JP6391615B2 - Annular rotary cutter - Google Patents

Description

  The present invention relates to an annular rotary blade such as a hole saw.

  In the present specification, the term “tapping bolt” is a bolt or screw that is screw-joined while forming a female thread in a pilot hole, and is called a thread rolling screw, a thread forming screw, a tapping screw, a tap bolt, or the like. including. The tapping bolt is screwed into a pilot hole in which at least one of the plurality of members is not subjected to female threading, thereby forming a female thread by plastic deformation, and proceeds while screwing and screwing. The tapping bolt may be formed by screwing into the prepared hole, by elastic deformation of the female screw, or by cutting. The directions such as the up and down direction and the left and right direction are directions in the referenced drawings, and are used only for convenience of explanation and are not intended to limit the configuration.

  A method for repairing a steel deck as a bridge floor from the lower surface has been proposed, which eliminates the need to remove asphalt pavement and solves problems such as traffic regulation. An annular rotary knife is required, for example, to carry out this proposed method.

  FIG. 43 is a cross-sectional view showing a state in which the backing plate 3 for repair is bolted to the deck plate 2 of the steel floor slab 1 by the tapping bolt 4 in the method of repairing the steel floor slab 1 from the lower surface. The steel floor slab 1 is configured by asphalt pavement 5 being constructed on the upper surface of a deck plate 2 via a waterproof layer 13. The tapping bolt 4 is driven with a large torque upward from below the steel deck 1 by an impact device such as a hand-held impact driver. In order to obtain the desired strength of the bolt joint, the tapping bolt 4 is inserted into the pilot hole 11 of the backing plate 3 and the pilot hole 12 penetrating through the length equal to the thickness of the deck plate 2 from below the steel deck 1. In the normal posture where the axis of the tapping bolt 4 is on a common straight line of the axes of the pilot holes 11 and 12, the screw must be screwed as shown in FIG.

  45, the drilling machine 7 equipped with the conventional hole saw 8 is mistakenly operated, the hole saw 8 is guided by the pilot hole 11 formed in advance at the factory of the backing plate 3, and the pilot hole 12 of the deck plate 2 is formed. It is sectional drawing which shows the state which drills. The drilling machine 7 is attached to the backing plate 3 by magnetic attraction force, and the operator moves the feed handle by pressing the hole saw 8 against the deck plate 2.

  When trying to drill the pilot hole 12 that penetrates the deck plate 2 by a length equal to the thickness of the deck plate 2, if an operator makes a mistake, the cutting edge 17 of the hole saw 8 is moved to the upper surface of the deck plate 2. The waterproof layer 13 and the asphalt pavement 5 tend to be damaged. It is difficult to operate the drilling machine 7 that cuts only the thickness of the deck plate 2.

  Further, in the conventional drilling machine 7 in FIG. 45, the center pin 14 coaxial with the hole saw 8 protrudes axially outward (upward in FIG. 45) from the cutting edge 17 of the hole saw 8 in the natural state. Contrary to FIG. 45, when the drilling machine 7 is operated in such a posture that the cutting edge 17 is in the downward direction, the tip of the center pin 14 comes into contact with the upper surface of the workpiece, and relative to the hole saw 8 along with the cutting. Thus, a passage for supplying cutting oil from the supply tank by its own weight is formed from closed to open by elastically displacing inward in the axial direction. However, when the drilling machine 50 is operated so that the hole saw 8 faces upward as shown in FIG. 45, the cutting oil supply tank is positioned below the hole saw 8 shown in FIG. Can not be supplied.

  An object of the present invention is to provide an annular rotary cutter capable of forming a cutting hole having a desired depth in a workpiece such as a deck plate of a steel deck.

As shown in FIGS.
An annular rotary cutter 60 that cuts bolt joint holes 23 and 28 having a length L2 equal to the thickness of the deck plate 31 in an upward posture from below the deck plate 31 on the lower surface of the deck plate 31 of the steel deck 30. There,
(A) A blade body 62 having an axis 61,
(A1) A clearance angle is formed in the cutting edge 65,
On the outer periphery, an annular cutting edge portion 63 formed with a discharge groove 68 for guiding chips from the cutting blade 65, and
(A2) A mounting portion 64,
(A2-1) a large-diameter trunk 71 continuous to the cutting edge 63;
(A2-2) a mounting portion 64 that is connected to the large-diameter body portion 71 and includes a mounting shaft portion 72 that is detachably engaged and mounted so as to be rotationally driven around the axis 61;
(A3) The cutting blade 65 extends coaxially with the blade body 62 from the cutting blade 65 in the cutting edge portion 63 to the large diameter body portion 71 inward in the axial direction (below FIGS. 15, 16, 26, 27, and 31). The hollow portion 66 into which the chips 91 cut by the cutting member are formed is formed, and the blade edge portion 63 is cylindrical.
(A4) A blade body 62 in which an attachment hole 67 is formed coaxially with the blade body 62 and formed in the mounting shaft portion 72 so as to pass through the hollow portion 66;
(B) a stopper 80,
(B1) The blade body 62 is inserted into the attachment hole 67, the one end 83 faces the hollow portion 66, the other end 84 is hermetically closed and fixed to the mounting shaft 72 by the weld metal 75, and is fixed to the one end 83. A holding rod 82 engraved with a screw hole facing the outside in the axial direction of the holding rod 82 (above FIGS. 15, 16, 26, 27, and 31);
(B2) an abutting member 85 having an abutting end 81 against which chips 91 entering the hollow portion 66 abut,
(B2-1) a bolt 86 screwed to the screw hole so as to be attachable / detachable;
(B2-2) A spacer 89 provided with a spacer 89 for setting the length L2 of the cutting edge 65 and the abutting end 81 to the thickness of the deck plate 31 for cutting the bolt joint holes 23 and 28 so as to be exchangeable by the bolt 86. A contact member 85;
(B3) A stopper 80 that forms a clearance for cutting oil storage between the inner peripheral surface of the hollow portion 66 and the outer peripheral surface of the stopper 80;
(C) An annular rotary cutter including a cutting oil 77 stored in the hollow portion 66 including the clearance for storing the cutting oil.
The present invention is as shown in FIGS. 26-28, 30, 31 and when reference signs such as FIGS.
On the lower surface of the deck plate 31 of the steel deck 30 is an annular rotary blade 140 that cuts bolt joint holes 23 and 28 having a length L3 equal to the thickness of the deck plate 31 in an upward posture from below the deck plate 31. There,
(A) a blade body 62c having an axis 61c,
(A1) A clearance angle is formed in the cutting edge 65c,
On the outer periphery, an annular cutting edge portion 63c formed with a discharge groove 68 for guiding chips from the cutting blade 65c,
(A2) the attachment portion 64c,
(A2-1) a large-diameter trunk portion 71c connected to the blade edge portion 63c;
(A2-2) having a mounting portion 64c that is connected to the large-diameter body portion 71c and includes a mounting shaft portion 72c that is detachably engaged and mounted so as to be rotationally driven around the axis 61c;
(A3) The cutting edge 65c extends coaxially with the blade body 62c from the cutting edge 65c of the cutting edge portion 63c to the large-diameter barrel 71 inward in the axial direction (below FIGS. 15, 16, 26, 27, and 31). The hollow portion 66c into which the chips 91c cut by the cutting member are formed is formed, and the cutting edge portion 63c is cylindrical.
(A4) a blade body 62c coaxially formed with the blade body 62c and having a mounting hole 67c formed in the mounting shaft portion 72c and penetrating through the hollow portion 66c;
(B) a magnetic attracting body 141 having a magnetic attracting end 145 against which the chip 91c entering the hollow portion 66c comes into contact;
(B1) Inserted into the attachment hole 67c of the cutter body 62c, one end 83c faces the hollow 66c, and the other end 84c is hermetically closed and fixed to the mounting shaft 72c by the weld metal 75c, and is fixed to the one end 83c. A holding rod 82c provided with a screw hole facing outward in the axial direction (above FIGS. 15, 16, 26, 27, and 31);
(B2) a bolt 143 screwed to the screw hole so as to be attachable / detachable;
(B3) a permanent magnet piece 142 provided at one end 83c of the holding rod 82c by a bolt 143;
(B4) having a spacer 144 that can be replaced by a bolt 143, and that sets the length L3 of the cutting edge 65c and the magnetic adsorption end 145 to the thickness of the deck plate 31 that cuts the bolt joint holes 23 and 28;
(B5) A magnetic adsorber 141 that forms a cutting oil storage gap between the inner peripheral surface of the hollow portion 66c and the outer peripheral surface of the magnetic adsorber 141;
(C) An annular rotary cutter including a cutting oil 77 stored in a hollow portion 66c including the cutting oil storage gap.
The present invention is as shown in FIGS. 25-31, and when the reference marks such as FIGS.
The upper end portion of the web 33 of the longitudinal truffle 32 which forms a closed space together with the deck plate 31 is joined to the lower surface of the deck plate 31 of the steel deck 30 by a weld metal 35 extending along the bridge axis direction. An annular rotary cutter 140 that cuts a cutting hole 29 having a length L3 equal to the thickness of the web 33 in an obliquely upward posture from the side (section XXV in FIG. 25),
(A) a blade body 62c having an axis 61c,
(A1) A clearance angle is formed in the cutting edge 65c,
On the outer periphery, an annular cutting edge portion 63c formed with a discharge groove 68 for guiding chips from the cutting blade 65c,
(A2) the attachment portion 64c,
(A2-1) a large-diameter trunk portion 71c connected to the blade edge portion 63c;
(A2-2) having a mounting portion 64c that is connected to the large-diameter body portion 71c and includes a mounting shaft portion 72c that is detachably engaged and mounted so as to be rotationally driven around the axis 61c;
(A3) The cutting edge 65c extends coaxially with the blade body 62c from the cutting edge 65c of the cutting edge portion 63c to the large-diameter barrel 71 inward in the axial direction (below FIGS. 15, 16, 26, 27, and 31). The hollow portion 66c into which the chips 91c cut by the cutting member are formed is formed, and the cutting edge portion 63c is cylindrical.
(A4) a blade body 62c coaxially formed with the blade body 62c and having a mounting hole 67c formed in the mounting shaft portion 72c and penetrating through the hollow portion 66c;
(B) a magnetic attracting body 141 having a magnetic attracting end 145 against which the chip 91c entering the hollow portion 66c comes into contact;
(B1) Inserted into the attachment hole 67c of the cutter body 62c, one end 83c faces the hollow 66c, and the other end 84c is hermetically closed and fixed to the mounting shaft 72c by the weld metal 75c, and is fixed to the one end 83c. A holding rod 82c provided with a screw hole facing outward in the axial direction (above FIGS. 15, 16, 26, 27, and 31);
(B2) a bolt 143 screwed to the screw hole so as to be attachable / detachable;
(B3) a permanent magnet piece 142 provided at one end 83c of the holding rod 82c by a bolt 143;
(B4) having a spacer 144 that can be replaced by a bolt 143, and that sets the length L3 of the cutting edge 65c and the magnetic adsorption end 145 to the thickness of the deck plate 31 that cuts the bolt joint holes 23 and 28;
(B5) A magnetic adsorber 141 that forms a cutting oil storage gap between the inner peripheral surface of the hollow portion 66c and the outer peripheral surface of the magnetic adsorber 141;
(C) An annular rotary cutter including a cutting oil 77 stored in a hollow portion 66c including the cutting oil storage gap.
The present invention
A chip removal device 160 for the above-mentioned annular rotary blades 60, 140,
On the outer end face 93 of the chips 61 and 91c on the outer side of the axes 61 and 61c, there is a flange 168 extending outward in the radial direction depending on the clearance angle of the cutting blades 65 and 65c of the annular rotary blades 60 and 140.
An operation bar 161;
An extraction permanent magnet having an extraction adsorption end 163 that is fixed to one end of the operation rod 161 and magnetically adsorbs to the other end surface 93 facing outward from the cutting blades 65, 65c of the chips 91, 91c entering the hollow portions 66, 66c. Piece 162;
The chip removing device is characterized by including an operation protrusion 166 formed to protrude outward in the radial direction of the operation bar 161 at the other end of the operation bar 161.

  According to the present invention, when the annular rotary blade is rotationally driven to drill a workpiece such as a deck plate, for example, disk-shaped chips enter a hollow portion formed in the blade body. The stopper has a contact end provided in the hollow portion of the blade body. As cutting progresses, the chips that enter the hollow portion come into contact with the contact end provided at a position equal to the depth of the cutting hole inward in the axial direction from the cutting edge, and further cutting is impossible. Thus, a cutting hole having a desired depth is formed in the workpiece. Therefore, when the desired depth is set to the thickness of the workpiece, for example, a through hole cut by the thickness of the workpiece is formed, and the cutting edge at the blade edge portion is only the thickness of the workpiece. It does not cut the object that is cut and further laminated behind it, ie adjacent downstream in the depth direction of the cut. Therefore, when the workpiece is, for example, a deck plate of a steel floor slab and is cut from below, in a later-described embodiment, the magnetic adsorbent of the annular rotary blade 140 and the annular rotary blade 140 described later in the embodiment described later. 141 does not damage the waterproof layer or asphalt pavement on the deck plate.

  According to the present invention, since the position of the abutting end can be adjusted in the axial direction of the blade body, the cutting depth can be changed and set to a predetermined value.

  According to the present invention, the stopper is securely fixed to the blade body, and the axis of rotation of the blade body and the axis of the stopper, and hence the contact end, can be made to coincide with each other in a straight line. Can reliably contact the contact end.

  According to the present invention, the holding rod of the stopper is inserted into the attachment hole of the blade body, and the contact member is provided at one end facing the hollow portion so that the position of the contact end can be adjusted in the axial direction of the blade body. Therefore, the stopper is securely fixed coaxially to the blade body.

  According to the present invention, in a posture in which the drilling machine 50 is operated so that the annular rotary cutter 8 faces upward as shown in FIGS. 7 and 15 described later, the cutting oil supply tank is more than the annular rotary cutter 8 of FIG. Therefore, even if it is not possible to supply the cutting oil by its own weight in the past, for example, the welding metal 75 can store the cutting oil in the hollow portion without flowing downward, and smooth cutting is possible. is there.

  According to the present invention, as will be described later in connection with FIGS. 24 to 32, when the workpiece is made of a ferromagnetic material, the chips are held magnetically attracted to the abutting end, and therefore the chips are removed. It is easy to take out from the cutting hole, and even when no object is present behind the workpiece as shown in FIG. 24, or, for example, a deck plate of a steel floor slab that is a workpiece as shown in FIG. When there is a waterproof layer behind the deck plate that is an object separable from the deck plate, the collection of chips is reliable.

The present invention
A cover member 101 for the cutting device 50,
The cutting device 50
(A) the aforementioned annular rotary blades 60, 140;
(B) an apparatus body 51,
(B1) a mounting portion 52 to which the mounting portions 64 and 64c of the annular rotary blades 60 and 140 are detachably mounted;
(B2) a driving unit 53 that is connected to the mounting unit 52 along the axes 61 and 61c of the cutter main bodies 62 and 62c, and rotationally drives the mounting unit 52 around the axes 61 and 61c;
(B3) an apparatus main body 51 including a support portion 54 that rotatably supports the drive portion 53 around the axes 61 and 61c.
(C) The cover member 101 is
(C1) an end wall portion 102 having an attachment hole 104 through which a part of the annular rotary blade 60, 140 attached to the attachment portion 52 is inserted in the middle in the axial direction from the blade edge portion 63, 63c to the attachment portion 64, 64c;
(C2) having a peripheral wall portion 103 connected to the end wall portion 102 in the axial direction;
(C3) The end wall portion 102 and the peripheral wall portion 103 form a space 105 that covers the attachment portions 64 and 64c, and the mounting portion 52, the drive portion 53, and the support portion 54 in the vicinity of the attachment portions 64 and 64c. And
(C4) It is made of a material having elasticity, and the inner peripheral surface of the mounting hole 104 elastically contacts the outer peripheral surface of the annular rotary cutters 60, 140 and rotates together with the annular rotary cutters 60, 140. It is a cover member for the cutting device to perform.
As shown in FIGS. 1 and 19, the cover member 101 protects the cutting device 50 from chips.

It is sectional drawing which shows a part of cyclic | annular rotary blade 60 for prepared holes for the tapping bolt 20 in one Embodiment of this invention, and the protection apparatus 100 from a chip. It is sectional drawing which shows the state which guides the tapping bolt 20 with the guide apparatus 200 of the tapping bolt 20 of one Embodiment of this invention, and is screwed in. 2 is a cross-sectional view showing a steel deck slab 30 constituting a bridge deck structure of a steel bridge repaired using the guide device 200 of FIG. 2 and the annular rotary blade 60 for drilling a pilot hole and the chip protection device 100 of FIG. is there. It is a flowchart which shows the repair method of one Embodiment of this invention. It is sectional drawing which simplifies and shows a part of steel deck 30, and expands and shows the weld metal 35 vicinity collectively. It is a longitudinal cross-sectional view along the bridge axis direction of the backing plate 40. It is sectional drawing of the steel deck 30 for demonstrating step a2, a3. It is a perspective view which shows the magnetic adsorption | suction holding apparatus 170. FIG. It is a front view of the magnetic adsorption holding device 170. It is a side view of the magnetic adsorption holding device 170. It is the simplified perspective view for demonstrating the principle which switches the magnetic attraction force of the magnetic attraction tool 172 to magnitude. FIG. 11 (1) shows a state where the same magnetic poles of the fixed magnet piece 192 and the moving magnet piece 193 overlap in the direction of the angular displacement axis. FIG. 11B shows a state in which different magnetic poles of the fixed magnet piece 192 and the moving magnet piece 193 overlap in the direction of the angular displacement axis. It is a side view of the magnetic adsorption | suction holding | maintenance apparatus 170a of other form of implementation of this invention. 3 is a perspective view of the entire rotary blade 60. FIG. It is the perspective view seen from the blade edge | tip part 63 of the rotary blade 60. FIG. 3 is a cross-sectional view of a rotary blade 60. FIG. 5 is an enlarged cross-sectional view of a contact member 85. FIG. It is a side view of the protection apparatus 100 which protects the apparatus main body 51 of the drilling machine 50 from a chip. 3 is a plan view of the protection device 100. FIG. 3 is a perspective view of a cover member 101. FIG. It is a perspective view of the chip collection | recovery apparatus 110. FIG. It is a perspective view which shows a part of side plate 112 vicinity of the chip collection | recovery apparatus 110. FIG. It is a figure which shows the magnetic attracting member. FIG. 22 (1) is a front view of the permanent magnet piece 123. FIG. 22 (2) is a cross-sectional view of the permanent magnet piece 123. It is a perspective view which shows the magnetic adsorption member 122. FIG. In step a5, it is sectional drawing which shows the state which drills the bolt insertion hole 138 in the web 33 using the conventional hole saw 137 for reference. It is sectional drawing which shows the state which drills the bolt insertion hole 29 for the hack high strength bolt 230 in the web 33 of the U rib 32 using the annular rotary blade 140 according to this invention, and also shows the expanded section of section XXV. is there. It is sectional drawing of the rotary blade 140. FIG. It is sectional drawing which decomposes | disassembles and shows the rotary blade 140. FIG. It is the front view seen from the blade edge | tip part 63c of the rotary blade 140. FIG. It is sectional drawing which shows the state which completed the drilling of the bolt penetration hole 29 for the hack high strength bolt 230 to the web 33 of the U rib 32 using the rotary blade 140. FIG. It is sectional drawing of the chip removal apparatus 160. FIG. FIG. 30 (1) shows a state in which the chips 91 c are magnetically attracted to the magnetic attraction end 145 in the hollow portion 66 c after cutting the rotary blade 140. FIG. 30 (2) shows an operation of taking out the chips 91 c magnetically attracted to the magnetic adsorption end 145 from the hollow portion 66 c by the chip takeout device 160. It is sectional drawing which shows the use condition of the chip removal apparatus. It is sectional drawing of the chip removal apparatus 160d of other form of implementation of this invention. It is sectional drawing perpendicular | vertical to a bridge axis. It is sectional drawing in alignment with the bridge axis which shows operation which performs the primary fastening in step a6, a9 using the tool 250, and subsequent fastening in step a10 in step a6, a9. It is a perspective view which shows the guide apparatus 200 of the tapping bolt 20 used for driving-in of the tapping bolt 20 in step a8. It is sectional drawing which shows the guide cylinder 211 and the seating part 212. FIG. It is a top view which shows the guide cylinder 211 and the seating part 212. FIG. It is a bottom view showing a guide device 200 including a guide tube 211 and a seating portion 212. It is a figure which shows the permanent magnet piece. FIG. 39 (1) is a plan view of the permanent magnet piece 221. FIG. 39 (2) is a cross-sectional view of the permanent magnet piece 221. FIG. 5 is a cross-sectional view showing a procedure for manually supporting the impact driver 205 and tightening the tapping bolt 20 with the pilot holes 25 and 23 to achieve the support joint between one joining portion 41 of the backing plate 40 and the deck plate 31. FIG. 40 (1) shows a state where the socket 206 to which the tapping bolt 20 is attached is inserted from the free end portion 214 of the guide tube 211 of the guide device 200. FIG. 40 (2) shows a state in which the guide device 200 is moved to one joining portion 41 of the contact plate 40 and the permanent magnet piece 221 is magnetically attracted. FIG. 40 (3) shows a state in which the impact driver 205 is operated and the impact driver 205 is fastened to the pilot holes 25 and 23 with a large impact torque. 3 is a cross-sectional view of the entire hack high-strength bolt 230. FIG. 6 is a simplified cross-sectional view for explaining a part of sequential operations of primary fastening and final fastening of a hack high-strength bolt 230. FIG. FIG. 42 (1) is a cross-sectional view showing a state where the hack high-strength bolt 230 is inserted into the bolt insertion holes 27 and 29 in step a6. FIG. 42 (2) is a cross-sectional view showing a state in which the nut 239 is rotationally driven relative to the pin 234 by the drive units 251 and 252 of the tool 250. FIG. 42 (3) is a cross-sectional view showing a primary tightening state of the hack high-strength bolt 230. FIG. 42 (4) is a cross-sectional view showing a state in which the hack high-strength bolt 230 is finally tightened in step a 10 and the web 33 and the other joining portion 42 are friction-joined. FIG. 3 is a cross-sectional view showing a state in which a repair plate 3 is bolted to a deck plate 2 of the steel floor slab 1 by a tapping bolt 4 in the method of repairing the steel floor slab 1 from the lower surface. It is sectional drawing for demonstrating operation to screw in the tapping bolt shown by the reference marks 4a and 4b accidentally conventionally. A state in which the drilling machine 7 with the conventional hole saw 8 is mistakenly operated, the hole saw 8 is guided by the pilot hole 11 formed in advance in the factory of the backing plate 3, and the pilot hole 12 of the deck plate 2 is drilled. FIG.

  FIG. 1 is a cross-sectional view showing a part of an annular rotary blade 60 for preparing a hole for tapping bolt 20 and a chip protection device 100 according to an embodiment of the present invention. FIG. 2 is a cross-sectional view showing a state in which the tapping bolt 20 is guided and screwed by the guide device 200 for the tapping bolt 20 according to the embodiment of the present invention. FIG. 3 shows a steel deck slab 30 constituting a bridge deck structure of a steel bridge repaired by using the guide device 200 of FIG. It is sectional drawing shown. The steel floor slab 30 of FIG. 3 is configured by stiffening a deck plate 31 made of a steel plate by a vertical truffle 32 having an inverted trapezoidal closed cross section abbreviated as a U-rib. The upper end portion of the web 33 of the U rib 32 is welded to the lower surface of the deck plate 31 by continuous fillet welding of a weld metal 35. A plurality of U ribs 32 are arranged at intervals in the lateral direction of the bridge (left and right direction in FIG. 3). The U rib includes a web 33 and a flange 34. On the deck plate 31, the waterproof layer 36 and the asphalt pavement 37 are constructed in this order.

  When a fatigue crack occurs in the weld metal 35, the weld metal 35 is repaired using the contact plate 40 below the deck plate 31 and outside the U rib 32. In the backing plate 40, one joining portion 41 joined in contact with the lower surface of the deck plate 31 and the other joining portion 42 joined in contact with the outer surface of the web 33 are connected at a curved continuous portion. Composed. One joining portion 41 and the deck plate 31 are supported and joined by a tapping bolt 20 that is applied on one side below the deck plate 31. The other joining portion 42 and the web 33 are friction-joined by a hack high-strength bolt 230 that is applied on one side outside the web 33. As a result, it is not necessary to peel off the waterproof layer 36 and the pavement 37 on the upper surface of the deck plate 31. Therefore, there is no need for traffic regulation and road closure of the traveling vehicle, and a great effort and time are reduced in the construction work.

  FIG. 4 is a flowchart showing a repair method according to an embodiment of the present invention. In repairing, in step a1, first, for example, in order to replace the weld metal 35 in which the bead penetration crack has occurred with the contact plate 40, the weld metal 35 is removed by cutting over the region to be repaired using the contact plate 40.

  FIG. 5 is a cross-sectional view showing a part of the steel deck 30 in a simplified manner, and also shows the vicinity of the weld metal 35 in an enlarged manner. When the steel deck 30 is manufactured in a factory, it is welded in a state where FIG. 5 is turned upside down. Therefore, in the upper part of the web 33 of the U rib 32 in FIG. 5, the inner end 43 abuts on the deck plate 31, and the weld metal 35 is formed together with the deck plate 31 on the outer end, so that the stressed deck plate 31 and U rib are formed. 32 is transmitted by the contact of the inner end portion 43 and the weld metal 35.

The weld metal 35 is cut by the rotary cutting blade 46 by manual operation of the grinder 45 and is removed by cutting. The rotary cutting blade 46 prevents the deck plate 31 from being damaged and prevents the stress concentration of the deck plate 31 from occurring. The inner end 43 of the U rib 32 is not cut by the rotary cutting blade 46 and remains in contact with the deck plate 31.
Next, the backing plate 40 is prepared.

  FIG. 6 is a longitudinal sectional view of the caul plate 40 along the bridge axis direction. In one joint portion 41, a plurality of pilot holes 25 of the tapping bolt 20 and a plurality of temporary fixing bolt insertion holes 26 for temporary fixing bolts are formed at equal intervals in the longitudinal direction of the contact plate 40. The temporary fixing bolt is realized by a tapping bolt, and the shaft portion of the temporary fixing bolt has a smaller diameter than the shaft portion of the tapping bolt 20. As an example, the length of the shaft portion of the temporary fixing bolt is 24 mm, the length of the shaft portion of the tapping bolt 20 is 20 mm, and the shaft portion of the temporary fixing bolt does not protrude from the deck plate 31 to the waterproof layer 36 side. As described above, the spacer is interposed between the head of the temporary fixing bolt and the one joint portion 41 of the contact plate 40. The pilot holes 25 and the temporary fixing bolt insertion holes 26 form one row, and the temporary fixing bolt insertion holes 26 are adjacent to or adjacent to the center position of the row in the row direction (see FIG. 6 (left and right direction of 6), and a plurality of, for example, two are arranged at intervals at symmetrical positions. In the other joint portion 42, bolt insertion holes 27 for the hack high-strength bolts 230 are formed in a row at equal intervals, similarly to the interval in the one joint portion 41.

  In step a2 in FIG. 4, a pilot hole 28 (see FIG. 7) for a temporary fixing bolt to be drilled in the deck plate 31 is positioned.

  FIG. 7 is a cross-sectional view of the steel deck 30 for explaining steps a2 and a3. In step a2, the abutting plate 40 is moved to a position to be repaired, and the joints 41 and 42 are brought into contact with the lower surface of the deck plate 31 and the outer surface of the web 33 of the U rib 32 by the magnetic adsorption holding device 170, respectively. Hold and hold. In step a3, the temporary fixing bolt pilot hole 28 positioned by the temporary fixing bolt insertion hole 26 of the held contact plate 40 is drilled.

  8 is a perspective view showing the magnetic adsorption holding device 170, FIG. 9 is a front view of the magnetic adsorption holding device 170, and FIG. 10 is a side view of the magnetic adsorption holding device 170. The magnetic adsorption holding device 170 includes a magnetic adsorption tool 172 that can switch the magnetic adsorption force of the magnetic adsorption surface 171 between large and small, and a holding body 173 that is attached to one side of the magnetic adsorption tool 172. The holding body 173 can be moved close to and away from the lower surface of the deck plate 31 that is the target surface on which the magnetic attracting surface 171 is magnetically attracted, and the distance L1 (FIG. 9) between the lower surface of the deck plate 31 can be set.

  The holding body 173 includes a bracket 175 protruding outward from one side of the magnetic attracting tool 172, a nut member 176 fixed to the bracket 175, a bolt member 177 screwed into the nut member 176, and a bolt member 177, a pressing piece 178 provided at one end near the lower surface of the deck plate 31, which is the target surface, and a butterfly provided at the other end of the bolt member 177 opposite to the lower surface of the deck plate 31 and operated manually. A shape operation piece 179. The pressing piece 178 includes a supporting piece 181 fixed to one end of the bolt member 177 and a pressing part 182 made of a resilient material such as rubber or synthetic resin fixed to the supporting piece 181 so as to face the lower surface of the deck plate 31. And have. The bracket 175 has a protruding piece 183 and a fixed piece 184 formed in an L shape and is reinforced by ribs 185. A nut member 176 is fixed to the projecting piece 183, and a bolt member 177 is inserted therethrough. The fixed piece 184 is screwed to one side of the magnetic attracting tool 172 by a bolt 186.

  FIG. 11 is a simplified perspective view for explaining the principle of switching the magnetic attraction force of the magnetic attraction tool 172 between large and small. 8 to 11 are shown upside down from the use state of FIG. 7 for convenience of illustration. The magnetic suction tool 172 includes a fixed magnet piece 192 that is fixed to the magnetic suction tool body 191 and a moving magnet piece 193 that can be operated by 180 ° reciprocal angular displacement with respect to the fixed magnet piece 192 by the operation unit 194. The fixed magnet piece 192 and the moving magnet piece 193 are composed of permanent magnets having two NS magnetic poles formed in the circumferential direction around the axis of the angular displacement operation.

  As shown in FIG. 11A, in the state where the same magnetic poles of the fixed magnet piece 192 and the moving magnet piece 193 overlap in the direction of the angular displacement axis 195, a large combined magnetic flux is formed. Therefore, the magnetic attracting surface 171 is attracted to the deck plate 31 with a large magnetic attracting force. Thus, the magnetic attracting surface 171 is attracted to the deck plate 31, and the joining portion 41 of the abutting plate 40 can be pressed against the lower surface of the deck plate 31 and held by the pressing piece 178.

  As shown in FIG. 11B, in the state where the different magnetic poles of the fixed magnet piece 192 and the moving magnet piece 193 overlap in the direction of the angular displacement axis 195, the combined magnetic flux is small or the magnetic flux becomes zero. Therefore, the magnetic adsorption surface 171 can be detached from the deck plate 31. In this manner, the state where the backing plate 40 is held on the lower surface of the deck plate 31 by the magnetic adsorption holding device 170 can be released.

  FIG. 12 is a side view of a magnetic adsorption holding device 170a according to another embodiment of the present invention. This embodiment is similar to the embodiment of FIGS. 8 to 11, and corresponding portions are denoted by the same reference numerals, and the same numerals are denoted by the subscript “a”. It should be noted that in this magnetic adsorption holding device 170a, not only the above-mentioned holding body 173 is fixed to one side portion of the magnetic adsorption tool 172, but also the separation preventing body 196 is fixed to the other opposite side portion. In the detachment prevention body 196, a projecting piece 183a and a fixed piece 184a projecting outward from the other side of the magnetic adsorbing tool 172 are formed in an L shape and are reinforced by ribs 185a. The fixed piece 184a is screwed to the other side portion of the magnetic attracting tool 172 by a bolt 186a. The lower surface in FIG. 12 of the protrusion 183a is flush with the magnetic adsorption surface 171.

  During use, when the pressing piece 178 of the holding body 173 presses and holds the joint portion 41 of the abutting plate 40 against the lower surface of the deck plate 31, a moment is applied to the magnetic attracting tool 172 by the reaction force received by the pressing piece 178. 197 acts. At this time, the detachment prevention body 196 contacts the lower surface of the deck plate 31 on the opposite side (left side in FIG. 12) with respect to the holding body 173, so that the magnetic suction tool 172 falls by the moment 197. This prevents the magnetic adsorption surface 171 of the magnetic adsorption tool 172 from being detached from the lower surface of the deck plate 31. The detachment prevention body 196 may be made of a ferromagnetic material such as steel, which can increase the magnetic attractive force.

  Although the magnetic attraction force of the magnetic attraction / holding devices 170 and 170a depends on the area and the like, it is, for example, 30 to 250 kg, which is a large value. Since the contact plate 40 has a length of 1 m and a weight of 15 kg, for example, according to the magnetic adsorption holding devices 170 and 170a, the burden of the operation of holding the contact plate 40 on the deck plate 31 by the operator can be greatly reduced.

  The magnetic adsorption holding devices 170 and 170a can also be used to hold the other joint portion 42 of the backing plate 40.

  In step a3, as shown in FIG. 7, the thickness of the deck plate 31 is adjusted to the deck plate 31 in the holding state in which the joining portion 41 of the contact plate 40 is in contact with the lower surface of the deck plate 31 by the magnetic adsorption holding device 170 in step a2. The preliminary fixing bolt pilot hole 28 having a length equal to is drilled by an annular rotary blade 60a that is a hole saw of a drilling machine 50 that is a cutting device. The operation of step a3 is similar to the operation of drilling the drilling hole 23 of the tapping bolt 20 through the deck plate 31 with the drilling machine 50 in step a7 to be described later with reference to FIG. 1, and a similar description is repeated. In order to avoid this, the drilling of the pilot hole 23 of the tapping bolt 20 in step a7 will be described.

  As shown in FIG. 1, the drilling machine 50 includes an annular rotary blade 60 that is a hole saw rotated around an axis 61 for drilling the pilot hole 23 of the tapping bolt 20, and an apparatus main body 51. The apparatus main body 51 has a magnetic device 95 for detachably attaching the body 56 to one joint portion 41 of the contact plate 40 with a magnetic attraction force. The apparatus main body 51 includes a mounting portion 52 such as a chuck on which the rotary blade 60 is mounted, an arbor 53 that is a drive unit that rotationally drives the mounting portion 52 around the axis 61, and a support portion 54. The support portion 54 supports the arbor 53 rotatably about the axis 61 and linearly displaces the arbor 53 along the axis 61, and linearly displaces the quill 54 a along the axis 61 and is relative to the body 56. And a quill guide 54b that linearly displaces. The quill guide 54 b is guided along the axis 61 so as to be linearly displaceable by a guide portion 96 constituting a part of the body 56. The quill guide 54b has a projecting portion 97 formed on the cutting blade 65 side (upper side in FIG. 1) with a gap 107 that is smaller than the inner diameter of the guide portion 96.

  The quill guide 54b is provided with an operation shaft 57 that can be angularly displaced. One end portion and the other end portion of the operation shaft 57 are provided so as to protrude forward and rearward in the vertical direction with respect to the paper surface of FIG. 7 and FIG. 17 to be described later, and at each of these end portions, the base end portion of the feed handle 55 is provided. Is detachably attached. A pinion 58 is fixed to the operation shaft 57. The pinion 58 meshes with the rack 94, and the rack 94 is fixed to the body 56. By swinging the feed handle 55, the quill 54a and the quill guide 54b are individually linearly displaced relative to the body 56, thereby increasing the amount of displacement of the arbor 53 relative to the body 56.

  FIG. 13 is a perspective view of the entire rotary blade 60. The rotary blade 60 has a blade body 62 and a stopper 80. The blade main body 62 includes an annular cutting edge portion 63 that is a processing portion that rotates around the axis 61 and cuts, and an attachment portion 64 that is continuous with the cutting edge portion 63 in the direction of the axis 61.

  FIG. 14 is a perspective view of the rotary blade 60 as viewed from the cutting edge portion 63, and FIG. 15 is a cross-sectional view of the rotary blade 60. The blade main body 62 has a disk-shaped chip 91 (in the axial direction inward (leftward in FIG. 13, downward in FIG. 15)) extending from the plurality of cutting edges 65 in the cutting edge portion 63 and cut by the cutting edge 65. A hollow 66 into which FIG. 16) enters is formed. The blade body 62 is formed coaxially with an attachment hole 67 that continues to the hollow portion 66. The cutting edge 65 of the cutting edge portion 63 faces upstream in the rotation direction 76 around the axis 61. The cutting edge portion 63 is formed with a discharge groove 68 for guiding chips from the cutting blade 65, and the end of the discharge groove 68 is continuous with a constricted portion 69 having a circular cross section perpendicular to the axis. The attachment portion 64 has a large-diameter body portion 71 that is continuous with the constricted portion 69, and a mounting shaft portion 72 that is detachably engaged with the mounting portion 52. In the region from the cutting edge 65 to the vicinity of the end of the discharge groove 66, the cutting edge portion 63 has a truncated cone shape that has a truncated cone shape that decreases along the axis 61 as the outer diameter thereof becomes closer to the mounting portion 64. The outer diameter of the constricted portion 69 may be a uniform right circular cylinder shape along the axis 61 or may be a truncated cone shape.

  The stopper 80 is provided on the blade body 62 in the hollow portion 66. In the stopper 80, the length, that is, the depth of the cutting hole which is the pilot hole 23 (FIG. 1) of the tapping bolt 20 drilled in the deck plate 31 inward in the axial direction from the cutting edge 65, that is, the deck plate 31. A contact end 81 is formed at a position equal to the thickness of the contact.

The stopper 80 includes a holding rod 82 and a contact member 85. As clearly shown in FIG. 15 , the holding rod 82 is inserted into the mounting hole 67 formed in the mounting shaft portion 72 , the one end portion 83 faces the hollow portion 66, and the other end portion 84 is the mounting shaft of the mounting portion 64. It is fixed to the free end portion 74 of the portion 72 by fillet welding. The weld metal 75 hermetically closes the gap between the outer peripheral surface of the holding rod 82 connected to the hollow portion 66 and the inner peripheral surface of the attachment hole 67. The contact member 85 has a contact end 81, and is provided at one end 83 of the holding rod 82 so that the position of the contact end 81 can be adjusted in the axial direction of the blade body 62. In the embodiment of FIGS. 26 and 27, the corresponding parts are indicated by adding the suffix c to the same reference numerals.

  FIG. 16 is an enlarged cross-sectional view of the contact member 85. The contact member 85 includes a bolt 86 and a spacer 89. The free end surface of the head 232 of the bolt 86 forms a contact end 81. The shaft portion 88 of the bolt 86 is screwed to the one end portion 83 of the holding rod 82 so as to be attachable and detachable in a screw hole formed coaxially with the axis 61. The contact end 81 is perpendicular to the axis 61. The bolt 86 may be a flat head screw or the like. The spacer 89 is formed in a flat annular shape, is exchangeably inserted into the shaft portion 88 of the bolt 86, and is sandwiched between the head portion 232 of the bolt 86 and the end face of the one end portion 83 of the holding rod 82. The spacer 89 may be a single piece or a plurality of pieces, and the length L2 (FIG. 15) along the axis 61 between the cutting edge 65 and the contact end 81 is the desired depth of the aforementioned cutting hole. The thickness is set so as to be the thickness of the deck plate 31.

  A push rod 59 is provided on the body 56 of the apparatus main body 51 so as to be displaceable in the direction of the axis 61. A spring force is applied to the push rod 59 outward 48 in the direction of the axis 61. 45, when a conventional hole saw 8 is used as shown in FIG. 24 described later, the push rod 59 pushes the center pin 14 that is movable in the hole saw 8 to remove chips 139 after cutting. Discharge outside the hole saw 8. In the embodiment of the present invention, the push rod 59 is elastically brought into contact with the other end portion 84 of the holding rod 82 of the rotary blade 60 and remains stopped.

  In drilling the pilot hole 23 (FIG. 1) of the tapping bolt 20 in the deck plate 31, the rotary blade 60 for the pilot hole 23 is mounted on the drilling machine 50, and the cutting blade 65 is directed upward in the hollow portion 66. Cutting oil 77 (FIG. 15) is put and stored, and then the drilling machine 50 is magnetically placed so that the rotary blade 60 is located directly below the tapping bolt 20 formed in one joint portion 41 of the contact plate 40. It attaches to one joining part 41 of the contact plate 40 with adsorption | suction force. The rotary blade 60 is rotationally driven, guided by the pilot hole 25 of the tapping bolt 20, and moved toward the deck plate 31 by operating the feed handle 55 of the drilling machine 50. The cutting oil 77 rises as indicated by reference numeral 78 (FIG. 15) on the inner peripheral surface of the hollow portion 66 due to the centrifugal force caused by the rotation, thereby enabling smooth cutting.

In the present invention, with the posture in which the rotary blade 60 faces upward, the cutting oil 77 is put in and stored in the hollow portion 66 to solve the problem relating to the supply of the cutting oil in FIG.
The stopper 80 includes a holding rod 82 and a contact member 85, and the contact member 85 includes a bolt 86 and a spacer 89. As clearly shown in FIGS. 15 and 16, the stopper 80 forms a clearance for storing cutting oil between the inner peripheral surface of the hollow portion 66 and the outer peripheral surface of the stopper 80. The cutting oil 77 is stored in the hollow portion 66 including the clearance for cutting oil storage. This cutting oil 77 is shown with hatching in FIG.

  The cutting blade 65 cuts the deck plate 31 upward from the lower surface, and the chips 91 (FIG. 15) enter a hollow portion 66 in a disk shape. When the chip 91 comes into contact with the contact end 81 of the stopper 80, the thickness of the chip 91 is a length L2 between the cutting edge 65 and the contact end 81, and a pilot hole that penetrates by the thickness of the deck plate 31. 23 is formed, and further cutting with the cutting edge 65 becomes impossible. Therefore, the waterproof layer 36 and the pavement 37 on the deck plate 31 are prevented from being damaged by the cutting blade 65 of the rotary blade 60. In another embodiment of the present invention, the contact end 81 may be magnetized so as to be magnetically attracted, and may be realized by a magnetic attracting end 141 in FIG.

  FIG. 17 is a side view of the protection device 100 that protects the device main body 51 of the drilling machine 50 from chips, and FIG. 18 is a plan view of the protection device 100. The protection device 100 includes a cover member 101 and a chip collection device 110. In the cover member 101, chips that fall and scatter from the deck plate 31 due to the cutting operation of the rotary blade 60 enter a gap in a portion where the device main body 51 moves, such as rotation and linear displacement, and inhibit the smooth motion. To prevent. The chip collection device 110 serves to collect chips so that the chips do not deteriorate the environment around the cutting operation.

FIG. 19 is a perspective view of the cover member 101. The cover member 101 has an end wall portion 102 and a peripheral wall portion 103 that is continuous with the end wall portion 102 in the axial direction. The cover member 101 has elasticity such as rubber such as silicon rubber or synthetic resin, and is translucent. Made of a material, manufactured by injection molding and machining. This material must be excellent in heat resistance because it comes into contact with high-temperature chips, and since cutting oil is often used, it is preferable that the material is excellent in oil resistance. An attachment hole 104 through which the constricted portion 69 of the rotary blade 60 is inserted is formed in the end wall portion 102. Due to the expansion and contraction of the end wall portion 102, the rotary blade 60 is inserted into the attachment hole 104 from the cutting blade 65 or from the free end portion 74, and the inner peripheral surface of the attachment hole 104 is elastic to the outer peripheral surface of the constricted portion 69. Therefore, the constricted portion 69 and the cover member 101 rotate integrally, for example, at 1100 rpm. As a result, during cutting, the cover member 101 drops and scatters chips that come into contact with the outer surfaces of the end wall portion 102 and the peripheral wall portion 103 by centrifugal force, and the inside of the space 105 between the end wall portion 102 and the peripheral wall portion 103. Prevents chips from entering.
As clearly shown in FIG. 1 and the like, a part of the cover member 101 in the axial direction from the blade edge portions 63 and 63c of the annular rotary blades 60 and 140 attached to the attachment portion 52 to the attachment portions 64 and 64c is inserted. An end wall portion 102 having a mounting hole 104 and a peripheral wall portion 103 connected to the end wall portion 102 in the axial direction. The end wall portion 102 and the peripheral wall portion 103 form a space 105 that covers the attachment portions 64 and 64c and the portions of the mounting portion 52, the drive portion 53, and the support portion 54 in the vicinity of the attachment portions 64 and 64c.

  In the natural state in which the cover member 101 is stopped together with the rotary blade 60, the inner diameter of the end portion 252a opposite to the end wall portion 102 (downward in FIG. 1) of the peripheral wall portion 103 is the quill guide 54b including the protrusion 97. Therefore, the inner peripheral surface of the end portion 252a and the outer peripheral surface of the quill guide 54b including the protrusion 97 are not in contact with each other, and a gap 109 exists. When the cover member 101 rotates together with the rotary blade 60, the peripheral wall 103 is slightly expanded radially outward by the centrifugal force, and the gap 109 is further expanded. Therefore, the quill including the inner peripheral surface of the end 252a and the protrusion 97 is provided. Contact with the outer peripheral surface of the guide 54b is reliably avoided.

  Since the chips do not enter the space 105 during the rotary cutting of the rotary blade 60, the gap 106 between the quill 54a and the quill guide 54b of the support portion 54, the gap 107 between the quill guide 54b and the guide portion 96 of the body 56, and the arbor, in particular. 53 does not enter the gap 108 between the quill 54a and the like, and does not enter the inside of the mounting portion 52, and the smooth movement of these portions such as rotation and linear displacement is not hindered. Since the cover member 101 has translucency, the operator can observe the inside of the space 105 during the cutting operation.

  FIG. 20 is a perspective view of the chip collection device 110. The chip collection device 110 includes a storage body 111 and magnetic adsorption members 120 to 122 that magnetically attract the storage body 111 to one joining portion 41 of the contact plate 40 on the lower surface of the deck plate 31. The storage body 111 covers the cover member 101 and at least a part of the apparatus main body 51 below the cutting edge portion 63, and stores and collects chips that fall and scatter.

  The storage body 111 has a pair of side plates 112 and 113 arranged on both sides in the axial direction of the peristaltic shaft 57 of the feed handle 55 with respect to the guide portion 96 of the body 56 and an outer side opposite to the guide portion 96 of the body 56 ( 17), an outer end plate 114 connected to the side plates 112 and 113, an inner end plate 115 connected to the side plates 112 and 113 below the body 56, the side plates 112 and 113, the outer end plate 114, and the inner end. The bottom plate 116 connected to the lower end of the plate 115 is combined with the bottom plate 116 to form an internal collection space 117 for storing and collecting chips. The side plates 112, 113, the outer end plate 114, the inner end plate 115, and the bottom plate 116 are realized by light-transmitting synthetic resin plates. Therefore, the operator can enter the collection space 117 and the cover member 101 from the outside. The inside can be observed. The upper end portion 115 a of the inner end plate 115 and the side portions 112 a and 113 a of the side plates 112 and 113 form an opening 118 through which the guide portion 96 of the body 56 enters the collection space 117.

  A reinforcing member 131 made of, for example, metal, which is substantially U-shaped, is fixed to the inner surface facing the recovery space 117 between the upper end portions of the side plates 112 and 113 and the upper end portion of the outer end plate 114. The inner end plate 115 is formed in a closed loop shape on the inner surface facing the recovery space 117 of the upper end portion 115a and the inner surfaces of the side plates 112 and 113 and the outer end plate 114 facing the recovery space 117 at the same position as the upper end portion 115a. For example, a metal reinforcing member 132 is fixed. Similarly, on the bottom plate 116, for example, a metal reinforcing member 133 formed in a closed loop is fixed over each inner surface facing the recovery space 117 of the inner end plate 115, the side plates 112, 113, and the outer end plate 114. Is done. The reinforcing members 131 to 133 are made of, for example, a nonmagnetic material or metal, and prevent chips from being magnetically adsorbed.

  FIG. 21 is a perspective view showing a part near the side plate 112 of the chip collecting device 110. The side plate 112 is formed with a long hole 134 through which the operation shaft 57 of the feed handle 55 is inserted. The long hole 134 is defined to have a vertical length that allows the operation shaft 57 to move up and down in FIG. In order to use the chip collection device 110, the feed handle 55 is once removed, and one end portion of the operation shaft 57 is inserted into the elongated hole 134 from the inside of the collection space 117, and then the proximal end portion of the feed handle 55 is inserted into the operation shaft. Attach to one end of 57. The other side plate 113 is also formed with a long hole 135 similar to the long hole 134, and the other end portion of the operation shaft 57 is inserted therethrough.

  The magnetic attraction member 120 includes a permanent magnet piece 123 disposed on the outer surface opposite to the recovery space 117 at the upper end of the side plate 112, and a bolt that is a countersunk screw for fixing the permanent magnet piece 123 to the outer surface of the side plate 112. 136 and a nut 137 screwed into the bolt 136.

  FIG. 22 is a view showing the magnetic attracting member 120, FIG. 22 (1) is a front view of the permanent magnet piece 123, and FIG. 22 (2) is a sectional view of the permanent magnet piece 123. The permanent magnet piece 123 has a rectangular flat plate shape, for example, a square, and the bolt insertion hole 128 is dished. The upper end surface 123a of the permanent magnet piece 123 is in one virtual plane together with the upper end surfaces of the side plate 112 and the reinforcing member 131. Therefore, the upper end surface 123a of the permanent magnet piece 123 is in surface contact with one of the joint portions 41 of the backing plate 40 on the lower surface of the deck plate 31 together with the upper end surfaces of the side plate 112 and the reinforcing member 131, and is strong by magnetic attraction force. Mounted on. The magnetic attracting member 121 is also fixed to the side plate 113 in the same manner as the magnetic attracting member 120.

  FIG. 23 is a perspective view showing the magnetic attracting member 122. The magnetic attracting member 122 is configured in the same manner as the magnetic attracting member 120 and is given the same reference numerals. The magnetic attraction member 122 is fixed to the outer end plate 114, and the upper end surface 123a of the magnetic attraction member 122 is in one imaginary plane together with the upper end surfaces of the outer end plate 114 and the reinforcing member 131. 31 is in surface contact with one of the joint portions 41 of the backing plate 40 on the lower surface of 31 and is firmly attached by magnetic attraction force.

  In step a4 in FIG. 4, a temporary fixing bolt is driven to frictionally bond the deck plate 31 and the joint 41. As shown in FIG. 7, the temporary fixing bolt is inserted into the temporary fixing bolt insertion hole 26 formed in one joint portion 41 of the backing plate 40, and is threaded into the temporary fixing bolt lower hole 28 drilled in step a3. While proceeding, it is screwed and joined.

  In step a5, a bolt insertion hole 29 (for a hack high-strength bolt 230 having an axis line with the bolt insertion hole 27 formed in the other joint portion 42 of the backing plate 40 is formed in the web 33 of the U rib 32. 2 is drilled in FIG.

  FIG. 24 is a sectional view showing, for reference, a state in which the bolt insertion hole 138 is drilled in the web 33 using the conventional hole saw 137 in step a5. According to the conventional hole saw 137, the disk-shaped chip 139 falls into the space in the U rib 32 and remains, cannot be recovered, and is left as it is. The left chips 139 are rusted by air, moisture and the like. One embodiment of the present invention solves this problem.

  FIG. 25 is a cross-sectional view showing a state in which the bolt insertion hole 29 for the hack high-strength bolt 230 is drilled in the web 33 of the U-rib 32 using the annular rotary blade 140 according to the present invention, and an enlarged section XXV. A cross section is also shown. In the drilling machine 50 shown in FIG. 25, the apparatus main body 51 rotates and feeds the annular rotary blade 140 to drill the bolt insertion hole 29.

  26 is a cross-sectional view of the rotary blade 140, and FIG. 27 is an exploded cross-sectional view of the rotary blade 140. The rotary blade 140 is partially similar to the rotary blade 60 described above, and corresponding portions are indicated by adding the suffix c to the same numerals to simplify the description. The rotary blade 140 has a blade body 62c and a magnetic attracting body 141. The blade body 62c includes an annular blade edge portion 63c that is a processing portion that rotates around the axis 61c and cuts, and an attachment portion 64c that is continuous with the blade edge portion 63c in the direction of the axis 61c.

  The blade main body 62c has a disk-shaped chip 91c (described later) that extends inward in the axial direction (downward in FIGS. 26 and 27) from the plurality of cutting blades 65c in the cutting edge portion 63c and is cut by the cutting blade 65c. A hollow portion 66c into which 29) enters is formed. The blade body 62c is formed coaxially with an attachment hole 67c extending to the hollow portion 66c. The end of the chip discharge groove 68c of the blade edge part 63c is continuous with the constricted part 69c. The attachment portion 64c includes a body portion 71c and a mounting shaft portion 72c that is detachably engaged with and mounted on the mounting portion 52 of the apparatus main body 51.

  The magnetic attracting body 141 is provided on the blade body 62c in the hollow portion 66c. In the magnetic attracting body 141, the depth of the cutting hole which is the bolt insertion hole 29 for the hack high-strength bolt 230 drilled in the web 33 inward in the axial direction from the cutting edge 65c, and thus the thickness of the web 33 is set. Magnetic attracting ends 141 are formed at equal positions.

  The magnetic attracting body 141 includes a holding rod 82c, a permanent magnet piece 142, a bolt 143, and a spacer 144. The holding rod 82c is inserted into the attachment hole 67c, one end 83c faces the hollow portion 66c, and the other end 84c is fixed to the free end 74c of the attachment portion 64c by fillet welding. The weld metal 75c airtightly closes the gap between the outer peripheral surface of the holding rod 82c connected to the hollow portion 66c and the inner peripheral surface of the mounting hole 67c. Both the blade body 62c and the holding rod 82c may be made of a ferromagnetic material, which ensures the welding of the similar materials with the weld metal 75c.

  The permanent magnet piece 142 has a magnetic attracting end 145, and is provided at one end 83 of the holding rod 62 so that the position of the magnetic attracting end 145 can be adjusted in the axial direction of the blade body 62. The free end surface of the head 147 of the bolt 143 is formed flush with the magnetic adsorption end 145. The shaft portion 148 of the bolt 143 is screwed to the one end portion 83c of the holding rod 82c so as to be detachably adjustable in a screw hole cut coaxially with the axis 61c. The magnetic attraction end 145 is perpendicular to the axis 61c. The bolt 143 may be a countersunk screw or the like. The spacer 144 is formed in a flat annular shape, and the shaft portion 148 of the bolt 143 is exchangeably inserted, and is sandwiched between the head portion 147 of the bolt 143 and the end surface of the one end portion 83c of the holding rod 82c. The spacer 144 may be a single piece or a plurality of pieces, and a length L3 (FIG. 26) along the axis 61 between the cutting edge 65c and the magnetic adsorption end 145 becomes a desired depth of the above-mentioned cutting hole. As set. By making the bolt 143 made of a ferromagnetic material, the area for magnetic attraction can be increased.

  FIG. 28 is a front view of the rotary blade 140 as viewed from the blade edge portion 63c. The rotary blade 140 is driven by the apparatus main body 51 with the cutting edge 65 c facing downstream in the rotation direction 151. The tightening direction 152 of the bolt 143 is determined opposite to the rotational direction 151. As a result, the rotation of the rotary blade 140 and the like, and loosening of the bolt 143 due to contact between the chips 91 and 91c and the bolts 86 and 143 are prevented. Therefore, the permanent magnet piece 142 is kept attached to the one end 83c of the holding rod 82c. This configuration is the same for the bolt 86 and the holding rod 82 in the rotary blade 60 described above.

FIG. 29 is a cross-sectional view showing a state where the drilling of the bolt insertion hole 29 for the hack high-strength bolt 230 to the web 33 of the U rib 32 is completed using the rotary blade 140. Referring also to FIG. 25, the rotary blade 140 is mounted on the drilling machine 50, the cutting blade 65c is faced up, and the cutting oil 65 is stored in the hollow portion 66c. 40 is located in the bolt insertion hole 27 formed in the other joint portion 42 in advance , and as shown in the section XXV in FIG. 25, the cutting blade 65c is in an obliquely upward posture, and the drilling machine 50 is applied with a magnetic attraction force. 40 is attached to the other joint 42. The rotary blade 140 is driven to rotate and guided by the bolt insertion hole 27, and the bolt insertion hole 29 is drilled in the other joint portion 42.
In the annular rotary blade 140, each member or part that is not provided with a reference symbol in FIGS. 25 and 26 may be indicated by using the same reference symbol as in FIGS. The magnetic attracting body 141 includes a holding rod 82c, a bolt 143, a permanent magnet piece 142, and a spacer 144. The magnetic adsorption body 141 forms a gap for storing cutting oil between the inner peripheral surface of the hollow portion 66 c and the outer peripheral surface of the magnetic adsorption body 141. The cutting oil 77 is stored in the hollow portion 66c including the clearance for cutting oil storage.

  As the cutting blade 65c cuts the other joining portion 42, the chips 91c become a disk and enter the hollow portion 66c. When one end surface 92 of the chip 91c comes into contact with the magnetic adsorption end 145 of the permanent magnet piece 142, the thickness of the chip 91c is the length L3 between the cutting blade 65c and the magnetic adsorption end 145, and the other joint portion. A bolt insertion hole 29 penetrating by a thickness of 42 is formed. At this time, as shown in FIG. 29, the one end surface 92 of the chip 91c remains magnetically attracted to the magnetic attracting end 145 and can be taken out of the U rib 32 together with the rotary blade 140 and collected. Therefore, the chips 91c do not fall and remain in the space inside the U-rib 32, and the problem of rusting is solved.

The magnetic attracting body 141 can also function as the stopper 80 described above.
The rotary blade 140 can also be implemented to drill the pilot holes 23 and 28 in the deck plate 31. That is, the rotary blade 140 has a length L2 equal to the thickness of the deck plate 31 in the posture upward from below the deck plate 31 on the lower surface of the deck plate 31 of the steel deck 30 as in FIG. Bolt joint holes 23 and 28 are cut.

  FIG. 30 is a cross-sectional view of the chip removal device 160. FIG. 30 (1) shows a state in which the chips 91c are magnetically attracted to the magnetic attracting end 145 in the hollow portion 66c after cutting the rotary blade 140, and FIG. 30 (2) is magnetically attracted to the magnetic attracting end 145. The operation which takes out the chip 91c which exists from the hollow part 66c by the chip extraction apparatus 160 is shown. The chip removal device 160 includes an operation rod 161, a permanent magnet piece 162 having a removal adsorption end 163, and a bolt 164 through which the permanent magnet piece 162 is inserted. The take-out adsorption end 163 is magnetically adsorbed to the other end surface 93 facing outward (upward in FIG. 30) from the cutting edge 65c of the chip 91c. The bolt 164 is screwed into a screw hole 165 formed in one end of the operation rod 161. The bolt 164 may be a countersunk screw or the like. The magnetic poles of the magnetic attracting end 145 and the take-out attracting end 163 facing each other through the chips 91c are determined to have opposite polarities.

  An operation protrusion 166 is formed at the other end of the operation bar 161 so as to protrude outward in the radial direction of the operation bar 161. When the operator grips the operation rod 161 by hand and pulls the chips 91c from the hollow portion 66c in the longitudinal direction of the operation rod 161 in the longitudinal direction of FIG. is there.

  Compared to the attractive force F2 at which the magnetic attracting end 145 of the permanent magnet piece 142 is magnetically attracted to the one end face 92 of the chip 91c, the take-out attracting end 163 of the permanent magnet piece 162 is magnetically attracted to the other end face 93 of the chip 91c. (F2 <F3). For this reason, when the magnetic characteristics of the permanent magnet pieces 142 and 162 are the same, that is, when the attracting force per unit area with the same size and shape is the same, for example, the permanent magnet pieces 142 and 162 are more permanent than the permanent magnet pieces 142. The thickness of the magnet piece 162 is increased. Alternatively, the other end surface 93 of the chip 91c has a flange 168 extending outward in the radial direction due to the clearance angle of the cutting edge 65c, so that the cross-sectional area perpendicular to the axis of the take-out suction end 163 is larger than the magnetic suction end 145. Can be made larger.

  FIG. 31 is a cross-sectional view showing a use state of the chip removal device 160. During use of the chip removal device 160, fine chips 169 enter the magnetic adsorption end 145 of the permanent magnet piece 142 between the one end surface 92 of the disk-shaped chip 91c and are magnetically attracted. The fine chip 169 may be separated from the magnetic adsorption end 145 and the one end surface 92, and the chip 91c may not be sufficiently magnetically adsorbed to the magnetic adsorption end 145. Therefore, during use of the chip removal device 160, fine chips 169 are scraped and removed from the hollow portion 66c.

  FIG. 32 is a cross-sectional view of a chip removal device 160d according to another embodiment of the present invention. This chip removal device 160d is similar to the above-described chip removal device 160, and corresponding portions are denoted by the same reference numerals, and the same numerals with a suffix d. It should be noted that the magnetic attracting body 141d has a permanent magnet piece 142 and a holding rod 82c to which the permanent magnet piece 142 is attached via a coil spring 154. The holding rod 82c is inserted through the coil spring 154, It is guided in the mounting hole 67c so as to be displaceable in the direction of the axis 61c. The permanent magnet piece 142 is given a spring force on the outer side 48 in the direction of the axis 61c by a coil spring 154 interposed between the permanent magnet piece 142 and the bottom of the hollow portion 66c. The spring constant of the coil spring 154 is smaller than that of the push rod 59, and the spring force of the coil spring 154 is smaller than the spring force applied to the push rod 59. A retaining prevention piece 155 is fixed to the holding rod 82 c and is pushed by the push rod 59. The retaining block 155 can come into contact with the free end 74c of the cutter body 62c, thereby ensuring that the magnetic attracting body 141d does not separate from the cutter body 62c and does not separate from the cutter body 62c in FIG. .

  In another embodiment of the present invention, instead of the permanent magnet piece 141, the hollow portion 66c is connected to a negative pressure suction source, and the chip 91c is stopped and held at the same position as the magnetic suction end 145 so as to be attracted. In this case, the annular portion 66 may be similarly connected to the negative pressure suction source so that the chip 91 is stopped and held at the contact end 81.

  The permanent magnet piece 142 and other permanent magnet pieces used in the invention disclosed in the present specification may be a neodymium magnet, a samakoba magnet, or the like.

  The magnetic attraction end 145 of the permanent magnet piece 142 faces outward from the cutting edge 65c like a reference numeral 145d in a natural state where the chip removal device 160d is not driven to rotate and is not cut. Therefore, the fine chips 169 described above with reference to FIG. 31 can be easily removed.

  In step a6, the hack high-strength bolt 230 is inserted into all the bolt insertion holes 26 and 28. Thereafter, a plurality of, for example, two, are arranged in the vicinity of the central positions of the bolt insertion holes 26 and 28 forming a row, adjacent to each other or spaced symmetrically with respect to the central position in the row direction (left and right direction in FIG. 7). Only the hack high-strength bolt 230 is temporarily tightened. The two hack high-strength bolts 230 near the center of the bolt row are primarily tightened, whereby the U rib 32 and the second joint portion 42 of the backing plate 40 are friction-joined. Due to the temporary fastening of the backing plate 40 with the temporary fastening bolt in step sa4 and the primary tightening of the hack high-strength bolt 230 in step a6, the backing plate 40 becomes undesired with respect to the deck plate 31 during the operation after step a7. It is prevented that they are displaced. The configuration and friction bonding of the hack high strength bolt 230 will be described later with reference to FIGS.

  FIG. 33 is a cross-sectional view perpendicular to the bridge shaft showing the operation of performing the primary tightening of the hack high-strength bolt 230 in steps a6 and a9 using the tool 250 and the subsequent final tightening in step a10. 34 is a cross-sectional view along the bridge axis. FIG. 33 also shows a state where the tapping bolt 20 is pressure-supported and joined to the pilot holes 25 and 23 of the one joining portion 41 of the backing plate 40 and the deck plate 31.

  In steps a7 and a8, the drilling and driving operations are repeated for each tapping bolt 20. That is, the drilling of the pilot hole 23 of the tapping bolt 20 to the deck plate 31 is performed from one end to the other end of the backing plate 40 in FIG. 34 (for example, from the left side in FIG. 34) as described above with reference to FIGS. To the right) At each position of the pilot hole 25 formed in one joint part 41 of the abutting plate 40, one by one is performed in this order. The tapping bolt 20 is tightened into the prepared pilot hole 23, and such a work is sequentially repeated one by one to repeat one joint 41 of the backing plate 40 and the deck plate 31. And are supported. Thus, after completing the drilling of the pilot hole 23 and tightening and tightening of the tapping bolt 20 into the drilled pilot hole 23 and pilot hole 25 for one tapping bolt 20, the next adjacent one Drilling and tightening for the tapping bolts 20 are performed, and such operations for each tapping bolt 20 are sequentially repeated in the row direction. At the position of the temporary fixing bolt insertion hole 26 of the contact plate 40 and the temporary fixing bolt lower hole 28 of the deck plate 31, the temporary fixing bolt screwed to them is removed, and the lower holes 25, 23 are expanded at the same position. The diameter is drilled, and the tapping bolt 20 is tightened to support and join.

  FIG. 35 is a perspective view showing the guide device 200 of the tapping bolt 20 used for driving the tapping bolt 20 in step a8. Referring also to FIG. 1, the guide device 200 inserts the tapping bolt 20 into the prepared holes 25 and 23 formed in advance on one joining portion 41 and the deck plate 31 of the backing plate 40 that is a workpiece. The bolt axis 21 of the tapping bolt 20 is used for screwing in a posture that matches the pilot hole axis 22 on the common straight line of the pilot holes 25 and 23. In this embodiment, the bolt axis 21 and the pilot hole axis 22 are perpendicular to the lower surface in FIG.

  The tapping bolt 20 includes, for example, a bolt head 201 formed with a hexagonal wrench engaging portion, a washer 202, and a bolt shaft portion 203, and is integrally formed. An impact wrench or impact driver 205, which is a manually operated, hydraulic or pneumatic fluid pressure driven rotary drive device, includes a socket 206 as a mounting portion and a drive portion 207. The bolt head 201 is fitted in a hooking hole 209 formed at one end of the socket 206, and the socket 206 has a rotation axis 207 on a straight line including the bolt axis 21 of the tapping bolt 20. The surface is formed in a right cylindrical shape. The drive unit 207 rotationally drives the other end of the socket 206 around the rotation axis 208.

  The bolt shaft portion 203 is rotated while being applied with a pressing force, so that it advances while forming a female screw by plastic deformation in the pilot holes 25 and 23 not subjected to female screw processing. The bearing joint between one joining portion 41 of the backing plate 40 and the deck plate 31 is achieved. The guide device 200 prevents an undesired stress such as a bending moment from being generated on the tapping bolt 20 when the tapping bolt 20 is tightened. The guide device 200 includes a guide tube 211 and a seating portion 212.

  36 is a cross-sectional view showing the guide tube 211 and the seating portion 212, FIG. 37 is a plan view showing the guide tube 211 and the seating portion 212, and FIG. 38 is a guide device including the guide tube 211 and the seating portion 212. FIG. The guide tube 211 has a guide hole 213, and the socket 206 can be inserted into the guide hole 213 from the free end portion 214 so as to be rotatable with respect to each other. The guide hole 213 has a guide axis that coincides with the rotation axis 208. The seat portion 212 is connected to the base end portion 215 of the guide tube 211 and seats on the lower surface in FIG. 1 of one joint portion 41 that is an attachment surface where the pilot holes 25 and 23 are opened. The tapping bolt 20 attached to the socket 206 can project upward from the seating portion 212 in FIG. 1 (downward in FIGS. 35 and 36).

  A notch 217 is formed in the base end portion 215 of the guide tube 211, and a notch 218 connected to the notch 217 is formed in the seating portion 212, and these notches 217 and 218 constitute an observation window 219. The observation window 219 enables the operator to observe that the end face of the bolt head 201, and hence the washer 202 on the bolt shaft 203 side, is in contact with the lower surface in FIG. . The guide tube 211 and the seating portion 212 are made of a translucent synthetic resin and are manufactured by injection molding. Thus, it becomes easier to observe the state of the tightening operation of the tapping bolt 20 by the operator.

  The seating portion 212 is provided with a plurality of, for example, three permanent magnet pieces 221 at equal intervals in the circumferential direction on the side opposite to the guide tube 211 (upper side in FIG. 1, lower side in FIGS. 35 and 36). . The permanent magnet piece 221 can be magnetically attracted to the lower surface in FIG.

  FIG. 39 is a diagram showing the permanent magnet piece 221. FIG. 39A is a plan view of the permanent magnet piece 221, and FIG. 39B is a cross-sectional view of the permanent magnet piece 221. The permanent magnet piece 221 is formed in a flat disk shape. The bolt 222 may be a countersunk screw or the like, and is inserted through the bolt insertion hole 223 of the permanent magnet piece 221. The permanent magnet piece 221 and the bolt head of the bolt 222 are formed flush with each other on the opposite side of the guide tube 211, thereby making surface contact with the lower surface in FIG. And the posture of the guide device 200 during the tightening operation of the tapping bolt 20 is stabilized. A nut 224 is screwed onto the bolt 222 on the guide tube 211 side.

  40, the impact driver 205 is manually operated by the operator's hand 204, the tapping bolt 20 is tightened with the pilot holes 25 and 23, and the bearing 41 is joined between the one joint 41 of the backing plate 40 and the deck plate 31. It is sectional drawing which shows the procedure achieved. As shown in FIG. 40 (1), the socket 206 to which the tapping bolt 20 is attached is inserted from the free end portion 214 of the guide tube 211 of the guide device 200. The posture of the impact driver 205 is set so that the bolt shaft portion 203 of the tapping bolt 20 protrudes from the seating portion 212 and the bolt shaft line 21 of the tapping bolt 20 is aligned with the pilot hole shaft line 22 of the pilot hole 25. To do.

  Next, as shown in FIG. 40 (2), the guide device 200 is moved to one joining portion 41 of the contact plate 40 to magnetically attract the permanent magnet piece 221. Thereby, the bolt axis 21 and the pilot hole axis 22 are stably maintained on a straight line.

  As shown in FIG. 40 (3), the impact driver 205 is operated to tighten the impact driver 205 in the pilot holes 25 and 23 with a large impact torque. From the observation window 219, the operator is aware that the end face of the washer 202 is in contact with the lower surface in FIG. 1 of one of the joints 41 and that the inner cylinder 211 and the seating part 212 are translucent. Thus, it is possible to easily observe and to know the completion of the bearing joint accurately, and therefore, a high-strength bolt joint is achieved without applying excessive tightening torque to the tapping bolt 20 and damaging it. Is done.

  In step a9, the primary tightening of all the remaining hack high-strength bolts 230 that are not primarily tightened is performed. This primary tightening is performed one or more in the direction away from the center alternately from the vicinity of the center of the row of the remaining hack high-strength bolts 230 to both sides.

  In Step a10, after the primary tightening of the hack high-strength bolt 230 is completed in Step a9 described above, all the final tightening is performed. The order in which the hack high-strength bolts 230 are finally tightened after all the primary tightenings is the same as the order in which the primary tightening is performed in step a9.

  The configuration and friction bonding of the hack high-strength bolt 230 will be described with reference to FIGS. FIG. 41 is a cross-sectional view showing the hack high strength bolt 230. The hack high-strength bolt 230 includes a pin 234, a first sleeve 235 inserted through the shaft portion 232, a second sleeve 236, a shear washer 237, a support washer 238, and a nut 239. The pin 234 has a shaft portion 232 and a large-diameter head portion 233 formed at the end of the shaft portion 232. A first male screw portion 241, a small-diameter groove-like fracture portion 242, a second male screw portion 243, and a third male screw portion 244 are sequentially formed on the shaft portion 232. The nut 239 can be screwed into the first to third male screw portions 241, 243 and 244. The first sleeve 235 bulges radially outward by a compressive force between the head 233 and the second sleeve 236 and plastically deforms. The inner periphery of the shear washer 237 contacts the end surface of the second sleeve 236, and the outer periphery thereof is supported by the support washer 238.

  FIG. 44 is a cross-sectional view for explaining an operation of erroneously screwing a tapping bolt indicated by reference numerals 4a and 4b. Since the hand-held impact device gives a large impact reaction to the operator's hand, the axes of the tapping bolts 4a and 4b do not exist on a common straight line of the axes of the pilot holes 11 and 12 as shown in FIG. As shown in FIG. 44, it is easy to be screwed in erroneously in an obliquely abnormal posture. When the tapping bolts 4a and 4b in FIG. 44 are in an oblique and abnormal posture, the torque required for tightening the tapping bolts 4a and 4b becomes excessive, the thread is damaged, and the desired strength of the bolt joint cannot be obtained. The guide device 200 for the tapping bolt 20 solves this problem as described above.

  FIG. 42 is a cross-sectional view for explaining the sequential action of the primary fastening and the final fastening of the hack high-strength bolt 230. The hack high-strength bolt 230 frictionally joins the web 33 of the U rib 32 and the other joint portion 42 of the backing plate 40 using the tool 250. The tool 250 includes a drive unit 251 that rotates the nut 239 and a drive unit 252 that is screwed into the third male screw unit 244 to rotate.

  FIG. 42 (1) is a cross-sectional view showing a state where the hack high-strength bolt 230 is inserted into the bolt insertion holes 27 and 29 in step a6.

  FIG. 42 (2) is a cross-sectional view showing a state in which the nut 239 is rotationally driven relative to the pin 234 by the drive units 251 and 252 of the tool 250. As a result, the first sleeve 235 is compressed between the head 233 and the second sleeve 236, and the bulging portion 245 in the closed space of the U rib 32 is radially outward from the inner diameter of the bolt insertion hole 29. It is greatly formed.

  FIG. 42 (3) is a cross-sectional view showing a primary tightening state of the hack high-strength bolt 230. When the nut 239 is further driven to rotate, the inner periphery and the outer periphery of the shear washer 237 are sheared by the second sleeve 236 in the vertical direction of FIG. In this state, the web 33 and the other joined portion 42 are frictionally joined between the bulging portion 245 and the nut 239 via the support washer 238 by the axial force of the pin 234 when the shear washer 237 is sheared. The above-described primary tightening is achieved.

  FIG. 42 (4) is a cross-sectional view showing a state in which the hack high-strength bolt 230 is finally tightened in step a 10 and the web 33 and the other joining portion 42 are friction-joined. For the final tightening, after the primary tightening, the third male screw portion 244 is driven in a state where the rotation of the nut 239 is prevented, and the other joint 42 of the backing plate 40 and the web 33 are connected to the pin 33. An even greater axial force of 234 is introduced. As a result, the fracture portion 242 is twisted and sheared at the outer side in the axial direction than the nut 23, and the above-described final fastening is achieved. Thus, the frictional joining between the web 33 and the other joining portion 42 of the backing plate 40 by the final fastening of the hack high-strength bolt 230 is completed.

  An example of the dimensions will be described. As shown in FIG. 22, the deck plate 31 has a thickness of 12 mm, the U-rib 32, the backing plate 40 has a thickness of 8 mm, and an outer diameter φ12 mm of a temporary fixing bolt that temporarily fixes one joint 41 of the backing plate 40 to the deck plate 31. The inner diameter φ12.5 mm of the temporary fixing bolt insertion hole 26 for the temporary fixing bolt, and the inner diameter φ11.5 mm of the temporary fixing bolt lower hole 28. The screwing length of the temporary fixing bolt can be adjusted with a washer.

  The outer diameter of the tapping bolt 20 is φ16 mm, and the inner diameter φ15.5 mm of the pilot holes 23 and 25 between the deck plate 31 for the tapping bolt 20 and one joint portion 41 of the contact plate 40.

  The bolt shaft portion 203 of the tapping bolt 20 is selected to have a value capable of achieving the bearing joint strength. According to the support joint, the steel material of the deck plate 31 is thin, so that the axial length of the bolt shaft portion 203 is short, and the high axial force necessary for the frictional joining between the deck plate 31 and the contact plate 40 cannot be exhibited. In addition, even if there is no axial force of the tapping bolt 20, the support bearing can be achieved.

  The outer diameter before use of the hack high-strength bolt 230 is φ20 mm, and the inner diameter φ21.5 mm of the bolt insertion holes 29 and 27 between the web 33 of the U-rib 32 and the other joint portion 42 of the abutting plate 40.

The following embodiments are possible for the present invention.
(1) (a) a mounting portion having an end portion to which a bolt head portion of a tapping bolt is mounted, and having a rotation axis on a straight line including a bolt axis line of the tapping bolt;
By a rotational drive device having a drive unit that rotationally drives the other end of the mounting unit around the rotation axis,
A tapping bolt guide device for screwing a tapping bolt into a pre-formed prepared hole of a workpiece in a posture in which the bolt axis of the tapping bolt matches the prepared hole axis of the prepared hole,
(B) a guide tube having a guide hole,
The mounting part can be freely inserted into the guide hole from the free end of the guide cylinder,
The guide hole has a guide cylinder having a guide axis that coincides with the rotation axis;
(C) a seating portion connected to the base end portion of the guide tube,
Sit on the mounting surface where the workpiece's pilot hole opens,
A tapping bolt mounted on the mounting portion includes a seating portion that can protrude from the seating portion,
(D) An observation window for observing that the end surface of the bolt head on the bolt shaft side is in contact with the mounting surface is formed in the base end portion and the seating portion of the guide tube. Tapping bolt guide device.
Mounting portions such as chucks, sockets, and adapters of the rotational drive device are inserted into the guide holes from the free end portion of the guide tube of the guide device so as to be rotatable with respect to each other, and the tapping bolt mounted on the mounting portion is the base of the guide tube. It can protrude from the seating part connected to the end part. The seating part is seated on the attachment surface of the workpiece. The workpiece has a mounting surface in which a pre-formed prepared hole is opened. The workpiece is a backing plate used for repairing the steel deck from the lower surface, for example, and the mounting surface is the lower surface of the backing plate.
As shown in FIG. 2 and FIG. 35 to FIG. 40, the inner peripheral surface of the guide hole of the guide tube and the outer peripheral surface of the mounting portion are such that the guide axis of the guide hole is the bolt axis of the tapping bolt attached to the mounting portion, It is formed so as to be kept in a straight line together with the rotation axis of the mounting portion that is rotationally driven by the drive portion of the rotation drive device. With the seating part seated on the mounting surface and the pilot hole axis line aligned with the guide axis line of the guide cylinder, and therefore the bolt axis line of the tapping bolt, the other end part of the mounting part is driven to rotate by the drive part of the rotary drive device. By doing so, it is possible to easily screw and screw the tapping bolt into the prepared hole while keeping the prepared hole axis of the prepared hole and the bolt axis of the tapping bolt in a straight line.
It can be observed from the outside that the end surface on the bolt shaft side of the bolt head is in contact with the mounting surface through the observation window formed in the base end portion and the seating portion of the guide tube. Thereby, the operator can grasp the screwed state of the tapping bolt to the workpiece, and the operation is ensured. The guide tube may be made of a light-transmitting or light-blocking material, such as a synthetic resin or a metal. Regardless of these materials, the screwed state of the tapping bolt to the workpiece can be grasped. For example, even if the guide tube is made of a light-transmitting material and scratches are formed on the surface by chips, making it difficult to see the inside of the guide tube, it is possible to accurately observe the screwed state of the tapping bolt from the outside through the observation window. Can be achieved.
The mounting surface and the pilot hole axis may be perpendicular, but may have other predetermined angles, and the bolt axis is aligned with the pilot hole axis in the seated state corresponding to this angle. The base end portion of the guide tube is continuous with the seating portion.
The rotary drive device may be an impact driver, but may also be an impact wrench or other impact device that strikes in the rotational direction, and has a configuration that rotates the tapping bolt without impacting in the rotational direction. May be. The rotary drive device may be a hand-held device that feeds the feed by hand, but other devices may also be used. The drive unit may have a configuration that operates by fluid pressure such as electric or pneumatic pressure, but may be a configuration that manually rotates the tapping bolt by an operator, such as a hand-turning torque wrench.

(2) The seating area
A permanent magnet piece that is magnetically attracted to the mounting surface is provided.
When the mounting member is made of a ferromagnetic material such as steel, the seating portion is seated on the mounting surface of the mounting member by the magnetic attraction force of a permanent magnet piece such as a neodymium magnet. The magnetic attraction force is large in the proximity direction between the seating portion and the mounting surface, but small in the direction perpendicular to the proximity direction. Therefore, the seating portion is liable to skid or angularly displace around the guide axis. Is easy. Therefore, in a seated state, it is easy to align the pilot hole axis line of the pilot hole and the guide axis line that matches the bolt axis line of the tapping bolt mounted on the mounting portion inserted in the guide tube. Is possible. Thus, the tapping bolt can be screwed and screwed into the prepared hole while keeping the prepared hole axis line and the bolt axis line of the tapping bolt accurately in a straight line.

(3) The guide tube is made of a translucent synthetic resin.
The guide tube is made of a transparent or translucent synthetic resin so that the mounting portion and the tapping bolt inside the guide tube can be seen from the outside. As a result, the rotational drive device can be operated while observing the screwing condition of the tapping bolt from the outside, and accurate screwing is possible. The guide tube may be ground glass-like translucent so that scratches due to chips and the like are not noticeable.

(4) The rotary drive device is a manually operated electric or fluid pressure impact device.
The rotary drive device is a manually operated impact device such as a hand-held type, which may be an electric motor or a fluid pressure actuation such as pneumatic or hydraulic pressure, and thus includes the operator's hand during operation of the impact device. The body will receive a big reaction. The guide device can accurately screw the tapping bolt into the prepared hole of the workpiece even if such a large reaction acts on the worker's body.

(5) (a) a mounting portion having one end portion to which the rotational action member is attached, and having a rotational axis on a straight line including the axis of the rotational action member;
By a rotational drive device having a drive unit that rotationally drives the other end of the mounting unit around the rotation axis,
A rotating action member guiding device for working in a posture in which the axis of the rotation acting member forms a predetermined angle with the surface of the workpiece by the rotating action member,
(B) a guide tube having a guide hole,
The mounting portion can be freely inserted into the guide hole from one end thereof,
The guide hole has a guide axis that coincides with the rotation axis,
A guide tube from which the other end portion of the mounting portion on which the rotary action member is mounted protrudes from the other end portion of the guide hole;
(C) a seating portion connected to the base end portion of the guide tube,
Sitting on the surface of the workpiece,
In this seated state, the seat includes a seating portion that has a posture in which the axis of the rotation member forms a predetermined angle with the surface,
(D) An apparatus for guiding a rotary action member, wherein an observation window for observing the rotary action member and the surface is formed at a base end portion and a seating portion of the guide tube.
The rotating member may be a tapping bolt, but may be another bolt, a nut, or other screw member. Furthermore, according to the present invention, the rotary action member may be a rotary cutting blade such as a drill for drilling, a hole saw, a steel core, or an annular cutter, or may be a blade for rotary cutting or rotary grinding such as a grindstone. Other members for machine manufacture may be used.

(6) a blade body having an annular blade edge and an attachment portion connected to the blade edge, extending inward in the axial direction from the cutting edge at the blade edge, and forming a hollow portion into which chips cut by the cutting blade enter;
An annular rotary cutter characterized in that it includes a magnetic adsorber provided on the cutter body within the hollow portion and having a magnetic adsorption end at a position equal to the depth of the cutting hole, inward in the axial direction from the cutting edge.
As shown in FIGS. 24 to 32, the magnetic attracting body 141 magnetically attracts the chips 91c to enable recovery.

  (7) An annular rotary cutter characterized in that the position of the magnetic adsorption end can be adjusted in the axial direction of the cutter body.

(8) The cutter body is coaxially formed with an attachment hole extending through the hollow portion,
Magnetic adsorber is
A holding rod that is inserted into the attachment hole, one end faces the hollow portion, and the other end is fixed to the attachment portion of the blade body;
An annular rotary cutter having a magnetic attraction end and including a permanent magnet piece provided at the one end portion of the holding rod so that the position of the magnetic attraction end can be adjusted in the axial direction of the blade body.

(9) a blade body having an annular blade edge and an attachment portion connected to the blade edge, extending inward in the axial direction from the cutting edge in the blade edge, and forming a hollow portion into which chips cut by the cutting blade enter;
A magnetic adsorber that is provided so as to be displaceable in the axial direction of the blade body within the hollow portion, and has a magnetic adsorption end facing the hollow portion;
Including a spring for applying a spring force outward in the axial direction to the magnetic attractant,
An annular rotary blade characterized in that the magnetic attractant does not leave the blade body.

(10) A cover member for a cutting apparatus,
Cutting device
(A) a rotary blade having a cutting edge portion that is rotated around an axis and cut, and an attachment portion that is continuous with the cutting edge portion in the axial direction;
(B) an apparatus body,
(B1) a mounting portion on which the mounting portion of the rotary blade is detachably mounted;
(B2) a drive unit that is connected to the mounting unit along the axis, and that rotates the mounting unit around the axis;
(B3) an apparatus main body including a support portion that rotatably supports the drive member around the axis,
(C) The cover member is
Has an insertion hole,
In this insertion hole, a part of the axial direction from the processing part to the attachment part of the rotary cutter attached to the attachment part is inserted and rotated together with the rotary cutter,
A cover member for a cutting apparatus, characterized by forming a space 105 covering gaps 106, 107, 108 that are displaced from each other while facing a rotary blade between a mounting part and a driving part and a support part.
As shown in FIGS. 1 and 19, the cover member 101 protects the cutting device 50 from chips.

(11) The cover member is
Made of elastic material,
A cover member for a cutting apparatus, wherein an inner peripheral surface of an insertion hole is elastically in contact with an outer peripheral surface of a rotary blade.

(12) A chip recovery device for a cutting device,
The cutting device is operated in a posture in which the rotary blade is directed upward from the device body,
The chip recovery device
A storage body 111 that has a recovery space 117 that covers at least a part of the apparatus main body below the blade edge, and stores and recovers chips that fall and scatter,
A chip recovery apparatus for a cutting apparatus, comprising: a magnetic adsorption member 120 that is provided at an upper portion of the storage body and that magnetically adsorbs the magnetic adsorption member.
As shown in FIGS. 17 to 22, the chip collection device 110 stores and collects chips from the annular rotary blades 60 and 140 in the collection space 117.

(13) a magnetic adsorption tool capable of switching the magnetic adsorption force of the magnetic adsorption surface between large and small;
A magnetic attraction holding device, comprising: a holder attached to a magnetic attraction tool and capable of setting a distance from the target surface by moving the magnetic attraction surface close to and away from the target surface to be magnetically attracted.

(14) The holder is
A bracket projecting outward from the side of the magnetic suction tool;
A nut member fixed to the bracket;
A bolt member screwed onto the nut member;
A pressing piece provided at one end near the target surface of the bolt member;
A magnetic attraction holding device including an operation piece provided at the other end opposite to the target surface of the bolt member and manually operated to rotate.

  The present invention can be widely implemented not only for a bridge provided with a steel deck 30 but also for other types of bridges and steel structures other than bridges. The guide device 200 can also be implemented to screw the temporary fixing bolt through the temporary fixing bolt insertion hole 26 in FIG. 7 to the temporary fixing bolt lower hole 28, and to screw other types of bolts, for example, other than tapping bolts. It can also be implemented to wear. The guide device 200 can also be implemented for drilling with the rotary blades 60, 140 and other rotary blades.

20 Tapping bolt 23, 25 Pilot hole 26 Temporary fixing bolt insertion hole 27, 29 Bolt insertion hole 28 Temporary fixing bolt lower hole 30 Steel floor slab 31 Deck plate 32 U rib 33 Web 35 Weld metal 36 Waterproof layer 37 Asphalt pavement 40 Placing plate 41 One joint portion 42 The other joint portion 50 Drilling machine 51 Device main body 52 Mounting portion 53 Arbor 54 Support portion 54a Quill 54b Quill guide 55 Feed handle 56 Body 57 Operation shaft 60, 60a Annular rotary blade 61, 61c Axis 62, 62c Axis Blade main body 63, 63c Cutting edge portion 64, 64c Mounting portion 65, 65c Cutting blade 66, 66c Hollow portion 69, 69c Constricted portion 72, 72c Mounting shaft portion 77 Cutting oil 80 Stopper 81 Contact end 82, 82c Holding rod 85 Contact Member 91, 91c Chip 95 Magnetic Device 96 Guide part 100 Protection device from chip 101 Cover member 102 End wall part 103 Peripheral wall part 104 Mounting hole 105 Space 106, 107, 108 Crevice 110 Chip collection apparatus 111 Storage body 117 Collection space 118 Opening part 120-122 Magnetic adsorption member 131, 132, 133 Reinforcing member 134 Long hole 140 Annular rotating blade 141, 141d Magnetic attracting body 142, 162 Permanent magnet piece 145 Magnetic attraction end 154 Coil spring 155 Retaining prevention piece 160, 160d Chip removal device 161 Operation rod 163 Extraction adsorption End 164 Bolt 170, 170a Magnetic adsorption holding device 171 Magnetic adsorption surface 172 Magnetic adsorption tool 173 Holding body 191 Magnetic adsorption device main body 192 Fixed magnet piece 193 Moving magnet piece 200 Tapping bolt guide device 201 Bolt head 205 Impact driver 206 Socket 207 Drive portion 211 Guide tube 212 Seating portion 213 Guide hole 215 Base end portion 219 Observation window 230 Hack high-strength bolt 250 Tool

Claims (5)

An annular rotary cutter that cuts a bolt joint hole having a length L2 equal to the thickness of the deck plate in a posture upward from below the deck plate on the lower surface of the deck plate of the steel deck,
(A) a blade body having an axis,
(A1) A clearance angle is formed on the cutting edge,
On the outer periphery, an annular cutting edge portion in which a discharge groove for guiding chips from the cutting blade is formed, and
(A2) an attachment part,
(A2-1) a large-diameter trunk continuous to the cutting edge,
(A2-2) having a mounting portion that includes a mounting shaft portion that is connected to the large-diameter body portion and is removably engaged to be rotationally driven around the axis,
(A3) A hollow portion is formed coaxially with the blade body, extending inward in the axial direction from the cutting edge at the blade edge portion to the large diameter body portion, and into which chips cut by the cutting blade enter, and the blade edge portion is cylindrical. And
(A4) A blade body in which a mounting hole is formed coaxially with the blade body and formed in the mounting shaft portion so as to pass through the hollow portion;
(B) a stopper,
(B1) Inserted into the mounting hole of the cutter body, one end faces the hollow portion, the other end is hermetically closed and fixed to the mounting shaft portion by weld metal, and the holding rod is axially outward from the one end portion. A holding rod with a threaded hole facing
(B2) An abutting member having an abutting end against which chips entering the hollow portion abut,
(B2-1) a bolt that is screwed into the screw hole so as to be attachable / detachable;
(B2-2) having a contact member provided with a spacer that sets the length L2 of the cutting edge and the contact end to the thickness of the deck plate that cuts the bolt joint hole, so that it can be replaced by a bolt.
(B3) a stopper that forms a clearance for cutting oil storage between the inner peripheral surface of the hollow portion and the outer peripheral surface of the stopper;
(C) An annular rotary cutter characterized by including cutting oil stored in a hollow portion including the cutting oil storage gap. An annular rotary cutter that cuts a bolt joint hole having a length L3 equal to the thickness of the deck plate on the lower surface of the deck plate of the steel floor slab in an upward posture from below the deck plate,
(A) a blade body having an axis,
(A1) A clearance angle is formed on the cutting edge,
On the outer periphery, an annular cutting edge portion in which a discharge groove for guiding chips from the cutting blade is formed, and
(A2) an attachment part,
(A2-1) a large-diameter trunk continuous to the cutting edge,
(A2-2) having a mounting portion that includes a mounting shaft portion that is connected to the large-diameter body portion and is removably engaged to be rotationally driven around the axis,
(A3) A hollow portion is formed coaxially with the blade body, extending inward in the axial direction from the cutting edge at the blade edge portion to the large diameter body portion, and into which chips cut by the cutting blade enter, and the blade edge portion is cylindrical. And
(A4) a blade body that is coaxial with the blade body and has a mounting shaft c formed in the mounting shaft portion that extends through the hollow portion;
(B) a magnetic adsorption body having a magnetic adsorption end against which chips entering the hollow portion abut,
(B1) A screw that is inserted into the attachment hole of the cutter body, has one end facing the hollow portion, the other end is hermetically closed and fixed to the mounting shaft portion by weld metal, and faces the one end portion outward in the axial direction. A holding rod in which a hole is engraved;
(B2) a bolt that is screwed into the screw hole so as to be attachable / detachable;
(B3) a permanent magnet piece provided at one end of the holding rod by a bolt;
(B4) having a spacer for setting the length L3 of the cutting blade and the magnetic adsorption end to the thickness of the deck plate for cutting the bolt joint hole, so that it can be replaced by a bolt.
(B5) a magnetic adsorbent that forms a clearance for cutting oil storage between the inner peripheral surface of the hollow portion and the outer peripheral surface of the magnetic adsorbent;
(C) An annular rotary cutter characterized by including cutting oil stored in a hollow portion including the cutting oil storage gap. The upper end of the web of the vertical truffle rib that forms a closed space with the deck plate is joined to the lower surface of the deck plate of the steel deck by weld metal extending along the bridge axis direction, and in an obliquely upward position from the outside of the web An annular rotary cutter for cutting a cutting hole having a length L3 equal to the thickness of the web,
(A) a blade body having an axis,
(A1) A clearance angle is formed on the cutting edge,
On the outer periphery, an annular cutting edge portion in which a discharge groove for guiding chips from the cutting blade is formed, and
(A2) an attachment part,
(A2-1) a large-diameter trunk continuous to the cutting edge,
(A2-2) having a mounting portion that includes a mounting shaft portion that is connected to the large-diameter body portion and is removably engaged to be rotationally driven around the axis,
(A3) A hollow portion is formed coaxially with the blade body, extending inward in the axial direction from the cutting edge at the blade edge portion to the large diameter body portion, and into which chips cut by the cutting blade enter, and the blade edge portion is cylindrical. And
(A4) a blade body that is coaxial with the blade body and has a mounting shaft c formed in the mounting shaft portion that extends through the hollow portion;
(B) a magnetic adsorption body having a magnetic adsorption end against which chips entering the hollow portion abut,
(B1) A screw that is inserted into the attachment hole of the cutter body, has one end facing the hollow portion, the other end is hermetically closed and fixed to the mounting shaft portion by weld metal, and faces the one end portion outward in the axial direction. A holding rod in which a hole is engraved;
(B2) a bolt that is screwed into the screw hole so as to be attachable / detachable;
(B3) a permanent magnet piece provided at one end of the holding rod by a bolt;
(B4) having a spacer for setting the length L3 of the cutting blade and the magnetic adsorption end to the thickness of the deck plate for cutting the bolt joint hole, so that it can be replaced by a bolt.
(B5) a magnetic adsorbent that forms a clearance for cutting oil storage between the inner peripheral surface of the hollow portion and the outer peripheral surface of the magnetic adsorbent;
(C) An annular rotary cutter characterized by including cutting oil stored in a hollow portion including the cutting oil storage gap. A chip removal device for an annular rotary blade according to one of claims 1 to 3,
On the outer end surface of the axis of the chip, there is a ridge extending radially outward due to the clearance angle of the cutting blade of the annular rotary cutter,
An operation bar;
A permanent magnet piece for extraction having an extraction adsorption end that is fixed to one end of the operation rod and magnetically adsorbs to the other end surface facing outward from the cutting blade of the chips that have entered the hollow portion;
A chip removing device comprising an operation protrusion formed at the other end portion of the operation rod so as to protrude outward in the radial direction of the operation rod. A cover member for a cutting device,
Cutting device
(A) the annular rotary cutter according to one of claims 1 to 3;
(B) an apparatus body,
(B1) a mounting portion on which the mounting portion of the annular rotary cutter is detachably mounted;
(B2) a drive unit that is connected to the mounting unit along the axis of the blade body, and that rotates the mounting unit around the axis;
(B3) an apparatus main body including a support unit that rotatably supports the drive unit around the axis,
(C) The cover member is
(C1) an end wall portion having a mounting hole through which a part of the axial direction from the blade tip portion c of the annular rotary cutter mounted on the mounting portion to the mounting portion is inserted;
(C2) having an end wall portion and a peripheral wall portion continuous in the axial direction;
(C3) The end wall portion and the peripheral wall portion form a space that covers each portion of the attachment portion and the mounting portion, the drive portion, and the support portion in the vicinity of the attachment portion;
(C4) For a cutting device comprising a material having elasticity, wherein the inner peripheral surface of the mounting hole elastically contacts the outer peripheral surface of the annular rotary cutter and rotates together with the annular rotary cutter. Cover member.

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