KR101805884B1 - Remote control device for a clinometer - Google Patents

Abstract

The present invention relates to a remote control device for a clinometer, which can remotely controlling horizontality or the direction of the clinometer by being connected to the clinometer measuring a gradient and strike of a bedding plane. The remote control device for a clinometer includes: a plate coupled to be separated to the clinometer to be rotated and tilted with the clinometer by being pressed; a fixing member fixing the clinometer to the plate to be separated; and a stick of which one end part is coupled to be rotated and tilted to the plate to allow the rotating and tilting of the plate through pressurization, and the other end part has a handle and controls horizontality or the direction of the plate. The stick includes: a telescopic pipe comprising a plurality of pipes formed in multiple layers to be extended in a telescopic method; and a joint unit connected to the plate in order for an angle to be controlled while being connected to be rotated to one end of the telescopic pipe, thereby allowing the rotating and tilting of the plate.

Description

[0001] REMOTE CONTROL DEVICE FOR A CLINOMETER [0002]

The present invention relates to a control device capable of controlling a clinometer. More particularly, the present invention relates to a control device capable of controlling a clinometer, and more particularly, to a control device capable of controlling a clinometer, And more particularly to a remote control device for a clinometer capable of measurement.

Generally, the direction of the line of intersection between the ground plane and the horizontal plane is referred to as a diagonal direction, and an angle between the ground plane and the horizontal plane is referred to as an inclination. In the actual field survey, in the past, the incline was measured by supporting the side surface of the compass on the above-mentioned ground surface, aligning the level, reading the direction of the incision, and measuring the inclination angle by reading the angle.

The strike of the stratum surface is measured by supporting the side of the compass on the stratum surface and leveling, and then reading the direction of the staple. The tilt of the ground surface is measured by placing an inclinometer perpendicular to the horizontal plane and reading the angle.

The inclination (hereinafter referred to as a line orientation) and the inclination (hereinafter referred to as a line inclination) of a line structure observed in a line form on the surface of the ground layer can be measured by the same method as that of the measurement of inclination and inclination of the surface layer, . Especially, when the size of the line structure is small, it is difficult to measure the orientation of the ship and the pre-warp yarn.

An example to solve such a problem is disclosed in Korean Patent Application No. 10-2012-0026506, " Ship propulsion and ship inclination clinometer, ship propulsion and line inclination measurement assisting device ".

In the prior art, the ship propulsion and ship inclination clinometer have a rod arranged parallel to the line structure, a hinge shaft connected to one end of the rod, rotatable about the center axis of the rod, and extending in a direction perpendicular to the center axis A plate provided on the hinge shaft for measuring a line inclination, and a compass provided on the plate for measuring an incline, the plate being provided on the hinge axis, And measuring means including the measuring means.

Shipboard inclinations and line inclination clinometers can measure ship propensity and line inclination at the same time.

The prior art arranges the rod parallel to the line structure and simultaneously measures the orientation and the line inclination using the angle of the compass and the angle between the rotating block and the plate when the plate is horizontal, Even if the size is small, you can measure the ship's incense and line inclination reproducibly and conveniently.

While the prior art has the advantages described above, it is almost impossible to measure the inclination and the inclination of the surface of the stratum in the blind spot or the blind spot where the observer can not see the sight, and because of the absence of the compass fixing function of the clinometer, Measurement is difficult.

In addition, since the observer does not have the function of photographing or storing the measured information, there is a problem in that it is inconvenient to use as well as time constraints since it is necessary to promptly confirm the above information at the work site.

Korean Registered Patent No. 10-1147686 (title of invention: ship propulsion and ship inclination clinometer and ship propulsion and line inclination measurement assisting device)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a remote control device for a clinometer capable of measuring a shave of a ground where an observer's gaze does not touch a clinometer while measuring a bow and a slope using a clinometer .

Specifically, it is possible to measure the inclination and the inclination of a clinometer by placing the clinometer on a desired surface of the ground using a member having a length extending and a member capable of rotating and adjusting the angle.

Another object of the present invention is to provide a remote control device for a clinometer provided with a photographing device for photographing or storing information measured by a clinometer.

It is still another object of the present invention to provide a remote control device for a clinometer having a display device for displaying a clinometer for measuring and photographing a stratum surface where an observer's line of sight does not reach the clinometer.

Another object of the present invention is to provide a remote control device for a clinometer in which a clinometer and a photographing device operation can be controlled by wire or wireless.

In order to achieve the above object, a remote control device for a clinometer according to the present invention is a remote control device for a clinometer connected to a clinometer for measuring the orientation and inclination of a bed surface to remotely control the direction and the horizontal direction of the clinometer, A plate detachably coupled to the clinometer and rotated and tilted together with the clinometer; A fixing member detachably fixing the clinometer to the plate; And a bar-shaped stick coupled to the plate such that one end thereof is rotatable and tiltable to allow rotation and tilting of the plate by pressurization and the other end provides a handle,

The stick may be a telescopic pipe made of a plurality of pipes forming a multi-tier and extending and contracting in a telescopic manner; And a joint part that is rotatably coupled to one end of the telescopic pipe to be angularly adjustable with respect to the plate to allow rotation and tilting of the plate.

The joint part may include a circular rod rotatably coupled to one end of the telescopic pipe coaxially with the telescopic pipe and rotating about the telescopic pipe by pressing; A plate connecting rod connected to the other side of the circular rod so as to be adjustable in angle while being fixed to the plate by the same body; And a hinge pin for connecting the circular rod and the plate connecting rod to form a rotating shaft for adjusting the angle of the plate connecting rod and fixing the connecting portion between the plate connecting rod and the circular rod by pressing to fix the plate in an angle- As shown in FIG.

The stick may further include a rotation control member installed at a predetermined portion of the circular rod and allowing a portion of the circular rod to move laterally in a predetermined range of angles by pressing with an external force.

The rotation control member may include: a rotation adjusting hinge installed at a predetermined portion of the circular rod to allow the circular rod to move left and right; And a rotation adjusting pin coupled to the rotation adjusting hinge and pressing the rotation adjusting hinge with an external force to adjust a rotation angle of the rotation adjusting hinge.

The fixing member may include at least one tongue provided on the plate and gripping and fixing the clinometer through an elastic force.

The remote control device may further include: a camera detachably installed on the plate, for photographing the clinometer and providing an image of the clinometer; And a bracket installed on the plate and fixing the position and angle of the camera while fixing the camera to the upper portion of the clinometer.

The remote control device may further include a monitor installed at a lower end of the telescopic pipe so as to be able to separate and adjust the position thereof and to display an image of the clinometer captured by the camera, have.

The remote control device may further include a remote controller for controlling the operation of the clinometer and the camera by wire or wireless.

The remote control device may further include an LED lamp detachably installed on the bracket together with the camera to provide light to the clinometer.

The remote control device for a clinometer according to the present invention is capable of adjusting the length of a remote control device through a telescopic stick in addition to the basic functions for measuring the inclination and the inclination of the clinometer, thereby measuring the inclination and inclination of the ground surface And the like.

Specifically, it is possible to measure the inclination and the inclination of the clinometer on the desired surface by using a member having a length and a length and members capable of rotating and adjusting the angle.

Further, it is possible to photograph or store information measured by a clinometer using a camera.

In addition, a monitor can be used to measure the surface of a stratum where the observer does not reach his / her eyes, and to provide an effect of shooting.

In addition, the remote controller can be used to control the operation of the clinometer and the camera in a wired or wireless manner.

1 is a perspective view of a remote control device for a clinometer according to an embodiment of the present invention;
2 is a plan view of the control device.
3 is a side view of the control device.
4 shows an embodiment of a hinge pin of the control device.
5 is a view showing an embodiment of the screw fixing method of the control device fixing member.
6 is a view showing an embodiment of the rotation control member.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It should also be understood that the position or arrangement of individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 is a perspective view of a remote control device for a clinometer according to an embodiment of the present invention, Fig. 2 is a plan view of the control device, Fig. 3 is a side view of the control device, and 4 is an embodiment of a hinge pin Fig. 5 is a view showing an embodiment of the screw fixing method of the control device fixing member, and Fig. 6 is a view showing an embodiment of the rotation control member.

1 to 6, the present invention can be a constitution including the plate 200, the fixing member 240, and the stick 100.

The plate 200 is a component that provides space in which the clinometer 210 is placed.

The plate 200 is detachably coupled to the clinometer 210 by a fixing member 240, which will be described later. The plate 200 may be rotated or inclined with the clinometer 210 on the ground layer surface which is twisted by the user's pressing in accordance with the shape of the ground layer to be observed and measures the inclination while aligning the level with the leveler 230 can do.

The fixing member 240 is a component for detachably fixing the clinometer 210 to the plate 200.

The fixing member 240 may be a method using the clamp 250 in such a manner as to fix the clinometer 210 to the plate 200.

The method using the forceps 250 may be installed on the upper portion of the plate 200 to grip and fix the clinometer 210 through the elastic force.

Two clamps 250 may be provided at both ends of the plate 200 in the longitudinal direction of the plate 200. Alternatively, two clamps 250 may be provided on the left and right sides of the plate 200 to fix the clinometer 210 to the plate 200 .

In addition, the fixing member 240 may be a method of using the plate screw 270 in such a manner as to fix the clinometer 210 to the plate 200.

A method using the plate screw 270 is to use a plurality of plate screws 270 to be coupled with the plate 200 in a threaded manner through a through hole and a through hole provided in the clinometer 210.

The method of holding and fixing the clinometer 210 to the plate 200 using the fixing member 240 is not limited to the above-described method, and the best method can be selected and used.

The stick 100 is a component that is held by the user while being connected to the plate 200 to fix the plate 200 while controlling the direction of movement of the plate 200.

The stick 100 may be formed in a rod shape and coupled to the plate 200 so that one end thereof can be rotated and tilted.

This stick 100 allows rotation and tilting of the plate 200 by pressing the user so that the direction or angle of the clinometer 210 is adjusted to fit the surface of the ground surface and the other end of the plate 200, The direction and the horizontal direction can be adjusted.

Specifically, the stick 100 may be a telescopic pipe 140 and a joint 110 configuration.

The telescopic pipe 140 is composed of a plurality of tubes constituting multiple stages and is connected to the plate 200 through a joint part 110 which will be described later and is telescopically stretched to remotely control movement and position change of the plate 200 do.

The joint part 110 is a component that connects the telescopic pipe 140 and the plate 200 and adjusts the orientation or angle of the clinometer 210 to match the surface of the ground by adjusting the rotation or angle of the plate 200 .

The joint 110 is angularly coupled with the plate 200 in a rotatable manner at one end of the telescopic pipe 140 to permit rotation and tilting of the plate 200, The clinometer 210 can be used to measure the incidence and inclination of the viewer's eyes.

The joint portion 110 may be configured to include a circular rod 112, a plate connecting rod 114, and a hinge pin 116.

1 to 6, the circular rod 112 is rotatably hinged to one end of the telescopic pipe 140 coaxially with the telescopic pipe 140 and is connected to the telescopic pipe 140 by pressure, (I.e., in the lateral direction with respect to the user in the embodiment of the present invention shown in Figs. 1 to 6).

That is, the user can rotate the circular plate 112 by using the circular rod 112 because the circular rod 112 is rotatably manufactured and connected to the telescopic pipe 140. Therefore, the user can rotate the clinometer 210 installed on the plate 200 and measure the inclination and the inclination according to the shape of the ground surface.

The plate connecting rod 114 may be connected to the plate 200 so as to be adjustable in angle with the other side of the circular rod 112 while being fixed in the same body.

The plate connecting rod 114 is connected to the circular rod 112 by a hinge pin 116 to be described later so that it is possible to measure the inclination and the inclination of the stratum surface that is not exposed to the user's eyes through the extension of the length by the telescopic pipe 140 But also the rotational force by the circular rod 112 can be transmitted to the plate 200.

The hinge pin 116 may form a rotation axis for adjusting the angle of the plate 200 while connecting the circular rod 112 and the plate connecting rod 114.

The hinge pin 116 can fix the connection portion between the plate connecting rod 114 and the circular rod 112 by the user's pressing so as to tighten the plate 200 in an angularly adjusted state.

Specifically, the hinge pin 116 may be formed as a butterfly-shaped butterfly bolt type, and the butterfly bolt may be fixed by fixing the angle while adjusting the angle.

The user can adjust the angle of the plate 200 by using a nut on one side of the hinge shaft of the circular rod 112 connected to the plate connecting rod 114 and using a butterfly bolt on the other side.

Alternatively, the user may make the hinge pin 116 by using a member capable of jointly bending and fixing the hinge pin 116 at the same time.

That is, it is possible to measure the inclination and the inclination of the desired surface of the ground through the rotation of the plate 200 and the angle adjustment using the joint part 110 having the above-described structure.

In addition, the stick 100 may further include a rotation control member 500.

The rotation control member 500 may be installed in a predetermined portion of the circular rod 112 to allow a part of the circular rod 112 to move leftward and rightward at an angle of a predetermined range by the external force.

The rotation control member 500 may include a rotation adjusting hinge 510 and a rotation adjusting pin 520.

The rotation-controlling hinge 510 may be installed in a predetermined portion of the circular rod 112 to allow the circular rod 112 to move left and right.

The rotation control pin 520 is coupled to the rotation control hinge 510 and can control the rotation angle of the rotation control hinge 510 by pressing the rotation control hinge 510 with an external force.

That is, the rotation control member 500 is rotatable up to 90 degrees to the left and right, so that the orientation of the clinometer 210 can be measured by rotating the clinometer 210 by 90 degrees according to the terrain.

The remote control apparatus 10 of the present invention may further include a camera 300, a bracket 330, a monitor 400, and a remote controller 320.

The camera 300 is a component for photographing and storing the inclination and the inclination of the ground surface measured by the clinometer 210.

The camera 300 is detachably installed on the plate 200 on the plate 200 on the clinometer 210 in a face-to-face relationship with the clinometer 210 to provide an image of the clinometer 210, Can be photographed and stored.

The camera 300 may include a cable port or an optical sensor so that the camera 300 can be connected to a remote controller 320, which will be described later, by wireless or wire.

The bracket 330 is mainly formed of a metal bar made of the same material and may be installed on the plate 200 to fix the camera 300 on the clinometer 210.

That is, the bracket 330 is detachably attached to both sides of the plate 200 in the longitudinal direction so that the camera 300 can photograph the clinometer 210 at a position corresponding to the clinometer 210, Is fixed to the upper portion of the clinometer 210 and the position and angle of the camera 300 can be adjusted.

The monitor 400 is detachably installed at the lower end of the telescopic pipe 140 and is adjustable in position.

Specifically, the user can remotely control the monitor 400 by providing a port to which the monitor 400 is attached at the lower end of the stick 100 and attaching the monitor 400 to the port.

The monitor 400 may be connected to the camera 300 to display an image of the clinometer 210 captured by the camera 300 and provide the image to an observer.

Accordingly, the observer can measure the inclination and the inclination of the ground surface in the clinometer, which is out of sight while adjusting the remote controller 10 through the monitor 400 connected to the camera 300.

In addition, the monitor 400 may adopt a touch screen method.

When the user uses the touch screen type monitor 400, the operation of the camera 300 can be controlled by the touch screen type monitor 400 and the orientation measurement needles 224 of the instrument panel 222 can be controlled. Therefore, The controller 320 need not be provided.

The remote controller 320 is a component for controlling the operation of the clinometer 210 and the camera 300 by wire or wireless.

That is, the wireless remote controller 320 can fix the stool measurement needle 224 of the instrument panel 222 and fix the stool measurement needle 224 after being horizontally aligned through the leveler 230 And enables precise measurement of direction.

The observer can use the remote controller 320 and the stick 100 to measure the incline and inclination of the stratum surface that is out of sight by the remote controller 320, It is possible to do.

The wired remote controller 320 may further include a cable 340 and an operation button 130.

The cable 340 is discharged through a hole formed at one end of the telescopic pipe 140 to control the operation of the camera 300 and is connected to the operation button 130 to connect the clinometer 210 (224) can be fixed.

The operation button 130 may be provided at the lower end of the telescopic pipe 140 and may be connected to the cable 340.

The operation button 130 is connected to the camera 300 and the clinometer 210 by a cable 340 to control the operation of the camera 300 and to detect the orientation of the clinometer 210, Can be fixed.

The control device 10 of the present invention may be configured to further include an LED lamp 310. [

The camera 300 is detachably attached to the clinometer 210 by a bracket 330 so as to be able to measure the inclination or the inclination of the stratum in the dark working environment at night or outdoors so as to provide light to the clinometer 210 can do.

A method of using a remote control device for a clinometer according to the present invention includes the steps of fixing a clinometer 210 to a plate 200 by using a clamp 250 or a plate screw 270 as a fixing member 240 on a plate 200 And brackets 330 are provided on both sides of the plate 200 to mount the camera 300 and the LED lamp 310 in the direction of the clinometer 210 on the bracket 330.

The user attaches the monitor 400 to the lower end of the stick 100 and stretches the telescopic pipe 140 of the stick 100 while watching the monitor 400 and rotates or tilts the plate 200 using the joint 110 And the slope of the stratum surface that does not reach the user's own gaze can be measured through the clinometer 210.

In addition, the user can control the operation of the camera 300 and fix the orientation measuring needle 224 of the instrument panel 222 using the wireless or wired remote controller 320.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And such variations and modifications are intended to fall within the scope of the appended claims.

10: remote control device 100: stick
110: joint part 112: circular rod
114: plate connecting rod 116: hinge pin
130: Operation button 140: Telescopic pipe
200: plate 210: clinometer
222: Instrument panel 224: Measuring stool
226: Slope measuring needle 230: Level
240: fixing member 250:
270: plate screw 300: camera
310: LED lamp 320: remote controller
330: Bracket 340: Cable
400: monitor 500: rotation control member
510: hinge for rotation adjustment 520: rotation adjustment pin

Claims (9)

A remote control device for a clinometer connected to a clinometer for measuring the inclination and inclination of a ground surface to remotely control a direction or a horizontal direction of the clinometer,
A plate detachably coupled to the clinometer and rotated and tilted with the clinometer by pressure;
A fixing member detachably fixing the clinometer to the plate;
The telescopic pipe is composed of a plurality of pipes forming a multi-tier and is stretched in a telescopic manner. The telescopic pipe is rotatably coupled to one end of the telescopic pipe and is angularly adjustable to allow rotation and tilting of the plate. A stick that allows the rotation and tilting of the plate by pressurization and the other end provides a handle;
A camera detachably installed on the plate for photographing the clinometer and providing an image of the clinometer;
A bracket installed on the plate for fixing the position and angle of the camera while fixing the camera to the upper portion of the clinometer;
A monitor installed at a lower end of the telescopic pipe so as to be able to separate and adjust the position and to display an image of the clinometer taken by the camera; And
And a remote controller for controlling the operation of the clinometer and the camera by wire or wireless,
The camera and the monitor can be used to measure the inclination and the inclination of the stratum surface located at a position out of sight of the observer and to photograph and store the measured information, Wherein the operation of the camera is remotely controllable, so that it is possible to more easily and accurately measure the inclination and the inclination of the stratum surface which is not exposed to the observer's line of sight.
The method according to claim 1,
The joint part
A circular rod coupled to one end of the telescopic pipe so as to be coaxial with the telescopic pipe so as to be pivotable about the center axis of the telescopic pipe by pressure;
A plate connecting rod connected to the other side of the circular rod so as to be adjustable in angle while being fixed to the plate by the same body; And
And a hinge pin for connecting the circular rod and the plate connecting rod to form a rotation axis for adjusting the angle of the plate connecting rod and fixing the connecting portion between the plate connecting rod and the circular rod by pressing to fix the plate in an angle- The remote control device for a clinometer.
The method of claim 2,
Wherein the stick comprises:
And a rotation control member installed at a predetermined portion of the circular rod and allowing a part of the circular rod to move leftward and rightward at an angle of a predetermined range by pressing by an external force.
The method of claim 3,
The rotation control member
A rotation adjusting hinge installed at a predetermined portion of the circular rod to allow the circular rod to move left and right; And
And a rotation adjusting pin coupled to the rotation adjusting hinge and pressing the rotation adjusting hinge with an external force to adjust the rotation angle of the rotation adjusting hinge.
The method according to claim 1,
Wherein:
And at least one tongue installed at an upper portion of the plate for gripping and fixing the clinometer through an elastic force.
delete delete delete The method according to claim 1,
The remote control device includes:
Further comprising an LED lamp detachably attached to the camera with the bracket to provide light to the clinometer.

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