to the present invention accommodates the transmitter and the transducer in close contact with the surface of the concrete structure.

The transmitting probe according to the present invention transmits ultrasonic waves, and the receiving probe receives the ultrasonic waves transmitted from the transmitting probe.

These transmitting and receiving transducers are in close contact with the surface of the concrete structure to measure the crack depth of the concrete structure.

1 is a perspective view showing a concrete ultrasonic measurement auxiliary device according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing a transmitter adapter according to an embodiment of the present invention, and FIG. 3 is “A” shown in FIG. ”Is an enlarged enlarged view, Figure 4 is an operation diagram showing the operating state of the movement control member according to an embodiment of the present invention, Figure 5 shows the operating state of the pressing member according to an embodiment of the present invention Fig. 6 and Fig. 7 are a plan view showing an operation state of the ultrasonic concrete measurement aid according to an embodiment of the present invention, and Fig. 8 is a cross-sectional view showing a cross section of a pressing member according to an embodiment of the present invention. , Figure 9 is a front view showing a cut in accordance with another embodiment of the present invention.

Referring to FIGS. 1 to 9, a concrete ultrasonic measurement aid according to an embodiment of the present invention includes a transmitter adapter 100, a receiver adapter 200, a distance adjustment unit 300, and a support 400.

The transmitter adapter 100 is in close contact with the surface of the concrete structure 800 so that the transmission probe 500 for transmitting ultrasonic waves is fixed, and the distance to the receiver adapter 200 can be easily adjusted.

The transmitter adapter 100 includes a sliding unit 110 and a transducer receiving unit 120.

The sliding unit 110 is formed on the other surface opposite to the direction in which the concrete structure 800 is disposed in the transducer receiving unit 120, and is perpendicular to the direction in which the transmitting transducer 500 is received in the transducer receiving unit 120. One end and the other end of the direction are mutually penetrated and are coupled to the distance adjusting unit 300 in a sliding manner.

Accordingly, the sliding unit 110 can easily adjust the distance to the receiver adapter 200.

The sliding unit 110 includes a sliding housing 111, a movement adjusting member 114, and a pressing member 115.

The sliding housing 111 constitutes the body of the sliding unit 110, and a space is formed therein, and the distance adjusting unit 300 is slidably coupled.

It is preferable that the sliding housing 111 is coupled to the distance adjusting unit 300 therein, thereby forming a space having a shape corresponding to the cross-sectional shape of the distance adjusting unit 300 therein.

For this reason, the distance adjusting unit 300 can be easily coupled to the sliding housing 111.

On the other hand, in the other surface of the sliding housing 111 in the opposite direction to the direction in which the concrete structure 800 is arranged, the movement adjustment groove 112 through which the movement control member 114 passes and the pressing groove through which the pressing member 115 passes ( 113) is formed.

The movement control groove 112 penetrates into an area overlapping the distance control unit 300 on the other surface opposite to the direction in which the concrete structure 800 is disposed, and the transmitter adapter 100 follows the distance control unit 300. The movement adjustment member 114 for controlling movement can be easily inserted into the distance adjustment unit 300.

And, the pressing groove 113 is made of a pair, penetrates into the area overlapping the transmission transducer 500 on the other surface opposite to the direction in which the concrete structure 800 is disposed, and supports the inclination of the transmitting transducer 500 It allows the pressing member 115 to be easily inserted.

These pressing grooves 113 are mutually horizontally formed on both sides based on the center of the sliding housing 111.

That is, the pressing groove 113 allows the pressing member 115 inserted therein to support the inclination of the transmission transducer 500 in a balanced manner.

Meanwhile, a cable 700 for transmitting the measurement signal measured from the concrete structure 800 to the ultrasonic measurement body is drawn out at the other end of the transmission probe 500.

Therefore, when the transmission transducer 500 is accommodated in the transducer receiving unit 120 at the other end of the sliding housing 111, the cable 700 of the transmitting transducer 500 can be drawn out of the transducer receiving unit 120. It is preferable that the withdrawal hole 116 is formed so that.

The movement control member 114 is formed at a position corresponding to the movement control groove 112 on the other surface of the sliding housing 111 as shown in FIGS. 2 and 3, and is coupled to the distance control unit 300 in a sliding manner. The transmitter adapter 100 is controlled to move from the distance adjustment unit 300.

The movement control member 114 includes a bolt member 114A, a bearing ball 114B, a first elastic member 114C, and a fixing nut 114D.

The bolt member 114A is fixed to the movement control groove 112 of the sliding housing 111 and is formed in a cylindrical shape with a thread formed on the outer circumferential surface.

In addition, the bolt member 114A has one surface in the direction in which the concrete structure 800 is disposed in communication with the outside, and the other surface is sealed.

One end of the bolt member 114A is screwed into the movement control groove 112, and the other end protrudes from the other surface of the sliding housing 111 to the outside.

The bearing ball 114B is seated on one surface of the bolt member 114A, and is inserted into the locking groove 320 of the distance adjustment unit 300 through the movement adjustment groove 112.

The first elastic member 114C is disposed inside the bolt member 114A, and one end in the direction of the concrete structure 800 contacts the bearing ball 114B to elastically support the bearing ball 114B in one end direction, The other end is in contact with the other end surface inside the bolt member 114A.

That is, the first elastic member 114C elastically supports the bearing ball 114B, so that the bearing ball 114B can be firmly inserted into the locking groove 320 of the distance adjusting unit 300.

Meanwhile, the first elastic member 114C is preferably made of a coil spring so that it can be easily accommodated in the bolt member 114A, but is accommodated in the bolt member 114A to facilitate the bearing ball 114B. If it can support elasticity, it is also possible to use various types of first elastic members 114C.

The fixing nut 114D is disposed on the other surface of the sliding housing 111 and is coupled to the other end of the bolt member 114A protruding from the other surface of the sliding housing 111 in a screwing manner.

Therefore, the fixing nut (114D) by tightening the bolt member (114A) coupled to the movement adjustment groove (112), the bolt member (114A) can be firmly fixed to the movement adjustment groove (112) of the sliding housing (111). have.

When the operator wants to move the transmitter adapter 100 to a desired position for inspection of the strength, cracks, etc. of the concrete structure 800, the movement control member 114 of the present invention made of the above configuration, as shown in FIG. Likewise, by sliding the transmitter adapter 100 along the distance adjustment unit 300, the bearing ball 114B is separated from the locking groove 320 of the distance adjustment unit 300.

The bearing ball 114B slides in a state in which the curved surface of the bearing ball 114B is in contact with the stepped jaws of the body 310 and the locking groove 320 of the distance adjustment unit 300, so that the bearing ball 114B is a bolt member It is elastically pressed into the interior of (114A), and is easily separated from the locking groove 320 of the distance adjustment unit 300.

In addition, when the bearing ball 114B is separated from the locking groove 320 of the distance adjusting unit 300, the transmitter adapter 100 is moved to a desired position.

At this time, the bearing ball 114B is inserted into the locking groove 320 of the distance adjustment unit 300 by the elastic force of the first elastic member 114C, as shown in FIG. 4.

For this reason, it is possible to quickly and efficiently move the sender adapter 100 to a position desired by the operator.

The pressing member 115 is inserted into a pair of pressing grooves 113, as shown in FIGS. 2 and 3, and is formed at a position corresponding to the transmission transducer 500 on the other surface of the sliding housing 111. .

In particular, when the pressing member 115 measures the concrete structure, the measurement auxiliary device is inclined or accommodated in the transducer accommodating unit 120 by bending the wrist of the operator who presses the measurement auxiliary device to contact the surface of the concrete structure. When the transmitting transducer 500 and the receiving transducer 600 come into contact with the surface of the concrete structure 800 with an uneven surface and a slope occurs due to the height difference between the transmitting transducer 500 and the receiving transducer 600, the slope is caused by the slope. It prevents that a space is formed between the transmission transducer 500 and the surface of the concrete structure 800.

To this end, the pressing member 115 includes a pressing needle 115A, a support portion 115B, and a second elastic member 115E.

The pressing needle 115A is formed in a cylindrical shape and corresponds to the pressing groove 113 made of a pair.

These pressure needles (115A) are inserted into each of the pressing grooves 113 made of a pair, and one end is in contact with the other surface of the transmission transducer (500).

The support part 115B controls the movement of the pressure needle 115A by supporting the elastic force of the second elastic member 115E, and the first support member 115C extending outward along the outer circumferential surface of the pressure needle 115A And formed on the inner circumferential surface of the pressing groove 113 and having an inner diameter of the same size as the outer diameter of the first supporting member 115C at a position corresponding to the first supporting member 115C and larger than the inner diameter of the pressing groove 113 It consists of a second support member (115D) formed of.

A second elastic member 115E is disposed between the first support member 115C and the second support member 115D to support the elastic force of the second elastic member 115E.

The second elastic member 115E is inserted into the pressing needle 115A formed in a cylindrical shape, and has one end in contact with the first support portion 115B of the pressing needle 115A, and the other end is formed in the pressing groove 113. It contacts with the support part 115B.

That is, the second elastic member 115E is elastically pressed by the first support member 115C formed on the pressing needle 115A when the pressing needle 115A is in contact with the other surface of the transmission transducer 500 and is pressed, and the second branch It is supported by the material 115D.

Therefore, when the pressing member 115 measures the concrete structure as shown in Figs. 5 and 6, the measurement auxiliary device is inclined due to the bending of the wrist of the operator pressing so that the measurement auxiliary device comes into contact with the surface of the concrete structure. As shown in FIGS. 5 and 7, the transmitting transducer 500 and the receiving transducer 600 are in contact with the surface of the concrete structure 800 with the uneven surface, so that the transmitting transducer 500 is inside the transducer receiving unit 120 When inclined at, the pressing needle 115A in contact with the other surface of the transmitting transducer 500 is elastically supported, so that the surfaces of the transmitting transducer 500 and the concrete structure 800 are kept parallel to each other.

That is, the pressing member 115 can minimize the formation of a space between the transmitting transducer 500 and the surface of the concrete structure 800 due to the inclination caused by the height difference between the transmitting transducer 500 and the receiving transducer 600. .

Due to this, the pressing member 115 is inclined due to the bending of the operator's wrist that pressurizes the measurement auxiliary device to contact the surface of the concrete structure, or even when measuring the concrete structure 800 with an uneven surface, By minimizing the space as described above, an accurate crack depth measurement result of the concrete structure 800 can be obtained.

The transducer receiving unit 120 has a space formed therein so that the transmitting transducer 500 is accommodated therein, and includes a fixing socket 121, a stopper 122, and an elastic ring 123.

On the other hand, as shown in the transducer receiving unit 120, in detail, as shown in FIG. 8, the inner diameter (D1) of the fixing socket 121 is formed larger than the outer diameter (D2) of the transmission transducer 500.

For this reason, the transmission transducer 500 accommodated in the transducer receiving unit 120 can be easily inclined from the transducer receiving unit 120.

The fixed socket 121 constitutes the body of the transducer accommodating part 120, and a space is formed therein.

In addition, the transmission transducer 500 is accommodated in the inner space of the fixing socket 121 from one end to the other end, which is the direction in which the concrete structure 800 is disposed.

The fixed socket 121 is accommodated in the transmission transducer 500, so that a space having a shape corresponding to the cross-sectional shape of the transmitting transducer 500 is formed therein.

For this reason, the fixed socket 121 can easily accommodate the transmission transducer 500.

And, the inner diameter (D1) of the fixing socket 121 is formed larger than the outer diameter (D2) of the transmitting transducer 500, the measurement aid device by bending the wrist of the operator pressing the measurement aid to contact the surface of the concrete structure When is inclined or when the transmitting transducer 500 contacts the surface of the uneven concrete structure 800, the transmitting transducer 500 may be easily inclined from the transducer receiving unit 120.

The stopper 122 is formed at the other end of the fixing socket 121 in a direction opposite to the direction in which the concrete structure 800 is disposed, and seals a part of the other end of the fixing socket 121.

Accordingly, the stopper 122 limits the excessive movement of the transmitting transducer 500 when the transmitting transducer 500 is received in the direction from one end of the concrete structure 800 to the other end.

Meanwhile, a cable 700 for transmitting the measurement signal measured from the concrete structure 800 to the ultrasonic measurement body is drawn out at the other end of the transmission probe 500.

Therefore, when the transmission probe 500 is accommodated in the fixed socket 121 at the other end of the stopper 122, the cable 700 of the transmission probe 500 is withdrawn to the outside of the fixed socket 121. (116) should be formed.

In addition, the stopper 122 has a sliding housing so that the pressing needle 115A of the pressing member 115 that presses the transmission transducer 500 accommodated in the transducer receiving unit 120 can contact the other surface of the transmitting transducer 500 ( The pressing groove 113 formed in 111 must be formed.

The elastic ring 123 is disposed between the transmission probe 500 and the fixed socket 121.

To this end, the elastic ring 123 is made in a circular ring shape, the outer circumferential surface of the elastic ring 123 is in contact with the inner circumferential surface of the fixing socket 121, and the inner circumferential surface of the elastic ring 123 is on the outer circumferential surface of the transmitting transducer 500. Touch.

Accordingly, the elastic ring 123 allows the transmission transducer 500 to be firmly accommodated in the fixing socket 121.

The elastic ring 123 has a length shorter than the depth of the fixing socket 121 and is disposed at the end of the transmission transducer 500 and the fixing socket 121 in the direction in which the concrete structure is arranged.

Accordingly, a space is formed between the transmission probe 500 and the fixing socket 121 from the area where the elastic ring 123 is disposed to the stopper 122.

And, the elastic ring 123 is made of an elastic material.

Therefore, when measuring the concrete structure, the transmission probe 500 inserted into the fixing socket 121 is tilted by the angle of the forearm according to the bending of the wrist held by the worker, or the transmission probe 500 is uneven. When contacting the surface of the concrete structure 800, one end of the transmitting transducer 500 elastically presses the elastic ring 123, and the other end of the transmitting transducer 500 is formed in the fixing socket 121. ) And the stopper 122, the transmission transducer 500 can be easily inclined inside the fixing socket 121.

On the other hand, a cut groove 130 is formed on the side surfaces of the sliding part 110 and the transducer receiving part 120.

The cut groove 130 is cut from the side of the transducer receiving unit 120 and the sliding unit 110 to the center of the other surface of the sliding unit 110, that is, to the withdrawal hole 116, so that the sliding unit 110 and the transducer receiving unit 120 ) To communicate with each other.

This cut-out groove 130 allows the cable 700 drawn from the transmission probe 500 to be easily inserted into the lead-out hole 116 when the transmission probe 500 is received in the probe storage unit 120. .

On the other hand, the cut groove 130 according to an embodiment of the present invention may be formed in a right angle direction, but the cut groove 130 according to another embodiment of the present invention is a transmission probe 500 as shown in FIG. When viewed from the direction of the other side, it is also possible to form an oblique direction.

Therefore, when performing the actual measurement work, the cut groove 130 is the cable 700 drawn out to the withdrawal hole 116 of the sliding part 110 through the cut groove 130 through the cut groove 130 by its own weight. It is possible to effectively prevent separation from the withdrawal hole 116.

The receiver adapter 200 is symmetrically spaced apart from the transmitter adapter 100 in the horizontal direction, and is in close contact with the surface of the concrete structure 800 so that the receiving probe 600 receiving the signal from the transmitting probe 500 is fixed.

The receiver adapter 200 is to be able to easily adjust the distance between the receiving transducer 600 and the transmitting transducer 500 fixed to the sender adapter 100, and includes a transducer receiving unit 120 and a sliding unit 110 do.

On the other hand, the transducer receiving unit 120 and the sliding unit 110 of the receiver adapter 200 are the same as those constituting the sender adapter 100, and in order not to obscure the subject matter of the present invention, the same reference numerals in the drawings And a detailed description thereof will be omitted.

The distance adjustment unit 300 controls the movement of the sender adapter 100 and the receiver adapter 200 so that the sender adapter 100 and the receiver adapter 200 are coupled in a sliding manner so that the operator can accurately move to a desired position.

This distance adjustment unit 300 includes a body portion 310 and a locking groove (320).

The body part 310 is the sender adapter 100 and the receiver adapter 200 are coupled in a sliding manner, and the cross section is formed in a bar shape having the same shape as the inside of the sliding housing 111.

Accordingly, the body portion 310 may be easily coupled with the sliding portion 110 of the transmitter adapter 100 and the receiver adapter 200 in a sliding manner.

A scale 330 is formed on the body 310.

A plurality of scales 330 are spaced apart from each other at equal intervals in the longitudinal direction from the other surface of the body portion 310.

The scale 330 has a center dimension of the body 310 of 0, and the dimension of the scale 330 increases as it is arranged in the horizontal direction based on the dimension 0.

This scale 330 is formed at the same interval as the arrangement interval of the locking groove 320.

For this reason, as the bearing ball 114B is accommodated in the locking groove 320 in accordance with the dimensions described on the scale 330, the transmission probe 500 without measuring the distance between the transmission probe 500 and the reception probe 600 individually 500) and the receiving transducer 600 can be accurately arranged.

At this time, it is preferable that the sender adapter 100 and the receiver adapter 200 slide symmetrically in the horizontal direction based on the scale 330 of 0.

A plurality of locking grooves 320 are spaced apart from each other at equal intervals in the length direction from the other surface opposite to the direction in which the concrete structure 800 is arranged in the body portion 310.

The bearing ball 114B of the movement adjusting member 114 is accommodated in the locking groove 320 to limit the movement of the sender adapter 100 and the receiver adapter 200.

Accordingly, the locking groove 320 penetrates from the other surface of the body 310 to a position corresponding to the movement adjustment groove 112 through which the bearing ball 114B of the movement adjustment member 114 penetrates.

That is, since the bearing ball 114B is easily accommodated in the locking groove 320, it is possible to effectively control the movement of the transmitter adapter 100 from the distance adjusting unit 300.

The support 400 is connected to the distance adjustment unit 300 to be gripped by an operator, and is fixed in the center on one surface opposite to the surface on which the locking groove 320 and the scale 330 are formed.

Specifically, the support 400 is made in a bar shape corresponding to the distance control unit 300, is disposed parallel to the distance control unit 300, and is provided at one end and the other end of the distance control unit 300 through a spacer. Thus, it is fixed at a position spaced apart from the distance adjustment unit 300.

Therefore, the support 400 can quickly and easily move the concrete ultrasonic measurement aid.

For this reason, it is possible to prevent an error from occurring in the crack depth measurement result of the concrete structure 800 in the process of carrying the transmitting transducer 500 and the receiving transducer 600 and moving.

In addition, since the support 400 is fixed to the center of the other surface of the body 310, the sender adapter 100 and the receiver adapter 200 are not obstructed to move in a sliding manner, so that the sender adapter 100 and the receiver adapter 200 Can be moved easily by sliding method.

This support 400 is a handle portion 410 is fixed.

The handle part 410 is fixed in the center of the support 400.

This, the handle portion 410 can quickly and easily move the measurement aid.

And the handle part 410 is made of a gripping part 411, a support part 412, and a connection part 413.

The gripping part 411 is directly gripped by an operator, and is fixed to the center of the support 400.

And, the receiving portion 412 is spaced apart from the gripping portion 411 in a direction opposite to the surface on which the locking groove 320 and the scale 330 are formed, and below the operator who gripped the gripping portion 411 Supports the arm, preferably in contact with the lower side of the forearm.

In addition, the connection part 413 is disposed at both ends of the gripping part 411 and the receiving part 412, respectively, to connect the gripping part 411 and the receiving part 412 to each other.

At this time, the length of the connection part 413 may be formed in various lengths according to the length of the operator's arm.

Meanwhile, the support part 412 is formed in an inclined shape from the connection part 413.

Specifically, the support 412 is preferably made at an angle at which the worker's forearm is stably supported according to the degree of bending of the worker's wrist when the measurement aid is pressed against the concrete structure in order to measure the concrete structure.

This support part 412 is made inclined from the connection part 413, and by contacting the lower surface of the forearm, the transmitter adapter 100 and the receiver adapter 100 in which the transmission probe 500 and the reception probe 600 are accommodated, respectively. Even if the sender adapter 100 and the receiver adapter 200 try to be struck downward due to the weight of 200), the support part 412 may be stably supported on the lower side of the operator's lower arm.

Therefore, the support part 412 can firmly prevent the measurement auxiliary device from rotating in a counterclockwise direction around the gripping part 411 based on the drawing shown in FIG. 6, and the transmission probe 500 and the reception It is possible to stably lift the measuring aids in which the transducers 600 are accommodated.

Meanwhile, a rubber pad 414 may be disposed between the support part 412 and the operator's lower arm to protect the operator's lower arm.

Due to this, the rubber pad 414 prevents injury to the lower arm of the worker supporting the weight of the sender adapter 100 and the receiver adapter 200 in which the transmitting transducer 500 and the receiving transducer 600 are respectively accommodated. , It can effectively reduce the fatigue of the forearm due to long-term work.

On the other hand, the forearm refers to between the elbow and the wrist of a person.

As described above, in the ultrasonic measurement aid for concrete according to the present invention, the measurement aid is tilted by bending the wrist of the operator who presses the measurement aid to contact the surface of the concrete structure, or the pressure member 115 is transmitted to the transmitter. 500) and when the receiving transducer 600 contacts the surface of the concrete structure 800 with an uneven surface and the transmitting transducer 500 is inclined in the inside of the transducer receiving unit 120, contacting the other surface of the transmitting transducer 500 Since the pressure needle 115A is elastically supported, the surface of the transmission transducer 500 and the concrete structure 800 are kept parallel to each other, thereby obtaining an accurate crack depth measurement result of the concrete structure 800.

And, since the inner diameter (D1) of the fixed socket 121 is formed larger than the outer diameter (D2) of the transmission transducer 500, the transmitting transducer 500 accommodated in the transducer receiving unit 120 from the transducer receiving unit 120 Can be tilted easily.

The present invention is not limited to the above-described embodiments, and can be implemented with various modifications within the scope of the technical idea of the present invention.

100: sender adapter 110: sliding part
111: sliding housing 112: moving adjustment groove
113: pressure groove 114: movement control member
114A: bolt member 114B: bearing ball
114C: first elastic member 114D: fixing nut
115: pressing member 115A: pressing needle
115B: support portion 115C: first support member
115D: second support member 115E: second elastic member
116: withdrawal hole 120: transducer storage unit
121: fixing socket 122: stopper
123: elastic ring 130: incision groove
200: receiver adapter 300: distance adjustment unit
310: body 320: locking groove
330: scale 400: support
410: handle portion 411: grip portion
412: support part 413: connection part
414: rubber pad 500: transmitting transducer
600: receiving transducer 700: cable

Claims (17)

In a concrete ultrasonic measurement auxiliary device that fixes the transmitting transducer in close contact with the surface of the concrete structure to transmit ultrasonic waves and the receiving transducer in close contact with the surface of the concrete structure to receive ultrasonic waves transmitted from the transmitting transducer at a position separated from the transmitting transducer. In,
A sender adapter accommodating the transmission probe;
A receiver adapter horizontally spaced apart from the sender adapter and receiving the receiver probe;
A distance adjusting unit in which the sender adapter and the receiver adapter are coupled in a sliding manner; And
It is connected to the distance control unit and includes a support that can be gripped by an operator,
Outer diameters of the transmitting transducer and the receiving transducer are respectively smaller than inner diameters of the sender adapter and the receiver adapter,
The sender adapter and the receiver adapter,
And a sliding unit having one end and the other end in a direction orthogonal to a direction in which the transmitting probe and the receiving probe are accommodated, and are coupled to the distance adjusting unit in a sliding manner,
The sliding part,
A sliding housing constituting a body and slidably coupled to the distance adjusting unit therein;
A movement adjustment member for controlling movement in the horizontal direction from the distance adjustment unit; And
Comprising a pair of pressing members for supporting the inclination of the transmitting transducer and the receiving transducer in contact with the surface of the concrete;
The sliding housing,
A movement control groove through which the movement control member passes through an area overlapping the distance control unit on the other surface opposite to the direction in which the concrete structure is disposed; And
A pair of pressing grooves through which the pressing member penetrates through an area overlapping the transmitting transducer or the receiving transducer on the other surface opposite to the direction in which the collet structure is disposed; is formed.
In concrete ultrasonic measurement aid.
The method of claim 1,
The sender adapter and the receiver adapter,
A space is formed therein, and the transducer receiving unit in which the transmitting transducer and the receiving transducer are respectively accommodated; further comprising
In concrete ultrasonic measuring aid.
delete The method of claim 1, wherein the distance adjustment unit,
A body portion to which the sliding portion is coupled in a sliding manner;
Including; a plurality of locking grooves arranged at equal intervals along the horizontal direction of the other surface opposite to the direction in which the concrete structure is arranged in the body part, and into which the movement control member is selectively inserted;
In concrete ultrasonic measuring aid.
The method of claim 4, wherein the sliding housing,
In the other surface opposite to the direction in which the concrete structure is disposed, a movement control groove is formed through which the movement control member penetrates through the area overlapping the distance control unit
In concrete ultrasonic measuring aid.
The method of claim 1, wherein the pair of pressing grooves,
Formed on both sides based on the center of the sliding housing
In concrete ultrasonic measuring aid.
The method of claim 5, wherein the movement control member,
A bolt member formed in a cylindrical shape, one side communicating with the outside, the other side sealed, and having one end inserted into the movement control groove;
A bearing ball disposed on one surface of the bolt member and selectively inserted into the locking groove;
A first elastic member disposed inside the bolt member to elastically support the bearing ball in one surface direction;
And a fixing nut disposed on the other surface of the sliding housing and coupled to the other end direction of the bolt member in a threaded manner to fix the bolt member to the sliding housing
In concrete ultrasonic measuring aid.
The method of claim 1, wherein the pressing member,
A pressing needle inserted into the pressing groove and having one end in contact with the other surfaces of the transmitting and receiving probes;
Consisting of a first support member extending along an outer circumference of the pressure needle and a second support member formed in a size corresponding to the circumference of the first support member at a position corresponding to the first support member on the inner peripheral surface of the pressing groove Support; And
And a second elastic member inserted into the pressure needle and having one end in contact with the first support member and the other end in contact with the second support member
In concrete ultrasonic measuring aid.
The method of claim 4,
A scale is formed on the other surface of the body,
The center of the body has a dimension of 0, and the dimension increases as it is arranged in a horizontal direction based on the dimension 0.
In concrete ultrasonic measuring aid.
The method of claim 9, wherein the scale,
Formed at the same interval as the arrangement interval of the locking grooves
In concrete ultrasonic measuring aid.
The method of claim 9, wherein the sender adapter and the receiver adapter,
Sliding in the horizontal direction based on the scale of 0
In concrete ultrasonic measuring aid.
The method of claim 2, wherein the probe storage unit,
Fixing sockets forming a body and receiving the transmitting transducer and the receiving transducer, respectively;
A stopper formed on the other surface opposite to the direction in which the concrete structure is arranged in the fixed socket to seal a part of the fixed socket and to limit excessive movement of the transmitting or receiving transducer to the other end; And
Arranged between the transmission transducer and the fixing socket, comprising an elastic ring made of an elastic material
In concrete ultrasonic measuring aid.
The method of claim 12, wherein the elastic ring,
Having a length shorter than the depth of the fixing socket, and arranged at the end of the transmission transducer and the direction in which the concrete structure is arranged in the fixing socket
In concrete ultrasonic measuring aid.
The method of claim 1,
A cut-out groove is formed in the side of the transducer receiving unit and the sliding unit to the center of the other surface of the transducer receiving unit in vertical communication between the side surfaces of the sliding unit and the transducer receiving unit
In concrete ultrasonic measuring aid.
The method of claim 14, wherein the cut groove,
Consisting of a diagonal line on the other surface of the sliding part
In concrete ultrasonic measuring aid.
The method of claim 1,
A handle part is fixed in the center of the support,
The handle part is composed of a gripping part gripped by an operator, a support part supporting the operator's lower arm, and a connection part respectively disposed at both ends of the gripping part and the support part to connect the gripping part and the support part
In concrete ultrasonic measuring aid.
The method of claim 16,
The support portion is inclined from the connection portion
In concrete ultrasonic measuring aid.

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