JP6286143B2 - Surveying pin pole base - Google Patents

Description

The present invention is related to the pedestal of the surveying pinholes.

  For general surveying, install a surveying instrument at this reference point with a known position as the reference point, or set up a pin pole at the measurement point to be measured, and then the reflecting prism provided on the pin pole from the surveying instrument Surveying the distance to the.

  As a conventional surveying pin pole, for example, the one described in Patent Document 1 is known and is shown in FIG. In FIG. 7, a surveying pin pole 1 is provided with a prism device 4 including a reflecting prism 2 and a level 3 in which bubbles and liquid are sealed. The prism device 4 is arranged in the axial direction of the pin pole 1. It has become freely movable. A stone bump 5 is formed at the lower end portion of the pin pole 1, and this stone bump 5 is inserted into a measurement point on the ground as a measurement surface.

Then, the distance measuring light emitted from the surveying instrument is irradiated onto the reflecting prism 2 of the pin pole 1 inserted into the measuring point, the distance measuring light reflected from the reflecting prism 2 is incident on the measuring instrument, and the measuring point is measured by the measuring device. The three-dimensional position is obtained.
By the way, in the case of the pin pole 1 having a structure in which the stone protrusion 5 is inserted into the measurement point, the pin pole 1 stabs and sinks in the case of soft ground (for example, earth) that is not paved, and the measurement surface is high. The accuracy cannot be measured accurately.

In order to prevent such a problem from occurring, for example, it is conceivable to use a base 6 shown in FIG. In FIG. 8, the pedestal 6 includes a hollow cylindrical portion 7 into which the lower portion of the pin pole 1 is inserted, and a disk-shaped bottom plate portion 8 provided at the lower end portion of the hollow cylindrical portion 7 and in surface contact with the ground E. Yes.
If the pin pole 1 is inserted into the pedestal 6 and the pin pole 1 is erected on the ground E via the pedestal 6, the pin pole 1 sinks into the ground E even when the pin pole 1 is installed on the soft ground. Thus, the height of the ground E can be accurately measured, and the measurement accuracy of the measurement points can be prevented from deteriorating.

JP 2001-272230 A

  However, since the base 6 of such a conventional surveying pin pole has a structure in which the hollow cylindrical portion 7 and the bottom plate portion 8 are integrated, as shown in FIG. When the pedestal 6 is placed on E, the vertical axis cannot be detected by the level, and the axis 9a of the pin pole 1 is inclined with respect to the vertical axis 9b. For this reason, the measuring point 10 on the ground E and the reflecting surface of the reflecting prism 2 accurately positioned with respect to the measuring point 10 are shifted in the horizontal direction by the distance L at which the pin pole 1 is inclined. There was a problem that it was impossible to survey accurately.

As a first aspect of the present invention, a pedestal of a surveying pin pole includes a surveying instrument provided with an optical component that reflects the ranging light emitted from the surveying instrument to the surveying instrument and a level that detects the vertical axis. A pedestal attached to the lower end of the pin pole for mounting and erected on the measurement surface, the pedestal main body having a bottom surface in surface contact with the measurement surface, and swingable with respect to the pedestal main body A holding portion that holds a lower end portion of the pin pole, and the pedestal main body is attached to the outer peripheral portion of the flat member and the transparent member having the bottom surface, and along the outer peripheral portion of the transparent member An extended frame body and a position located above the transparent member and extending from one outer peripheral portion of the frame body to the other outer peripheral portion of the frame body with the central portion of the transparent member interposed therebetween, and the holding An arm member for swingably supporting the portion; It comprise characterized in that it is configured.

FIG. 1 is a view showing an embodiment of a pedestal of a surveying pin pole according to the present invention, and is an external view of the pin pole. FIG. 2 is a view showing an embodiment of the pedestal of the surveying pin pole of the present invention, and is an external view of the pedestal. FIG. 3 is a view showing an embodiment of the pedestal of the surveying pin pole of the present invention, and is a top view of the pedestal in a state where the holding portion and the arm portion are removed. FIG. 4 is a view showing an embodiment of the pedestal of the surveying pin pole of the present invention, and is a bottom view of the pedestal in a state where the holding portion and the arm portion are removed. FIG. 5 is a view showing an embodiment of the pedestal of the surveying pin pole of the present invention, and is an external view of the pedestal and the pin pole installed on the horizontal ground. FIG. 6 is a view showing an embodiment of the pedestal of the surveying pin pole of the present invention, and is an external view of the pedestal and the pin pole installed on the inclined ground. FIG. 7 is a view showing an embodiment of a pedestal of a survey pin pole according to the present invention, and is an external view of a conventional pin pole. FIG. 8 is a view showing an embodiment of a pedestal of a surveying pin pole according to the present invention, and is an external view of a conventional pedestal. FIG. 9 is a view showing an embodiment of a pedestal of a surveying pin pole of the present invention, and is an external view of a conventional pedestal and a pin pole installed on an inclined ground.

Hereinafter, embodiments of a pedestal for a surveying pin pole according to the present invention will be described with reference to the drawings.
1-5 is a figure which shows the base of the pin pole for surveying of one Embodiment based on this invention.
First, the configuration will be described. In FIG. 1, the pin pole 11 includes a reflecting prism 12 and a level 13 as optical components. The reflecting prism 12 is attached to the prism holder 14 and reflects distance measuring light such as a laser beam emitted from a total station as a surveying instrument (not shown) to the total station. The total station is configured so that the three-dimensional position (x, y, z coordinate position) of the measurement point can be specified based on the distance measuring light reflected from the reflecting prism 12. Although the total station is taken as an example of the surveying instrument, the surveying instrument is not limited to the total station. Further, although the reflecting prism 12 is taken as an example of the optical component, the optical component is not limited to the reflecting prism 12.

The level 13 has a bubble tube 15 in which liquid and bubbles are enclosed, and detects the vertical axis according to the position of the bubbles.
That is, the level 13 is configured such that the bubbles enclosed in the bubble tube 15 are located at an arbitrary position in a state where the axis of the pin pole 11 coincides with the vertical axis. Therefore, the operator can determine that the axis of the pin pole 11 coincides with the vertical axis when the bubble enclosed in the bubble tube is located at an arbitrary position.

A pedestal 16 shown in FIG. 2 is attached to the lower end portion of the pin pole 11, and this pedestal 16 is configured to install the pin pole 11 on the ground E as a measurement surface (see FIG. 5).
The pedestal 16 includes a transparent flat plate-like transparent member 17 such as an acrylic resin, a ring-shaped frame 18 made of metal, and an arm member 19 attached to the frame 18. And.

The transparent member 17 is formed in a disk shape, and the bottom surface of the transparent member 17 is formed into a flat surface so as to come into surface contact with the ground E. 3 and 4, the frame 18 is fixed to the upper surface of the outer peripheral portion of the transparent member 17 by a plurality of bolts 20, and extends along the outer peripheral portion of the transparent member 17, that is, the circumferential direction of the transparent member 17. Exist. FIG. 4 is a view of the pedestal 16 as viewed from the lower surface, and the frame 18 can be seen through the transparent member 17. The transparent member 17 need not be limited to a disk shape, and may be a square shape. In this case, the shape of the frame 18 is not a ring shape, and may be matched to the shape of the transparent member 17.
The arm member 19 is positioned above the transparent member 17 and extends from the outer peripheral portion 18 a of the frame body 18 to the outer peripheral portion 18 b of the frame body 18 with the central portion O of the transparent member 17 interposed therebetween. The arm member 19 includes two arm portions 19A and 19B, and the base end portions 19a of the arm portions 19A and 19B are connected by a connecting piece 19C. The arm portions 19A and 19B are rotatably attached to a bracket 22 attached to the outer peripheral portion 18a of the frame 18 via a bolt 23, and the base end portion 19a of the arm member 19 is a frame 18. Rotate with respect to.

The distal ends of the arm portions 19A and 19B are connected by a connecting piece 19D, and the connecting piece 19D is screwed into a screw 24 provided upright on the outer peripheral portion 18b of the frame 18. A wing nut 25 is screwed onto the screw 24, and the connecting piece 19 </ b> D moves up and down along the axial direction of the screw 24 by rotating the wing nut 25 in the vertical direction along the axial direction of the screw 24. It is like that.
Therefore, the distal end portion 19b of the arm member 19 can be moved close to and separated from the frame 18 with the proximal end portion 19a as a fulcrum. Here, as for the base 16 of this embodiment, the transparent member 17, the frame 18, and the arm member 19 comprise the base main body.

  A ring member 26 having an opening 26a is provided in the central portion of the arm member 19 in the extending direction. The ring member 26 is provided on the lower surfaces of the arm portions 19A and 19B so as to connect the arm portions 19A and 19B. ing. A spherical portion 28 is provided between the ring member 26 and the central portion O of the transparent member 17, and a stud portion 29 protruding upward from the opening 26 a of the ring member 26 is integrally formed on the upper portion of the spherical portion 28. Is provided.

  A screw 29a is formed at the upper end of the stud portion 29. As shown in FIG. 5, a screw formed on the inner peripheral surface of the concave portion 11a at the lower end portion of the pin pole 11 is screwed into the screw 29a. The pin pole 11 is connected to the stud portion 29.

  The spherical portion 28 rolls between the ring member 26 and the central portion O of the transparent member 17, and the stud portion 29 moves to the center of the transparent member 17 as the spherical portion 28 rolls. Swing around the part O. Here, as for the base 16 of this embodiment, the ball stud 27 which has the spherical part 28 and the stud part 29 comprises the holding | maintenance part.

  Further, when the wing nut 25 is moved downward along the screw 24 and tightening of the wing nut 25 is strengthened, the arm member 19 rotates so that the distal end portion 19b of the arm member 19 comes close to the frame body 18. The ring member 26 presses the spherical portion 28 against the transparent member 17. For this reason, rolling of the spherical portion 28 is restricted, and a large operating force is required to operate the stud portion 29 in the swinging direction, and the stud portion 29 is moved to the transparent member 17 and the stud portion 29 so that the stud portion 29 does not swing. It can be fixed to the arm member 19. Therefore, the pinball 11 can be prevented from being tilted by its own weight.

  Further, when the wing nut 25 is moved upward along the screw 24 and tightening of the wing nut 25 is weakened, the arm member 19 rotates so that the distal end portion 19b of the arm member 19 is separated from the frame body 18. The force with which the ring member 26 presses the spherical portion 28 against the transparent member 17 is reduced. For this reason, the spherical portion 28 can be rolled with a small force, and the operating force for operating the stud portion 29 in the swinging direction can be reduced.

  That is, the pedestal 16 of this embodiment includes a fixed state in which the ball stud 27 is fixed to the transparent member 17 and the arm member 19 so that the ball stud 27 does not swing with respect to the transparent member 17 and the arm member 19, and a transparent member. The state can be switched between a swinging state in which the ball stud 27 is swung with respect to the arm member 19 and the arm member 19. The screw 24, the wing nut 25, and the ring member 26 provided on the arm member 19 of the present embodiment constitute a switching unit.

As shown in FIGS. 3 and 4, a concentric scale 30 is formed on the transparent member 17, and this concentric scale 30 has a central portion when the center portion O of the transparent member 17 is set to “zero”. Numbers that increase from O toward the outside in the radial direction are marked. The concentric scales 30 are given numerical values that increase from, for example, 20 (mm), 40 (mm), and 60 (mm) from the central portion O toward the radially outer peripheral portion.
The transparent member 17 is formed with cross lines 31 that are orthogonal to each other about the central portion O. The crosshairs 31 are graduated, and four notches 32 are formed on the outer periphery of the transparent member 17 located on the outer periphery in the radial direction of the crosshairs 31.

Next, the operation will be described.
A pedestal 16 for standing the pin pole 11 of the present embodiment on the ground E is a flat plate-like transparent member 17, a frame 18 attached to the outer peripheral portion of the transparent member 17, and extending in the circumferential direction of the transparent member 17. The ball stud 27 is positioned above the transparent member 17 and extends from the outer peripheral portion 18a of the frame body 18 to the outer peripheral portion 18b of the frame member 18 with the central portion O of the transparent member 17 interposed therebetween, and supports the ball stud 27 in a swingable manner. And an arm member 19.
Therefore, at the time of surveying, when installing the pin pole 11 at the measurement point A (inking position) A on the ground E as shown in FIG. 5, the operator visually recognizes the measurement point A on the ground E through the transparent member 17. can do. For this reason, the pin pole 11 can be easily installed above the vertical axis 33 of the measurement point A, and the workability of the surveying work can be improved.

  Further, when the pin pole 11 is installed, when the operator places the base 16 on the soft ground E (for example, soil) by bringing the bottom surface of the transparent member 17 into surface contact with the ground E, the pin pole 11 is It is possible to prevent sinking to the ground E, to accurately measure the height of the ground E, and to prevent the measurement accuracy of the measurement point A from deteriorating.

Further, as shown in FIG. 6, when the pedestal 16 is placed on the inclined ground E by the operator, the ball stud 27 is swung with respect to the transparent member 17, and the level 13 is connected to the vertical axis 33 and the pin pole. 11, the pin pole 11 is fixed on the vertical axis 33 by strongly tightening the wing nut 25 and pressing the spherical portion 28 against the transparent member 17 by the ring member 26. As a result, even when the ground E is inclined, the pin pole 11 can be made to coincide with the vertical axis 33 in accordance with the inclination angle of the ground E, and it is possible to prevent the measurement accuracy from deteriorating.
In addition, by changing the tightening force of the wing nut 25 and changing the pressing force of the spherical portion 28 by the ring member 26, the ball stud 27 can be swung with the operator's force or an operating force according to preference, The pin pole 11 can be easily operated.

Further, since the concentric circle scale 30 with respect to the central portion O of the transparent member 17 is formed on the transparent member 17 of the pedestal 16 of the present embodiment, the axis of the pin pole 11 is shifted from the measurement point A in the horizontal direction. The operator who operates the pin pole 11 in the horizontal direction moves the pin pole 11 from the position shifted from the measurement point A to the measurement point A while viewing the concentric scale 30 based on the guidance of the operator who operates the surveying instrument. Can be moved to.
Specifically, when the central portion O of the transparent member 17 that is the axis of the pin pole 11 is displaced 20 mm in the horizontal direction from the measurement point A, the operator visually observes the concentric scale 30 and sets the central portion O to 20 mm. If the pedestal 16 is moved in the horizontal direction so as to be shifted, the pin pole 11 can be easily moved to the measurement point A. As a result, the workability of the surveying work can be improved more effectively.

  Further, the pedestal 16 of this embodiment operates the wing nut 25 to rotate the arm member 19, thereby changing the pressing force of the ring member 26 for pressing the spherical portion 28, so that the ball stud 27 is The state can be switched between a fixed state that is fixed to the transparent member 17 so as not to swing with respect to the transparent member 17 and a swing state in which the ball stud 27 is swung with respect to the transparent member 17. For this reason, the pin pole 11 can be swung so that the axis of the pin pole 11 coincides with the vertical axis 33 by making the ball stud 27 rock by the ring member 26.

  Further, when the axis of the pin pole 11 coincides with the vertical axis 33, the pin stud 11 is fixed to the base 16 so that the attitude of the pin pole 11 does not change by fixing the ball stud 27 to the transparent member 17 by the ring member 26. Therefore, the workability of surveying work can be improved.

  In addition, since the pedestal 16 of the present embodiment has four notches 32 formed on the outer peripheral portion of the transparent member 17 positioned on the outer peripheral portion of the cross wire 31 in the radial direction, the notches 32 are formed by scoring the notches 32. The ground E can be marked with the intersection as a measurement point, and the workability of the surveying work can be improved more effectively.

  While embodiments of the invention have been disclosed, it will be apparent to those skilled in the art that changes may be made without departing from the scope of the invention. All such modifications and equivalents are intended to be included in the following claims.

  DESCRIPTION OF SYMBOLS 11 ... Pin pole, 12 ... Reflection prism (optical component), 13 ... Level, 16 ... Base, 17 ... Transparent member (base body), 18 ... Frame (base body), 18a ... One outer peripheral part of a frame, 18b ... the other outer periphery of the frame, 19 ... arm member (base body), 24 ... screw (switching portion), 25 ... wing nut (switching portion), 26 ... ring member (switching portion), 27 ... ball stud ( Holding part), 30 ... concentric scale, 33 ... vertical axis

Claims (3)

It is attached to the lower end of a survey pin pole that includes an optical component that reflects the distance measuring light emitted from the survey instrument to the survey instrument and a level that detects the vertical axis. The pin pole stands on the measurement surface. A pedestal to be installed,
A pedestal body having a bottom surface in surface contact with the measurement surface; and a holding part that is swingably provided with respect to the pedestal body and holds a lower end of the pin pole,
The pedestal body is positioned above the transparent member, a flat transparent member having the bottom surface, a frame attached to the outer peripheral portion of the transparent member, and extending along the outer peripheral portion of the transparent member. And an arm member extending from one outer peripheral portion of the frame body to the other outer peripheral portion of the frame body with the central portion of the transparent member interposed therebetween, and supporting the holding portion in a swingable manner. A pedestal for surveying pin poles.   The pedestal of a surveying pin pole according to claim 1, wherein concentric scales with respect to a central portion of the transparent member are formed on the transparent member. The arm member is between a fixed state in which the holding portion is fixed to the transparent member so that the holding portion does not swing with respect to the transparent member, and a swing state in which the holding portion swings with respect to the transparent member. pedestal of surveying pinhole according to claim 1 or claim 2 characterized in that it has a switching unit for switching the state.

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