KR101987653B1 - Device for measuring mounting angle of bridge shoe - Google Patents

Abstract

An objective of the present invention is to provide a device for measuring an installation direction of a shoe for a bridge which can accurately measure an installation direction of a shoe installed between an abutment or a bridge post and a superstructure. To achieve the objective, the device for measuring an installation direction of a shoe for a bridge comprises: an angle indication plate which has a plate structure of a perpendicular cross section having angle gradations imprinted on an upper surface thereof, and is seated across an upper surface and a side of an abutment or a bridge post; a first height adjustment device mounted on a center position of an inner end of the angle indication plate to adjust a height of a shoe installation angle indication hand; and the shoe installation angle indication hand including a hinge coupling end hinged on an upper end of the first height adjustment device, a shoe contact end extended backwards from the hinge coupling end, and an angle indication end extended forwards from the hinge coupling end to point to an angle gradation of the angle indication plate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a shoe installation direction measuring instrument for a bridge, and more particularly, to a shoe installation direction measuring instrument for a bridge, The present invention relates to a shoe installation direction meter for measuring a shoe installation direction.

1, the bridge is comprised of a plurality of superstructures 30 mounted on alternating 10, pier 20 and alternate 10 or pier 20.

The upper structure 30 is a structure including a girder and an upper plate, and concrete or asphalt pavement is installed on the upper surface of the structure.

Particularly, since the upper structure 30 rotates due to shrinkage, expansion, and live load in accordance with the temperature change, the upper structure 30 is installed at an interval capable of relative displacement.

Moreover, as a means for permitting the relative displacement of the upper structure 30 to be applied on the alternation 10 or the bridge 20, it is preferred that the bridge 10 and the upper structure 30 and between the bridge 20 and the upper structure 30, (Shoe) 40 is provided between the upper and lower shrouds 30.

1, the shoe 40 includes a lower shoe 41 provided in a plate shape having a concave groove 43 and fixedly mounted on the alternating 10 and the pier 20, And an upper shoe 42 provided in a plate shape having a convex portion 44 and mounted on a bottom portion of the upper structure 30. [

At this time, the upper shoe 42 is arranged along the width direction of the upper structure 30, and the lower shoe 41 is also arranged and arranged along the width direction of the alternation 10 and the pier 20 State.

The convex portion 44 of the upper shoe 41 mounted on the upper structure 30 is rotated by the alternation 10 And the recesses 43 of the lower shoe 41 mounted on the bridge 20 to enable relative displacement between the upper structures 30.

On the other hand, in the plurality of upper structures 30, the boundary lines are linearly arranged in a linear section, and the boundary lines are arranged in an oblique line in a curved section or a slant section.

2 (a) and 2 (b) show an example in which a plurality of upper structures are installed in a straight section, and FIG. 2 (b) Fig. 2 (c) is a schematic plan view showing an example in which a plurality of superstructures are installed in a curved section, and Fig. 2 (c) is a schematic plan view showing an example in which a plurality of superstructures are installed in a curved section.

2 (a), when a plurality of superstructures 30 are installed in a straight section, boundary lines between the superstructures 30 are arranged in parallel along the width direction so that the edges of the superstructure 30 The portion becomes a right angle.

2 (b), when a plurality of upper structures 30 are installed in a curved section or a slant section, the boundary line between the upper structures 30 is inclined at a predetermined angle And &thetas; 2).

Referring to FIG. 2 (c), when a plurality of upper structures 30 are installed in curved bridges forming arcs, the boundary lines between the upper structures 30 are arranged diagonally at a predetermined angle along the width direction .

Of course, a separate expansion joint (not shown) is installed at the boundary between the upper structures 30.

The convex portion 44 of the upper shoe 41 mounted on the upper structure 30 is displaced in the direction of the shift 10 Since the shoe 40 is moved in the same groove 43 of the lower shoe 41 mounted on the bridge 20 and moved in the same direction as the displacement of the upper structure 30, Direction.

The convex portion 44 of the upper shoe 41 may be disposed on the lower shoe 41 so that the lower shoe 41 can be moved in a direction different from the direction of displacement of the upper structure 30 during the design and construction of the shoe 40. [ The distance traveled within the groove 43 of the upper structure can be restricted, thereby making it impossible to accommodate displacement of the superstructure, which can act as a risk factor for bridge safety.

Accordingly, the safety check is performed periodically or irregularly not only immediately after the bridge construction but also after a certain time after the bridge construction, and the safety check item includes items for measuring the installation state of the shoe.

2 (a), when a plurality of upper structures 30 are installed in a straight section, the boundary lines between the upper structures 30 are arranged in parallel along the width direction, The mounting direction of the shoe 40 can be easily arranged in a linear array along the width direction of the upper structure 40 in accordance with the displacement of the upper structure 30 in the longitudinal direction.

However, as shown in FIGS. 2B and 2C, when a plurality of upper structures 30 are installed in an oblique section or a curved section or the like, the boundary line between the upper structures 30 is formed in a predetermined So that the installation direction of the shoe 40 should also have a diagonal arrangement at a predetermined angle.

In other words, when the upper structure 30 constructed with the boundary line at a predetermined angle (indicated by? 1 and? 2 in FIG. 2) along the width direction is relatively displaced by contraction and expansion, the upper structure 30 The convex portion 44 of the mounted upper shoe 41 is moved in the groove 43 of the lower shoe 41 mounted on the alternation 10 and the pier 20 so that the displacement direction of the upper structure 30 The installation direction of the shoe 40 should also be diagonal with a predetermined angle (indicated by? 1 and? 2 in FIG. 2).

If the mounting direction of the shoe 40 is deviated from a predetermined angle (indicated by? 1 and? 2 in FIG. 2), the convex portion 44 of the upper shoe 41 is inserted into the groove 43 of the lower shoe 41 May be limited, thereby making it impossible to accommodate the displacement of the superstructure and thus acting as a risk factor for bridge safety.

In addition, if the installation angle of the shoe is shifted, the movement direction of the shoe does not move properly in the originally set direction, thereby causing a problem of separation of the shoe, damage to the pier / change, and upper structure .

Therefore, when the safety check is performed regularly or irregularly not only immediately after the bridge construction but also after a certain time after the bridge construction, the installation direction of the shoe must be accurately measured. Especially, It is necessary to investigate and examine whether the directions of movement of the bridges coincide with each other.

However, since there is no separate mechanism for measuring the installation direction of the shoe, there is a problem that the installation direction of the shoe can not be accurately measured in order to check the safety of the bridge by measuring with the naked eye or using a general protractor.

Patent Registration No. 10-1745958 (2017.06.05)

It is an object of the present invention to provide a shoe installation direction measuring device for a bridge capable of accurately measuring an installing direction of a shoe installed between alternate piers and an upper structure .

According to an aspect of the present invention, there is provided an angular indication plate comprising: an angle indicating plate which is mounted on an upper surface and a side surface of an alternating or pierced angle, A first height adjusting device mounted at a center position of an inner end of the angle indicating plate to adjust a height of the shoe installing angle indicating needle; A hinge fastening end hinged to the upper end of the first height adjusting device; a shoe contact end extending rearward from the hinge fastening end; and a shoe having an angle indicating end extending forward from the hinge fastening end and indicating an angle scale of the angle indicating plate Installation angle indication needle; When the shoe contact end of the shoe installation angle indicating needle is brought into close contact with the shoe provided between the alternate and upper structure or between the pier and the upper structure in a state where the angle indicating plate is alternately placed on the upper surface of the pier, Wherein the shoe installation angle indicating needle is rotated at an angle corresponding to the installation angle of the shoe about the hinge fastening end and the angle indicating end indicates the angle scale on the angle indicating plate corresponding to the installation angle of the shoe Provides a shoe installation direction meter for bridges.

In one embodiment of the present invention, the first height adjusting device comprises: a fixing pipe fixedly mounted at an inner end central position of the angle indicating plate; A first laminating pipe and a second laminating pipe which are sequentially stacked on a fixed pipe; A first nut disposed between the fixed pipe and the first laminated pipe; A second nut disposed between the first stacking pipe and the second stacking pipe; An upper end portion of the upper bolt is hinged to a hinge fastening end of the shoe installation angle indicating needle via a ball bearing, a lower end portion of the upper bolt is screwed to the second nut and disposed in the second laminating pipe and the first laminating pipe; A lower bolt screwed into the first nut and disposed in the first laminated pipe and the fixed pipe; .

Preferably, a laser pointer for irradiating an angle scale on the angle indicating plate is mounted at an end of the angle indicating end of the shoe installation angle indicating needle.

According to another aspect of the present invention, there is provided a plate structure of a rectangular cross-section having a half ring having an angular scale on an upper surface thereof, the plate having an angle indicating plate mounted on an upper surface and a side surface of an alternating or piercing angle; A first height adjusting device mounted at a center position of an inner end of the angle indicating plate to adjust a height of the shoe installing angle indicating needle; A hinge fastening end hinged to the upper end of the first height adjusting device; a shoe contact end extending rearward from the hinge fastening end; and a shoe having an angle indicating end extending forward from the hinge fastening end and indicating an angle scale of the angle indicating plate Installation angle indication needle; A second height adjusting device connected between the half ring of the angle indicating plate and an angle indicating end of the shoe mounting angle indicating needle, the second height adjusting device adjusting the height of the shoe installing angle indicating needle, Height adjustment device; When the shoe contact end of the shoe installation angle indicating needle is brought into close contact with the shoe provided between the alternate and upper structure or between the pier and the upper structure in a state where the angle indicating plate is alternately placed on the upper surface of the pier, The shoe installation angle indicating needle is rotated at an angle corresponding to the installation angle of the shoe about the hinge fastening end, the angle indicating stage and the second height adjusting device are rotated at the same angle along the half ring, And a plurality of shoe-mounted shoe-mounting-direction meters.

In another embodiment of the present invention, the first height adjusting device comprises: a fixing pipe fixedly mounted at an inner end center position of the angle indicating plate; A first laminating pipe and a second laminating pipe which are sequentially stacked on a fixed pipe; A first nut disposed between the fixed pipe and the first laminated pipe; A second nut disposed between the first stacking pipe and the second stacking pipe; An upper end portion of the upper bolt is hinged to a hinge fastening end of the shoe installation angle indicating needle via a ball bearing, a lower end portion of the upper bolt is screwed to the second nut and disposed in the second laminating pipe and the first laminating pipe; A lower bolt screwed into the first nut and disposed in the first laminated pipe and the fixed pipe; .

In another embodiment of the present invention, the second height adjusting device includes: a first conveying pipe having a slide groove formed at a lower portion thereof so that a half ring of the angle indicating plate is inserted; A second conveying pipe stacked on the first conveying pipe with a first nut interposed therebetween; A third conveying pipe which is stacked on a second conveying pipe with a second nut therebetween and whose upper end is engaged with an angle indicating end of the shoe installation angle indicating needle; A lower bolt screwed into the first nut and disposed in the first conveying pipe and the second conveying pipe; An upper bolt screwed into the second nut and disposed in the second conveying pipe and the third conveying pipe; .

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

First, it is possible to accurately measure the installation direction of the shoe installed between the piers and the superstructure, immediately after the bridge construction, and at regular or irregular safety checks.

Secondly, since the installation direction of the shoe can be accurately measured, the displacement amount of the upper structure displaced in the same direction with the shoe can be measured. Accordingly, the correlation with the upper structure or the correlation Can be accurately interpreted.

1 is a schematic sectional view showing a construction state of a bridge,
2 (a) and 2 (b) show an example in which a plurality of upper structures are installed in a straight section, and FIG. 2 (b) FIG. 2 (c) is a schematic plan view showing an example in which a plurality of superstructures are installed in a curved section, FIG. 2
3 is a plan view of a shoe installation direction measuring instrument according to an embodiment of the present invention,
4 is a side view of a shoe installation direction measuring instrument according to an embodiment of the present invention,
FIG. 5 is a side view showing a usage state of a shoe installation direction measuring instrument according to an embodiment of the present invention, FIG.
6 is a plan view of a shoe installation direction measuring instrument according to another embodiment of the present invention,
FIG. 7 is a side view showing a shoe installation direction measuring device for a bridge according to another embodiment of the present invention;
8 is a side view showing a state of use of a shoe installation direction measuring instrument according to another embodiment of the present invention.

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

3 and 4 are a plan view and a side view showing a shoe installation direction measuring device for a bridge according to an embodiment of the present invention, and FIG. 5 is a sectional view of the shoe installing direction measuring device for a bridge according to an embodiment of the present invention Shows the usage status for measuring the shoe installation angle.

3 to 5, reference numeral 100 denotes an angle indicating plate.

The angle indicating plate 100 has a plate-like structure in which the upper plate and the side plate are perpendicular to each other, and an angle scale 102 for indicating the shoe installation angle is marked on the upper surface of the upper plate.

In order to measure the shoe installation angle, the upper plate and the side plate of the angle indicating plate 100 are respectively seated over the upper surface and the side surface of the alternating tongue 10 or the pierced angle 20.

In addition, a first height adjusting device 110 using bolts and nuts is mounted at the center of the inner end of the angle indicating plate 100 to adjust the height of the shoe installing angle indicating needles 130.

A shoe installation angle indicating needle 130 is rotatably mounted on an upper end of the first height adjusting device 110 to indicate an angle scale 102 of the angle indicating plate 100 according to a shoe installing angle.

More specifically, the shoe installation angle indicating needle 130 includes a hinge fastening end 132 hinged to the upper end of the first height adjusting device 110 and a hinge fastening end 132 hinged to the rear of the hinge fastening end 132 A contact end 134 and an angle indicating end 136 extending forward from the hinge fastening end 132 and indicating an angle scale 102 of the angle indicating plate 100 are integrally formed.

The first height adjusting device 110 is for adjusting the height of the shoe installing angle indicating needle 130. The first height adjusting device 110 includes a fixing pipe 111 fixedly mounted at the center of the inner end of the angle indicating plate 100, A first laminating pipe 112 and a second laminating pipe 113 which are sequentially stacked on the fixed pipe 111 and a first nut 114 disposed between the fixing pipe 111 and the first laminating pipe 112 A second nut 115 disposed between the first and second laminated pipes 112 and 113 and a second nut 115 disposed between the first and second laminated pipes 112 and 113. The upper end of the nut 115 is connected to the hinge fastening end 132 of the shoe- An upper bolt 117 which is hinged via a hinge 116 via a second laminating pipe 113 and a first laminating pipe 112 while a lower end thereof is screwed to the second nut 115, 114 and a lower bolt 118 disposed in the first pipe 111 and the second pipe 111.

At this time, the fixed pipe 111 and the first laminating pipe 112 can move up and down the lower bolt 118 and support the vertical standing state of the lower bolt 118, The first and second lamination pipes 112 and 113 support the upper bolt 117 in a vertically standing state by vertically moving the upper bolt 117 upward and downward.

When the first nut 114 is rotated, the lower bolt 118 is raised and lowered by screw rotation. When the second nut 115 is rotated, the upper bolt 117 is raised and lowered by the screw rotation.

More specifically, when the first nut 114 is rotated in one direction, the lower bolt 118 is raised by the screw rotation, and the support end 118-1 formed around the lower bolt 118 is pressed against the first stacking When the pipe 112 is pushed up and the second nut 115 is rotated in one direction, the upper bolt 111 is raised by screw rotation, and at the same time, the hinge fastening end 132 of the shoe installation angle indicating needle 130 is pushed up The height of the shoe installation angle indicating needle 130 is adjusted to be increased.

On the contrary, when the first nut 114 is rotated in the other direction, the lower bolt 118 is lowered by the screw rotation, the first lamination pipe 112 is lowered, and the second nut 115 is rotated in the other direction The upper bolt 111 is lowered by the screw rotation and at the same time the hinge fastening end 132 of the shoe installation angle indicating needle 130 is pulled down so that the height of the shoe installed angle indicating needle 130 is adjusted down.

The reason for adjusting the height of the shoe installation angle indicating needle 130 is that it is installed between the shift 10 and the upper structure 30 and between the bridge 20 and the upper structure 30, This is because the installation height of the shoe (40, shoe) is different.

That is, the reason why the height of the shoe installation angle indicating needle 130 is adjusted is that the height from the upper surface of the alternation 10 and the bridge 20 to the position where the shoe 40 is installed differs from bridge to bridge, The height of the shoe installation angle indicating needle 130 for measuring the mounting direction (angle) is adjusted to the height from the upper surface of the alternating tongue 10 and the bridge 20 to the position where the shoe 40 is installed.

Hereinafter, the use state of the shoe installation direction measuring instrument according to an embodiment of the present invention will be described with reference to FIG.

First, the angle indicating plate 100 is seated over the upper surface and the side surface of the alternating portion 10 or the pierced angle 20. [

The shoe contact end 134 of the shoe installation angle indicating needle 130 is closely contacted with the shoe 40 provided between the alternating 10 and the upper structure 30 or between the bridge 20 and the upper structure 30 .

2 (b) and 2 (c), when the upper structure 30 is installed in an oblique section, a curved section, or the like, the boundary line between the upper structures 30 is formed along the width direction, (Indicated by &thetas; 1 and &thetas; 2 in Fig. 2), the mounting direction of the shoe 40 is also oblique or curved at a predetermined angle You should have an array.

When the shoe contact end 134 of the shoe installed angle indicating needle 130 is brought into close contact with the shoe 40, preferably the shoe contact end 134 of the shoe installed angle indicating needle 130 is brought into contact with the shoe 40 , The shoe installation angle indicating needle 130 is rotated so as to match the installation direction (angle) of the shoe, so that the rotation of the shoe- The angle indicating end 136 of the installation angle indicating needle 130 indicates the angle scale 102 on the angle indicating plate 100 corresponding to the installation angle of the shoe 40. [

The laser pointer 104 for irradiating the angle scale 102 on the angle indicating plate 100 is mounted at the end of the angle indicating stage 136 of the shoe installed angle indicating needle 130 so that the laser pointer 104 The laser beam is irradiated while accurately pointing at the angle scale 102 on the angle instruction plate 100. [

At this time, the angle scale 102 on the angle indicating plate 100 corresponding to the installation angle of the shoe 40 in the laser pointer 104 mounted on the angle indication stage 136 of the shoe installation angle indicating needle 130 (For example, indicated by? 1 and? 2 in FIG. 2) when the shoe 40 is pointed at the original installation angle of the shoe 40 (indicated by &thetas; 1 and &thetas; 2), it is determined that the shoe installation direction has been erroneously constructed and diagnosed as having a safety problem.

As described above, according to the embodiment of the present invention, it is possible to accurately measure the installation direction of the shoe installed between the piers and the upper structure immediately after the bridge construction, and periodically or irregularly, when the safety check is performed.

In addition, since the installation direction of the shoe can be accurately measured, the displacement amount of the upper structure displaced in the same direction with the shoe can be measured. Accordingly, the correlation with the upper structure or the correlation between the upper structure and the bridge Can be accurately interpreted.

Hereinafter, a bridge shoe installation direction measuring instrument according to another embodiment of the present invention and its use state will be described.

6 and 7 are a plan view and a side view showing a shoe installation direction measuring device for a bridge according to another embodiment of the present invention, .

In another embodiment of the present invention, the means for indicating the shoe mounting direction (angle) instead of the laser pointer is replaced by the half ring 106 having the angle scale 102, and the angle indication And a second height adjusting device 120 which is adjustable in height between the step 136 and the half ring 106 and movable along the half ring 106 is connected.

For this purpose, the angle indicating plate 100 is formed in a plate-like structure in which the upper plate and the side plate are perpendicular to each other, and a half ring 106 having an angle scale 102 is formed on the upper surface of the upper plate .

In another embodiment of the present invention, at the center of the inner end of the angle indicating plate 100, a first height adjusting device using bolts and nuts to adjust the height of the shoe installing angle indicating needles 130, And a shoe installation angle indicating needle 130 for indicating an angle scale 102 of the angle indicating plate 100 in accordance with the shoe installing angle is mounted on the upper end of the first height adjusting device 110 And is rotatably mounted.

The first height adjusting device 110 and the shoe installed angle indicating needles 130 according to another embodiment of the present invention have the same configurations as those described in the above embodiment, .

According to another embodiment of the present invention, a second height adjusting device 120 is provided between the half ring 106 of the angle indicating plate 100 and the angle indicating end 136 of the shoe installing angle indicating needle 130 The second height adjusting device 120 adjusts the height of the shoe installation angle indicating needle 130 together with the first height adjusting device 110 and attaches the angle indicating stage 136, .

To this end, the second height adjusting device 120 includes a first conveying pipe 121 having a slide groove 121-1 formed at a lower portion thereof so that the half ring 106 of the angle indicating plate 100 is inserted, A second conveying pipe 122 which is stacked on the first conveying pipe 121 with a first nut 124 interposed therebetween and a second nut 125 which is stacked on the second conveying pipe 122 The upper end portion is connected to the third conveying pipe 123 which is engaged with the angle indicating end 136 of the shoe installation angle indicating needle 130 and the third conveying pipe 123 which is screwed to the first nut 124, A lower bolt 126 disposed in the transfer pipe 122 and an upper bolt 127 disposed in the second transfer pipe 122 and the third transfer pipe 123 while being screwed to the second nut 125 .

When the first nut 124 is rotated in one direction, the lower bolt 126 is raised and the support end 126-1 formed around the lower bolt 126 pushes up the second transfer pipe 122 The upper bolt 127 is raised and the support pin 127-1 formed around the upper bolt 127 pushes up the third transfer pipe 123. When the second nut 125 is rotated in one direction, The third transfer pipe 123 pushes up the angle indicating end 136 of the shoe installation angle indicating needle 130.

Therefore, the height of the hinge fastening end 132 of the shoe installation angle indicating needle 130 is height-adjusted by the first height adjusting device 110 and the height of the angle indicating end 136 of the shoe installing angle indicating needle 130 is adjusted. The second height adjusting device 120 adjusts the height thereof to the same height.

Hereinafter, the use state of the shoe installation direction measuring instrument according to another embodiment of the present invention will be described with reference to FIG.

First, the angle indicating plate 100 is seated over the upper surface and the side surface of the alternating portion 10 or the pierced angle 20. [

The shoe contact end 134 of the shoe installation angle indicating needle 130 is closely contacted with the shoe 40 provided between the alternating 10 and the upper structure 30 or between the bridge 20 and the upper structure 30 .

2 (b) and 2 (c), when the upper structure 30 is installed in an oblique section, a curved section, or the like, the boundary line between the upper structures 30 is formed along the width direction, (Indicated by &thetas; 1 and &thetas; 2 in Fig. 2), the mounting direction of the shoe 40 is also oblique or curved at a predetermined angle You should have an array.

When the shoe contact end 134 of the shoe installed angle indicating needle 130 is brought into close contact with the shoe 40, preferably the shoe contact end 134 of the shoe installed angle indicating needle 130 is brought into contact with the shoe 40 The shoe installation angle indicating needle 130 rotates so as to match the installation direction (angle) of the shoe, when the shoe is brought into close contact with the side surface of the convex portion 44 of the upper shoe 42.

At the same time, the shoe installation angle indicating needle 130 rotates the second height adjusting device 120.

That is, since the half ring 106 of the angle indicating plate 100 is inserted into the slide groove 121-1 formed in the first conveying pipe 121 of the second height adjusting device 120, The first conveying pipe 121 rotates at the same angle along the half ring 106 when the shoe installation angle indicating needle 130 rotates.

The shoe installation angle indicating needle 130 rotates at an angle corresponding to the installation angle of the shoe 40 about the hinge fastening end 132 and the angle indicating stage 136 and the second height adjusting device 120 are rotated, Is rotated at the same angle along the half ring 106 to indicate an angle scale 102 formed on the half ring 106. [

At this time, when the angle indicating end 136 of the shoe installation angle indicating needle 130 indicates the angle scale 102 formed on the half ring 106 at a position stopped after rotation, (For example, indicated by? 1 and? 2 in FIG. 2), the normal state is determined. On the other hand, if the angle indicates an original installation angle of the shoe 40 (e.g., indicated by? 1 and? 2 in FIG. 2) It is judged that it is erroneously installed and diagnosed as having a safety problem.

Thus, according to another embodiment of the present invention, when the safety inspection is performed immediately after the bridge construction and periodically or irregularly, the installation direction of the shoe installed between the bridge piers and the upper structure can be accurately measured.

In addition, since the installation direction of the shoe can be accurately measured, the displacement amount of the upper structure displaced in the same direction with the shoe can be measured. Accordingly, the correlation with the upper structure or the correlation between the upper structure and the bridge Can be accurately interpreted.

The first height adjusting device 110 and the second height adjusting device 120 may be coated with an anti-corrosive coating layer to prevent corrosion of the metal surface. The anti-corrosive coating layer may be formed of a guanadinobenzo 20 weight% of imidazole, 15 weight% of oxycarboxylic acid leaves, 10 weight% of imidazoline thion, 15 weight% of hafnium, 10 weight% of molybdenum molybdate (MoS2), 25 weight% of aluminum oxide and 5 weight% of diglycidyl aniline And a coating thickness of 7 mu m.

Guanadinobenzimidazole, oxycarboxylic acid lobe, imidazoline thione, and diglycidyl aniline serve to prevent corrosion and prevent discoloration.

Hafnium acts as a corrosion-resistant transition metal element with excellent waterproofness and corrosion resistance.

Emulsified molybdenum acts to impart wettability and lubricity to the surface of the coating film.

Aluminum oxide is added for the purpose of refractoriness and chemical stability.

The reason why the ratio of the constituent components and the thickness of the coating are limited as described above is that the present inventor has analyzed through several test results, and as a result, showed the optimum corrosion inhibiting effect at the above ratios.

In addition, the anti-fouling coating layer coated with the anti-fouling coating composition may be formed on the angle indicator plate 100 and the shoe installation angle indicator needle 130 to effectively prevent and remove the adhesion of contaminants.

The antifouling coating composition comprises amphodiglycinate and sorbitol ester in a molar ratio of 1: 0.01 to 1: 2, and the total content of amphodiglycinate and sorbitol ester is 1 to 10 wt% to be.

The amphodiglycinate and sorbitol ester are preferably used in a molar ratio of 1: 0.01 to 1: 2, and when the molar ratio is out of the above range, the coating property of the base material is lowered or the surface moisture adsorption is increased after coating, .

The amphodiglycinate and sorbitol ester are preferably used in an amount of 1 to 10% by weight based on the total composition aqueous solution. When the amount of the amphodiglycinate and sorbitol ester is less than 1% by weight, the applicability of the angle indicating plate 100 and the shoe- And when it exceeds 10% by weight, crystal precipitation tends to occur due to an increase in the coating film thickness.

On the other hand, it is preferable to apply the present anti-contamination coating composition to the angle indicating plate 100 and the shoe installation angle indicating needles 130 by a spray method.

The thickness of the final coated film on the angle indicating plate 100 and the shoe installed angle indicating needles 130 is preferably 500 to 2000 Å, more preferably 1000 to 2000 Å. When the thickness of the coating film is less than 500 ANGSTROM, there is a problem that it deteriorates in the case of a high-temperature heat treatment. When the thickness is more than 2000 ANGSTROM, crystallization of a coated surface tends to occur.

The anti-contamination coating composition may also be prepared by adding 0.1 mol of amphodiglycinate and 0.05 mol of sorbitol ester to 1000 mL of distilled water, followed by stirring.

10: Shift 20: Pier
30: superstructure 40: shoe
41: lower shoe 42: upper shoe
43: groove 44: convex portion
100: Angle indicating plate 102: Angle scale
104: laser pointer 106: half ring
110: first height adjuster 111: fixed pipe
112: first laminated pipe 113: second laminated pipe
114: first nut 115: second nut
116: Ball bearing 117: Upper bolt
118: lower bolt 118-1:
120: second height adjuster
121: first conveying pipe 121-1: slide groove
122: second conveying pipe 123: third conveying pipe
124: first nut 125: second nut
126: lower bolt 126-1:
127: upper bolt 127-1:
130: Shoe installation angle indication needle 132: Hinge fastening end
134: shoe contact stage 136: angle indicator stage

Claims (6)

An angle indicating plate 100 provided on an upper surface of a plate structure of a rectangular cross section imprinted with an angular scale 102 and seated over the upper surface and the side surface of the alternation 10 or the pierced angle 20;
A first height adjusting device 110 mounted at the center of the inner end of the angle indicating plate 100 to adjust a height of the shoe installing angle indicating needle 130;
A hinge fastening end 132 hinged to an upper end of the first height adjusting device 110, a shoe contact end 134 extending rearward from the hinge fastening end 132, A shoe installation angle indicating needle 130 extending from the shank 120 to an angle indicating stage 136 indicating an angle scale 102 of the angle indicating plate 100;
And,
The shoe contact end 134 of the shoe installation angle indicating needle 130 is placed on the upper surface of the alternating 10 or the upper surface of the upper structure 30 The angle of the shoe installation angle indicator 130 is set to a predetermined angle with respect to the installation angle of the shoe 40 with respect to the hinge fastening end 132 when the shoe 40 is brought into close contact with the shoe 40 installed between the pier 20 and the upper structure 30. [ And the angle indication stage (136) indicates the angle scale (102) on the angle indicating plate (100) corresponding to the installation angle of the shoe (40) Measuring instrument.
The method according to claim 1,
The first height adjustment device 110 includes:
A fixing pipe 111 fixedly mounted at a center position of an inner end of the angle indicating plate 100;
A first lamination pipe 112 and a second lamination pipe 113 which are sequentially stacked on the fixed pipe 111;
A first nut (114) disposed between the fixed pipe (111) and the first lamination pipe (112);
A second nut 115 disposed between the first stacking pipe 112 and the second stacking pipe 113;
The upper end portion is hinged to the hinge fastening end 132 of the shoe installation angle indicating needle 130 via a ball bearing 116 and the lower end is screwed to the second nut 115, An upper bolt 117 disposed in the first lamination pipe 112;
A lower bolt 118 screwed into the first nut 114 and disposed in the first stacked pipe 112 and the fixed pipe 111;
And a plurality of shafts for mounting the shoe.
The method according to claim 1,
Wherein a laser pointer (104) for irradiating an angle scale (102) on an angle indicating plate (100) is mounted at an end of an angle indicating end (136) of the shoe installing angle indicating needle (130) Measuring instrument.
An angle indicating plate 100 provided in a plate-like structure of a rectangular cross section formed with a half ring 106 having an angle scale 102 on an upper surface thereof and seated over the upper surface and the side surface of the alternation 10 or the pierced angle 20;
A first height adjusting device 110 mounted at the center of the inner end of the angle indicating plate 100 to adjust a height of the shoe installing angle indicating needle 130;
A hinge fastening end 132 hinged to an upper end of the first height adjusting device 110, a shoe contact end 134 extending rearward from the hinge fastening end 132, A shoe installation angle indicating needle 130 extending from the shank 120 to an angle indicating stage 136 indicating an angle scale 102 of the angle indicating plate 100;
And is connected between the half ring 106 of the angle indicating plate 100 and the angle indicating end 136 of the shoe installing angle indicating needle 130 so that the shoe installing angle indicating A second height adjusting device 120 for adjusting the height of the needles 130 and for mounting and supporting the angle indicating end 136;
And,
The shoe contact end 134 of the shoe installation angle indicating needle 130 is placed on the upper surface of the alternating 10 or the upper surface of the upper structure 30 The angle of the shoe installation angle indicator 130 is set to a predetermined angle with respect to the installation angle of the shoe 40 with respect to the hinge fastening end 132 when the shoe 40 is brought into close contact with the shoe 40 installed between the pier 20 and the upper structure 30. [ The angle indicating stage 136 and the second height adjusting device 120 are rotated at the same angle along the half ring 106 to rotate the angle dial 102 formed on the half ring 106 Wherein the guide shoe is provided with a torsion spring.
The method of claim 4,
The first height adjustment device 110 includes:
A fixing pipe 111 fixedly mounted at a center position of an inner end of the angle indicating plate 100;
A first lamination pipe 112 and a second lamination pipe 113 which are sequentially stacked on the fixed pipe 111;
A first nut (114) disposed between the fixed pipe (111) and the first lamination pipe (112);
A second nut 115 disposed between the first stacking pipe 112 and the second stacking pipe 113;
The upper end portion is hinged to the hinge fastening end 132 of the shoe installation angle indicating needle 130 via a ball bearing 116 and the lower end is screwed to the second nut 115, An upper bolt 117 disposed in the first lamination pipe 112;
A lower bolt 118 screwed into the first nut 114 and disposed in the first stacked pipe 112 and the fixed pipe 111;
And a plurality of shafts for mounting the shoe.
The method of claim 4,
The second height adjustment device 120 includes:
A first conveying pipe 121 having a slide groove 121-1 formed at a lower portion thereof so that the half ring 106 of the angle indicating plate 100 is inserted;
A second conveying pipe (122) stacked on the first conveying pipe (121) with a first nut (124) interposed therebetween;
A third conveying pipe 123 which is fastened to the angle indicating end 136 of the shoe installation angle indicating needle 130 and an upper end of which is stacked on the second conveying pipe 122 with a second nut 125 therebetween, ;
A lower bolt 126 screwed into the first nut 124 and disposed in the first transfer pipe 121 and the second transfer pipe 122;
An upper bolt 127 screwed into the second nut 125 and disposed in the second transfer pipe 122 and the third transfer pipe 123;
And a plurality of shafts for mounting the shoe.

Images