JP5914012B2 - Concrete wall cleaning equipment - Google Patents

Description

  The present invention relates to a concrete wall surface cleaning apparatus, and more particularly to a concrete wall surface cleaning apparatus capable of cleaning a downward wall surface of a concrete structure by a water jet from below the downward wall surface.

  In recent years, dirt and harmful substances attached to the surface of concrete structures have been removed, the surface of existing concrete has been roughened when concrete is spliced, and the surface of concrete structures has been applied. A method that uses a water jet to clean the walls of concrete structures to remove deteriorated coatings and surface layers of concrete when a coating agent such as a protective agent or water-stopper is applied again. Has been.

  In addition, the water jet is used to clean the walls of concrete structures and other walls using a water jet gun with multiple pressure water injection holes or a small water jet processing device with a vacuum function. However, since operations cannot be performed efficiently by manual operation, the device equipped with the water jet spray nozzle is automatically controlled and the walls of the concrete structure and other walls are used. Various polishing apparatuses that can efficiently perform the above-described polishing work have been developed (see, for example, Patent Document 1, Patent Document 2, and Patent Document 3).

JP-A-9-169000 JP 2000-141354 A JP 2005-254156 A

  On the other hand, for example, water storage tanks that store tap water, rainwater, drainage, etc. are often formed in the ground as large-scale spaces made of concrete structures, but concrete deteriorates or stops due to the effects of stored water. In order to prevent the water from being damaged, a coating agent such as a protective agent or a water-stopping agent is generally applied to cover the concrete surface inside the water tank. Since the coating films of these coating agents also deteriorate due to long-term use of the water storage tank, for the purpose of maintenance, a coating agent is newly added after the lapse of a predetermined period, preferably after removing the deteriorated coating film. It is necessary to re-apply, and when removing the deteriorated coating film, it is conceivable to employ a surface treatment method or a surface treatment apparatus using a water jet.

  However, when the surface of the concrete inside the water tank is cleaned by a water jet, for example, for the upward wall facing upward that constitutes the bottom surface of the water tank, for example, a patent document for cleaning the pavement surface of a road. 2 can be efficiently cleaned from above the upward wall surface using a known apparatus as disclosed in FIG. 2, for example, a concrete structure that constitutes a ceiling surface having a vast area of a water tank It is difficult to efficiently clean the downward wall surface facing the bottom of the object by the work from below by the processing apparatus having the conventional water jet spray nozzle.

  On the other hand, in recent years, various articulated robots that can control the movement of the arm tip along the outer peripheral surface of a three-dimensional solid shape with high accuracy have been developed as industrial robots, for example. By using such an articulated robot, for example, a state in which a water jet spray nozzle attached to the tip of the arm is held along a downward wall surface of the concrete structure with a predetermined interval between the downward wall surface It is considered that the downward wall surface of the concrete structure can be uniformly ground by moving at a predetermined moving speed.

  Further, when the water jet spray nozzle is moved along the downward wall surface of the concrete structure using an articulated robot and the downward wall surface is cleaned, the arm tip at the installation position of one articulated robot is located. Since the moving area is limited to a narrow range, when cleaning up the downward wall surface of a concrete structure with a large area, it is necessary to perform the polishing while re-installing the articulated robot at multiple installation positions. There is.

  However, the installation position of an articulated robot or a device equipped with an articulated robot is not appropriate, the partitioning of the downward wall surface of the concrete structure to be cleaned is not appropriate, and the articulated type at each installation position. If the height position where the robot is placed is not appropriate, or if the multi-joint robot cannot move horizontally at each installation position, the part that has been ground over the same part or the part that has been left behind In particular, the downward wall surface of a concrete structure with a large area may be cleaned in a homogeneous state with high accuracy and efficiency. become unable.

  According to the present invention, an articulated robot and an apparatus including the articulated robot can be easily and smoothly placed at an appropriate installation position and height according to an appropriate division of the downward wall surface of the concrete structure to be cleaned. Using a multi-joint robot with a water jet spray nozzle attached to it, it can be installed and placed on a downward wall surface of a concrete structure with a large area in a homogeneous state with high accuracy. An object of the present invention is to provide a concrete wall polishing treatment apparatus that enables efficient polishing.

The present invention includes a multi-joint robot equipped with a water jet spray nozzle, and is a concrete wall surface polishing apparatus capable of cleaning a downward wall surface of a concrete structure with a water jet from below the downward wall surface. A lower base that is movable along a base surface below a downward wall surface of the concrete structure, an upper base that is movable up and down relative to the lower base, and an upper surface of the upper base The articulated robot in which the robot base is slidably installed along the part, an elevating mechanism provided between the lower base and the upper base, and an upper surface of the upper base A slide movement mechanism of the robot base provided in the section, and the water jet spray nozzle attached to the tip of the arm of the articulated robot. And O over coater jet jig, wherein provided in the upper base, wherein is configured to include a distance sensor for measuring a distance between the downward wall of the concrete structure, the lifting mechanism, the X-shaped It consists of a pantograph type lifter formed by connecting a plurality of unit lifting arms by a pair of arranged arm members in the vertical direction, and the lower ends of the pair of arm members of the unit lifting arms arranged at the bottom can be expanded and contracted The upper end of the pair of arm members of the unit elevating arm disposed at the top is telescopically connected to slide support plates attached to both sides of the lower hydraulic jack. Each of the lower hydraulic jacks is rotatably connected to slide support plates mounted on both sides of the upper hydraulic jack. One of the pair of slide support plates attached to the side and the pair of slide support plates attached to both sides of the upper hydraulic jack is fixed to the upper surface of the lower base or the lower surface of the upper base. And the other is attached so as to be slidable in the extending / contracting direction of the lower hydraulic jack or the upper hydraulic jack along a slide rail laid on the upper surface of the lower base or the lower surface of the upper base. The above-mentioned object is achieved by providing a concrete wall surface polishing treatment apparatus.

  In the concrete wall surface polishing treatment apparatus of the present invention, it is preferable that the lower base is composed of a traveling part and a base part, and an outrigger part is provided so as to be able to project from the base part.

  Further, in the concrete wall surface polishing apparatus of the present invention, it is preferable that the outrigger portion is rotatably joined to the base portion.

  Furthermore, in the concrete wall surface polishing apparatus according to the present invention, the unit elevating arms adjacent vertically are pin-coupled to both connecting ends between the connecting ends of the arm members adjacent vertically. It is preferable that they are connected via a gear plate.

  Further, in the concrete wall surface polishing apparatus of the present invention, the slide moving mechanism is a pair of lower front / rear direction guide rails or lower left / right direction guide rails laid on the upper surface portion of the upper base, and the pair of lower steps. A pair of upper-stage left-right directions on which the robot base of the articulated robot is slidably mounted along the front-rear direction guide rail or the lower-stage left-right direction guide rail. It is preferable to include a guide rail or an upper front / rear direction guide rail.

  According to the concrete wall surface polishing treatment apparatus of the present invention, an articulated robot or an apparatus including the articulated robot is installed in an appropriate installation position according to an appropriate division of the downward wall surface of the concrete structure to be cleaned. Using an articulated robot equipped with a water jet spray nozzle while being installed and arranged easily and smoothly at a high position, especially on the downward wall of a concrete structure with a large area In a homogeneous state, it can be cleaned with high accuracy and efficiency.

It is a side view of the state which extended the raising / lowering mechanism explaining the structure of the concrete wall surface polishing treatment apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. It is a schematic side view explaining the operation | work process of the concrete wall surface erosion processing method using the concrete wall surface erosion processing apparatus which concerns on preferable one Embodiment of this invention. The mechanism which projects an outrigger part is demonstrated, (a) is a top view of a lower base, (b) is a side view of a lower base. (A) is a side view of the raising / lowering mechanism by a pantograph type lifter, (b) is sectional drawing along BB of (a). (A) is the C section enlarged view of Fig.9 (a), (b) is the right view which looked at (a) from the right side. The slide moving mechanism will be described. (A) is a plan view of the upper base, and (b) is a side view of the upper base. The virtual curved surface and the virtual cut surface of the maximum movable region drawn by the articulated robot and the arm tip of the articulated robot will be described. (A) is a schematic top view, and (a) is a schematic side view. is there. It is the A section enlarged view of FIG. 2 explaining a water jet jig provided with a water jet spray nozzle. It is explanatory drawing of a unit construction block and a rectangular construction block. It is explanatory drawing of the condition which grinds the downward wall surface of a concrete structure, reciprocating the arm front-end | tip part to which the water jet injection nozzle was attached.

A concrete wall surface cleaning apparatus 10 according to a preferred embodiment of the present invention shown in FIG. 1 is a large-scale space formed in the ground as a concrete structure, for example, as shown in FIGS. In a water storage tank for storing tap water, rainwater, drainage, etc., a coating film of a protective agent or a waterproofing agent or the like applied to the downward wall 20 of the vast area constituting the ceiling surface of the inside is provided. When it becomes necessary to reapply a coating agent after deterioration due to long-term use of a water storage tank, the downward facing wall surface 20 of the concrete structure is polished with a water jet prior to the operation of applying the coating agent. It is used as an apparatus for sweeping and efficiently removing a coating film deteriorated in a desired scouring state. In addition, the concrete wall surface cleaning apparatus 10 of the present embodiment uses the articulated robot 11 to clean the downward wall surface 20 while moving the water jet spray nozzle 12 along the downward wall surface 20 of the concrete structure. (See FIG. 5). Furthermore, the concrete wall surface cleaning apparatus 10 according to the present embodiment divides the downward wall surface 20 of the concrete structure so that the articulated arm portion 16 of the articulated robot 11 can operate efficiently by a method described later. For each rectangular construction block 22 comprising the unit construction blocks 21 (see FIG. 14), it is possible to easily and smoothly re-install, and the downward wall 20 of the concrete structure is made homogeneous by the articulated robot 11. It has a function that makes it possible to sharpen with high accuracy and efficiency.

  The concrete wall surface cleaning apparatus 10 of the present embodiment includes an articulated robot 11 to which a water jet spray nozzle 12 is attached, and the downward wall surface 20 of the concrete structure is viewed from below the downward wall surface 20. As shown in FIG. 1, the apparatus can be sharpened by a water jet, and as shown in FIG. 1, a lower base 13 that can travel along a base surface 23 below a downward wall surface 20 of a concrete structure, and the lower base 13 An upper base 14 provided so as to be movable up and down, an articulated robot 11 in which a robot base 15 is slidably installed along the upper surface of the upper base 14, a lower base 13 and an upper part A lifting mechanism 17 provided between the base 14 and a slide moving mechanism 18 of the robot base 15 provided on the upper surface of the upper base 14; The distance between the water jet jig 19 having the water jet spray nozzle 12 attached to the arm tip 16a of the articulated robot 11 and the downward wall surface 20 of the concrete structure provided on the upper base 14 is as follows. And a distance sensor 24 to be measured.

In the present embodiment, the lower base 13 of the concrete wall surface cleaning apparatus 10 includes, for example, a caterpillar type traveling unit 25 and a base unit 26 provided to be rotatable with respect to the traveling unit 25 via a turntable. For example, a known mechanism that is substantially the same as a base machine used for a back-for is provided. The base portion 26 of the lower base 13 preferably has a substantially rectangular planar shape, and an elevating mechanism 17 composed of a pantograph lifter for raising and lowering the upper base 14 is provided on the base portion 26. Is provided.

  Further, as shown in FIGS. 8A and 8B, the base part 26 of the lower base 13 can be projected outward from one pair of side parts 26a having a substantially rectangular plane shape. And an outrigger portion 27 is provided. In the present embodiment, four outrigger portions 27 are pivotally connected to the four corner portions of the base portion 26 having a substantially rectangular planar shape. As a result, the outrigger portions 27 are rotated so as to open from the respective side portions 26a of the base portion 26, and the leg portions 27a are extended to be grounded to the base surface 23 outside the running portion 25, and The leg portion 27a is contracted and can be switched between a state in which the leg portion 27a is folded along the side portions 26a and stored in the base portion 26.

  Since the outrigger portion 27 is provided so as to be able to project from the base portion 26 of the lower base 13, the outrigger is provided on the base surface 23 positioned outside the traveling portion 25 at each installation position of the concrete wall surface polishing apparatus 10. By supporting the portion 27, the concrete wall surface cleaning apparatus 10 can be installed on the base surface 23 in a more stable state. Further, since the outrigger portion 27 is rotatably joined to the base portion 26 of the lower base 13, for example, in the direction in which the outrigger portion 27 is projected from the base portion 26, the column of the water storage tank When there is an obstacle such as, by adjusting the opening angle of the outrigger portion 27, the outrigger portion 27 can be projected and supported on the base surface 23 in a state where these obstacles are dodged. .

  In this embodiment, the lifting mechanism 17 provided on the base portion 26 of the lower base 13 and raising and lowering the upper base 14 is, as shown in FIGS. 1, 9A, and 9B, X It is a pantograph type lifter formed by connecting a plurality of unit elevating arms 28 by a pair of arm members 28a arranged in a letter shape in the vertical direction. That is, the pantograph lifter 17 includes a plurality of unit elevating arms 28 that are arranged in an X shape by pin-joining a pair of arm members 28a so as to be rotatable at the center thereof (in this embodiment). 3 in the form) are connected to each other, and the upper and lower connecting ends of the pair of arm members 28a of the unit elevating arms 28 adjacent to each other are connected to each other in a rotatable manner.

  In the present embodiment, the lower ends of the pair of arm members 28a of the unit elevating arm 28 arranged at the lowermost part are attached to the slide support plates 30 attached to both sides of the lower hydraulic jack 29a that can be expanded and contracted. , Each is rotatably connected. The upper ends of the pair of arm members 28a of the unit elevating arm 28 arranged at the uppermost part are respectively coupled to slide support plates 30 mounted on both sides of the upper hydraulic jack 29b that can be expanded and contracted so as to be rotatable. ing. Further, one of the pair of slide support plates 30 attached to both sides of the lower hydraulic jack 29a and the pair of slide support plates 30 attached to both sides of the upper hydraulic jack 29b is one of the upper surface portion and the upper portion of the lower base 13. The lower hydraulic jack 29 a and the upper hydraulic jack are fixed to the lower surface portion of the base 14, and the other is along the slide rail 31 laid on the upper surface portion of the lower base 13 and the lower surface portion of the upper base 14. It is slidably mounted in the expansion / contraction direction of 29b.

  Accordingly, for example, the lower hydraulic jack 29a and the upper hydraulic jack 29b shown in FIG. 2 and FIG. 9 (a) are extended to extend between the lower ends of the pair of arm members 28a of the unit lifting arm 28 arranged at the lowermost position. And the pantograph lifter 17 is folded by lowering the upper base 14 to the lowest position by expanding the space between the upper ends of the pair of arm members 28a of the unit lifting arm 28 arranged at the uppermost position. 1 and FIG. 5, for example, the lower hydraulic jack 29a and the upper hydraulic jack 29b are contracted, and the other slide support plate 30 is slid along the slide rail 31 to be disposed at the bottom. The unit elevating arm 28a is contracted between the lower end portions of the pair of arm members 28a and the unit elevating arm disposed at the uppermost portion. By contracting between the upper end portions of the pair of arm members 28a of the arm 28, the pantograph lifter 17 is extended upward, and the arm tip portion 16a of the articulated robot 11 approaches the downward wall surface 20 of the concrete structure. The upper base 14 is moved up and down with respect to the lower base 13 in a smooth and stable manner while adjusting the amount of expansion and contraction of the lower hydraulic jack 29a and the upper hydraulic jack 29b until the upper base 14 is raised. It can be made to.

  In the present embodiment, as shown in FIG. 9B, the pantograph lifter 17 is disposed along each of a pair of opposite side portions 26b of the base portion 26 having a substantially rectangular planar shape. Thus, a pair is provided on the base portion 26 so as to overlap with each other in the front and back direction of the paper surface of FIG. The pair of pantograph lifters 17 includes, for example, a pair of arm members 28a that form a unit lifting arm 28 in each stage connected in the vertical direction, and a pin joint portion at the center portion and a connecting end portion at the upper or lower end. Are connected via a plurality of span rods 50 mounted across the pair of pantograph lifters 17, so that they can move as a unit.

  Accordingly, the pair of front and back pantograph lifters 17 are folded downward or extended upward in a synchronized state. The upper base 14 is a unit disposed at the uppermost part in the vicinity of the four corners of the upper base 14 having a substantially rectangular planar shape via a slide support plate 30 attached to the lower surface of the upper base 14. The upper and lower ends of the pair of arm members 28a of the elevating arm 28 are respectively connected. As a result, the upper base 14 can be lifted and lowered while being supported in a stable state at the four corners by the pair of front and back pantograph lifters 17.

  Further, in this embodiment, the unit lifting arm 28 constituting the pantograph lifter 17 is an arm member of the unit lifting arm 28 adjacent to the upper and lower sides as shown in FIGS. 10 (a) and 10 (b). Between the connection end parts of the upper end or the lower end of 28a, it is connected in the state which interposed the gear board 32 each pin-joined to both connection end parts. Thus, the upper base 14 can be moved up and down by the pantograph lifter 17 in a more stable state.

  In the present embodiment, the lower base 13 is provided with a controller 51 of the articulated robot 11, an electric control panel 52, a hydraulic tank 53, etc., as shown in FIG.

The upper base 14 supported by the pantograph lifter 17 so as to be movable up and down is preferably substantially similar to the base portion 26 of the lower base 13 as shown in FIGS. 1 and 11A and 11B. It has a rectangular planar shape. As described above, the lower base of the upper base 14 is connected to the slide support plate 30 to which the upper ends of the pair of arm members 28a of the unit elevating arm 28 disposed at the top of the pantograph lifter 17 are coupled, A rail 31 is attached. The upper base 14 is provided with a slide movement mechanism 18 that slides the robot base 15 of the articulated robot 11 in the front-rear direction and the left-right direction, and the slide movement mechanism 18 is interposed therebetween. An articulated robot 11 is installed on the upper surface of the upper base 14.

  In this embodiment, the slide moving mechanism 18 slides in the front-rear direction along a pair of lower front / rear direction guide rails 33 laid on the upper surface of the upper base 14 and the pair of lower front / rear direction guide rails 33. The robot base portion 15 of the articulated robot 11 that is movably provided includes a pair of upper left and right guide rails 34 that are slidably mounted in the left and right directions. Further, the slide moving mechanism 18 is a multi-joint type along the front-rear direction slide drive device 35 that slides the upper-rear direction guide rail 34 in the front-rear direction along the lower-stage front-rear direction guide rail 33 and the upper-stage left-right direction guide rail 34. A left-right direction slide drive device 36 that slides the robot base 15 of the robot 11 in the left-right direction is provided. Thus, the robot base 15 of the articulated robot 11 is installed so as to be slidable in the front-rear direction and the left-right direction along the upper surface of the upper base 14. In this embodiment, the surface passing through the upper surfaces of the pair of upper left and right guide rails 34 is the actual installation surface P0 ′ of the robot base 15 on the upper surface of the upper base 14 (see FIGS. 4 and 5). be able to.

  In the present embodiment, the upper base 14 is provided with a distance sensor 24 that measures the distance from the downward wall surface 20 of the concrete structure. A pair of distance sensors 24 is provided at a substantially diagonal position of the upper base 14 having a substantially rectangular planar shape. By providing a pair of distance sensors 24 arranged substantially diagonally on the upper base 14, the distance between the upper base 14 and the downward wall surface 20 of the concrete structure can be measured more accurately. Is possible. As the distance sensor 24, for example, various distance sensors known as sensors having a function of detecting a reflected wave from a measurement object and measuring the distance to the measurement object can be used. For example, the ultrasonic wave is emitted from the emitting part toward the downward wall surface 20 of the concrete structure, and the ultrasonic wave reflected from the downward wall surface 20 is detected by the wave receiving part, thereby measuring the distance from the downward wall surface 20. Various known ultrasonic distance sensors that can be used are preferably used.

  An articulated robot 11 slidably installed on the upper surface of the upper base 14 is, for example, a known art developed as an industrial robot, as shown in FIGS. 1 and 12A and 12B. It is a robot. The articulated robot 11 has a function capable of moving the arm tip 16a to an arbitrary position in an arbitrary direction and at an arbitrary speed inside the maximum movable region of the arm tip 16a. For example, it has a function that enables the movement of the arm tip along the outer peripheral surface of the three-dimensional solid shape to be controlled with high accuracy. As such an articulated robot 11, for example, a medium-sized handling robot “FANUC Robot M-710iC” (manufactured by FANUC CORPORATION), which is a 6-axis articulated robot, can be preferably used.

  In the present embodiment, the articulated robot 11 includes a robot base 15 and an articulated arm 16, and as described above, the robot base 15 is provided on a slide movement mechanism provided on the upper surface of the upper base 14. 18 is installed so as to be slidable in the front-rear direction and the left-right direction along the upper surface portion of the upper base 14 (see FIGS. 11A and 11B). As a result, the articulated robot 11 raises the upper base 14 and places its arm tip 16a close to the downward wall 20 of the concrete structure (see FIGS. 1 and 5). Inside the maximum movable region of the arm tip portion 16a, the arm tip portion 16a can be moved along the downward wall surface 20 at a predetermined moving speed. In addition, the articulated robot 11 is slid in the front-rear direction and the left-right direction along the upper surface of the upper base 14, so that the arm tip 16 a can be moved at the maximum position at each installation position of the concrete wall surface polishing apparatus 10. Arbitrary position over the entire area of the rectangular construction block 22 (see FIG. 14) composed of a plurality of unit construction blocks 21 set in the downward wall surface 20 of the concrete structure to be described later by expanding the area in the front-rear direction and the left-right direction. In addition, the arm tip 16a to which the water jet spray nozzle 12 is attached can be moved.

  In this embodiment, as shown in FIG. 1, the water jet spray nozzle 12 is attached to the arm tip 16 a of the articulated arm portion 16 of the articulated robot 11 via a water jet jig 19. That is, as shown in FIG. 13, the water jet jig 19 includes a water jet spray nozzle 12 that is rotatable around a rotating shaft 12 a and a cover that surrounds the water jet spray nozzle 12. The body 38 includes a body 38 and a connection base 39 that supports these and is connected to the arm tip 16 a of the articulated robot 11.

  The water jet injection nozzle 12 is a known nozzle member that is used when polishing concrete surfaces or pavement surfaces. In this embodiment, for example, an air motor or an electric motor provided in the water jet jig 19 is used. A plurality of rotating shafts 12a are provided on the rotating shaft 12a so as to extend in the radial direction from the tip of the rotating shaft 12a rotated by the rotation driving device 40. While the water jet spray nozzle 12 is rotated by the rotation of the rotary shaft 12a, high-pressure water pressurized to about 100 to 250 MPa, for example, that is pumped through a high-pressure hose 41 from a high-pressure water supply device (not shown), By spraying toward the downward wall surface 20 of the concrete structure from the injection port at the tip, the downward wall surface 20 is sharpened.

  In this embodiment, the cover body 38 is a flat, hollow, bottomed cylindrical outer body formed of, for example, a stainless steel plate and having an opening surface on the front side, and has a diameter of, for example, about 380 mm and about 170 mm. With a depth of. As described above, for example, a pair of water jet spray nozzles 12 are provided on the inner side of the cover body 38 so as to be rotatably supported by the rotary shaft 12a. The cover body 38 is integrally attached to the connection base 39, and the outer peripheral edge of the cover body 38 protrudes forward from the tip of the cover body 38 so that the peripheral brush member 37 extends over the entire circumference. Attached. Since the peripheral brush member 37 is attached to the entire outer periphery of the opening peripheral portion of the cover body 38, mist generated when the downward wall surface 20 of the concrete structure is cleaned by the water jet is generated by the cover body 38. It is possible to effectively suppress the scattering to the outside. A suction hose (not shown) is connected to the bottom of the cover body 38 for sucking dust, mist, and the like that have been cleaned by a water jet.

  The connection base 39 is a part to which the water jet spray nozzle 12 and the cover body 38 are integrally attached, and serves as a support for connecting these to the arm tip 16 a of the articulated robot 11. The connection base portion 39 includes a rotation joint portion 39a, and is connected to the arm tip portion 16a via the rotation joint portion 39a so as to be capable of rotation control. In addition to the water jet spray nozzle 12 and the cover body 38, the rotation shaft 12a, the rotation drive device 40, and the like are attached to the connection base 39.

  And according to this embodiment, the downward wall surface 20 of a concrete structure is polished as follows using the concrete wall surface polishing treatment apparatus 10 provided with the above-mentioned structure. That is, in this embodiment, first, as shown in FIGS. 12A, 12B, and 14, the maximum movable region drawn by the arm tip 16a of the articulated robot 11 to which the water jet spray nozzle 12 is attached. The virtual curved surface P1 is cut into an outer peripheral shape of the virtual cut surface P3 obtained by cutting a virtual surface P2 parallel to the installation surface P0 located at a predetermined height from the installation surface P0 of the robot base 15. The inscribed rectangular area is defined as a reference block B (see FIGS. 12A and 12B). Based on the rectangular reference block B, the downward wall 20 of the concrete structure is constructed in a plurality of rectangular units. The blocks are divided into blocks 21 (see FIG. 14).

  In addition, a plurality of unit construction blocks included in a region that can be constructed by sliding movement along the upper surface of the upper base 14 of the robot base 15 of the articulated robot 11 (in this embodiment, four unit construction blocks that are arranged vertically and horizontally). For each rectangular construction block 22 composed of unit construction blocks 21) (see FIG. 14), the concrete wall scouring treatment apparatus 10 is moved and moved along the base surface 23 and fixed downward. The wall surface 20 is cleaned (see FIGS. 2 to 7).

  That is, in the present embodiment, at each installation position of the concrete wall surface cleaning apparatus 10, for example, the robot base 15 of the articulated robot 11 is connected to the upper base 14 via the slide moving mechanism 18 as shown in FIG. 14. No. 1 on the right rear side of the upper base 14. In the state of being arranged at position 1, The rectangular wall surface 20 of the rectangular unit construction block 21 can be set to be cleaned by the water jet spray nozzle 12 attached to the arm tip 16a. . In the state of being arranged at position 2, It can be set so that the downward wall surface 20 of the two rectangular unit construction blocks 21 is cleaned by the water jet spray nozzle 12 attached to the arm tip 16a. In the same manner, the No. In the state of being arranged at position 3, The rectangular wall surface 20 of the unit construction block 21 having a rectangular shape 3 can be set to be cleaned by the water jet spray nozzle 12 attached to the arm tip 16a. . In the state of being arranged at the position of No. 4, The rectangular wall surface 20 of the four rectangular unit construction blocks 21 can be set to be cleaned by the water jet spray nozzle 12 attached to the arm tip 16a.

  As shown in FIGS. 2 and 3, each rectangular construction block 22 is subjected to a polishing operation with respect to each rectangular construction block 22 on the downward wall surface 20 of the concrete structure by the concrete wall surface polishing treatment apparatus 10. On the other hand, as a position where the work can be performed, for example, the concrete wall surface scouring treatment apparatus 10 is moved to a portion immediately below the rectangular construction block 22 to be scoured (see FIG. 2), and the base part 26 of the lower base 13 is moved. The outrigger portion 27 is projected from the base wall 23, and the concrete wall surface scouring treatment apparatus 10 is installed in a stable state on the base surface 23 of the portion immediately below (see FIG. 3).

  Thereafter, as shown in FIG. 4, the arm tip 16 a of the articulated robot 11 is attached to the water jet jig 19 by extending the elevating mechanism 17 using a pantograph lifter provided on the base portion 26. In a state where the peripheral brush member 37 is in contact with the downward wall surface 20 of the concrete structure, the upper base 14 is raised until the peripheral brush member 37 is disposed close to the downward wall surface 20 of the concrete structure.

  Here, in this embodiment, when the upper base 14 is raised, the distance sensor 24 provided on the upper base 14 measures the distance between the upper base 14 and the downward wall surface 20 of the concrete structure. Thus, the space between the actual installation surface P0 ′ of the robot base 15 of the articulated robot 11 and the downward wall 20 by the upper surface of the pair of upper left and right guide rails 34 laid on the upper surface of the upper base 14. Can be managed (see FIGS. 4 and 5). The elevation of the upper base 14 is the actual position of the robot base 15 of the articulated robot 11 measured by, for example, the distance sensor 24 as a height position where the articulated arm unit 16 of the articulated robot 11 can operate efficiently. In order for the distance between the installation surface P0 ′ and the downward wall surface 20 of the concrete structure to set the above-mentioned reference block B (see FIGS. 12A and 12B), the articulated robot 11 The virtual curved surface P1 of the maximum movable region drawn by the arm tip 16 is cut off, and the virtual surface P2 is controlled to automatically stop at a height position that matches a predetermined height from the installation surface P0 of the robot base 15. It has become so.

In the present embodiment, when the upper base 14 is raised until the arm tip 16a of the articulated robot 11 is disposed close to the downward wall surface 20 of the concrete structure, the diagonal of the rectangular construction block 22 to be constructed is diagonally formed. A teaching operation is performed to recognize the position as teaching points 43a and 43b (see FIG. 15). The teaching operation can be performed manually, for example, by an operator using a remote controller attached to the articulated robot 11 while viewing the downward wall surface 20. For example, on the upper surface of the upper base 14, the robot base 15 of the articulated robot 11 is connected to the No. 3, after recognizing the teaching point 43 a at the left front corner of the rectangular construction block 22, the robot base 15 of the articulated robot 11 is connected to the right rear No. 3 in FIG. The teaching operation can be performed by moving to the position 1 and recognizing the teaching point 43 b at the right rear corner of the rectangular construction block 22.

  Such teaching operation allows the articulated robot 11 to remember the rectangular construction block 22 of the downward wall surface 20 at each installation position of the concrete wall surface cleaning apparatus 10 as a construction area. The rectangular construction block 22 learned by various programs incorporated in the articulated robot 11 is automatically divided into a plurality of unit construction blocks 21 (four unit construction blocks in this embodiment). Is done. Further, according to various control programs incorporated in the articulated robot 11, for example, on the upper surface of the upper base 14, No. 1 in FIG. 1-No. 4, the robot base 15 is moved to the position 4, and at each moving position, the peripheral brush member 37 is brought into contact with the downward wall surface 20 of the concrete structure as shown in FIG. 5 with respect to each unit construction block 21. On the other hand, the articulated robot 11 is automatically moved by moving the concrete water jet spray nozzle 12 along the downward wall surface 20 at a predetermined movement speed while maintaining a predetermined distance between the concrete water jet injection nozzle 12 and the downward wall surface 20. It is possible to uniformly polish the downward wall surface 20 over the entire rectangular construction block 22 while controlling.

  Further, in this embodiment, the articulated robot 11 has a rectangular unit construction block as shown in FIG. 15 with the arm tip 16a to which the water jet spray nozzle 12 is attached in each unit construction block 21. While reciprocating in the left-right direction parallel to one side of 21, the downward wall surface 20 of the concrete structure is scoured while sequentially sliding at a predetermined pitch p of about 30 cm in the front-rear direction at the end of each reciprocation. It has become.

  Furthermore, in this embodiment, in the unit construction block 21 or the rectangular construction block 22, the arm tip 16a to which the water jet spray nozzle 12 is attached is reciprocated in the left-right direction parallel to one side of the rectangular unit construction block 21. In addition, the downward wall surface 20 of the concrete structure is scoured while sequentially sliding at a predetermined pitch p in the front-rear direction at each end of reciprocation, and a left uncut portion where the predetermined pitch p cannot be obtained on the front end side in the front-rear direction. When the portion is generated, when the next unit construction block 21 or the rectangular construction block 22 adjacent to the front end side in the front-rear direction is constructed, the downward wall surface 20 of the concrete structure is formed using the portion including the uncut portion as a processing region. It has come to be cleaned up.

  For example, when the predetermined pitch p for reciprocating the arm tip 16a in the unit construction block 21 is 30 cm and the width in the front-rear direction of the unit construction block 21 is 100 cm, the width of the unit construction block 21 on the front-end side in the front-rear direction Since an uncut portion of 10 cm is generated, the uncut portion of width 10 cm includes the uncut portion when the next unit construction block 21 adjacent to the front end in the front-rear direction is constructed. The downward wall surface 20 of the object is scoured. In the rectangular construction block 22, when a left uncut portion is generated on the front end side in the front-rear direction of the rectangular work block 22, when the next rectangular work block 22 adjacent to the front end side in the front-rear direction is constructed, The diagonal positions of the included rectangular region are recognized as teaching points 43a and 43b, and the downward wall surface 20 of the concrete structure is polished.

  As a result, according to the present embodiment, the water jet spray nozzle 12 is moved along the downward wall surface 20 of the concrete structure using the articulated robot 11, and the same portion is superposed and cleaned. Further, it is possible to polish the concrete structure downward wall surface 20 with high accuracy and efficiency in a homogeneous state without causing a portion left unpolished.

  As described above, at the installation position of the concrete wall surface cleaning apparatus 10, when the polishing operation of the downward wall surface 20 of the concrete structure with respect to each rectangular construction block 22 is completed, as shown in FIG. The lifting mechanism 17 by the lifter is folded to lower the upper base 14 to the lowermost part, and the outrigger part 27 protruding from the base part 26 is stored in the lower base 13. As a result, the concrete wall surface cleaning apparatus 10 can be moved and moved along the base surface 23, so that the concrete is preferably directly below the next rectangular construction block 22 adjacent to the front end in the front-rear direction. The same process as described above is repeated, in which the wall surface polishing apparatus 10 is moved and the downward wall surface 20 of the next rectangular construction block 22 is cleaned.

  Then, according to the concrete wall surface cleaning apparatus 10 of the present embodiment having the above-described configuration, the concrete wall surface polishing is performed according to, for example, the appropriate division of the downward wall surface 20 of the concrete structure to be cleaned. The articulated robot 11 to which the water jet spray nozzle 12 is attached is installed while the sweeper 10 and the articulated robot 11 are easily and smoothly installed and arranged at an appropriate installation position and height position. It is possible to polish the water storage tank downward wall 20 which is a concrete structure having a large area with high accuracy and efficiency in a homogeneous state.

  That is, the concrete wall surface cleaning apparatus 10 according to this embodiment includes a lower base 13 that can travel along the base surface 23 below the downward wall surface 20 of the concrete structure, and is moved up and down with respect to the lower base 13. An upper base 14 provided in a possible manner, an articulated robot 11 in which a robot base 15 is slidably installed along the upper surface of the upper base 14, a lower base 13, and an upper base 14. Are attached to a lifting mechanism 17 provided between the upper base 14, a slide moving mechanism 18 of the robot base 15 provided on the upper surface of the upper base 14, and an arm tip 16 a of the articulated robot 11. Distance for measuring the distance between the water jet jig 19 provided with the water jet injection nozzle 12 and the downward wall surface 20 of the concrete structure provided on the upper base 14 It is configured to include a Nsa 24.

Therefore, according to the present embodiment, for example, each unit construction block 21 or rectangular construction block divided as described above can be concretely ground so that the articulated arm portion 16 of the articulated robot 11 can operate efficiently. The sweeper 10 can be smoothly moved or re-installed by the lower base 13 that can be moved and moved, and while the distance sensor 24 measures the distance from the downward wall surface 20 of the concrete structure, The upper base 14 can be smoothly raised and raised by the elevating mechanism 17 to a predetermined height position where the arm tip portion 16a of the articulated robot 11 is disposed close to the downward wall surface 20 of the concrete structure. Since the articulated robot 11 can be slid back and forth and left and right on the upper base 14 While the articulated robot 11 is moved quickly and efficiently over a wide area, the water jet spray nozzle 12 attached to the arm tip 16a is applied to the downward wall surface 20 of the concrete structure by the function of the articulated robot 11. Along the downward wall surface 20 of the concrete structure having a particularly large area by moving at a predetermined movement speed while maintaining a predetermined space between the downward wall surface 20 and the downward wall surface 20. Therefore, it is possible to perform the polishing with high accuracy and efficiency in a homogeneous state without causing the portions to be cleaned one after another or causing a portion left uncleaned.

The present invention is not limited to the above-described embodiment, and various modifications can be made. For example , a slide movement mechanism that slides the robot base along the upper surface of the upper base does not necessarily need to be composed of a lower front / rear direction guide rail and an upper left / right direction guide rail. Various slide moving mechanisms may be used. The concrete wall surface polishing treatment apparatus of the present invention is not limited to the downward wall surface of the vast area constituting the ceiling surface of the water tank, but is an apparatus for polishing the downward wall surface of other various concrete structures. The downward wall surface to be processed may not have a vast area.

DESCRIPTION OF SYMBOLS 10 Concrete wall polishing processing apparatus 11 Articulated robot 12 Water jet spray nozzle 13 Lower base 14 Upper base 15 Robot base 16 Articulated arm part 16a Arm tip part 17 Elevating mechanism (pantograph type lifter)
18 Slide movement mechanism 19 Water jet jig 20 Downward wall surface 21 of concrete structure Unit construction block 22 Rectangular construction block 23 Base surface 24 Distance sensor 25 Lower base travel section 26 Lower base base section 27 Outrigger section 28 Unit Elevating arm 33 Lower longitudinal guide rail 34 Upper lateral guide rail 37 Peripheral brush member 38 Cover body 39 Connecting base 50 Span rod

Claims (5)

A concrete wall scouring treatment apparatus comprising an articulated robot equipped with a water jet spray nozzle and capable of scouring a downward wall surface of a concrete structure with a water jet from below the downward wall surface,
A lower base that is movable along a base surface below a downward wall surface of the concrete structure, an upper base that is movable up and down relative to the lower base, and an upper surface of the upper base The robot base is slidably installed along the articulated robot, an elevating mechanism provided between the lower base and the upper base, and an upper surface of the upper base. A slide movement mechanism of the robot base provided; a water jet jig provided with the water jet spray nozzle attached to the tip of the arm of the articulated robot; and the concrete provided on the upper base. It includes a distance sensor that measures the distance between the downward wall surface of the structure ,
The elevating mechanism comprises a pantograph lifter formed by connecting a plurality of unit elevating arms by a pair of arm members arranged in an X shape in the vertical direction,
The lower ends of the pair of arm members of the unit lifting arm arranged at the lowermost part are rotatably connected to slide support plates attached to both sides of the lower hydraulic jack that can be extended and contracted, respectively. The upper ends of the pair of arm members of the unit lifting arm arranged at the top are rotatably connected to slide support plates attached to both sides of the upper hydraulic jack that can be extended and contracted. ,
One of the pair of slide support plates attached to both sides of the lower hydraulic jack and the pair of slide support plates attached to both sides of the upper hydraulic jack is one of the upper surface portion of the lower base and the upper base. While being fixed to the lower surface portion, the other is along the slide rail laid on the upper surface portion of the lower base and the lower surface portion of the upper base, in the expansion and contraction direction of the lower hydraulic jack and the upper hydraulic jack A concrete wall scouring treatment device that is slidably mounted .   2. The concrete wall surface polishing apparatus according to claim 1, wherein the lower base includes a traveling portion and a base portion, and an outrigger portion is provided so as to be able to project from the base portion.   The concrete wall surface polishing apparatus according to claim 2, wherein the outrigger portion is rotatably joined to the base portion. The unit raising / lowering arms adjacent vertically are connected between the connecting ends of the arm members adjacent vertically by interposing gear plates that are respectively pin-coupled to both connecting ends . 4. The concrete wall surface cleaning apparatus according to any one of 3 above. The slide movement mechanism is provided along a pair of lower front / rear direction guide rails or lower left / right direction guide rails and a pair of lower front / rear direction guide rails or lower stage left / right direction guide rails laid on the upper surface of the upper base. It is configured to include a pair of upper left and right guide rails or upper front and rear direction guide rails that are slidably mounted on the articulated robot, which is slidably movable in the front-rear direction and the left-right direction. The concrete wall surface cleaning treatment apparatus according to any one of claims 1 to 4 .

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