JP5339252B2 - Injection nozzle for pinning method and pinning method using the same - Google Patents

Description

  The present invention relates to an injection nozzle for a pinning method capable of sufficiently injecting an adhesive into a “float” generated between a housing and a mortar and between a mortar and a decoration material, and a pinning method using the same. Is.

Conventionally, as this kind of injection nozzle, one that injects a resin (adhesive) into an insertion hole drilled in a repaired portion of an outer wall made of mortar and a concrete frame (frame) is known (patent document) 1).
The injection nozzle is mounted on a resin injector main body, and has a nozzle body (nozzle body) having a resin flow path formed in an axial center, and a base end portion is held by the nozzle main body. And an injection needle (nozzle tube) that forms a channel (first injection channel).
In this case, the tip of the nozzle body closes and seals the opening by inserting the injection nozzle into the insertion hole and pressing it. Then, the resin is gradually filled from the deepest part of the insertion hole by operating (pumping) the resin injector in this state, and reaches the floating part between the concrete frame and the mortar. Further, the resin injection is completed by performing the pumping a predetermined number of times.

JP 2003-147971 A

  However, in such an injection nozzle, when “floating” occurs not only between the concrete frame and the mortar but also between the mortar and the decorative material around the insertion hole, air is generated in the “floating” portion. Therefore, the resin is filled only in the “floating” between the concrete frame and the mortar first, and the resin may not reach the “floating” between the mortar and the decorative material. In such a case, the resin must be injected into this portion while pulling out the injection nozzle. However, since the opening is unsealed when the injection nozzle is pulled out, there is a problem that the resin cannot be sufficiently distributed to the “float” between the mortar and the decorative material.

  Then, this invention makes it a subject to provide the injection nozzle for the pinning method which can fully inject | pour an adhesive agent also to the "float" produced between mortar and a decoration material, and the pinning method using the same. Yes.

  The injection nozzle for the pinning method of the present invention is attached to the injector body, and the adhesive is applied to the insertion hole that penetrates the decorative material and the mortar and drills the casing to a predetermined depth while sealing the hole opening. An injection nozzle for a pinning method to be injected, which is mounted on an injector body and has a nozzle body in which an adhesive flow path is formed to be continuous with the injector body, and a nozzle cylinder whose proximal end is held by the nozzle body The nozzle cylinder has a first discharge port that opens to the tip and communicates with the adhesive flow path, and the nozzle body opens to the tip so as to face the hole opening, and the adhesive flow path It has the 2nd discharge port connected to.

  The nozzle cylinder is formed with a first injection channel that communicates the adhesive channel and the first discharge port, and the nozzle body has a second injection channel that communicates the adhesive channel and the second discharge port. A flow path is formed, and the flow resistance of the adhesive flowing through the first injection flow path is configured to be smaller than the flow resistance of the adhesive flowing through the second injection flow path at the initial stage of injection of the adhesive. It is preferable.

  According to these configurations, when the adhesive is poured into the insertion hole while sealing the hole opening of the insertion hole with the nozzle body, the adhesive first passes through the first injection channel formed in the nozzle cylinder. Then, the ink is discharged from the first discharge port and gradually filled from the deepest part of the insertion hole. Eventually, the adhesive reaches the floating portion between the housing and the mortar and flows into the floating portion. At the same time, the adhesive is discharged from the second discharge port via the second injection channel formed in the nozzle body, and is filled from the front side of the insertion hole. Eventually, the adhesive spreads over the float between the mortar and the decorative material. Therefore, the adhesive can be injected not only into the insertion hole but also into the floating portion between the housing and the mortar and the floating portion between the mortar and the decorative material.

  In this case, the tip of the nozzle body is inserted into the hole opening, seals the hole opening at the outer peripheral surface, and has a tapered seal portion that holds the nozzle tube at the axial center, and the second discharge port is It is preferable that the hole is opened at a portion inserted into the hole opening of the seal portion.

  In this case, the second discharge port is disposed so as to be positioned in front of the surface of the mortar in a state where the tip of the nozzle body is inserted into the hole opening and sealed.

  According to these configurations, the hole opening can be sealed by inserting the tip of the nozzle body into the insertion hole, and the second discharge port can be positioned in the vicinity of the hole opening. The adhesive can be reliably injected into the floating portion between the decorative material.

  In this case, the tip of the nozzle body is in contact with the opening edge of the decorative material in which the hole opening is formed, and the annular seal part that seals the hole opening, the annular seal part at the peripheral part, and the axial center part And the second discharge port is located between the annular seal portion and the nozzle tube and is open to the holding portion.

  According to this configuration, when the nozzle cylinder is inserted into the insertion hole and pressed, the annular seal portion comes into contact with the opening edge of the decorative material and seals the hole opening. Thereby, the adhesive injected into the insertion hole from the second discharge port can be injected from the position of the hole opening, and the adhesive is floated between the mortar and the decorative material regardless of the thickness of the decorative material. Can be reliably injected into the part.

  In this case, it is preferable that the nozzle cylinder is held so as to be movable forward and backward with respect to the nozzle body.

  According to this configuration, the nozzle cylinder advances in the injection direction with respect to the nozzle body by the viscous resistance (flow resistance) of the adhesive flowing through the first injection flow path by injecting the adhesive, and the insertion hole It hits the deepest part. Therefore, even if the depth of the insertion hole varies, the adhesive can always be injected from the deepest portion of the insertion hole. As a result, air cannot be accumulated in the deepest portion of the insertion hole. However, the nozzle cylinder can be extended to the maximum in advance, the nozzle cylinder can be abutted (retracted) into the deepest portion of the insertion hole, and then the adhesive can be injected.

  The pinning method of the present invention uses an adhesive injector comprising an injection nozzle for any of the above-described pinning methods and an injector body to which the injection nozzle is detachably mounted, and is composed of a casing, a mortar, and a decoration material. In the pinning method for repairing the wall body, a perforation process that penetrates the decorative material and mortar and drills the housing to a predetermined depth to form an insertion hole, and the hole opening of the insertion hole is sealed with an adhesive injector. An adhesive injection step of injecting an adhesive into the insertion hole while stopping and a pin insertion step of inserting an anchor pin into the insertion hole into which the adhesive has been injected are provided.

  According to this configuration, after the insertion hole is drilled in the repair required portion of the wall body, the adhesive is injected from the deepest portion of the insertion hole by the adhesive injector. Thereafter, the anchor pin is inserted into the insertion hole into which the adhesive has been injected, to the deepest part so as to cover the casing, the mortar, and the decorative material. Then, when the adhesive is cured, the decorative material and the mortar are fixed to the casing via the adhesive and the anchor pin. In this case, since the injection nozzle having the first injection flow path and the second injection flow path is used, the adhesive is injected from the deepest part side and the hole opening side of the insertion hole. It is possible to sufficiently spread the floating portion between the mortar and the mortar and the floating portion between the mortar and the decoration material.

It is a cross-sectional schematic diagram which uses the adhesive agent injector which has the injection nozzle for pinning methods with respect to the insertion hole formed in the outer wall. It is a top view of an adhesive injection device. It is sectional drawing of the injection nozzle which concerns on 1st Embodiment. It is sectional drawing of the injection nozzle which concerns on the modification of 1st Embodiment. It is process drawing (1) of the pinning construction method concerning this embodiment. It is process drawing (2) of the pinning construction method concerning this embodiment. It is sectional drawing of the injection nozzle which concerns on 2nd Embodiment. It is sectional drawing of the injection | pouring nozzle which concerns on the modification of 2nd Embodiment.

  Hereinafter, an injection nozzle for a pinning method according to an embodiment of the present invention (hereinafter simply referred to as “injection nozzle”) and a pinning method using the same will be described with reference to the accompanying drawings. In this pinning method, an injection syringe equipped with an injection nozzle is used, and the injection nozzle is inserted into the insertion hole drilled in the repaired portion of the outer wall of the building where the `` floating '' occurred, or the inner wall such as a blowout or a hole. Then, inject the adhesive, then insert the anchor pin and repair it. Hereinafter, the case where the outer wall of a building is constructed will be described.

  As shown in FIG. 1, an outer wall 1 of a building is composed of a concrete frame (frame) 2 as a foundation and a finishing material 3 applied to the surface thereof. , And decorative materials 5 such as tiles and stones pasted on the surface. In this case, it is assumed that the first floating portion 6 is generated between the concrete frame 2 and the mortar 4 and the second floating portion 7 is generated between the mortar 4 and the decorative material 5. Further, an insertion hole 8 is formed in the outer wall 1 so as to penetrate the decorative material 5 and the mortar 4 and perforate the concrete casing 2 to a predetermined depth so as to repair the first floating portion 6 and the second floating portion 7. Has been. Then, the outer wall 1 is repaired by injecting the adhesive R by the adhesive injector 11 and inserting the anchor pin 61 (see FIGS. 5 and 6) into the insertion hole 8. .

  Here, the adhesive injector 11 will be described with reference to FIG. The adhesive injector 11 is composed of a pump-type injector main body 12 that mainly supplies the adhesive R, and an injection nozzle 13 that is detachably attached to the distal end of the injector main body 12. .

  The injector body 12 includes a cylindrical casing 14 extending to the proximal end side, a pump body 15 to which the casing 14 is detachably attached, a substantially “L” -shaped lever 16 held by the pump body 15, and It is equipped with. The casing 14 is filled with an adhesive R, and the casing 14 is set on the pump body 15 from the base end side, and the injection nozzle 13 is mounted from the front end side. The injector body 12 is configured to discharge the adhesive R from the injection nozzle 13 by a certain amount by manually operating (pumping) the lever 16. In the present embodiment, an epoxy resin adhesive is used as the adhesive R, but the present invention is not limited to this. For example, various organic adhesives may be a viscous inorganic adhesive or the like.

  As shown in FIGS. 2 and 3, the injection nozzle 13 is detachably attached to the injector main body 12, and has a nozzle body 17 in which an adhesive flow path 43 connected to the injector main body 12 is formed, and the nozzle body. Nozzle cylinder 18 held by 17. The nozzle body 17 is connected to a rubber body main body 21 that slidably holds the nozzle cylinder 18, and a connecting member 22 that is abutted against the base end side of the body main body 21 and has an adhesive channel 43 formed therein. The holding member 23 is configured to be screwed into the member 22 and hold the body main body 21 so as to cover it. The injection nozzle 13 inserts the nozzle cylinder 18 in a nested manner from the base end side of the body main body 21, inserts the distal end of the connecting member 22 into the base end side of the body main body 21, and holds the holding member 23 into the body main body 21 from the front end side. And is assembled by screwing the base end side of the holding member 23 into the connecting member 22. In addition, it is disassembled in the reverse order and can be easily cleaned.

  The nozzle cylinder 18 is formed like an injection needle using a metal pipe such as stainless steel or a resin pipe, and is held slidable (movable back and forth) in the body body 21 in the axial direction. The nozzle cylinder 18 includes a first discharge port 24 opened at a distal end portion, a flange portion 25 formed at a proximal end portion, and a first injection flow formed in an axial center and communicating with the flange portion 25 and the first discharge port 24. And a path 26. The first discharge port 24 is cut obliquely to form an opening having an elliptical cross section, and does not close even when the tip of the nozzle cylinder 18 is in contact with the deepest portion of the insertion hole 8. The adhesive R can be appropriately injected. The flange portion 25 is formed with a first inflow port 27 that is expanded in a funnel shape so that the adhesive R flowing from the adhesive flow path 43 can be easily introduced, and when the injection nozzle 13 is pulled out. Prevents falling out. The first injection flow channel 26 communicates with the adhesive flow channel 43 of the connecting member 22 via the first inflow port 27, and the flowed adhesive R enters the insertion hole 8 from the first discharge port 24. Discharge. For example, the length of the nozzle cylinder 18 is about 100 mm, and the diameter of the nozzle cylinder 18 is 2 mm in outer diameter and 1.8 mm in inner diameter.

  The body main body 21 is made of an elastic material such as fluorine rubber or butyl rubber, and has a seal portion 31 that is tapered toward the front end side, and a cylindrical portion that is connected to the seal portion 31 and formed in a cylindrical shape. 32 and a large-diameter thick cylindrical portion 33 connected to the base end of the cylindrical portion 32 with an annular stepped portion. On the proximal end side of the thick cylindrical portion 33, a circular mounting groove 34 into which the distal end of the connecting member 22 is fitted is provided. In addition, a through-hole 35 for holding the nozzle cylinder 18 slidably is formed in the axial center portion of the body main body 21. A plurality of second discharge ports 36 and a plurality of second injection channels 37 connected thereto are formed around the through hole 35 at equal intervals in the circumferential direction.

  Each second discharge port 36 opens on the surface of the tapered seal portion 31. In this case, the second discharge port 36 is positioned on the side of the hole opening 9 in front of the surface of the mortar 4 (more preferably, the second floating portion 7) in a state where the injection nozzle 13 is inserted into the insertion hole 8. It is formed to do. Each second injection channel 37 that communicates with the second discharge port 36 communicates with the adhesive channel 43 via a second inlet 38 that opens at the bottom surface of the mounting groove 34. The adhesive R that has flowed into the adhesive flow path 43 is discharged from the first discharge port 24 through the first injection flow path 26, and on the other hand, the plurality of second injection paths 37 through the plurality of second injection flow paths 37. It is discharged from the discharge port 36. The numbers of the second discharge ports 36 and the second injection channels 37 are not particularly limited.

  The holding member 23 is formed in a cylindrical shape from a metal material such as stainless steel or steel, and has a large-diameter holding portion 39 that has the largest diameter in the injection nozzle 13 and a large-diameter holding portion 39 with an annular stepped portion. A small-diameter holding portion 40 connected to the distal end side. The inner diameter of the large diameter holding portion 39 is formed to be the same as that of the thick cylindrical portion 33 of the body main body 21, and the large diameter holding portion 39 surrounds the thick cylindrical portion 33 on the tip side. Further, a female thread that is screwed into the connecting member 22 is threaded on the inner peripheral surface of the base end side of the large diameter holding portion 39. On the other hand, the inner diameter of the small diameter holding portion 40 is formed to be the same diameter as the cylindrical portion 32 of the body main body 21, and the small diameter holding portion 40 surrounds the cylindrical portion 32. With the connecting member 22 abutting against the body main body 21, the holding member 23 is attached from the front, and when the large diameter holding portion 39 is screwed into the connecting member 22, the small diameter holding portion 40 (annular step portion) becomes the body. The main body 21 is strongly attracted to the connecting member 22 side. Thereby, the body main body 21 and the connecting member 22 are integrated, and the tip of the adhesive flow path 43 is sealed in the mounting groove 34 of the body main body 21.

  The connecting member 22 is formed of a metal material such as stainless steel or steel, and has a distal end side insertion portion 45 fitted into the mounting groove 34 of the body body 21 and a large diameter continuous to the proximal end side of the insertion portion 45. The large-diameter threaded portion 41 and a small-diameter small-diameter threaded portion 42 connected to the proximal end side of the large-diameter threaded portion 41 are integrally formed. Further, as described above, the adhesive flow path 43 connected to the injector main body 12 is formed in the axial center of the connecting member 22. The downstream end of the adhesive flow path 43 communicates with the first injection flow path 26 and the plurality of second injection flow paths 37. The large-diameter threaded portion 41 is formed in a cylindrical shape having a diameter larger than that of the insertion portion 45, and a male screw is threaded on the outer peripheral surface, and a pair of ground surfaces are ground flat on the outer peripheral surface proximal end side. A spanner hanging portion 44 (see FIG. 1) is formed. A male thread is also threaded on the outer peripheral surface of the small-diameter threaded portion 42 so as to be threaded into the injector body 12.

  When the small-diameter threaded portion 42 is screwed into the injector main body 12, the downstream end of the adhesive flow path 43 communicates with the injector main body 12. The adhesive R flowing into the adhesive flow path 43 from the injector main body 12 flows into the first injection flow path 26 from the first inlet 27 of the nozzle cylinder 18, and the second from the second inlet 38 of the body main body 21. The flow is divided into the flow into the two injection flow paths 37 and discharged from the first discharge port 24 and the plurality of second discharge ports 36. The first injection flow channel 26 and the second injection flow channel 37 have the flow resistance of the adhesive R flowing through the first injection flow channel 26 in the initial stage of the injection of the adhesive R. It is comprised so that it may become small compared with the flow resistance of the adhesive agent R which flows. That is, in the initial stage of the injection of the adhesive R, the adhesive R is mainly injected from the first injection flow path 26, and the adhesive R reaches the first floating portion 6 between the concrete housing 2 and the mortar 4. In this case, the adhesive R is mainly injected from each second injection channel 37.

  Next, a modification of the injection nozzle 13 according to the first embodiment will be described with reference to FIG. In addition, in order to avoid duplicate description, a different part from 1st Embodiment is mainly demonstrated. In this modification, the nozzle cylinder 18 has a sliding type (FIG. 4A: first modification) and a fixed type (FIG. 4B: second modification), both of which are nozzle bodies 17. Is different from that of the first embodiment. In the injection nozzle 13 with a sliding nozzle cylinder 18 as a first modification, a communication path 51 having the same diameter as the adhesive flow path 43 is formed deeply at the bottom of the mounting groove 34 of the nozzle body 17. The tip of the nozzle body 17 has a tapered taper-shaped seal portion 31, and the tip of the seal portion 31 is a flat surface 52. The flat surface 52 is formed with a through hole 35 at its axial center, and a plurality of second discharge ports 36 are opened around the through hole 35 (FIG. 4A).

  On the other hand, in the injection nozzle 13 with a fixed nozzle cylinder 18 as a second modification, a communication path 51 having the same diameter as the adhesive flow path 43 is formed deeply at the bottom of the mounting groove 34 of the nozzle body 17, and the nozzle The front end portion of the body 17 has a tapered tapered seal portion 31. A through hole 35 is formed in the axial center of the nozzle body 17, and the base end side of the nozzle cylinder 18 is fixed to the through hole 35. A plurality of second discharge ports 36 are opened on the outer peripheral surface of the seal portion 31, and the plurality of second injection channels 37 communicating with each second discharge port 36 are radially formed from the communication passage 51 side. It extends.

  Also in these modified examples, as in the first embodiment, each second discharge port 36 has the surface of the mortar 4 (more preferably, the first discharge port 13 in a state where the injection nozzle 13 is inserted into the insertion hole 8. 2 is formed so as to be positioned closer to the hole opening 9 than the floating portion 7).

  Next, with reference to FIG. 5 and FIG. 6, the pinning method to the outer wall 1 using said adhesive injection device 11 is demonstrated. In this pinning method, a hammer or the like is used to hit the outer wall 1, and based on the percussion sound, the repaired portion of the outer wall 1, that is, the first floating portion 6 between the concrete frame 2 and the mortar 4, and the mortar 4 and the decorative material are used. The second floating portion 7 is searched for and the drilling position of the insertion hole 8 is determined. Following this, after marking is performed at the drilling position, a drilling step of penetrating the decorative material 5 and the mortar 4 and drilling the concrete casing 2 to a predetermined depth to form an insertion hole 8, and adhesive injection The adhesive 5 is injected into the insertion hole 8 while sealing the hole opening 9 with the vessel 11, and the decoration material 5 is attached to the concrete housing 2 in the insertion hole 8 into which the adhesive R has been injected. A pin loading step of loading anchor pins 61 for anchoring is performed.

  In the drilling step, the insertion holes 8 are drilled at the drilling positions of the marked outer wall 1 using a drilling tool 62 such as a diamond core drill. That is, the concrete casing 2 is drilled to a predetermined depth so as to penetrate the decorative material 5 and the mortar 4 to form the insertion hole 8 (see FIG. 5A). At this time, drilling is performed at a right angle to the outer wall 1 and the drilling depth in the concrete frame 2 is set to 30 mm or more. The insertion hole 8 is formed in a straight hole having a diameter (1 mm to 2 mm thick) that is slightly larger than the anchor pin 61 so that the anchor pin 61 can be loosely fitted. When the straight hole is formed, preferably, the first floating portion 6 and the second floating portion 7 are confirmed using an exploration jig.

  In the adhesive injection step, the nozzle cylinder 18 is inserted into the deepest portion of the insertion hole 8 after adjusting the protruding dimension of the nozzle cylinder 18 to be sufficiently long (see FIG. 5B). And the hole opening 9 is sealed by the seal part 31 by pressing the adhesive injector 11 against the outer wall 1 (see FIG. 5C). At this time, the second discharge port 36 is located between the second floating portion 7 and the hole opening 9. Next, the lever 16 of the injector body 12 is operated (pumped) to inject the adhesive R into the insertion hole 8. When pumping is started, the adhesive R is discharged from the first discharge port 24 of the nozzle cylinder 18, and the adhesive R is gradually injected from the deepest portion of the insertion hole 8 (see FIG. 6A). Eventually, the adhesive R flows into the first floating portion 6 between the concrete housing 2 and the mortar 4, and at the same time, the adhesive R is also discharged from the second discharge port 36. It flows into the 2nd floating part 7 between the decoration materials 5 (refer FIG.6 (b)). At this time, air can be accumulated in the intermediate portion of the insertion hole 8 between the first floating portion 6 and the second floating portion 7, but the negative pressure when the injection nozzle 13 is pulled out of the insertion hole 8 causes air to Will come off.

  In the pin insertion process, the insertion is performed while guiding the pin body of the anchor pin 61 into the insertion hole 8 into which the adhesive R has been injected (see FIG. 6C). The anchor pin 61 to be inserted reaches the deepest portion so as to push away the adhesive R in the insertion hole 8. Along with this, the adhesive R flows into the gap so as to conform to the pin body portion, and a part thereof is pushed out toward the hole opening 9 of the insertion hole 8. The head of the anchor pin 61 closes the hole opening 9 when the tip of the anchor pin 61 reaches the deepest part.

  In this case, in the adhesive injection step, if the volume of the uninjected portion where the adhesive R generated after the nozzle cylinder 18 is pulled out is not injected and the volume of the anchor pin 61 are substantially the same. When the anchor pin 61 is inserted into the insertion hole 8, the insertion hole 8 can be substantially filled with the adhesive R without almost any leakage of the adhesive R from the insertion hole 8. A counterbore hole may be formed in the decorative material 5 and the head of the anchor pin 61 may be locked to this portion (not shown). In such a case, a decorative cap for closing the hole opening 9 is separately provided. Moreover, also when using the anchor pin with an injection hole, it is preferable to inject | pour the adhesive agent R as mentioned above, before loading the anchor pin with an injection hole.

  Next, the injection nozzle 13 according to the second embodiment will be described with reference to FIG. In this injection nozzle 13, the configuration of the nozzle body 17 is different from that of the first embodiment, and this different part will be mainly described. In the nozzle body 17 of the second embodiment, the body main body 21 does not have the tapered seal portion 31, and instead, the small-diameter holding portion 40 of the holding member 23 extends forward. An annular seal member (annular seal portion) 63 is attached to the extended portion. That is, the nozzle body 17 is abutted against the cylindrical annular seal member 63 provided at the distal end, the body main body 21 holding the nozzle cylinder 18 at the axial center, and the proximal end side of the body main body 21, A connecting member 22 having an adhesive flow path 43 formed thereon, and a holding member 23 screwed into the connecting member 22 so as to cover the body main body 21 and hold the annular seal member 63 at the tip. It is configured.

  The annular seal member 63 is formed in a cylindrical shape with an elastic material such as fluorine rubber or butyl rubber, and the tip of the annular seal member 63 abutted against the decorative material 5 is formed in a semicircular cross section. An annular recess 64 is formed on the proximal end side of the annular seal member 63 to be attached to the distal end portion of the holding member 23 (the distal end portion of the small diameter holding portion 40). The body main body 21 has a flat front end surface 65, and a through hole 35 that holds the proximal end side of the nozzle cylinder 18 is formed in the axial center portion. The body main body 21 has a plurality of second discharge ports 36 that are located around the through-hole 35 and are equally arranged in the circumferential direction, and a plurality of second injection channels 37 that are connected to the second discharge ports 37. Yes.

  The holding member 23 of the present embodiment has a small-diameter holding portion 40 extending beyond the body main body 21, and the annular seal member 63 (annular recess 64) is attached to the tip of the small-diameter holding portion 40. Has been. The distal end portion of the small diameter holding portion 40 is formed in a semicircular cross section so that the annular seal member 63 can be in close contact with the decorative material 5. The holding portion referred to in the claims includes a body main body 21 and a small diameter holding portion 40 of the holding member 23. Therefore, the small diameter holding portion 40 is positioned at the peripheral edge at the tip of the nozzle body 17 and holds the annular seal member 63.

  In the adhesive injection process using the injection nozzle 13, when the adhesive injector 11 is pressed against the outer wall 1 with the nozzle cylinder 18 inserted into the deepest part of the insertion hole 8, the opening edge of the hole opening 9 is formed. The abutting annular seal member 63 is appropriately deformed to seal the hole opening 9. That is, each second discharge port 36 of the present embodiment is located outside the decoration material 5. In this state, the second discharge port 36 and the hole opening 9 communicate with each other using the inner peripheral surface of the annular seal member 63 as a flow path for the adhesive R. When pumping is started here, the adhesive R is discharged from the first discharge port 24 of the nozzle cylinder 18, and then the adhesive R is also discharged from the plurality of second discharge ports 36. Thereby, like the injection nozzle 13 of the first embodiment, the adhesive R reaches the insertion hole 8, the first floating portion 6, and the second floating portion 7.

  Next, a modification of the injection nozzle 13 according to the second embodiment will be described with reference to FIG. In this modification, the body body 21, the connecting member 22, and the holding member 23 in the nozzle body 17 are integrally formed, and the nozzle cylinder 18 is fixed. That is, the nozzle body 17 includes a cylindrical annular seal member 63 provided at the tip, and a holding connection member 71 that holds the annular seal member 63 and is connected to the injector body 12. .

  The holding connecting member 71 is made of a metal material such as stainless steel or steel, and has a small diameter screw that is screwed into the member main body 72 holding the annular seal member 63 and the nozzle cylinder 18 at the tip and the injector main body 12. The mating portion 73 and a large-diameter tool hooking portion 74 interposed between the member main body 72 and the screwing portion 73 are integrally formed. A holding portion 75 that holds (fixes) the nozzle cylinder 18 at the axial center portion and holds the annular seal member 63 at the peripheral edge portion is formed at the distal end portion of the member main body 72. An annular peripheral portion of the holding portion 75 protrudes forward, and an annular seal member 63 is attached to this protruding portion. In addition, a plurality of second discharge ports 36 that are equally arranged in the circumferential direction are opened between the nozzle cylinder 18 and the annular seal member 63 in the holding portion 75, and a plurality of second injection channels 37 that are connected to the second discharge ports 37. Is formed.

  The adhesive flow path 43 in this modified example is formed in the part of the member main body 72 located behind the holding part 75, the shaft center part extending to the tool hooking part 74 and the screwing part 73, and at the downstream end thereof. One injection channel 26 and a plurality of second injection channels 37 communicate with each other. Therefore, the adhesive R flowing into the adhesive flow path 43 from the injector main body 12 is divided into one flowing into the first injection flow path 26 and one flowing into the plurality of second injection flow paths 37, and the first flow. The ink is discharged from the discharge port 24 and the plurality of second discharge ports 36, respectively.

  Also in this modified example, the second discharge port 36 is located outside the decorative material 5. Therefore, in the adhesive injection process using the injection nozzle 13, the adhesive R discharged from the second discharge port 36 is inserted from the hole opening 9 through the inner peripheral surface of the annular seal member 63 serving as a flow path. It is injected into the hole 8. Therefore, the adhesive R can be sufficiently spread over the insertion hole 8, the first floating portion 6, and the second floating portion 7.

  According to the above configuration, the adhesive R is discharged from the first discharge port 24 through the first injection channel 26 of the nozzle cylinder 18 and is gradually filled from the deepest portion of the insertion hole 8, and the concrete casing 2 And flows into the first floating portion 6 between the mortar 4 and the mortar 4. At the same time, the adhesive R is discharged from the second discharge port 36 through the second injection flow path 37 and filled from the front side of the insertion hole 8, and the mortar 4, the decorative material 5, To the second floating part 7 between. Accordingly, the adhesive can be reliably injected into the insertion hole 8, the first floating portion 6, and the second floating portion 7.

  DESCRIPTION OF SYMBOLS 2 ... Concrete frame 4 ... Mortar 5 ... Decoration material 8 ... Insertion hole 9 ... Hole opening 12 ... Injector body 13 ... Injection nozzle 17 ... Nozzle body 18 ... Nozzle 24 ... 1st discharge port 26 ... 1st injection flow path 31 ... Seal part 36 ... Second discharge port 37 ... Second injection flow path 43 ... Adhesive flow path 63 ... Annular seal member 75 ... Holding part R ... Adhesive

Claims (7)

This is an injection nozzle for the pinning method that is attached to the injector body and injects the adhesive into the insertion hole that penetrates the decorative material and mortar and drills the casing to a predetermined depth while sealing the hole opening. And
A nozzle body that is attached to the injector body and has an adhesive channel that is continuous with the injector body inside,
A nozzle cylinder having a base end side held by the nozzle body,
The nozzle cylinder has a first discharge port that opens at a tip and communicates with the adhesive flow path.
An injection nozzle for a pinning method, wherein the nozzle body has a second discharge port that opens at a tip portion so as to face the hole opening and communicates with the adhesive flow path. The tip of the nozzle body is inserted into the hole opening, seals the hole opening at the outer peripheral surface, and has a tapered seal portion that holds the nozzle cylinder at the axial center part,
2. The injection nozzle for the pinning method according to claim 1, wherein the second discharge port is opened at a portion to be inserted into the hole opening of the seal portion.   3. The second discharge port is disposed so as to be positioned in front of the surface of the mortar in a state where the tip end portion of the nozzle body is inserted into the hole opening and sealed. An injection nozzle for the pinning method described in 1. The tip of the nozzle body is in contact with the opening edge of the decorative material in which the hole opening is formed, and an annular seal portion that seals the hole opening;
Holding the annular seal part at the peripheral part and holding the nozzle cylinder at the axial center part, and
2. The injection nozzle for the pinning method according to claim 1, wherein the second discharge port is located between the annular seal portion and the nozzle cylinder and opens to the holding portion. The nozzle tube is formed with a first injection channel that communicates the adhesive channel and the first discharge port,
The nozzle body is formed with a second injection channel that communicates the adhesive channel and the second discharge port,
In the initial stage of injection of the adhesive, the flow resistance of the adhesive flowing through the first injection flow path is configured to be smaller than the flow resistance of the adhesive flowing through the second injection flow path. The injection nozzle for the pinning method according to any one of claims 1 to 4.   The injection nozzle for the pinning method according to any one of claims 1 to 5, wherein the nozzle cylinder is held so as to be movable forward and backward with respect to the nozzle body. An adhesive injector comprising the injection nozzle for the pinning method according to any one of claims 1 to 6 and the injector main body to which the injection nozzle is detachably attached, the casing, the mortar, and the mortar In the pinning method to repair the wall made of decorative materials,
A drilling step of penetrating the decorative material and the mortar, and drilling the casing to a predetermined depth to form the insertion hole;
An adhesive injection step of injecting the adhesive into the insertion hole while sealing the hole opening of the insertion hole by the adhesive injector;
A pinning method comprising: a pin insertion step of inserting an anchor pin into the insertion hole into which the adhesive has been injected.

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