阅读说明：本技术 施工装置 (Construction equipment ) 是由 山本道治 长尾知彦 青山均 藤谷雅嘉 竹内伸 武石英人 西山大三 于 2018-12-10 设计创作，主要内容包括：在为了实现车辆侧的驾驶支援控制而用于在道路铺设磁性标识器的施工推车(2)中,在车身(2B)的前后具有将成为磁性标识器的铺设位置的收容孔(108)穿设于路面(100S)的穿孔钻头(21),能够在停车于任一个位置的状态下不移动而在规定间隔的两处穿设收容孔(108),无需为了提高形成铺设位置的该两处收容孔(108)的间隔的精度而执行施工推车(2)的对位等,从而能够实施有效的铺设作业。(In a construction cart (2) for laying a magnetic marker on a road for realizing driving support control on a vehicle side, a piercing drill (21) for piercing a housing hole (108) serving as a laying position of the magnetic marker on a road surface (100S) is provided in the front and rear of a vehicle body (2B), the housing hole (108) can be pierced at two positions with a predetermined interval without moving in a state of being stopped at any position, and alignment of the construction cart (2) and the like are not required to be performed for improving the accuracy of the interval between the two housing holes (108) forming the laying position, so that effective laying work can be performed.)

1. A construction device for laying a magnetic marker on a road, wherein,

the construction device is provided with a working unit for arranging the laying position of the magnetic marker,

the construction device can be provided with the laying position of the magnetic marker at a plurality of positions in a predetermined relative positional relationship without moving.

2. The construction device according to claim 1,

the construction device is provided with a plurality of the working units, and the working units are arranged at the laying positions of the plurality of magnetic markers.

3. The construction device according to claim 1 or 2,

the construction machine is provided with a measurement site for which a relative positional relationship with the working unit is specified, and a positional information acquisition unit for acquiring positional information of the measurement site.

4. The construction device according to any one of claims 1 to 3,

the construction apparatus includes an orientation information acquiring unit that acquires orientation information for specifying an orientation of an arrangement shape of the laying positions of the plurality of magnetic markers.

Technical Field

The invention relates to a construction device for laying a magnetic marker on a road.

Background

Conventionally, there is known a marker detection system for a vehicle, which detects a magnetic marker laid on a road by using a magnetic sensor mounted on the vehicle (see, for example, patent document 1). According to such a marker detection system, various driving assistance such as automatic steering control, lane departure warning, and automatic driving using a magnetic marker laid along a lane can be realized.

Disclosure of Invention

Problems to be solved by the invention

However, the conventional magnetic marker has the following problems. For example, in order to realize driving support such as a lane departure warning, a plurality of magnetic markers need to be laid at short intervals with high positional accuracy, which causes a problem that the construction cost is likely to increase.

The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a construction device for a magnetic marker, which can suppress construction costs by effective construction.

Means for solving the problems

The invention relates to a construction device, which is used for laying a magnetic marker on a road,

the construction device is provided with a working unit for arranging the laying position of the magnetic marker,

the laying position of the magnetic marker can be set at a plurality of positions having a predetermined relative positional relationship without moving.

Effects of the invention

The construction device of the invention can not move and can arrange the laying position of the magnetic marker at a plurality of positions. The accuracy of the relative positional relationship can be relatively easily ensured with respect to the placement positions of a plurality of magnetic markers provided in a state where the construction machine is provided at any one position. When the plurality of magnetic markers are placed at the laying positions, the alignment of the construction apparatus is performed only once. Therefore, according to the construction apparatus of the present invention, the position of laying the magnetic marker can be efficiently set, and the construction cost can be suppressed.

The construction apparatus of the present invention is thus useful for suppressing construction costs by effective construction.

Drawings

Fig. 1 is an explanatory view of a laying work by a construction cart in example 1.

Fig. 2 is a diagram showing a magnetic marker of embodiment 1.

Fig. 3 is a plan view of the construction cart of embodiment 1.

Fig. 4 is a block diagram showing an electrical configuration for realizing inertial navigation of embodiment 1.

Fig. 5 is an explanatory diagram showing the layout specifications of the magnetic marker of example 1.

Fig. 6 is an explanatory diagram of a method of determining a laying position according to embodiment 1.

Fig. 7 is a top view of the construction cart of embodiment 2.

Detailed Description

As the construction device for laying the magnetic marker on the road in the present invention, in addition to the device for laying the magnetic marker on the road, for example, a device which is responsible for a housing hole for inserting the magnetic marker, or a preparation work for laying the magnetic marker such as placing a mark for specifying the laying position on the road surface may be used. The construction device for laying the magnetic marker on the road does not have to complete the laying of the magnetic marker. For example, if the operation of inserting the housing hole is performed without completing the placement of the magnetic marker, the position of the housing hole is determined as the placement position of the magnetic marker.

The following examples are used to specifically describe embodiments of the present invention.

(example 1)

This example is an example of a construction machine that performs work for laying the magnetic marker 10 on a road. This will be described with reference to fig. 1 to 6.

The construction cart 2 of fig. 1 is a construction device at a laying position where a magnetic marker 10 (fig. 2) is provided on a road. The construction cart 2 is configured to locate the position of laying the magnetic marker 10 by inserting the housing hole 108 for housing the magnetic marker 10 into the road surface 100S. The construction cart 2 includes one boring bit (an example of a working unit) 21 for boring the housing hole 108 in each of the front and rear of the vehicle body 2B. According to the construction cart 2, the two receiving holes 108 (placement positions) can be provided without moving.

Here, as shown in fig. 2, the magnetic marker 10 to be constructed is a small marker having a columnar shape with a diameter of 20mm and a height of 28 mm. The magnet forming the magnetic marker 10 is an isotropic ferrite plastic magnet in which magnetic powder of iron oxide as a magnetic material is dispersed in a polymer material as a base material, and has a maximum energy product (BHmax) of 6.4kJ/m³Such a property.

The magnet of the magnetic marker 10 has a magnetic flux density of 45mT (millitesla) on the surface and a magnetic flux density of about 8 μ T at a height of 250mm from the surface. Since the magnet as the isotropic ferrite plastic magnet is made of iron oxide, it is corrosion resistant and does not need to be accommodated in a metal case or the like. The magnetic marker 10 can be laid in a relatively small housing hole 108 (fig. 1) having a diameter of 25 to 30mm and a depth of 35 to 40mm, for example, by being directly housed therein.

As shown in fig. 1, the construction cart 2 is a four-wheeled vehicle including a left and right two-wheeled drive wheel 281 on the front side of the vehicle body 2B and a left and right two-wheeled free wheel 282 on the rear side. The front left and right drive wheels 281 can be driven independently, and the direction of the construction cart 2 can be changed according to the difference in the rotation speed. The left and right rear free wheels 282 can be freely changed in direction according to the direction of the construction cart 2. The construction cart 2 may have a three-wheel structure or a six-wheel structure.

A hand push handle 20 extending rearward beyond the rear drill bit 21 is provided at the rear portion of the body 2B of the construction cart 2. The operator can move the construction cart 2 by pushing the hand push handle 20 while walking. The hand push handle 20 is supported by a cantilever by an operation unit 201 having a sensor, not shown, for sensing an operation force of both hands of the operator. The driving wheel 281 is driven to rotate by an operation force applied to the hand push handle 20, thereby generating a suitable assisting force. Therefore, the operator can move the construction cart 2 with a relatively light force. A display panel (not shown) is attached to the operation unit 201 so as to be visible to the operator, and displays information such as the moving distance of the construction cart 2.

Guide rollers 280 are mounted on the front side of the vehicle body 2B. By using the guide rollers 280, it is easy to visually check whether or not the vehicle body 2B is along the target line, for example. A road counting roller 285 for measuring a moving distance is mounted on the rear side of the vehicle body 2B.

As shown in fig. 1, the construction cart 2 includes, in addition to the above-described front and rear boring heads 21, a generator 251 using light oil as fuel, a driving cylinder 211 for driving the boring head 21 in the vertical direction, a suction cleaner 252 for collecting punch chips and the like, the boring head 21 is driven by the driving cylinder 211 so as to advance and retreat in the vertical direction, and is not displaced in the horizontal direction with respect to the vehicle body 2B, in other words, the position of the boring head 21 in the horizontal plane along the road surface 100S is kept constant with respect to the vehicle body 2B, the front and rear boring heads 21 are positioned on a center line C L (see fig. 3) of the vehicle body 2B, the front and rear boring heads 21 are positioned at positions separated by 1m in the front and rear direction from a center CP of the vehicle body 2B along the center line C L (both spans D1 and D2 are 1m), and therefore, the interval between the front and rear boring heads 21 of the construction cart 2 is 2 m.

The relative positional relationship between the front and rear punches 21 with respect to the center CP of the vehicle body 2B is such that the front punch 21 is 1m forward of the center CP of the vehicle body 2B and the rear punch 21 is 1m rearward of the center CP of the vehicle body 2B. The offset amount (OF 1, OF2 in fig. 1 and 3) indicating the relative positional relationship is set in advance in the arithmetic unit 30 (described later) serving as an example OF the positional information acquisition unit as a parameter indicating the relative position OF the piercing bit 21 with respect to the center CP OF the vehicle body 2B.

As shown in fig. 4, the construction cart 2 includes a gyro compass unit (azimuth information acquisition unit) 36 that measures the azimuth (direction) of the center line C L of the vehicle body 2B, an encoder 37 that detects the rotation amount of the road counter roller 285, and a calculation unit 30 that determines the penetration position of the storage hole 108 that is the placement position of the magnetic marker 10.

The gyro compass unit 36 is a measuring device that measures the north orientation of the measurement object with respect to the reference orientation, and this gyro compass unit 36 uses a gyro effect in which the rotation axis of a gyroscope held horizontally on the surface of the earth on rotation is oriented along the north and south directions, and in the construction cart 2, the gyro compass unit 36 is provided so that the orientation of the measurement object is oriented along the center line C L of the vehicle body, and the gyro compass unit 36 measures the orientation of the center line C L of the vehicle body 2B with respect to the north orientation as the reference orientation, and inputs orientation information indicating the orientation to the arithmetic unit 30.

The arithmetic unit 30 (fig. 4) includes an electronic circuit (not shown) including a cpu (central Processing unit) that executes calculation Processing, a rom (read Only memory) that stores parameters and the like, a ram (random Access memory), and the like. The arithmetic unit 30 specifies the position (absolute position) of the construction cart 2 during the laying work by inertial navigation, and thereby executes arithmetic processing for specifying the penetration position of the housing hole 108 to be the laying position. The position information of the laying position is stored in the database 31 and stored as the laying information of the magnetic marker 10.

The calculation unit 30 calculates the travel distance and the relative position of the construction truck 2 based on the rotation amount input from the encoder 37, the azimuth of the center line C L input from the gyro-compass unit 36, and the like, the travel distance is calculated by multiplying the integrated value of the rotation amounts detected by the encoder 37 by the diameter of the road-counting roller 285, and the like, and the relative position is calculated by integrating the displacement amount (travel distance) at the moment of moving from the reference position at which the absolute position is determined in advance and then integrating the azimuth along the center line C L measured by the gyro-compass unit 36.

Here, the laying work of the magnetic markers 10 is performed by a construction cart (not shown) in which one magnetic marker 10 is disposed in each housing hole 108, a construction cart (not shown) in which the road surface 100S is finished after the disposition of the magnetic markers 10, and the like, in addition to the construction cart 2 of fig. 1 in which the housing holes 108 are bored. The installation cart is an installation device for installing the magnetic marker 10 in the housing hole 108 and supplying a mat material as an adhesive. The construction cart for finish machining of the road surface is a construction device as follows: after the paving material supplied to the receiving hole 108 is solidified, an operation of cutting off excess paving material rising from the periphery to smooth the road surface 100S is performed.

Next, the content of the laying work of the magnetic marker 10 by the construction cart 2 having the above-described configuration will be described.

When the laying work of the magnetic marker 10 is performed, as a preparation, a marker line M L (see fig. 5) as a target line for laying the magnetic marker 10 is formed on the road surface 100 s. the marker line M L can be formed by, for example, a vehicle equipped with a drip device for ink, paint, or the like for marking, and when the vehicle is caused to travel along a travel road such as a construction target lane, the marker line M L as a target line for laying the magnetic marker 10 can be formed.

The operator can manually push the construction cart 2 along the marker line M L to perform the work of piercing the receiving hole 108 that serves as the placement position of the magnetic marker 10, and for example, it is preferable to stop the construction cart 2 every 10M of the travel distance indicated on the display panel, and if the boring bit 21 and the driving cylinder 211 are operated every time the construction cart is stopped, the placement site 10G can be provided along the marker line M L at an interval of 10M in the span S2, as shown in fig. 5, and in this case, it is preferable to individually operate the front and rear boring bits 21 and the like while the construction cart 2 is stopped, and in this case, two adjacent receiving holes 108 (placement positions 10F) can be pierced in each placement site 10G at the span S1 of 2M that matches the span D of the boring bit 21 without moving the construction cart 2.

When starting the movement of the construction cart 2 in order to install the paved area 10G along the road, it is necessary to previously determine the initial position of the construction cart 2 which is the reference position. As a method of determining the reference position, for example, there is a method using a GPS device (not shown) that measures an absolute position in advance using a Global Positioning System (GPS). In an environment where GPS radio waves can be received, the absolute position of the center CP (fig. 1 and 3) of the vehicle body 2B can be measured by providing a GPS antenna at the center CP of the vehicle body 2B, and the absolute position can be determined as a reference position. For example, the reference position may be determined by measuring the absolute position of the center CP of the vehicle body 2B by triangulation using measuring devices (not shown) provided at two positions where the absolute position is determined.

The computing unit 30 calculates the relative position of the construction cart 2 with respect to the reference position by accumulating the displacement amount at each moment based on the rotation amount detected by the encoder 37 along the orientation at each moment of the center line C L of the vehicle body 2B input from the gyro-compass unit 36.

In fig. 6, an arrow V indicates a relative position calculated by the calculation unit 30 when the construction cart 2 performs the laying work for any one of the laying locations 10G. The arithmetic unit 30 adds the relative position indicated by the arrow V to the reference position, thereby specifying the absolute position of the center CP with respect to the construction cart 2 during the laying work.

As described above, the arithmetic unit 30 is preset with parameters indicating the arrangement OF the boring bits 21, such as the offset amount OF the boring bit 21 with respect to the center CP OF the vehicle body 2B (OF 1 is 1m and OF2 is 1m in fig. 6). the arithmetic unit 30 executes the arithmetic operation OF shifting the position along the center line C L OF the vehicle body 2B measured by the gyro compass unit 36 by an amount corresponding to the offset amount as shown in fig. 6. based on the arithmetic operation, the absolute positions OF the boring bits 21 in the front and rear can be determined with reference to the position OF the center CP OF the vehicle body 2B, and if the absolute position OF each boring bit 21 can be determined, the absolute positions OF the two housing holes 108, that is, the absolute position OF the laying position 10F can be determined, and the position information OF the laying position 10F thus determined is stored in the database 31 connected to the arithmetic unit 30 as the laying information OF the magnetic marker 10.

As described above, the construction cart 2 of the present example can set the laying position 10F of the magnetic marker 10 at two places without moving. The interval forming the relative positional relationship between the two laying positions 10F and the span D of the preceding and following drill bits 21 is precisely matched to 2m, and the possibility of variation for each laying position 10G is reduced.

According to the construction cart 2, two adjacent laying positions 10F can be efficiently provided at each laying site 10G at intervals of2 m. When two adjacent laying positions 10F are provided at an interval of 2m, it is not necessary to perform positioning, measurement, and the like of the construction cart 2 for achieving an interval of 2m with high accuracy. Therefore, when the construction cart 2 is used, two laying positions 10F can be efficiently and accurately provided at each laying site 10G, and the construction cost can be suppressed.

In this example, the paving sites 10G are provided every 10m by visual observation by the operator, and the absolute position of the paving position 10F is determined by measuring the position of the construction cart 2 during the paving work. According to such construction, since the man-hours such as measuring the position with high accuracy or positioning the construction cart 2 at a predetermined position with high accuracy are not required, the laying work can be performed extremely efficiently. On the other hand, since the position of the construction cart 2 is measured during the laying work, highly accurate position information can be acquired for each laying position 10F.

Since the construction cart 2 of the present example does not assume measurement by GPS, it can also cope with an environment such as a tunnel in which GPS radio waves cannot be received. For example, in the case of a tunnel, it is preferable to set the reference position by measuring the absolute position of the construction cart 2 at an entrance/exit at which the absolute position can be measured by GPS.

The construction cart 2 is illustrated as including the piercing drills 21 in the front and rear and capable of piercing two receiving holes 108 without moving, but the piercing drills 21 may be only one construction cart, in which case, it is preferable that a plurality of receiving holes 108 are pierced by moving the piercing drills 21 in a horizontal plane along the road surface 100S, and in addition, it is also possible to provide a construction cart including three or more piercing drills 21, in which case, the piercing drills 21 may not be arranged on a straight line, for example, three piercing drills 21 may be provided so as to form a triangle, in which case, by determining the orientation of the center line C L of the vehicle body 2B, the orientation of the triangle forming the arrangement shape of the three laying positions pierced by the three piercing drills 21 can be determined, and the orientation of the triangle can be expressed by, for example, a shift angle from the orientation serving as a reference to a bisector the angle that equally divides any one side or any vertex of the triangle.

In this example, the configuration is illustrated in which the position information indicating the absolute position of each laying position 10F is stored in the database 31 and stored as the laying information of the magnetic marker 10, in addition to the position information of each laying position 10F, orientation information indicating the orientation of a line segment (an example of the arrangement shape) connecting two laying positions 10F of each laying site 10G may be stored together, the orientation of the line segment is in a predetermined relationship (in this example, is matched) with the orientation of the center line C L of the construction cart 2 (vehicle body 2B) during the laying work, and therefore, the direction of travel of the vehicle passing through the two laying positions 10F can be detected with high accuracy based on the orientation of the center line C L measured by the gyro compass unit 36, and the direction (orientation) of the line segment connecting the two laying positions 10F is known during use of the road on which the magnetic marker 10 is laid.

(example 2)

This example is an example in which a GPS unit, which forms an example of a position information acquisition unit, is added to the construction truck of example 1. This will be explained with reference to fig. 7.

As shown in fig. 7, the GPS unit 38 is a unit that receives radio waves from GPS satellites and measures an absolute position. The GPS unit 38 corresponds to measurement by rtk (real Time kinematic) -GPS. The GPS unit 38 performs baseline analysis using a signal received by a fixed station for which an absolute position is determined, and thereby can determine a baseline vector from the fixed station to the GPS unit 38 to measure the absolute position with high accuracy.

The construction cart 2 of the present example includes one GPS unit 38 for measuring an absolute position, and two GPS antennas 381 are connected to the GPS unit 38. The GPS unit 38 measures the absolute position of the installation location of each GPS antenna 381. In this example, since the GPS antennas 381 are attached to the front and rear punches 21 directly above them, the positions of the respective punches 21 serve as measurement positions. In the construction cart 2, two absolute positions measured by the GPS unit 38 are set as the penetration positions of the housing holes 108, that is, the placement positions 10F of the magnetic markers 10.

In the construction cart 2 of the present example, the laying position 10F of the magnetic marker 10 can be specified by GPS in a situation where GPS radio waves can be received, and the laying position 10F of the magnetic marker 10 can be specified by inertial navigation as in example 1 in a situation where the reception situation of GPS radio waves is insufficient. By using the method of determining the laying position separately in this way, the laying work of the magnetic marker 10 including the generation of the laying information of the magnetic marker 10 can be performed more efficiently regardless of the situation.

In example 2, the example in which GPS antenna 381 is attached directly above each of two piercing bits 21 is illustrated, but GPS antenna 381 may be attached directly above only one of two piercing bits 21, and in this case, the absolute position of the other piercing bit 21 may be specified based on the absolute position of one piercing bit 21 measured by GPS, or the absolute position of the other piercing bit 21 may be specified based on the absolute position of one piercing bit 21 by shifting the position along the direction of center line C L of vehicle body 2B measured by a gyro unit, for example.

The other structures and the operational effects are the same as those of embodiment 1.

Specific examples of the present invention have been described in detail as in the examples, but these specific examples merely disclose one example of the techniques included in the technical solutions. It is needless to say that the technical means should not be construed restrictively by the structures, numerical values, and the like of the specific examples. The technical means includes known techniques, and techniques of variously changing, modifying, or appropriately combining the specific examples described above using knowledge of those skilled in the art.

Description of reference numerals:

10 magnetic marker

10F lay position

10G of paving site

108 accommodating hole

2 construction go-cart (construction equipment)

2B vehicle body

20 hand push handle

21 drill (operation unit)

285 road counting roller

30 arithmetic unit (position information acquisition unit)

31 database

36 Gyro compass unit (azimuth information acquisition unit)

37 encoder

38 GPS unit (position information acquisition unit)

381 GPS antenna.