KR101268359B1 - Inclinometer for safe diagnoses of bridge or tunnel - Google Patents

Abstract

An inclination measurement system for bridge and tunnel safety diagnosis according to the present invention includes an inclination instrument panel including a first instrument substrate indicating a gravity direction at a position at which the inclination is measured, and a second instrument substrate provided perpendicular to the first instrument substrate; A housing including a wall surface on which the inclination instrument panel is mounted and a space part surrounded by the wall surface; An indication needle fixed to the space part of the housing so as to simultaneously indicate the first and second substrates, the needle being further provided at an end portion of the gravity direction and having a tip at the end portion opposite the gravity; And a needle fixture for fixing the indicator needle to the housing such that the indicator needle rotates about an origin position of the first instrument substrate and an origin position of the second instrument substrate, according to the present invention. Simple to provide low failure rate, easy to carry, and can provide slope measuring system for bridge and tunnel safety diagnosis applicable anywhere.

Description

Inclinometer for bridge and tunnel safety diagnostics {INCLINOMETER FOR SAFE DIAGNOSES OF BRIDGE OR TUNNEL}

The present invention relates to an inclination measuring system for bridge and tunnel safety diagnostics, and more particularly, to a bridge and tunnel safety diagnostic inclination measuring system capable of simultaneously carrying, and simultaneously measuring inclinations in multiple axes. .

Inclinometer is a device for measuring the degree of inclination with respect to the reference plane. In general, the inclination measuring system used to measure the inclination was a droplet level that checks the level of the horizontal movement by the movement of bubbles located inside. This droplet level reads the inclination value according to the position of the bubble, which is a size in which the bubble is formed over several values. Therefore, an error occurs in measuring the inclination, there is a problem that the reliability is poor. In addition, when using a digital level or a laser level, such as the reliability of the measured value is high, but the device is expensive and the mechanical device is sensitive, there is a problem that it is not easy to use because the structure is complicated and complicated. In addition, since there is a need for a separate electric device to operate this, there was a problem that the position to measure the slope using such a device is limited.

Conventionally, in order to solve such a problem, as disclosed in the Republic of Korea Utility Model No. 367953, the filling of the liquid in the inner receiving space and the immersion in the filling liquid is rotated in the receiving space while the corresponding scale of the front plate through the leader line An inclinometer including a flow plate indicating a was provided. However, in the case of such a tilt measuring device, there is a problem that only the tilt of the direction parallel to the front plate can be measured.

Accordingly, the problem to be solved by the present invention is a bridge, which is simple in structure, easy to operate, easy to carry, high in reliability of measured inclination, and can measure inclination of multiple axes at the same time. To provide a slope measuring system for tunnel safety diagnosis.

In order to solve the above problems, the present invention provides an inclination instrument panel including a first instrument substrate indicating a gravitational direction at a position at which the inclination is measured and a second instrument substrate provided perpendicular to the first instrument substrate;

A housing including a wall surface on which the inclination instrument panel is mounted and a space part surrounded by the wall surface;

An indication needle fixed to the space part of the housing so as to simultaneously indicate the first and second substrates, the needle being further provided at an end portion of the gravity direction and having a tip at the end portion opposite the gravity; And

It provides an inclination measurement system for bridge and tunnel safety diagnostics comprising a needle fixture for fixing the indicator needle to the housing so that the indicator needle is rotated around the origin position of the first instrument substrate and the origin position of the second instrument substrate.

According to one embodiment of the invention, between the tip and the weight of the indicating needle, a fastening hole through which the needle fixture may be further provided.

At this time, the needle fixture is formed with a flow groove having a smaller thickness value than the adjacent position,

Preferably, the flow groove is equipped with the indicator needle.

In addition, the needle fixture,

Vertically coupled between the first substrate and the wall surface of the housing located opposite the first substrate, the first fixture and the second fixture may be coupled to each other.

At this time, the flow groove of the needle fixture is preferably formed by the combination of the taper provided in the first fixture and the second fixture.

Further, the needle holder is formed with a rotating ball formed in a sphere between the tip of the indicating needle and the weight,

The needle fixture may be rotatably coupled to the housing.

In addition, the bridge and tunnel safety diagnostic inclination measuring system is mounted to the position to measure the inclination, fastening device, and

It is preferable to further include a coupler coupled to the housing and detachably coupled to the fastening device such that the inclination measuring system is installed at an inclination measurement position.

According to the present invention, the measured inclination value is highly reliable, durable, easy to carry, and there is no need to install a separate electric facility to measure the inclination, and to measure the inclination in the multi-axis direction at once. In addition, the measurement time can be shortened, and the inclination can be repeatedly measured at the same position.

1 is a perspective view of an inclination measuring system for bridge and tunnel safety diagnosis according to various embodiments of the present invention.
Figure 2a is a front view of the indicating needle of the inclination measuring system for bridge and tunnel safety diagnostics according to an embodiment of the present invention.
Figure 2b is a side view of the needle fixture of the inclination measuring system for bridge and tunnel safety diagnostics according to an embodiment of the present invention.
Figure 2c is a side view combined with the needle and the needle fixture of the inclination measuring system for bridge and tunnel safety diagnostics according to an embodiment of the present invention.
Figure 3a is a front view of the indicating needle of the inclination measuring system for bridge and tunnel safety diagnostics in accordance with another embodiment of the present invention.
Figure 3b is a side view of the needle fixture of the inclination measuring system for bridge and tunnel safety diagnostics in accordance with another embodiment of the present invention.
Figure 3c is a side view combined with the needle and the needle fixture of the inclination measuring system for bridge and tunnel safety diagnostics according to another embodiment of the present invention.
4 is a perspective view of an inclination measuring system for bridge and tunnel safety diagnosis according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail.

The inclination measuring system for safety diagnosis of bridges and tunnels according to the present invention includes a first instrument 112 indicating a direction of gravity at a position at which the inclination is measured and a second instrument 114 provided perpendicular to the first instrument 112. Gradient instrument panel 110, including;

A housing (120) including a wall surface (122) on which the gradient instrument panel (110) is mounted and a space portion (124) formed surrounded by the wall surface (122);

It is rotatably fixed in the space portion 124 of the housing 120 so as to indicate the first and second substrates 112 and 114 at the same time, the gravity side side end is provided with weights (134, 234) At the opposite ends of gravity, the indicating needles 130 and 230 are provided with tips 132 and 232; And

The pointer needles 130 and 230 are rotated about the home position of the first instrument substrate 112 and the home position of the second instrument substrate 114 so as to rotate the instruction needles 130 and 230 to the housing 120. And needle fasteners 140 and 240 for fixing.

Gradient measuring system can be used to check the status of structures through safety diagnosis or survey of civil and construction structures constructed perpendicular to the ground, such as bridges, tunnels, and temporary facilities to prevent the outflow of soil. That is, by measuring the inclination of the structure, it is possible to predict the load on the structure.

The inclination measuring system for bridge and tunnel safety diagnosis according to the present invention, which is used for the above-mentioned purposes, has sharp ends (132, 232) and weights (134, 234) formed at both ends of the indicating needles (130, 230). ) Are formed respectively. Accordingly, when the weights 134 and 234 are positioned under the gravity, the tips 132 and 232 formed on the opposite side of the weights 134 and 234 indicate the inclination measurement value of the inclination instrument panel 110. In the slope measuring system for bridge and tunnel safety diagnosis according to the present invention, the edges of the tips 132 and 232 are formed close to the point shape, unlike the conventional water droplet level system in which bubbles are positioned over various numerical values. Thus, the tips 132 and 232 of the indicator needle 130 point to a point on the instrument panel. Therefore, the inclination measured by the inclination measuring system for the bridge and tunnel safety diagnosis according to the present invention is more reliable than the inclination measured by the conventional water level gauge.

Since the inclination measuring system for bridge and tunnel safety diagnosis according to the present invention has a simple structure for measuring the inclination through the indicating needle 130 whose position is changed by gravity as described above, it is more durable than digital and laser level gauges. Since it is high and there is no need to provide a separate electric facility for driving the inclination measuring system for bridge and tunnel safety diagnosis, the inclination can be measured at any desired position.

Hereinafter, the present invention will be described in more detail with reference to preferred embodiments. It will be apparent to those skilled in the art, however, that these examples are provided to further illustrate the present invention, and the scope of the present invention is not limited thereto.

Figure 1a is a perspective view of a bridge and tunnel safety diagnostic inclination measuring system according to an embodiment of the present invention, Figure 1b is a perspective view of a bridge and tunnel safety diagnostic inclination measuring system according to another embodiment of the present invention.

The indicator needle 130 mounted on the inclination measuring system for bridge and tunnel safety diagnosis according to an embodiment of the present invention, as shown in Figure 1a, between the tip 132 and the weight 134 of the indicator needle 130 The fastening hole 136 is formed. Here, the needle fixture 140 penetrates through the fastening hole 136. In particular, the fastening hole 136 is preferably formed to be located in the flow groove 146 of the needle fixture (140). As shown in FIG. 1A, the inclination measuring system for bridge and tunnel safety diagnosis according to an embodiment of the present invention has a thickness smaller than that of the needle fixture 146 in an adjacent position, such that the fastening hole 136 has the needle. It does not move in the longitudinal direction of the fixture 140, and rotates around the point where the flow groove 146 is formed.

In addition, the indicator needle 230 mounted to the inclination measuring system for bridge and tunnel safety diagnosis according to another embodiment of the present invention, as shown in Figure 1b, between the tip 232 and the weight 234 A rotating ball 236 formed in a ball shape is formed, and the indicating needle 230 is connected to the second rotating hole 236 by the rotating hole coupling ring 246 formed in the needle holder 240. Rotate around the origin of the instrument panel 114. In this case, the needle fixture 240 is rotatably coupled to the housing 120, so that the indicator needle 230 may rotate around the origin of the first instrument substrate 112.

As described above, the needles mounted on the inclination measuring system for the bridge and tunnel safety diagnosis according to the present invention are commonly coupled in a rotatable structure around the origin of the first and second instrument substrates 112 and 114. . Therefore, the inclination in the biaxial direction can be measured by one measurement, and therefore, it is not necessary to measure the inclination in the respective axial directions separately. Therefore, the time for measuring the inclination can be reduced.

Figure 2a is a front view of the indicating needle of the bridge and tunnel safety diagnostic gradient measuring system according to an embodiment of the present invention, Figure 2b is a needle fixture of the bridge and tunnel safety diagnostic gradient measuring system according to an embodiment of the present invention Figure 2c is a side view, Figure 2c is a side view showing the combined needle and the needle fixture of the inclination measuring system for the bridge and tunnel safety diagnosis according to an embodiment of the present invention.

In accordance with an embodiment of the present invention, the indicating needle 130 is fastened through which the needle fixture 140 passes between the tip 132 and the weight 134 of the indicating needle 130, as shown in FIG. 2A. A ball 136 is formed. The needle fixture 140 is inserted into the fastening hole 136. In this case, the indicator needle 130 is prevented from moving in the longitudinal direction of the needle fixture 140, and the indicator needle 130 to rotate about the origin of the gradient instrument panel 110 of the present invention Needle fixture 140 according to an embodiment is provided with the flow groove 146. The needle 130 is formed with a diameter value of the fastening hole 136 is greater than the thickness value of the flow groove 146, but smaller than the thickness of the needle fixture 146 provided at a position adjacent to the flow groove 146. do. Here, the needle fixture 140 may be provided with the flow groove 146 by forming a step in various ways. In particular, as illustrated in FIG. 2B, the first substrate 112 and the first substrate 112 are vertically coupled between the wall surfaces of the housing 120 opposite to the first substrate 112, and the first and second substrates are unevenly coupled to each other. It is preferable to form the needle fixture 140 including the first fixture 142 and the second fixture 144. That is, the taper is formed in the first fixture 142 and the second fixture 144, respectively, when the first fixture 142 and the second fixture 144 is coupled, the flow groove 146 is formed By doing so, the indicating needle 130 can be prevented from reciprocating in the longitudinal direction of the needle fixture 140. Accordingly, the indicator needle 130 seated in the flow groove 146 is provided at a position where the flow groove 146 coincides with the origin (Ox, Oy) of the first and second instrument substrates 114. As shown in FIG. 2C, the indicator needle 130 may rotate based on the flow groove 146.

Figure 3a is a front view of the indicating needle of the bridge and tunnel safety diagnostic gradient measuring system according to another embodiment of the present invention, Figure 3b is a needle fixture of the bridge and tunnel safety diagnostic gradient measuring system according to another embodiment of the present invention A side view is shown, and FIG. 3C shows a side view in which the indicating needle and the needle fixture of the inclination measuring system for the bridge and tunnel safety diagnosis according to another embodiment of the present invention are combined.

Pointing needle 230 according to another embodiment of the present invention, as shown in Figure 3a, forms a rotating sphere 236 formed in a spherical shape between the tip 232 and the weight 234 and In addition, as shown in FIG. 3B, the needle fixture 240 has a rotation hole coupling ring 246 to which the rotation hole 236 is coupled. Here, the spherical rotating ball 236 is rotated while maintaining the state coupled to the rotating ball coupling ring 246. To this end, the inner peripheral surface of the rotating ball coupling ring 246 is preferably formed in the same curvature shape as the rotating ball 236. Here, in order to easily explain the shape of the rotating ball coupling ring 246, the rotating ball coupling ring 246 is shown by omitting the opening and closing device.

As shown in FIG. 3C, since the indicator needle 230 is fastened to the pivot hole coupling ring 246 of the needle fixture 240, the indicator needle 230 is the origin of the second substrate 114. Can rotate around (Oy). In addition, the inclination measuring system for bridge and tunnel safety diagnosis according to another embodiment of the present invention, since the needle holder 240 is rotatably coupled to the housing 120, the indicating needle 230 is the first instrument substrate It rotates about the origin (Ox) of (112).

Figure 4 is a perspective view of the inclination measuring system for bridge and tunnel safety diagnostics according to another embodiment of the present invention.

The inclination measuring system 100 for safety diagnosis of the bridge and tunnel according to the present invention may further include a coupling hole 310 in the housing 120 in order to fix the inclination in a position to be measured. As the coupler 310, an adhesive such as a double-sided tape may be used, and after installing the fastening device 320 formed in a structure that is fastened to the coupler 310 in a position to measure the inclination, the fastening device The coupler 310 may be formed in a shape coupled to the 320. As the coupler 310 and the fastening device 320, a bulk tape or a concave-convex coupling structure may be used, as shown in FIG. 4. By fastening the coupler 310 to the fastening device 320 installed at a position to measure the inclination, the bridge and tunnel safety diagnostic inclination measuring system 100 can always measure the inclination at the same position. When the inclination is always measured at the same position as described above, it is possible to easily determine the state of the structure 1 such as a building, a bridge, etc., in which the inclination measurement is required. That is, by using the inclination measuring system 100 for the bridge and tunnel safety diagnostics, how much deformation has occurred in the structure 1 from the initial construction state, or when the structure 1 is initially constructed, You can see how much error occurred in the slope and the actual slope.

The gradient instrument panel 110 according to the present invention includes the first instrument substrate 112 and the second instrument substrate 114, but when it is necessary to add a value to be measured, it may further include a separate instrument panel. In addition, the scale of the gradient instrument panel 110 is not limited to the shape of the first instrument substrate 112 and the second instrument substrate 114 according to an embodiment of the present invention.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

110: gradient instrument panel 112: the first instrument panel
114: second instrument substrate 120: housing
122: wall surface 124: space part
130, 230: indicating needle 132, 232: peak
134 and 234 weight 136 fasteners
140, 240: needle fixture 142, 242: first fixture
144, 244: Secondary Fixture 146: Floating Groove
236: Hoedong-gu 246: Hoedong-gu coupling ring
Ox: Origin of First Substrate Oy: Origin of Second Substrate

Claims (7)

An inclination instrument panel including a first instrument substrate indicating a gravitational direction at a position at which the inclination is measured and a second instrument substrate provided perpendicular to the first instrument substrate;
A housing including a wall surface on which the inclination instrument panel is mounted and a space part surrounded by the wall surface;
It is rotatably fixed in the space portion of the housing so as to indicate the first and second substrate at the same time, an additional end is provided on the side of the gravity direction, the tip is provided on the opposite side of the gravity, An indication needle having a fastening hole through which a needle fixture is penetrated between the weight and the weight; And
A flow groove having a thickness smaller than an adjacent position is formed, and the flow needle is equipped with the command needle, and the command needle rotates about an origin position of the first instrument substrate and an origin position of the second instrument substrate. Gradient measurement system for bridge and tunnel safety diagnosis comprising a; needle fixture for fixing the needle to the housing. delete delete The method of claim 1,
The needle fixture,
Vertically coupled between the first substrate and the wall surface of the housing located opposite the first substrate, the slope for the bridge and tunnel safety diagnostics, characterized in that it comprises a first fixing sphere and a second fixing sphere to be unevenly coupled to each other Measuring system. 5. The method of claim 4,
The flow groove of the needle fixture, bridge and tunnel safety diagnostic gradient measuring system, characterized in that formed by the coupling of the taper provided in each of the first fixture and the second fixture. An inclination instrument panel including a first instrument substrate indicating a gravitational direction at a position at which the inclination is measured and a second instrument substrate provided perpendicular to the first instrument substrate;
A housing including a wall surface on which the inclination instrument panel is mounted and a space part surrounded by the wall surface;
An indication needle fixed to the space part of the housing so as to simultaneously indicate the first and second substrates, the needle being further provided at an end portion of the gravity direction, and having a tip at the end portion opposite to the gravity; And
And a needle fixture configured to fix the indicator needle to the housing such that the indicator needle rotates about an origin position of the first instrument substrate and an origin position of the second instrument substrate.
The needle holder is formed with a rotating sphere formed in a sphere between the tip of the indicating needle and the weight,
The housing, the inclination measuring system for safety diagnosis of bridges and tunnels, characterized in that the needle fixture is rotatably coupled. The method of claim 1,
A fastening device mounted at a position to measure the inclination, and
It is coupled to the housing, the bridge and tunnel safety diagnostic inclination measuring system further comprises a coupler which is detachably fastened to the fastening device so that the inclination measuring system for the bridge and tunnel safety diagnostics are installed at the inclination measurement position.

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