JP2575087B2 - Reference setting device for track laying - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reference line setting device for laying a railway line, particularly for a high-speed railway.

[0002]

2. Description of the Related Art Conventionally, when newly laying a track, a laying design line is prepared in advance by surveying or aerial photography or the like, and a line laying standard is provided at a predetermined interval along the laying design line. The track is installed, and the track is laid based on a reference point defined by the track setting standard.

FIGS. 13 and 14 show an example of the structure of a line laying reference device. Numeral 10 indicates a line laying reference device. The track laying reference device 10 includes a mounting plate 11 and a mounting plate 1.
Bearing pieces 12A, 12B formed by cutting and raising from 1;
A first screw shaft 13 rotatably inserted and supported between the bearing pieces 12A and 12B is supported. The first screw shaft 13 is screwed into the first screw shaft 13, and the first screw shaft 13 is rotated to be illustrated. Moving table 14 that moves in the X direction, and bearing pieces 15A, 15 cut and raised from a plate forming the first moving table 14
A second screw shaft 16 that is rotatably supported by B, and a second movement that is screwed to the second screw shaft 16 and that moves in the Y direction shown in FIG. 13 by rotating the second screw shaft 16. And a third screw 17 which is screwed to the second moving table 17 in the vertical direction.
It comprises a screw shaft 18 and a reference mark 19 formed at the upper end of the third screw shaft 18. When the mounting plate 11 is mounted on an inclined surface other than the horizontal plane, that is, when the cant is attached to the roadbed at the curved portion, the screws 21 and 22 correct the inclination due to the cant, and fix the third screw shaft 18. Fig. 4 shows a cant correction screw provided to correct a vertical posture.

Referring to FIG. 13, a reference mark 19 is provided with a cross mark on its head, and the intersection of the cross mark is used as a reference point RF. According to the structure of the line laying reference device 10 described above, the first screw shaft 13, the second screw shaft 16, and the third screw shaft 18 are rotated to set the reference point RF in the X direction and the Y direction. It can be moved in the Z direction. The track laying reference device 10 is installed in a reference device installation hole 24 formed in a roadbed 23 made of, for example, concrete as shown in FIGS. 15 and 16. The reference device installation holes 24 are provided at predetermined intervals of, for example, 10 to 20 meters along the line layout design image 25. Although not particularly shown, three anchor bolts are implanted in the reference device installation hole 24, and the line laying reference device 10 is fixed by the three anchor bolts. That is, an anchor bolt is inserted into a mounting hole formed in the mounting plate 11, a nut is hung on the anchor bolt, and the mounting plate 11 is fastened and fixed to a bottom surface of the reference device mounting hole 24.
At the time of this fixing, the second screw shaft 16 is connected to the line layout design object 2
5 is arranged in parallel. By installing in this direction, the second screw shaft 16 is rotated to move the reference point RF in the Y direction, so that the distance between the respective reference devices 10 can be accurately set to a predetermined distance. . Further, by rotating the first screw shaft 13 orthogonal to the second screw shaft 16, the reference point RF can be accurately set on the line layout design object line 25.

That is, the reference device installation hole 24 is roughly determined by a survey or the like. Therefore, the reference point RF is set to a position determined properly by using the adjusting means provided in the reference device 10 after the reference device 10 is mounted in the reference device installation hole 24. For this reason, the mounting direction of the reference device 10 is set such that the axis of the second screw shaft 16 is parallel to the line layout design image 25, and the rotation of the second screw shaft 16 reduces the distance between the reference points. Will be adjusted. In contrast, the first
The screw shaft 13 is used to set the position of the reference point RF on the line layout design object line 25.

[0007] Referring to FIGS. 17 and 18, among the reference devices 10 installed along the track layout design line 25, reference devices existing at intervals of, for example, 100 meters are A reference devices 10.
A is set, and the reference point RF of the A reference device 10A is set in advance by surveying or the like so as to match the line layout design image 25. An inner reference device sandwiched between the A reference device 10A and the A reference device 10A is defined as a B reference device 10B, and the position of each reference point RF of the B reference device 10B is set in the following procedure.

A) Vertical setting of the third screw shaft 18 b) Setting of the distance P between the reference points c) Setting of the distances X _{1 to} X ₇ d) Setting of the height direction Setting of the reference device for laying the track according to the present invention The device is a B standard 10
This is applied when the position of each reference point RF of B is set, and corresponds to the items c) and d). It is an object of the present invention to provide a line laying reference device setting device capable of accurately and easily setting any distance setting and height setting to anyone.

Here, how to set the direction and the height direction in the conventional manner will be described. Conventionally, there are a stringing method and a transit method as a method of setting the direction of passage, but the stringing method has a large error and is unsuitable for setting a standard device for a high-speed railway. Here, the transit method will be described. A reference device 10 shown in FIGS. 17 and 18
A transit is installed on one side of A and the other A
Set the target on A. The conventional line of sight of the transit is matched with the vertical line drawn on the target and the reference line 26
Set. Since FIG. 17 shows the case of the straight section, the reference line 26 matches the line layout design image 25. Therefore, the position of each reference point RF of each B reference device 10B is set so as to match the reference line 26 set between the transit and the target. For this purpose, the weight is suspended with a thread, and the thread is suspended at a position corresponding to a vertical collimation line that looks transit. In this state, the first screw shaft 13 of the B reference device 10B is rotated to adjust the position of the reference point RF of each B reference device 10B to the position of the weight.

FIG. 18 shows a case of a curved section. In the case of a curved section, a thread with a suspended weight is installed at a position orthogonal to each of the B reference devices 10B at a position matching the reference line 26. Distance X from the yarn position to the reference point RF of each B reference device 10B
₁ , X ₂ , X ₃ , X ₄ ... Are measured on a scale. The measured values of the distances X ₁ , X ₂ , X ₃ , X ₄ ... Correspond to the normal distance values (given as known values) from the line layout design image 25. First screw shaft 13
Is rotated to set the position of the reference point RF of each B reference device 10B.

On the other hand, the setting in the height direction c) is based on the height position of the reference point RF of the adjacent reference device, and the elevation given to each reference device 10B using a surveying instrument such as transit. Set sequentially.

[0011]

As described above, conventionally, a reference line 26 is set using a transit and a target, and based on the reference line 26, a weight X ₁ , X ₂ , X ₃ ... Are measured, and in the case of a straight section, the support value is set to 0.
Since the position of the reference point RF is set so as to be the distance values X ₁ , X ₂ , X ₃ ... Given to 0B, the person who operates the first screw shaft 13 to rotate, the reference point RF and the reference line 26 are set. Distance X up to
₁ , X ₂ , X ₃ ... Are measured by a scale, and at least three workers are required: a person who confirms that the target value is approaching by rotating the first screw shaft and a person who operates the transit. is there.

Since the distances X ₁ , X ₂ , X ₃ , X ₄ ... Are measured using a scale and a weighted thread, it is difficult to say that the measurement accuracy is high. ± 1m even considering yarn thickness
An error of about m occurs. Since the distances X ₁ , X ₂ , X ₃ ... Are measured by the scale, individual differences occur, and the reliability of the measured values is low. Therefore, there is a disadvantage that the setting accuracy of the reference device cannot be increased. In particular, it is impossible to set a standard for laying tracks of an ultra-high-speed linear railway and other high-speed railways.

SUMMARY OF THE INVENTION The present invention provides a line laying reference device setting apparatus which enables anyone to accurately set a line laying reference device.

[0014]

A mounting plate 11 and a mounting plate 1 are provided.
A pair of first bearing pieces 12A and 12B formed by cutting and raising the first bearing piece, a first screw shaft 13 rotatably supported between the first bearing pieces and supported, and a first screw A first moving base 14 that is screwed to the shaft 13 and is rotated in the first screw shaft 13 to move in a direction parallel to the first screw shaft 13, and is formed by being cut and raised from the first moving base 14. A second screw shaft 16 rotatably passed and supported between the pair of second bearing pieces 15A and 15B, and screwed to the second screw shaft 16 to rotate the second screw shaft 16 By doing so, the first screw shaft 13
A second movable table 17 that moves in a direction perpendicular to the direction of movement, a third screw shaft 18 that has a reference mark 19 formed on the upper end surface and is screwed to the second movable table 17 in the vertical direction, and provided on the second movable table 17. In a line laying standard setting device for setting the line laying standard 10 including the cant correcting screws 21 and 22,
One end has an engaging portion 31 which engages with the reference mark 19 of the line laying reference device 10, and the other end is supported by vertical position adjusting means 32 for moving the other end in the vertical direction. A main frame 30 provided with a scale indicating a distance L from the reference point RF of the reference mark 19 to the end side;
An index plate 33A, which is slidably supported by the main frame 30 and has an index 33 formed of a vertical line, is provided. A window 33G is formed through the index plate 33A by interrupting the index 33. A reference line setting device for line laying, comprising a sub-index plate 33E mounted behind a formed index plate 33A and forming a sub-index 33F formed of a vertical line, and including a transit for observing the index 33 and the sub-index 33F. Was configured.

When setting the transit reference line, the main frame 30 is installed on the line laying reference where the target opposite to the line laying reference where the transit is installed is installed, and the index 33 and the sub-index 33F are set. A reference line setting device for track laying was set up as a target for setting the transit reference line. The other end of the main frame 30 is attached to the vertical position adjusting means 32.
Guide 32F for guiding in a direction orthogonal to the 0 axis
A reference line setting device for laying a track provided with the above was constructed.

Further, the vertical position adjusting means 32 is provided with a pin for receiving the other end of the main frame 30 as a guide for guiding the other end of the main frame 30 in a direction perpendicular to the axis of the vertical position adjusting means 30. The reference device setting device for laying tracks was constructed. Further, a moving table 38 fixed to an arbitrary position of the main frame 30 is provided, and the moving table 38 and the index plate 33A are provided.
Fine movement device 3 interposed between and finely moves index plate 33A
7 was constructed.

Further, in the above-described reference device setting device for road laying, the beam 40 which is supported at three points by the three supporting screw shafts 41A, 41B and 41C and has a level 42 and is adjusted and installed in a horizontal posture is provided. A movable rod 51 that protrudes downward by receiving a bias force, has a display unit 52 that displays the amount of protrusion of the movable rod 51, and has a zero reset switch 54 that returns the amount of protrusion to zero. A reference line setting device for laying a track, comprising a measuring device 50 movably supported along the beam 40 was constructed.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIGS. Reference numeral 23 denotes a roadbed fixed by concrete. Trackbed design line 25
(See FIGS. 17 and 18).
4 are formed, and the reference device 10 is installed in the reference device installation hole 24.

The reference line setting device for laying a track according to the present invention includes a main frame 30 having an engagement portion 31 for engaging with the reference mark 19 of the reference device 10 at one end, and the other end of the main frame 30. Vertical position adjusting means 32 for supporting the main frame 30 movably in the vertical direction, an index 33 movably supported along the main frame 30, and a main scale 34 attached to the main frame 30.
It is constituted by and.

The engaging portion 31 is provided at a lower end of a leg 35 attached to the main frame 30 so as to protrude in a direction perpendicular to the end of the main frame 30. That is, the leg 35 is composed of, for example, two plates as shown in FIG.
A is formed, and pins 31B, 3
1C, the engaging portion 31 is supported by the structure for supporting the engaging member 31D.
Can be configured. The engagement element 31 shown in FIG.
D contacts the peripheral surface of the reference mark 19, and the engaging portion 31
9 without any backlash.

The vertical position adjusting means 32 supports the other end of the main frame 30, moves the supporting position up and down, and sets the main frame 30 to a horizontal posture. Reference numeral 36 denotes a level for measuring whether or not the main frame 30 is at a horizontal position. The vertical position adjusting means 32 includes a base 32A, a pair of guide shafts 32B implanted on the base 32A, a movable base 32C supported by the guide shaft 32B and supported so as to be able to move up and down. A screw shaft 32D that is screwed into the moving table 32C and moves the moving table 32C in the vertical direction by performing a rotation operation, and a screw shaft 3 that sets the posture of the base 32A.
2E.

The movable table 32C has a guide 32F in the horizontal direction.
Is formed, and a roller 30A rotatably mounted on the end of the main frame 30 is engaged with the guide 32F. With this engagement structure, the end of the main frame 30 is supported so as to be freely movable in the horizontal direction with respect to the vertical position adjusting means 32. 32BB denotes a knob for rotating the screw shaft 32D.

The index 33 is formed by drawing a vertical line on an index plate 33A slidably supported by the main frame 30. A window 33B is formed in a portion of the index plate 33A that is in contact with the main frame 30, and a sub-scale 33D is attached to an inclined surface 33C formed on an edge of the window 33B. The scale of the main scale 34 can be read at a resolution of, for example, 1/10 by the sub-scale 33D. Although the main scale 34 and the sub-scale 33D are roughly drawn in FIG. 1, scales in mm units are actually provided.

Referring to FIG. 1, by matching the zero point of the vernier scale 33D with the desired scale of the main scale 34, the index 33 is obtained.
The distance L between the reference mark RF and the reference point RF of the reference mark 19 of the reference device 10 is set to the scale distance of the main scale 34. For example,
When the zero point of the vernier scale 33D is adjusted to the position of 11.5 mm of the main scale 34, the distance L is set to 11.5 mm. Referring to FIG. 18, this distance L is set to the distances X ₁ , X ₂ , X ₃ ... Given to each reference device 10. Here, the distance L is L
By setting = 0, the index 33 and the sub-index 33F indicate the reference point RF indicated by the reference mark 19 of the reference device 10. When the distance provided by this setting state is 0, that is, in addition to using as a measuring device for setting the position of the reference mark of the reference device in the straight section shown in FIG. 26 can be used as a target.

Further, as shown in FIG. 5, a sub-index plate 33E is provided behind the index 33, and the sub-index plate 33E is provided with a sub-index 33F. The sub-index 33F is made to coincide with the position of the index 33, and the direction of the main frame 30 is set so that the index 33 and the sub-index 33F coincide with each other when viewed through the window 33G by transit. Referring to FIG. 18, this allows the main frame 30 to be installed in a direction crossing at right angles to the reference line 26 set by the transit.

Here, a method of setting a line laying reference device using the line laying reference device setting apparatus of the present invention will be described. This can be easily and easily implemented by a small number of about two people as follows. First, the reference line 26 described with reference to FIG. 18 is set using the transit and the target, and then the engaging portion 31 is engaged with the reference mark 19 of the reference device 10 to be set. The position of 32 is rotated around the reference mark 19 to change the direction of the main frame 30, and the index 33 is viewed from the transit.
And the sub-index 33F are set to overlap. With this setting, the main frame 30 is set in a direction orthogonal to the reference line 26 set by the transit.

Next, the knob 32 of the vertical position adjusting means 32
By operating BB, the posture of the main frame 30 is set to a horizontal state. The distance L between the index 33 and the reference point of the reference device 10 is set to a distance corresponding to the distance provided to the reference device 10. Observe the position of indicator 33 by transit,
A deviation between a vertical collimation line displayed on the transit (equivalent to the reference line 26) and the index 33 is measured. If the deviation is 0, the first screw shaft 13 of the reference device 10 is rotated and the index 33 is displayed in transit if the position of the index 33 is shifted to either + or-. Match 26. When the index 33 coincides with the reference line 26 displayed on the transit, the setting of the distance given to the reference device ends. This setting operation is performed for each of the B reference devices 10B shown in FIGS.

The above description is for the case where the surface of the roadbed 23 is horizontal. However, in the case of a curved section, the roadbed 23 is provided with a cant and has an inclination. Hereinafter, a setting method when a tilt is given will be described with reference to FIG. When the roadbed 23 is inclined, the third
The screw shaft 18 is set in a vertical posture by adjusting the cant correcting screws 21 and 22. By setting the third screw shaft 18 in a vertical position in advance in this way, the set distance value does not change even if the height direction described later is set.

The axis of the vertical position adjusting means 32 is set perpendicular to the inclined surface of the roadbed 23. By setting the axis of the vertical position adjusting means 32 perpendicular to the inclined surface of the roadbed 23, the guide 32F is arranged parallel to the roadbed 23. Therefore, even after the main frame 30 is set in the horizontal posture, the adjusting means in the X direction of the reference device 10, that is, the first screw shaft 13 is rotated to move the position of the index 33 together with the main frame 30. The frame 30 maintains the state of maintaining the horizontal posture, and the set distance value L is accurately maintained.

FIGS. 7 to 9 show another embodiment of the vertical position adjusting means 32. FIG. In this embodiment, the guide shaft 32
B and the lower end of the screw shaft 32D are brought into direct contact with the surface of the roadbed 23 to be self-supporting, and the movable base 32C is provided with a pin 32G instead of the guide 32F, and the main frame 30 is supported by the pin 32G. This structure is used when the straight section and the mounting surface of the reference device are horizontal.
This embodiment shows a case where a fine movement device 37 is provided as a means for moving the index 33 and the main frame 30.
That is, a moving table 38 is provided, a fine movement device 37 is inserted between the moving table 38 and the index 33, and the moving table 38 is screwed with a screw 38A.
And fixed to the main frame 30 with the fine movement device 3 in the fixed state.
The structure is such that the index 33 is slightly moved by operating the pointer 7. By providing the fine movement device 37 in this manner, there is obtained an advantage that the operation of setting the index 33 to the given distance value can be easily performed. The fine movement device 37 can be applied to the embodiment shown in FIG.

Referring to FIG. 10, a method of setting the height direction of the line laying reference device 10 will be described. The elevation of the temporary reference point of each track laying reference device 10 is obtained in advance by surveying. The provisional reference point of each track laying reference device 10 is shown in FIGS.
The upper end surface of the bearing piece 12A shown in FIG. The elevations H ₁ , H ₂ , H ₃ ... Of the upper end face of each bearing piece 12A are obtained by surveying. Based on the altitudes H ₁ , H ₂ , H _3, ..., A difference Δ
Find H. By calculating the difference ΔH, this difference ΔH
Should be set to the height difference between the upper surface of the reference mark 19 and the upper end surface of the bearing piece 12A. An apparatus used for setting the height will be described with reference to FIGS. Reference numeral 40 denotes a beam. The beam 40 has three supporting screw shafts 41A, 41A.
B and 41C, it is installed in a horizontal posture by the level 42. That is, regardless of the inclination of the roadbed 23, the beam 40 is installed in a horizontal posture with respect to the railroad laying reference device 10 installed at any position.

A measuring device 50 is attached to the beam 40 so as to be able to move laterally. As this measuring device 50, for example, an electronic micrometer called “Digimatic Indicator IDV-25” manufactured and sold by Mitutoyo Corporation can be used. The electronic micrometer is protruded by receiving an eccentric force in a direction in which the movable rod 51 projects from the body, and the movable amount of the movable rod 51 is displayed on the display unit 52. 53 denotes a power switch, 54 denotes a zero reset switch, and 51A denotes a handle for lifting the movable rod 51.

The movable rod 51 is supported vertically downward, and the beam 40 is supported by the bearing piece 1 serving as a reference point for the reference mark 19 and the elevation.
The measuring device 50 is placed parallel to the line connecting the upper surface of 2A and the measuring device 50 so as to be able to abut both the bearing piece 12A and the upper surface of the reference mark 19. The tip of the movable rod 51 is brought into contact with the upper surface of the bearing piece 12A, and in this state, the zero reset switch is operated to reset the display on the display unit 52 to zero. Next, the measuring device 50 is moved onto the reference mark 19, and the movable rod 51 is moved.
Is brought into contact with the reference point RF of the reference mark 19. At this time, the numerical value displayed on the display unit 52 is the height difference between the temporary reference point and the reference mark 19. The difference in height is the difference ΔH calculated earlier.
The third screw shaft 18 is rotationally adjusted so as to conform to the above, and the height adjustment is completed.

[0034]

As described above, according to the line laying standard setting device of the present invention, the setting of the line laying standard is performed by two persons as described in the method of setting the line laying standard. It can be easily and easily implemented by a small number of people. An index plate 33A slidably supported by the main frame 30 and formed with an index 33 formed of a vertical line is provided. A window 33G is formed through the index plate 33A by interrupting the index 33. Indicator plate 33A formed with 33
The main frame 30 is provided with a sub-index 33F formed of a vertical line and attached to the back of the main frame 30 by setting the index 33 and the sub-index 33F to overlap with each other when viewed from the transit. The line laying reference is set in a direction orthogonal to the set reference line 26, and is mainly set to a line laying reference in which a target opposed to a line laying reference in which a transit is installed is set when setting a transit reference line. With the frame 30 installed, the index 33 and the sub-index 33F can be used as accurate targets for setting the transit reference line.

The vertical position adjusting means 32 is provided with a guide 32F for guiding the other end of the main frame 30 in a direction perpendicular to the axis of the vertical position adjusting means 30. A pin for receiving the other end of the main frame 30 is provided as a guide for guiding in the direction perpendicular to the reference frame, so that the set distance value does not change even if the height of the reference device is set. .

Further, there is provided a moving table 38 fixed to an arbitrary position of the main frame 30, and the moving table 38 and the index plate 33A are provided.
Fine movement device 3 interposed between and finely moves index plate 33A
By providing 7, the operation of setting the index 33 to the given distance value can be easily and precisely performed.
The movable rod is provided with a beam 40 that is supported at three points by three support screw shafts 41A, 41B, and 41C and that has a level 42 and that is adjusted and installed in a horizontal posture, and that is protruded downward by receiving a biased force. A measuring device having a display unit 52 for displaying the amount of protrusion of the movable rod 51, a zero reset switch 54 for returning the amount of protrusion to zero, and supported movably along the beam 40. By providing 50 together, it is possible to easily and accurately set both the distance and height in the direction of the track laying reference device.

[Brief description of the drawings]

FIG. 1 is a front view illustrating an embodiment.

FIG. 2 is a side view of FIG. 1;

FIG. 3 is a plan view of FIG. 1;

FIG. 4 is a side view seen from the opposite side of FIG. 2;

FIG. 5 is a perspective view illustrating the structure of an index.

FIG. 6 is a front view showing a state where the embodiment of FIG. 1 is installed on an inclined surface.

FIG. 7 is a front view illustrating another embodiment.

FIG. 8 is a side view of FIG. 7;

FIG. 9 is a plan view of FIG. 7;

FIG. 10 is a sectional view illustrating setting in a height direction.

FIG. 11 is a front view of an apparatus for setting the height direction.

FIG. 12 is a plan view of FIG. 11;

FIG. 13 is a plan view illustrating the structure of a reference device for laying tracks.

FIG. 14 is a side view of FIG. 13 viewed from the side.

FIG. 15 is a plan view illustrating a line laying reference device.

FIG. 16 is a front view showing FIG. 17 in section.

FIG. 17 is a plan view showing an arrangement of line laying reference devices in a straight section.

FIG. 18 is a plan view showing a state of installation of a line laying reference device in a curved section.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 Line laying reference device 10A A reference device 10B B reference device 11 Mounting plate 12A, 12B Bearing piece 13 First screw shaft 14 First moving base 16 Second screw shaft 17 Second moving base 18 Third screw shaft 19 Reference mark Reference Signs List 30 Main frame 31 Engagement part 32 Vertical position adjusting means 33 Index 33F Secondary index 34 Main scale 36 Level 40 Beam 41A to 41C Support screw shaft 42 Level 50 Measurement device 51 Movable rod 52 Display 53 Power switch 54 Zero reset switch

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Koji Kano, Inventor, Japan 2-2-14-2 Nagatacho, Chiyoda-ku, Tokyo Inside the Japan Railway Construction Public Corporation (72) Inventor, Yoshihisa Kaneko 1-2-2, Zofukuji, Suginami-ku, Tokyo (56 References: JP-A-5-240616 (JP, A) JP-A-58-89815 (JP, U) JP-A-5-30705 (JP, U) JP-A-59-567 (JP, Y2)

Claims (6)

(57) [Claims] 1. A mounting plate, a pair of first bearing pieces formed by cutting and raising from the mounting plate, and a first screw rotatably supported between the first bearing pieces. A shaft, a first moving base that is screwed to the first screw shaft and is rotated in the first screw shaft to move in a direction parallel to the first screw shaft, and formed by cutting and raising from the first moving base. A second screw shaft rotatably passed and supported between the pair of second bearing pieces, and a first screw shaft that is screwed to the second screw shaft to rotate the second screw shaft. A second movable table that moves in a direction orthogonal to the screw axis, a third screw axis that has a reference mark formed on the upper end surface and is screwed vertically to the second movable table, and a cant correction provided in the second movable table A line laying reference device setting device for setting a line laying reference device consisting of a screw has an engaging portion on one end side for engaging with a reference mark of the line laying reference device. The other end is supported by vertical position adjusting means for moving the other end in the vertical direction, and a scale indicating the distance L from the reference point of the reference mark is provided between the one end and the other end. A frame, an index plate slidably supported by the main frame and formed with an index formed by a vertical line, a window interrupting the index and formed through the index plate, A reference setting device for laying a track, comprising: a sub-index plate attached to a back side of an index plate on which a sub-index composed of a vertical line is formed; and a transit for observing the index and the sub-index. 2. The line laying standard setting device according to claim 1, wherein a target opposed to the line laying standard on which the transit is installed is set when setting a transit reference line. A standard setting device for laying a track, wherein a main frame is installed in a vessel, and the index and the sub-index are used as targets for setting a transit reference line. 3. The reference setting device for laying a track according to claim 1, wherein the vertical position adjusting means includes the other end of the main frame with respect to an axis of the vertical position adjusting means. A reference line setting device for laying a track, comprising a guide for guiding in a direction perpendicular to the line. 4. The line laying reference device setting device according to claim 1, wherein the vertical position adjusting means has the other end of the main frame with respect to the axis of the vertical position adjusting means. A reference line setting device for laying a track, wherein a pin for receiving the other end of the main frame is provided as a guide for guiding in a direction orthogonal to the line. 5. The line setting reference device setting device according to claim 1, further comprising: a movable base fixed to an arbitrary position of the main frame, wherein the movable base and the index are provided. A reference device setting device for laying a track, comprising a fine movement device inserted between the plate and a fine movement device for finely moving the index plate. 6. The line setting standard setting device according to claim 1, wherein the level setting device is supported at three points by three support screw shafts and has a level. A zero reset switch that has a movable rod that protrudes downward by receiving an eccentric force, has a display that displays the amount of protrusion of the movable rod, and that returns the amount of protrusion to zero. A standard setting device for laying a track, comprising a measuring device having a measuring device supported movably along a beam.