JP4716175B2 - Construction support method and construction support system - Google Patents

Description

  The present invention relates to a construction support method and a construction support system, and in particular, automatically performs a process of presenting and marking an installation position for installing an installation on a predetermined construction target at a construction site, The present invention relates to a technique for correcting a correct installation position in consideration of a design shape and an actual shape.

  For example, in the tunnel construction site 1 represented by the three-dimensional model shown in FIG. 8, the work of attaching the canned product 2 (installed product) as shown in FIG. 9 to the ceiling wall surface with anchor bolts may be performed. Many. Reference numeral 3 is a hole of the anchor bolt, and it is necessary to perform the marking operation for the number of holes. When installing equipment on ceiling walls, side walls, floors, etc. not only at construction sites 1 such as tunnels, but also at general construction sites, the ink marking operation (installation) to determine the anchor bolt driving position for installing the devices in advance Marking to the position) is required.

  The conventional marking operation on the ceiling wall will be described. First, provisional marking is applied to the floor surface position corresponding to the X and Y coordinate positions of the installation position, and then the floor surface is lowered using a lowering / lowering or a laser vertical device. The ceiling wall surface position directly above the marking position was presented, and the worker who was waiting near the ceiling wall surface at this presentation position was marking (marking out).

By the way, in order to automate the inking operation, an autonomously moving inking robot has been proposed (Patent Document 1). The marking robot moves to the floor immediately below the installation position on the ceiling wall surface, and then lifts the marking portion upward to mark the installation position on the ceiling wall surface. As described above, this ink-drawing robot does not need to present the installation position on the ceiling wall surface using a lowering or laser vertical instrument, and also marks the correct installation position even if the design shape and actual shape of the ceiling wall surface are different. There is a merit that you can.
Japanese Patent Laid-Open No. 8-1552

  However, in the conventional ink marking method, the operator operates the swinging down or the laser vertical device, and the worker marks the indicated installation position, so that the efficiency of the ink marking work is poor and it takes time and effort. There's a problem.

  On the other hand, the ink marking robot of Patent Document 1 is a system in which the marking part is moved upward after moving to the floor surface directly below the installation position of the ceiling wall surface. There is a problem that it cannot be used when there is an arrangement. Further, the ink marking robot of Patent Document 1 is a device that marks a ceiling wall surface and cannot cope with marking on a side wall surface.

  Against this background, there is a demand for a construction support method and system that can perform a quick inking operation by automating the installation position presentation to marking, and in particular, the arrangements and installation surfaces present on the floor surface. There is a need for a construction support method and system that can perform the inking process regardless of the inking conditions such as the shape of the ink.

  The present invention has been made in view of such circumstances, and enables automation from presentation of the installation position to marking, and can be performed quickly regardless of the marking conditions such as the arrangement on the floor and the shape of the installation surface. An object of the present invention is to provide a construction support method and a construction support system that can perform a simple marking process.

In order to achieve the above object, the invention according to claim 1 is a construction support method for marking by marking an installation position for installing an installation object on a predetermined construction object at a construction site. Install the 3D measuring instrument at an arbitrary position on the construction site where the installation work of the installation is performed, and coordinate the 3D coordinate system of the 3D measuring instrument with the 3D coordinate system of the installation construction drawing One step of system, an input step of inputting design coordinate information of the installation position in the design drawing to the three-dimensional measuring instrument, and collimating the installation position by the three-dimensional measuring instrument based on the design coordinate information by irradiating Junsaki by the laser pointer, presented as a mark point for marking indicia, and presenting step of measuring the presentation position shown該提 three dimensions, before A position information step for obtaining a position information of the marking robot by three-dimensionally measuring a marking robot movably arranged at a construction site with the three-dimensional measuring instrument, and a three-dimensional presentation position obtained by the three-dimensional measurement. An information transfer step of transferring the coordinate information and the position information of the marking robot to the marking robot, and the marking robot moves to the presentation position based on the transferred three-dimensional coordinate information of the presentation position and the position information of the marking robot. And a marking step of marking a mark at the presentation position. Note that either the input step or the coordinate unification step may be performed first.

According to claim 1 of the present invention, a three-dimensional measuring instrument is installed at an arbitrary position on the construction site where the installation work is performed, and a three-dimensional coordinate system of the design drawing and a three-dimensional measuring system of the three-dimensional measuring instrument on the construction site. Match. The coordinate system coincides by measuring two reference points by aligning the Z-axis of the three-dimensional measuring instrument with the ground axis, and changing the coordinates of the three-dimensional measuring instrument so that they coincide with the two points on the design drawing. When the Z axis of the three-dimensional measuring instrument cannot be aligned with the ground axis, coordinate conversion can be performed by measuring three reference points. Next, design coordinate information of the installation position in the design drawing is input to the three-dimensional measuring instrument. Based on the design coordinate information of the input installation position, the installation position is collimated by a three-dimensional measuring instrument, and the collimation point is irradiated with a laser pointer to present the mark as a mark point for marking. Then, the three-dimensional coordinate information of the presentation position obtained by the three-dimensional measurement and the position information of the robot itself are transferred to the marking robot arranged at the construction site, and the marking robot moves based on the information to provide the presentation position. Mark the mark on

  Thus, since the installation position is directly presented on the ceiling wall surface, for example, by the three-dimensional measuring instrument and the laser pointer, marking can be performed without arranging a marking robot on the floor immediately below the installation position of the ceiling wall surface as in the prior art. In addition, since the installation position information obtained by the three-dimensional measuring instrument and the position information of the robot itself are transferred to the marking robot, automation from presentation to marking becomes possible. Thereby, it is possible to perform a quick inking operation by automating from installation position presentation to marking.

  A second aspect of the present invention is characterized in that, in the input step, the design coordinate information is read into an electronic field book from a CAD drawing, and the read design coordinate information is input to the three-dimensional measuring instrument.

  According to claim 2, the design coordinate information is read from the CAD drawing into the electronic field book, and the read design coordinate information is input to the three-dimensional measuring instrument, so that it is compared with a case where the design drawing information is manually picked up from the design drawing. Therefore, labor can be saved and input time can be shortened.

A third aspect of the present invention provides the correction step according to the first or second aspect, wherein, in the presenting step, when the presentation position coordinate presented by the laser pointer is different from the design coordinate based on the design coordinate information , a correction step is performed to make a match. It is characterized by including. Here, “matching” includes matching within an allowable range.

  When the design shape and the actual shape of the installation surface are different, an error may occur between the presentation position coordinates by the laser pointer and the design coordinates, so a correction step is performed to correct the presentation position and the installation position so as to match. As a result, it is possible to perform an accurate marking operation regardless of the shape of the installation surface.

  According to a fourth aspect of the present invention, in the third aspect of the present invention, in the correction step, the shape of the installation surface of the construction target on which the installation object is installed is virtually set to a plane, an inclined plane, and a curved surface, and the installation position at the design coordinates is A new coordinate position obtained by combining the X and Y coordinate values and the Z coordinate value at which the perpendicular from the X and Y coordinate plane intersects the surface of the virtual shape is used as a corrected installation position.

  The simplest method of correcting the presentation position when the design shape of the installation surface is different from the actual shape is that the X and Y coordinates of the presentation position collimated with a three-dimensional measuring instrument and presented with a laser pointer are X in the design drawing. In this method, the collimation position is changed at a constant interval until it coincides with the Y coordinate. However, in order to achieve practical coincidence, it is necessary to finely set the collimation swing angle, which requires a considerable amount of time.

  On the other hand, in claim 4, the shape of the installation surface of the installation target for installing the installation is virtually assumed to be a plane, an inclined plane, and a curved surface, the X and Y coordinate values of the installation position in the design coordinates, and the X Since the new coordinate position combining the perpendicular from the Y coordinate plane and the Z coordinate value where the virtual shape plane intersects is used as the corrected installation position, the collimation position does not need to be changed finely at regular intervals. Correction in time is possible.

Claim 5 is the claim 3, wherein the correcting step virtually assumes that the shape of the installation surface of the construction target for installing the installation object is a plane, and the Z coordinate value of the presentation position and the X of the design coordinates, A new coordinate position combined with the Y coordinate value is set as a corrected installation position, and the collimation target is irradiated with the laser pointer by collimating with the three-dimensional measuring device based on the corrected installation position coordinate , A first correction step presented as a mark point for marking a mark, a presentation coordinate obtained by three-dimensional measurement of the presentation position presented in the first correction step, and the design coordinate within a permissible range. a first confirmation step of confirming whether the match, the in the case is within the allowable range in the first confirmation step Ma marking robot presentation position presented in the first correction step While King, wherein when it is out of the allowable range in the first confirmation step, first three-dimensional measurement of the shape of the installation surface is collimated on the basis of the design coordinate information and virtual that the inclined plane The virtual shape of the inclined plane is created using the result and the second three-dimensional measurement result collimated in the first correction step, and the X and Y coordinate values of the design coordinates and the X and Y coordinate planes are used. A new coordinate position obtained by combining the Z coordinate value of the coordinates at which the perpendicular line intersects with the inclined plane is set as the second corrected installation position, and the three-dimensional measuring instrument based on the second corrected installation position coordinate by irradiating the collimated target by the laser pointer collimated, three-dimensional and a second correction step of presenting as a mark point for marking indicia, the presentation position presented in the second correction step A second confirmation step of confirming whether measurement and presentation coordinates obtained by said design coordinate match within a tolerance, the second is when it is within the allowable range in the second confirmation step If the marking robot presents a marking position presented in the correction step and is outside the allowable range in the second confirmation step, it is assumed that the shape of the installation surface is a curved surface. The first three-dimensional measurement result collimated based on the information, the second three-dimensional measurement result collimated in the first correction step, and the third three-dimensional measurement result collimated in the second correction step Is used to create a virtual shape of the curved surface and combine the X and Y coordinate values of the design coordinates with the Z coordinate value of the coordinates at which the perpendicular from the X and Y coordinate plane intersects the curved surface position For marking the mark by setting the third corrected installation position and collimating with the three-dimensional measuring device based on the third corrected installation position coordinates and irradiating the collimation tip with the laser pointer A third correction step presented as a mark point, and confirming whether the design coordinates and the presentation coordinates obtained by three-dimensional measurement of the presentation position presented in the third correction step are within an allowable range If it is within the allowable range in the third confirmation step and the third confirmation step, the presenting position presented in the third correction step is marked by the marking robot , and the allowable range in the third confirmation step. If it is outside, the third correction step is repeated until the collimated past three-dimensional measurement result is within an allowable range. That.

  Claim 4 shows the concept of the correction step. Claim 5 shows a specific step for correction.

That is, in the first correction step, a new combination of the Z coordinate value of the presentation position and the X and Y coordinate values of the design coordinates is assumed, assuming that the shape of the installation surface of the construction target for installing the installation object is a plane. A correct coordinate position is used as a corrected installation position, and a collimation point is irradiated with a laser pointer based on the corrected installation position coordinate and presented as a mark point for marking. Check whether the presented position matches the design coordinates within the allowable range. The allowable range is set as appropriate according to the installation accuracy of the installation.

If it is within the allowable range, the marking position is marked by the marking robot, and if it is outside the allowable range, the installation surface shape is assumed to be an inclined plane and further curved surface, and the same operation as in the first step is performed. Do in order. Usually, since the shape of the installation surface is any one of a plane, an inclined plane, and a curved surface, the correction is completed within three times. Thereby, correction can be performed in a short time. In this case, since the result collimated in the first amendment step can be used in the second amendment step, and the result collimated in the first and second amendment steps can be used in the third amendment step. Can be reduced. If even the third correction step does not match, the curved surface shape is changed little by little by repeating the third step.

In order to achieve the above-mentioned object, the invention according to claim 6 is a construction support system for presenting and marking an installation position for installing an installation on a predetermined construction object at a construction site. Installed at an arbitrary position on the construction site where the work is performed, collimates the installation position based on the design coordinate information that is the three-dimensional coordinate of the installation position in the design drawing, and irradiates with a laser pointer with a built-in collimation point By presenting the mark as a mark point for marking, a three-dimensional measuring instrument that three-dimensionally measures the presented presentation position, and a movably arranged on the construction site, transferred from the three-dimensional measuring instrument The marking robot moves to the presentation position based on the three-dimensional coordinate information of the presentation position and its own position information, and marks the presentation position with a stamp. Providing installation support system comprising the and.

  Claim 6 constitutes the present invention as an apparatus, and by combining a three-dimensional measuring instrument and a marking robot, it is possible to perform a quick inking operation by automating from installation position presentation to marking. .

  A seventh aspect of the present invention is characterized in that in the sixth aspect, an electronic field book is provided for reading design coordinate information of the installation position from a CAD drawing and inputting it to the three-dimensional measuring instrument.

  According to claim 7, by providing the electronic field book, the design coordinate information of the installation position can be automatically acquired from the CAD drawing.

  An eighth aspect of the present invention according to the sixth or seventh aspect, wherein the marking robot includes a cart that can move by itself, and a large operation drive unit that is supported on the cart and performs a lifting operation, a turning operation, and a horizontal operation with a large stroke. Supported on the large motion drive unit, and supported on the fine motion drive unit, and a fine motion drive unit that performs a lifting operation, a turning operation, and a horizontal motion with a smaller stroke than the large motion drive unit. A stamp and a control unit for driving and controlling the marking robot are provided.

  According to the present invention, the stamp can be automatically placed near the presenting position presented by the three-dimensional measuring instrument, and the stamp can be highly accurate by providing a large operation drive unit and a fine operation drive unit. Rapid positioning can be performed.

  A ninth aspect according to any one of the sixth to eighth aspects, wherein the marking robot is provided with a positioning target for measuring the position of the marking robot at the construction site with the three-dimensional measuring instrument. It is characterized by.

  According to the ninth aspect, by providing the target in the marking robot, the user's position can be known using the three-dimensional measuring instrument, so that the installation position and the user's position can be compared and moved to the presentation position. . In this case, your position may be replaced with the stamp position.

  According to the construction support method and the construction support system of the present invention, it is possible to perform a quick inking operation by automating from installation position presentation to marking. In addition, a quick inking operation can be performed regardless of various inking conditions such as the arrangement on the floor and the shape of the installation surface such as the ceiling wall surface.

  The best mode for carrying out the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is a conceptual diagram of a construction support system according to the present invention.

  The construction support system 10 is mainly composed of a three-dimensional measuring instrument 12 and a marking robot 14.

  The three-dimensional measuring instrument 12 measures the distance and direction to the collimation target by collimating the target, irradiating the collimation target with laser light or near-infrared light, and receiving and detecting recurring reflected light. And has a function of calculating the three-dimensional coordinates of the collimation destination.

  Here, collimation means changing the direction of the three-dimensional measuring instrument 12 in the set direction, and when looking into the telescope 12A built in the three-dimensional measuring instrument 12, There is an installation position that is a collimation destination. The collimation direction is set by driving means (not shown) built in the three-dimensional measuring instrument 12 based on the three-dimensional coordinate information of the installation position in the design drawing inputted to the three-dimensional measuring instrument 12. The direction of the telescope 12A is automatically changed. Then, the three-dimensional coordinates of the collimation target (presentation position) are obtained by three-dimensional measurement of the collimation target. However, the design shape and actual shape of the installation surface 16 are often different at the construction site, and when the three-dimensional measuring instrument 12 is installed at an arbitrary position as in the present invention, the three-dimensional coordinates of the installation position in the design drawing. And the three-dimensional coordinates of the installation position obtained by measurement with the three-dimensional measuring instrument 12 may be different, and correction is required.

  The three-dimensional coordinate data of the installation position input to the three-dimensional measuring instrument 12 may be manually acquired from a design drawing such as a blue chart and input to the three-dimensional measuring instrument 12, but as shown in FIG. It is preferable to directly acquire from the CAD drawing using the book 18 and automatically input to the three-dimensional measuring instrument 12. Moreover, the electronic field book 18 can also calculate the measurement result in the three-dimensional measuring device 12, and can reflect the result on a CAD drawing.

  The three-dimensional measuring instrument 12 has a built-in laser pointer (not shown), and presents a mark point P for marking with the marking robot 14 by irradiating the collimation tip with the laser pointer.

  As shown in FIGS. 1 and 3, the marking robot 14 is mainly mounted on the self-propelled carriage 20, the large operation drive unit 22 having a large operation stroke, and the operation stroke of the operation stroke. It is composed of a small fine movement drive unit 24.

  In the large operation drive unit 22, an elevator tower 26 is provided on the carriage 20, and a horizontal support base 28 is fixed to the upper end of the elevator tower 26. An arm plate 30 movable in the horizontal direction (A-B direction) is slidably supported on the support 28 and is horizontally driven by an arm plate drive unit (not shown). A fine motion drive unit 24 is provided on the tip of the arm plate 30.

  The fine movement drive unit 24 is provided with a fine movement tower 32, and a horizontal fine movement support base 34 is fixed to the upper end of the fine movement tower 32. On the fine movement support base 34, the fine movement arm plate that is horizontally movable in the same direction (AB direction) as the above-described arm plate 30 and is movable in the horizontal direction (CD direction) perpendicular to the AB direction. 36 is slidably supported and is horizontally moved by a fine movement arm driving section (not shown).

  A cylinder body 40 is provided on the fine movement arm plate 36 via a raising / lowering means 38 (see FIG. 3), and a stamp 44 is held at the tip of a cylinder rod 42 that expands and contracts with respect to the cylinder body 40. As a result, a desired mark (for example, ten characters) is marked with the stamp 44 on the mark point P such as the ceiling wall surface presented by the three-dimensional measuring instrument 12. The stamp 44 has a built-in pressure-sensitive sensor. The stub 44 is pressed against the mark point P with a constant pressure, and the cylinder rod 42 is contracted by detecting the pressure applied by the stamp 44. The expansion / contraction stroke of the cylinder rod 42 is preferably about 20 cm. Further, the raising and lowering means 38 can be switched between the case where the cylinder body 40 is raised and the stamp 44 is turned upright (the state shown in FIGS. 1 and 3) and the case where the cylinder body 40 is turned down and the stamp 44 is turned sideways. It is possible to mark the ceiling wall surface 16 by making it stand upright, and to mark the side wall surface by making it sideways.

  The elevating tower 22 and the fine elevating tower 32 are formed in a rod antenna shape by a plurality of rods formed in a nested structure, and extend and contract in the vertical direction by a built-in drive unit (not shown), and the most advanced rods It can swivel around the axis.

  Further, a control device 46 composed of a CPU (Central Processing Unit) is mounted on the carriage 20 and controls each part of the marking robot 14 in an integrated manner. Further, at least two positions on the lower surface of the fine movement support base are provided with position measurement targets 48, 48, and the position and orientation of the target 48 are three-dimensionally measured by the three-dimensional measuring instrument 12, so that the marking robot 14 Location information can be obtained. The same applies even if the position information of the marking robot 14 is replaced with the position information of the stamp 44. Then, when marking the ceiling wall surface 16, the three-dimensional coordinate information of the installation position and the position information of the marking robot 14 are transferred to the control device 46 of the marking robot 14, and the control device 46 transmits the carriage 20 and the large operation drive unit 22. When the stamp 44 is moved to near the lower part of the mark point P by controlling, the fine movement driving unit 24 is controlled so that the stamp 44 is positioned immediately below the mark point P. Then, the mark point P is marked with the stamp 44.

  A video camera 50 that is linked to the fine movement drive unit 24 is mounted on the fine movement arm plate 36, and the carriage 20 and the large movement drive unit 22 are controlled to move the stamp 44 to the vicinity below the mark point P. Then, the fine motion drive unit 24 may be controlled so that the video camera 50 captures the mark point P and the stamp 44 is directly below the mark point P.

  A weight balance 52 (weight) is suspended below the base end portion of the arm plate 30 and is adjusted so that the weight balance between the tip end and the base end portion of the arm plate 30 is balanced. Further, two wires 54, 54 supported at two positions on the front end portion of the support plate 28 are extended to the vicinity of the base end portion side of the support plate 28 via the guide wheels 56, 56. The balance 58 is suspended and supported. This prevents the elevator tower 26 from falling due to the eccentricity of the arm plate 30 and the arm support base 28 and the cart 20 from falling down, and prevents the arm plate 30 from bending.

  Next, using the construction support system 10 configured as described above, the work flow of the construction support method from the installation position presentation to the marking will be described. The design drawings will be described using an example in which a CAD drawing is used, and an example in which an installation object is installed on the ceiling wall surface 16 (installation surface).

  FIG. 4 is a work flow diagram showing the overall work flow of the construction support method, and FIG. 5 is a work flow diagram illustrating the main work of FIG. 4 in more detail.

  As shown in FIG. 4, an existing CAD drawing produced for construction is used as a design drawing (step 1). The installation position is described in the CAD drawing, and installation position information is extracted (step 2). About this step 2, it is preferable to carry out according to the construction support method of Japanese Patent Application No. 2004-235250 which the present applicant has already applied for. That is, first, a CAD drawing showing a construction target is displayed on a predetermined screen, and a pattern composed of a plurality of specific symbols corresponding to a plurality of black positions (installation positions) is arranged in the displayed CAD drawing. Then, based on a CAD drawing in which such a pattern is arranged, a plurality of black position dimension amounts are obtained based on a predetermined coordinate reference, a list of black position dimension amounts is created, and this list is output. In this case, when there are a plurality of coordinate references, a layer (image layer) is allocated for each coordinate reference, and the dimensional amount of the black position is obtained and output for each layer.

  The three-dimensional coordinate information of the installation position obtained in step 2 is input to the three-dimensional measuring instrument 12 (step 3). As this input method, as shown in FIG. 5, three-dimensional coordinate information of the installation position is read from a CAD device (not shown) into the electronic field book 18 (step 3-1). Then, by connecting the electronic field book 18 to the three-dimensional measuring instrument 12, three-dimensional coordinate information is input to the three-dimensional measuring instrument 12 (step 3-2). In FIG. 5, the connection of the electronic field book 18 to the three-dimensional measuring instrument 12 is performed after the coordinate system one step (step 4-1 to step 4-4) described below. You may go before.

  Next, the three-dimensional measuring instrument 12 is installed at an arbitrary position on the construction site where the installation work is performed, and the three-dimensional coordinate system of the design drawing and the three-dimensional coordinate system of the three-dimensional measuring instrument 12 on the construction site are matched (steps). 4). As shown in FIG. 5, the coordinate system is unified by setting the direction of the coordinate system in the three-dimensional measuring instrument 12 (step 4-1). That is, it is confirmed whether or not the coordinate system of the design drawing is parallel to the ground axis (step 4-2). If it is parallel, two reference points on the site are measured, and the three-dimensional coordinates of the installation position in the design drawing and the site The relationship with the three-dimensional coordinates is matched by coordinate transformation (step 4-2). If they are not parallel, three on-site reference points are measured and matched by coordinate transformation (step 4-4).

  Next, the three-dimensional measuring device 12 collimates the installation position based on the input three-dimensional coordinate information of the installation position, presents the collimation destination with the laser pointer, and three-dimensionally measures the presentation position (step 5). . That is, as shown in FIG. 5, the direction of the telescope 12A of the three-dimensional measuring instrument 12 is changed in the direction of the design value of the installation position, and the installation position (collimation destination) is presented by the built-in laser pointer (step 5-). 1). Thereby, the mark point P to be marked by the marking robot 14 is presented.

  Next, whether or not the three-dimensional coordinates (hereinafter referred to as presentation coordinates) of the presentation position obtained by the three-dimensional measurement 12 are the same as the three-dimensional coordinates (hereinafter referred to as design coordinates) of the installation position obtained from the design drawing. (Step 6). As shown in FIG. 6, there are many architectural deviations between the design shape and the actual shape of the installation surface 16 to be constructed, and the three-dimensional measuring instrument 12 is installed at an arbitrary position on the construction site. This is because the presentation coordinates are different from the design coordinates when collimating obliquely. In FIG. 6, the corrected installation position indicates a correct installation position according to the actual shape. Therefore, as shown in FIG. 5, three-dimensional measurement of the collimated point is performed (step 6-1), and it is confirmed whether or not the difference between the presentation coordinates and the design coordinates is within an allowable range (step 6-2). The allowable value may be set as appropriate depending on the installation accuracy of the installation. As a result of the confirmation, if it is within the allowable range, the presenting position presented by the laser pointer is presenting the correct installation position, and the presenting work for one installation position is completed (step 6-3).

  If it is out of the allowable range, the installation position is corrected according to the architectural displacement as shown in FIG. 4 (step 7). That is, as shown in FIG. 5, the correction amount of the presentation position is calculated based on the measurement value measured by the three-dimensional measuring instrument 12, and the presentation position is corrected. In this case, the correction amount calculation method is changed according to the number of corrections and the shape of the installation surface that is the presentation destination (step 7-1). The principle of this correction method is to confirm whether the installation surface 16 is a ceiling wall surface or a side wall surface (step 7-2), and in the case of the ceiling wall surface, the ceiling wall surface where the plane coordinates (X and Y coordinate values in the design coordinates) match. (Step 7-3), in the case of the side wall surface, the presentation position is set at the position of the side wall surface where the wall surface coordinates (Y, Z coordinate values or X, Z coordinate values in the design coordinates) coincide. Correct (step 7-4).

  The correction step 7-1 will be described in detail with reference to FIG.

  As shown in FIG. 7A, the Z coordinate value of the presentation coordinate and the X of the design coordinate presented in step S-5-1 assuming that the shape of the installation surface of the construction target for installing the installation object is a flat surface. , A new coordinate position combined with the Y coordinate value is set as a corrected installation position. Based on the three-dimensional coordinates of the corrected installation position (hereinafter referred to as the first corrected coordinates), the target is collimated by the three-dimensional measuring instrument 12, the collimation destination is presented with a laser pointer, and three-dimensional measurement is performed (first correction). Step). Then, it is confirmed whether the first-time corrected coordinates and the design coordinates measured three-dimensionally agree within an allowable range (first confirmation step).

  If it is within the allowable range in the first confirmation step, the first correction coordinate is set as the correct correction installation position.

  As shown in FIG. 7B, if it is outside the allowable range, it is assumed that the shape of the installation surface is an inclined plane, and the virtual shape of the inclined plane is determined using the above-described presentation coordinates and the first correction coordinates. A new coordinate position obtained by combining the X and Y coordinate values of the design coordinates and the Z coordinate value of the coordinates at which the perpendicular and the inclined plane from the X and Y coordinate planes intersect is set as a further corrected installation position. . Based on the three-dimensional coordinates of the corrected installation position (hereinafter referred to as the second corrected coordinates), the three-dimensional measuring device 12 collimates, presents the collimation destination with a laser pointer, and performs three-dimensional measurement (second correction step) ). Then, it is confirmed whether the second-time corrected coordinates and the design coordinates measured three-dimensionally match within an allowable range (second confirmation step).

  If it is within the allowable range in the second confirmation step, the first correction coordinate is set as the correct correction installation position.

  As shown in FIG. 7C, when it is outside the allowable range, it is assumed that the shape of the installation surface is a curved surface, and the above-described presentation coordinates, first correction coordinates, and second correction coordinates are used. Create a virtual shape of the curved surface, and further modify and install new coordinate positions that combine the X and Y coordinate values of the design coordinates and the Z coordinate values of the coordinates where the perpendicular from the X and Y coordinate plane and the curved surface intersect Position. Based on the three-dimensional coordinates of the corrected installation position (hereinafter referred to as the third corrected coordinates), the three-dimensional measuring device 12 collimates, presents the collimation destination with a laser pointer, and performs three-dimensional measurement (third correction step) ). Then, it is confirmed whether the third-time corrected coordinates and the design coordinates measured in three dimensions coincide with each other within an allowable range (third confirmation step).

  If it is within the allowable range in the third confirmation step, the third corrected coordinate is set as the correct corrected installation position. If it is out of the allowable range, it is within the allowable range using the collimated past coordinates. The third correction step and the confirmation step are repeated until it becomes.

  As described above, in the present invention, the shape of the installation surface to be installed on which the installation object is installed is virtually assumed to be a plane, an inclined plane, and a curved surface, and the X, Y coordinate values of the design coordinates and the X, Y coordinates Since a new coordinate position obtained by combining the Z-coordinate value at which the perpendicular from the plane and the surface of the virtual shape intersect is used as the correction installation position, it is possible to perform efficient correction in a short time. In this case, the result of collimation in the first correction step can be used in the second correction step, and the result of collimation in the first and second correction steps can be used in the third correction step. Can be reduced.

  When the corrected installation position is determined by the above-described correction step and the point of the installation position by the laser pointer is presented on the ceiling wall (step 8), the three-dimensional coordinate information regarding the corrected installation position and the position information of the marking robot (for example, the carriage reference) Is transferred from the three-dimensional measuring instrument 12 to the controller 46 of the marking robot 14 (step 9). Position information of the marking robot 14 can be obtained by three-dimensionally measuring the target 48 with the three-dimensional measuring instrument 20. Thereby, the control device 46 of the marking robot 14 can control each part of the marking robot 14 by the same coordinate system as the three-dimensional measuring instrument 12. The marking robot 14 moves the carriage 20 by itself to a floor surface position below the installation position based on the transferred three-dimensional coordinates regarding the corrected installation position and its own position information (step 10). In this case, if there is no arrangement of equipment or the like on the floor directly below the corrected installation position presented on the ceiling wall surface, the carriage can be moved to the floor directly below and marked, but as shown in FIG. If there is 60, the carriage 20 is moved close to the object 60.

  Next, the target 48 is again three-dimensionally measured by the three-dimensional measuring instrument 12, and this time, the stamp reference position information is transferred to the control device 46 of the marking robot 14 (step 11). The controller 46 of the marking robot 14 grasps the correct positional relationship between the corrected installation position and the stamp 44, and then controls the fine movement drive unit 24 to move the stamp 44 directly below the installation correction position (step 12). . Then, the control device 46 extends the cylinder rod 42 of the cylinder main body 40 and applies the stamp 44 to the mark point P at the corrected installation position. Thereby, marking is performed (step 13).

  In the present embodiment, in order to obtain the position information of the marking robot 14 as a whole and the position information of the stamp 44, the three-dimensional measuring device 12 performs the three-dimensional measurement by dividing the target 48 twice. Original measurement may be performed to calculate the position information based on the carriage and the position information based on the stamp in the marking robot.

Conceptual diagram of the construction support system of the present invention Explanatory drawing explaining the relationship between 3D measuring instrument and electronic field book Partial enlarged view of marking robot The flowchart explaining the work step of the enforcement support method of this invention The flowchart explaining further in detail the main work in the work step of the enforcement support method of this invention. Explanatory drawing explaining the shift of the presentation position by the design shape and actual shape of the installation surface Explanatory drawing explaining correction steps 3D CAD drawing showing examples of construction objects 3D CAD drawing showing examples of installed objects

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Construction support system, 12 ... Three-dimensional measuring instrument, 14 ... Marking robot, 16 ... Installation surface (ceiling wall surface and side wall surface), 18 ... Electronic field book, 20 ... Dolly, 22 ... Large operation drive part, 24 ... Fine Operational action part, 26 ... Elevating tower, 28 ... Supporting board, 30 ... Arm plate, 32 ... Elevating tower for fine movement, 34 ... Supporting board for fine movement, 36 ... Arm plate for fine movement, 38 ... Lifting means, 40 ... Cylinder body, 42 ... cylinder rod, 44 ... stamp, 46 ... control device, 48 ... target, 50 ... video camera, 52 ... weight balance, 54 ... wire, 56 ... guide wheel, 58 ... weight balance, 60 ... arrangement

Claims (9)

In the construction support method of marking by marking the installation position for installing the installation on a predetermined construction target at the construction site,
A 3D measuring instrument with a built-in laser pointer is installed at an arbitrary position on the construction site where the installation work of the installation is performed, and the 3D coordinate system of the 3D measuring instrument is set to the 3D coordinate of the design drawing of the installation work. A coordinate system step to match the system,
An input step of inputting design coordinate information of the installation position in the design drawing to the three-dimensional measuring instrument;
Based on the design coordinate information, the three-dimensional measuring device collimates the installation position and irradiates a collimation tip with the laser pointer, thereby presenting the mark as a mark point for marking, and the presented presentation A presentation step for measuring the position in three dimensions;
A position information step for obtaining a marking robot position information by three-dimensionally measuring the marking robot movably arranged at the construction site with the three-dimensional measuring instrument;
An information transfer step of transferring the three-dimensional coordinate information of the presentation position obtained by the three-dimensional measurement and the position information of the marking robot to the marking robot;
A marking step in which the marking robot moves to the presentation position and marks the presentation position based on the transferred three-dimensional coordinate information of the presentation position and the position information of the marking robot. Construction support method.   The construction support method according to claim 1, wherein in the input step, the design coordinate information is read from a CAD drawing into an electronic field book, and the read design coordinate information is input to the three-dimensional measuring instrument. 3. The presenting step includes a correction step of correcting the presentation position coordinates presented by the laser pointer and the design coordinates based on the design coordinate information so as to be matched when they are different. Construction support method.   In the correcting step, the shape of the installation surface to be installed on which the installation object is installed is virtually assumed to be a plane, an inclined plane, and a curved surface, the X and Y coordinate values of the installation position in the design coordinates, and the X The construction support method according to claim 3, wherein a new coordinate position obtained by combining a perpendicular from the Y coordinate plane and a Z coordinate value at which the surface of the virtual shape intersects is set as a corrected installation position. The correcting step includes
Assuming that the shape of the installation surface of the construction target for installing the installation object is a plane, a new coordinate position is corrected and installed by combining the Z coordinate value of the presentation position and the X and Y coordinate values of the design coordinates both when the position, by irradiating the collimated target by the laser pointer collimated by the three-dimensional measuring instrument based on the corrected mounting position coordinates, first presented as a mark point for marking indicia Correction steps,
A first confirmation step for confirming whether the presentation coordinates obtained by three-dimensional measurement of the presentation position presented in the first correction step and the design coordinates are within an allowable range;
When it is within the allowable range in the first confirmation step, marking the presentation position presented in the first correction step with a marking robot,
If the first confirmation step is out of an allowable range, the first three-dimensional measurement result collimated based on the design coordinate information assuming that the shape of the installation surface is an inclined plane, and the first The virtual shape of the inclined plane is created using the second three-dimensional measurement result collimated in the correction step of 1, the X and Y coordinate values of the design coordinates, the perpendicular from the X and Y coordinate planes, and the A new coordinate position obtained by combining the Z coordinate value of the coordinates intersecting the inclined plane is set as the second corrected installation position, and collimated by the three-dimensional measuring device based on the second corrected installation position coordinate. Illuminating a collimation tip with the laser pointer to present as a mark point for marking a mark ;
A second confirmation step for confirming whether the presentation coordinates obtained by three-dimensional measurement of the presentation position presented in the second correction step and the design coordinates are within an allowable range;
When it is within the allowable range in the second confirmation step, the presenting position presented in the second correction step is marked with a marking robot,
If the second confirmation step is outside the allowable range, the first three-dimensional measurement result collimated based on the three-dimensional information in the design drawing assuming that the shape of the installation surface is a curved surface; A virtual shape of the curved surface is created using the second three-dimensional measurement result collimated in the first correction step and the third three-dimensional measurement result collimated in the second correction step, and the design coordinates A new coordinate position obtained by combining the X and Y coordinate values and the Z coordinate value of the coordinates at which the perpendicular line from the X and Y coordinate plane and the curved surface intersect is set as the third corrected installation position and the third time A third correction step of presenting a mark as a mark point for marking by irradiating a collimation point with the laser pointer after collimating with the three-dimensional measuring device based on the corrected installation position coordinates ;
A third confirmation step for confirming whether the presentation coordinates obtained by three-dimensional measurement of the presentation position presented in the third correction step and the design coordinates are within an allowable range;
When it is within the allowable range in the third confirmation step, the presenting position presented in the third correction step is marked with a marking robot,
The third correction step is repeated when the third confirmation step is outside the allowable range, and the collimated past three-dimensional measurement result is used to make it within the allowable range. 3. Construction support method. In the construction support system that presents and marks the installation position for installing the installation on a predetermined construction target at the construction site,
It is installed at an arbitrary position on the construction site where the installation work of the installation object is performed, and a collimation point is built in by collimating the installation position based on design coordinate information which is a three-dimensional coordinate of the installation position in a design drawing. By irradiating with a laser pointer, presenting it as a mark point for marking , and a three-dimensional measuring instrument for three-dimensionally measuring the presented presentation position;
Based on the three-dimensional coordinate information of the presentation position and the own position information transferred from the three-dimensional measuring instrument and movably arranged at the construction site, the presentation position is stamped. A construction support system characterized by comprising a marking robot for marking.   7. The construction support system according to claim 6, further comprising an electronic field book for reading design coordinate information of the installation position from a CAD drawing and inputting it to the three-dimensional measuring instrument. The marking robot is
A self-propelled cart,
A large operation drive unit supported on the carriage and performing a lifting operation, a turning operation, and a horizontal operation with a large stroke;
A fine motion drive unit that is supported on the large motion drive unit and performs a lifting operation, a turning motion, and a horizontal motion with a smaller stroke than the large motion drive unit,
A stamp supported on the fine motion drive;
The construction support system according to claim 6, further comprising a control unit that drives and controls the marking robot.   The construction according to any one of claims 6 to 8, wherein the marking robot is provided with a positioning target for measuring the position of the marking robot at the construction site with the three-dimensional measuring instrument. Support system.

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