KR100403789B1 - Cable Tension Measurement Device - Google Patents

Abstract

The present invention is a device for measuring the tensile force of the structural cable used in the dome-shaped structure, bridge structure, etc., in one embodiment having a cable entry hole (20a) axially penetrated therein as a cylindrical, the structural cable (10) A load cell 20 positioned on the rear surface of the one end side fixed support to be fixed; Including the chucking means for chucking the end of the structural cable 10 drawn in and out of the cable entry hole (20a) of the load cell 20 to transmit the tension hung on the structural cable 10 to the load cell (20) In this case, an electric tension signal is output from the load cell 20.

Description

Cable Tension Measurement Device for Structural Cables

The present invention relates to a device for measuring the tensile force hanging on the structural cable applied to the example of the cable structure, roof membrane structure, bridge structure, etc. In particular, it is installed with the structural cable to enable the tension check at all times to maintain the maintenance of the structural cable And a tensile force measuring device of a structural cable for managing changes.

In general, structural cables used in the cable structure has a structural rigidity capable of withstanding the tension of several tons to tens of tons. Therefore, in order to maintain such structural rigidity, the structural cable should be checked for tensile force from time to time to adjust tension or maintain maintenance such as maintenance replacement.

Conventionally, the tension force adjustment and measurement of the structural cable used a hydraulic pump, a hydraulic jack and a pressure gauge. This was a method of adjusting or measuring the tension of the cable by repeating the hydraulic jack several times to measure the average tension value.

In addition, recently, a measuring device called a load cell was used, which used a method of installing and measuring a load cell to receive a tensile force by using a hydraulic jack as a hydraulic pump whenever necessary.

However, the measuring method including the hydraulic jack is a cumbersome operation because the hydraulic device must be installed every time the tension measurement, and the load cell fixing method is limited, the environment that the operator is very difficult to measure. Moreover, because the cable tension could not be measured at all times, it was difficult to find an imbalance in a structural cable with multiple strands.

For this reason, there are cases where the cable structure actually collapses. In the roof membrane structure built by the cable dome method, several structural cables support the roof membrane. Each structural cable is subjected to even tension when tension imbalance occurs, causing stress to concentrate on the cable that is subjected to the greatest tension, resulting in a partial or complete collapse of the structure.

Therefore, the present invention was devised in view of the above circumstances, and it is hypothesized that it is possible to check the tension at all times by being installed together with the structural cable so that the tension can be monitored at any time, and the maintenance of the cable is possible at all times. The present invention provides a device for measuring tensile force of structural cables.

Another object of the present invention is to provide a tensile force measuring device of a structural cable to facilitate the installation of a load cell for measuring cable tension.

1 is an installation example as a configuration diagram of a tensile force measuring device of a structural cable according to a first embodiment of the present invention.

2 is an assembled cross sectional view of FIG.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a perspective view of a tensile force measuring device of a structural cable according to a second embodiment of the present invention.

5 is an assembled state diagram of FIG. 4 for explaining the use state of the second embodiment;

6 is an exploded front view of FIG. 5;

Figure 7 is a use state as an assembled cross-sectional view according to a third embodiment of the present invention.

8 is a state of use as an assembled cross-sectional view according to a fourth embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: Structural cable 20,20 ': Load cell

20a: Inlet hole 20b: Male threaded part

22: screw shaft 22a: through hole

30: wedge 31: split wedge

32: elastic ring 33: wedge hole

40: wedge socket 41: tapered hole

50, 51: Connection socket 50a: Screw hole

50b: taper hole

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

FIG. 1 is an exemplary view illustrating an installation of the apparatus for measuring tensile force of a structural cable according to a first embodiment of the present invention. FIG. 2 is an assembled cross-sectional view of FIG. 1, and FIG. 3 is a cross-sectional view taken along line A-A of FIG.

In FIG. 1, reference numeral 20 is a load cell.

The load cell 20 is cylindrical and has a cable entry hole 20a axially penetrated therein, and is provided on the rear surface of any one end side supporting member 5 to which the structural cable 10 is to be fixed.

The load cell 20 is a sensor that electrically detects the amount of compression change when subjected to a tensile force. The load cell 20 is connected to a known strain measuring device 1 to detect an electrical signal and then converted into a digital signal by a computer device. Tensile force can be expressed numerically. In addition, a monitoring system can be connected to the strain measuring device to display a graph on the image.

One side of the load cell 20 is provided with a chucking device for transmitting the tensile force hung on the structural cable 10 to the load cell 20. That is, the chucking device chucks the end of the structural cable 10 that enters and exits the cable entry hole 20a of the load cell 20 to transfer the tension hung on the structural cable 10 to the load cell 20. It is supposed to be done.

The chucking device is composed of a wedge 30 and a wedge socket 40 which is in contact with one side of the load cell 20 and has a perforated taper hole 41 tapered with the wedge 30. .

The wedge 30 is divided into a plurality of divided wedges on the circumference and tapered outer circumference as shown in FIG. 3, and an elastic ring 32 for arranging the divided wedges 31 on the circumference with elastic force. And a wedge hole 33 formed in the center at least smaller than the diameter of the structural cable 10 when the plurality of split wedges 31 are aligned by the elastic ring 32. The wedge hole 33 is preferably threaded in accordance with the surface structure of the structural cable 10.

The outer circumferential surface of the wedge (30) is tapered because the radius of the split wedge (31) when it first enters the taper hole (41) of the socket (40) after the cable (10) is first bited by the elastic force of the elastic ring (32) This is to prevent the cable 10, which is tightened further in the center direction, from which the tens of tons of force is deviated from the wedge 31.

The elastic ring 32 may be made of a spring steel wire or rubber as a circular shape, and is composed of a cutting type rather than a closed type.

The cable entry hole 20a may further include a screw shaft 22 having a through hole 22a to allow the structural cable 10 to be inserted therethrough. The screw shaft 22 has a screw thread formed on its outer circumferential surface and is screwed into the cable entry hole 20a as shown in FIG.

The reason why the screw shaft 22 is added is that the structural cable 10 prevents the structural cable 10 from directly contacting the inner surface of the load cell 20 when the structural cable 10 flows slightly in the tensile structure, thereby preventing the load of the load cell 20. This is to prevent damage and measurement errors.

The installation method and operation of the first embodiment configured as described above will be described.

First, as shown in FIG. 1, one end of the cable 10 is inserted into the through hole 5a formed in the fixing member 5 (part of the tensile structure) to which one end of the cable 10 is to be fixed, and then fixed. On the back side of the member 5, the screw shaft 22, the load cell 20, the wedge socket 40 and the wedge 30 are sequentially inserted into the cable 10. At this time, the screw shaft 22 and the load cell 20 may be screwed together and inserted into the cable 10 at the same time.

In this state, when the cable 10 is properly pulled, the wedge 30 is tapered to the wedge socket 40 as shown in FIG. 2, and the back side of the load cell 20 of the socket 40 is in contact with the wedge 30. The other surface is in contact with the fixing member (5) side.

Next, when the main tensile force acts on the structural cable 10, the force acts axially on the load cell 20 through the wedge 30 and the wedge socket 40 holding the cable 10.

Therefore, the load cell 20 is compressively deformed, and this amount of deformation is sent to a known strain measuring apparatus 1 electrically connected to the load cell 20 as an electrical signal. In the strain measuring apparatus 1, this signal is amplified and converted to be displayed as a digital or analog signal. Since these measurement data are always available at each measuring point from multiple structural cables, comparing these figures can reveal cables with unbalanced tensile forces, and adjusting their tensions can provide a totally balanced tension.

Therefore, it is possible to take measures such as finding and replacing cables that have reached the fatigue limit due to intensive tension.

The chucking means presented in the first embodiment is an example, and the present invention is not limited thereto. As another example, if a pair of blocks is provided, the cable tightening hole smaller than the diameter of the cable is formed in the split surface of the pair of blocks, and the pair of blocks is fastened by using a fastening bolt and a nut. The cable is chucked.

That is, a pair of blocks may be disposed on the cable so that the tightening hole is wrapped around the portion to be fixed in the structural cable, and the tightening hole may be tightened by tightening the block with a plurality of fastening bolts and nuts.

4 and 5 are a perspective view and an assembled state of the tensile force measuring device of the structural cable according to a second embodiment of the present invention, Figure 6 is an exploded front view of FIG.

The main feature of the second embodiment is not to install the load cell 20 on the fixing member 5 side as shown in Figures 4 and 5, the load cell 20 'to be deformed in the middle of the break of the cable 10 to connect the tensile force It is supposed to be measured.

That is, as shown in FIG. 5, the load cell 20 ′ and a pair of connection sockets 50 and 51 for connecting the load cell 20 ′ to the cable 10 are included.

The load cell 20 'is cylindrical and has male threaded portions 20b on the outer circumferential surfaces of both ends, respectively, and is located at the connection portion where the tensile measurement of the structural cable 10 is to be made.

The connecting sockets 50 and 51 are screw holes 50a for screwing into the male screw portions 20b at both ends of the load cell 22, respectively, and tapered holes 50b extending coaxially from the screw holes 50a. )

The connection end of the cable 10 to be fixed to the connection sockets 50 and 51 extends in a tapered shape.

In the tensile force measuring device of the second embodiment configured as described above, as shown in FIGS. 5 and 6, a pair of connecting sockets 50 and 51 are inserted into the ends of both cables 10, respectively, so that the connecting sockets 50 and 51 are opposite to each other. To place.

Here, one method of manufacturing the conical shape so that the end of the cable 10 does not escape in the pulling direction from the connecting sockets 50 and 51 is to melt the lead containing in the conical mold after loosening the end wires of the end of the cable 10. It can be made by pouring metal to solidify it.

Next, the load cell 20 'is positioned between the pair of connecting sockets 50 and 51, and the screw holes 50a of the connecting sockets 50 and 51 are respectively provided at the male threaded portions 22b at both ends of the load cell 20'. ) To assemble as shown in FIG.

When tensions (F, F) are applied to the cable (10) in this state, the tension tensions the load cell (20 ') through connecting sockets (50, 51) arranged on both sides of the load cell (20').

Therefore, the deformation amount according to the tensile force is generated in the load cell 20 ', and this deformation amount is sent to the known deformation measuring apparatus 1 electrically connected to the load cell 20' as an electric signal value. In this deformation measuring apparatus 1, measurement data is obtained in the same manner as in the first embodiment, and the tension can be adjusted based on this to maintain a uniform tension, and the concentrated tension cable can be replaced before breaking.

7 is an exemplary view according to a third embodiment of the present invention, in which the chucking means of the first embodiment is modified. That is, the first embodiment is a case where the cross-sectional structure of the structural cable 10 can use the wedge 30, but the structural cable 10 shown in Fig. 7 of the third embodiment is composed of a single wire, and this structural cable The end and one end of the 10 is connected to the forging process is provided with a screw rod 26 for forming a male thread on the other end, the screw rod 26 is fixed to the tension hanging on the structural cable 10 The fastening nut 27 to be transmitted to the load cell 20 located on the back of the (5) is screwed structure.

Therefore, the tensile force acting on the structural cable 10 compresses the load cell 20 through the screw rod 26 and the fastening nut 27 to measure the tensile force.

8 is an exemplary view according to a fourth embodiment of the present invention, which is a modification of FIG. 5.

As shown in FIG. 8, a load cell 20 ′ having a male screw portion 20 b on both ends of the outer circumferential surface as a cylindrical shape and positioned at a connection portion at which tensile measurement of the structural cable 10 is to be made, and at one end of the load cell 20 ′ And a pair of connecting sockets 50 'and 51' each having a screw hole 50a 'for screwing to both ends of the male screw portion 20b of the c) and a socket screw hole 50b' at the other end thereof. The connecting end of the structural cable 10 is provided with connecting sockets 40 and 40 'which are screwed into the socket screw holes 50b', so that the load cell 22 when a tensile force occurs at both sides of the structural cable 10. ), The electrical tension signal is output.

At this time, the connection between the connecting sockets 40 and 40 'and the cable 10 is forged.

Thus, it can be seen that embodiments of the present invention can measure the tensile force regardless of the structure of the structural cable.

As described above, according to the present invention, it is possible to continue to use it by installing a single tensile force measuring device, and to reduce maintenance costs, and to always check without a professional technician or a professional company, and to check the abnormal state of each structural cable. Monitoring and accurate reinforcement planning can be established to prevent safety accidents.

Claims (6)

In the device for measuring the tensile force hung on the structural cable 10, A load cell 20 which is cylindrical and has a cable entry hole 20a axially penetrated therein and is located on the rear surface of any one end fixing support portion 5 on which the structural cable 10 is to be fixed; Including the chucking means for chucking the end of the structural cable 10 drawn in and out of the cable entry hole (20a) of the load cell 20 to transmit the tension hung on the structural cable 10 to the load cell (20) , Tensile force measuring device of the structural cable, characterized in that the electrical tension signal is output from the load cell (20). The method of claim 1, wherein the chucking means, A plurality of split wedges 31 divided into a plurality of circumferences and tapered outer circumferences, an elastic ring 32 for aligning the split wedges 31 with an elastic force on a circumference, and a plurality of split wedges by the elastic rings 32 A wedge 30 having a wedge hole 33 formed in the center at least smaller than the diameter of the structural cable 10 when the two wedges 31 are aligned; Measurement of the tensile force of the structural cable comprising a wedge socket 40 which is installed in contact with one side of the load cell 20 having a through tapered hole 41 tapered to the wedge 30 in the center in a cylindrical shape Device. The method of claim 1, A screw shaft 22 having a through hole 22a is screwed into the cable entry hole 20a so that the structural cable 10 can be inserted therein, thereby damaging the load cell 20 due to the movement of the structural cable 10. Tensile force measuring device of a structural cable, characterized in that configured to prevent. The method of claim 1, The chucking means may include a screw rod 26 having an end portion and one end portion of the structural cable 10 connected by forging and forming a male screw at the other end portion; It is composed of a fastening nut 27 screwed to the screw rod 26, and transmits the tension hung on the structural cable 10 to the load cell 20 located on the back of the fixed support (5). Tensile force measuring device for structural cables. In the device for measuring the tensile force hung on the structural cable 10, A load cell 20 'having a cylindrical shape having male threads 20b on the outer circumferential surface of both ends and positioned at a connection portion where the tensile measurement of the structural cable 10 is to be made; A pair of connecting sockets having a screw hole 50a for screwing to both male screw portions 20b at both ends of the load cell 20 ', and a tapered hole 50b extending coaxially from the screw hole 50a. 50, 51), After extending the connecting end of the structural cable 10 and fixed to each of the tapered holes 50b of the pair of connecting sockets 50 and 51 arranged in opposite directions, the electrical tension signal is transmitted from the load cell 22. Tensile force measuring device of the structural cable characterized in that the output. In the device for measuring the tensile force hung on the structural cable 10, A load cell 20 'having a cylindrical shape having male threads 20b on the outer circumferential surface of both ends and positioned at a connection portion where the tensile measurement of the structural cable 10 is to be made; A pair of connecting sockets 50 'each having a screw hole 50a' for screwing into both male screw portions 20b of the load cell 20 'at one end and a socket screw hole 50b' at the other end thereof. , 51 '), The connecting end of the structural cable 10 is provided with connection sockets 40 and 40 'which are screwed into the socket screw holes 50b', so that the load cell 22 when a tensile force occurs at both sides of the structural cable 10. Tensile force measuring device of the structural cable, characterized in that the electrical tension signal is output from).