CN212316913U - Supporting body anchor rod and supporting body anchor rod with bag - Google Patents

Abstract

The utility model provides a supporting body anchor rod, which comprises an anchor rod body and at least one supporting body sleeved on the anchor rod body, wherein the outer surface of the anchor rod body is provided with external ribs; the nesting surface of the supporting body and the anchor rod body is provided with inner ribs matched with the outer ribs, and the supporting body is nested in the anchor rod body and meshed with the outer ribs; and a flexible interlayer is arranged between the outer rib of the anchor rod body and the inner rib of the bearing body. The utility model discloses utilize flexible interbedded deformation, can improve the occlusal force of supporting body on the stock body of rod, reduce or avoid the stock when drawing the stress concentration that probably produces between the supporting body and the stock body of rod, make simultaneously the impetus that is used in on supporting body and the slip casting body tend to the equilibrium, stock anchor strength increases substantially, has reliably guaranteed the result of use and the security of stock. The utility model also provides a supporting body stock of area bag sets up a bag at the lower extreme of the above-mentioned stock body of rod, has increased the diameter of stock anchor section, has further improved the withdrawal resistance of stock.

Description

Supporting body anchor rod and supporting body anchor rod with bag

Technical Field

The utility model relates to an anchor rod technical field especially relates to a supporting body stock and have supporting body stock of bag.

Background

The anchor rod is widely applied to urban infrastructure construction and engineering construction of water conservancy, hydropower, traffic, railways, mines and the like, and comprises underground engineering, mining engineering, anti-floating and anti-overturning engineering, foundation pit and side slope maintenance and the like.

The anchor rod may be classified into a tension type anchor rod and a pressure type anchor rod according to a stress transfer manner. The anchor rod body of the tension type anchor rod is directly bonded with the grouting body, and the anchor rod and the soil body are anchored through the bonding force of the anchor rod body and the grouting body. The pressure type anchor rod can convert the pulling force of the anchor rod body into the pressure of the grouting body, the better compressive resistance of the grouting body is fully utilized, and the bearing body applies compressive stress to the grouting body, so that the grouting body and surrounding rock and soil bodies generate frictional resistance, and the bearing capacity required by the anchor rod is provided. Because the pressure type anchor rod grouting body is expanded under pressure, the limit frictional resistance between the pressure type anchor rod grouting body and the surrounding soil body is increased, the bearing capacity and the deformation performance of the pressure type anchor rod grouting body are enhanced compared with those of a tension type anchor rod, and theoretically, the pressure type anchor rod grouting body has higher anchoring force and reliability. However, in actual use, the above theoretical effect is not achieved, and the anchoring force and reliability of some bolts are also significantly reduced or even failed, so that the pressure type bolts are not widely used at present.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defect of prior art pressure type stock, improve the anchor power and the reliability of stock.

The utility model firstly provides a supporting body anchor rod, which comprises an anchor rod body and at least one supporting body sleeved on the anchor rod body, wherein the outer surface of the anchor rod body is provided with external ribs; the nesting surface of the supporting body and the anchor rod body is provided with inner ribs matched with the outer ribs, and the supporting body is used for being nested in the anchor rod body and meshed with the outer ribs; and a flexible interlayer is arranged between the outer rib of the anchor rod body and the inner rib of the bearing body.

In particular, the flexible interlayer is disposed between at least one occlusal surface of the rib side of the outer rib and the rib side of the inner rib.

Specifically, the outer rib of the outer surface of the anchor rod body is a spiral thread, the supporting body is provided with a through hole, the inner rib is arranged on the inner surface of the through hole, the inner rib is a spiral thread matched with the spiral thread of the outer surface of the anchor rod body, and the supporting body is sleeved on the anchor rod body in a spiral mode.

Specifically, the outer ribs on the outer surface of the anchor rod body are herringbone, crescent or spiral ribs, the supporting body comprises a cylinder body, and the inner surface of the cylinder body is provided with herringbone, crescent or spiral ribs matched with the outer ribs of the anchor rod body; the barrel is provided with a bearing plate.

Specifically, the outer rib of the anchor rod body is herringbone, crescent or spiral, the supporting body comprises a cylinder body, the inner surface of the cylinder body is provided with herringbone, crescent or spiral matched with the outer rib of the anchor rod body, and the cylinder body is formed by splicing at least two splicing units arranged in rows along the circumferential direction into a whole.

Specifically, the splicing units are two, wherein one sides of the left half cylinder body and the right half cylinder body are hinged, and the other sides of the left half cylinder body and the right half cylinder body are connected into a whole through a connecting piece or fixed into a whole through clamping; or the two sides of the left half cylinder body and the right half cylinder body are connected into a whole through connecting pieces, or are fixed into a whole through clamping, or are fixed into a whole through binding of ropes or iron wires.

Specifically, the number of the splicing units is 2-4, the splicing units are fixedly spliced into a whole through binding of ropes or iron wires, or an outer cylinder or a circular ring is sleeved on the outer side of each splicing unit, and the splicing units are hooped through the outer cylinders or the circular rings, so that the splicing units are spliced into a whole.

Specifically, the flexible interlayer is a flexible pipe sleeved on the outer rib of the anchor rod body, and the pipe wall of the flexible pipe is attached to the outer rib in a concave-convex manner along with the shape of the outer rib of the anchor rod body; or, the geotextile is wound on the outer rib of the anchor rod body; or the heat-shrinkable film is attached to the outer ribs of the anchor rod body or/and the inner ribs of the bearing body.

Specifically, the flexible interlayer has a thickness of 300 μm to 7 mm.

The utility model also provides a supporting body stock of area bag, it is in above on the stock body of rod of supporting body stock, still be equipped with the bag, the bag with the supporting body interval sets up.

Specifically, an anti-corrosion sleeve is further arranged on the anchor rod body.

Furthermore, the anchor rod body is further surrounded with a reinforcing framework, and the reinforcing framework is a spring, a spiral hoop or a cylindrical steel wire mesh.

The utility model discloses the supporting body stock can make no longer be the rigid contact between the stock body of rod and the supporting body through set up flexible intermediate layer between the stock body of rod and the supporting body fitting surface, and usable flexible interbedded buffering or deformation avoid the stock body of rod and the supporting body occlusal surface between stress concentration that probably produces, avoid the supporting body to take place to destroy. Meanwhile, when the bearing body is under the uneven pressure of the grouting body, the flexible interlayer can be used for buffering or/and deforming to bear a part of load higher than the average value of the pressure, so that the pressure finally acting on the bearing body tends to be balanced, the bearing body and the grouting body are prevented from being crushed and cracked due to unbalanced stress, the stress states of the bearing body and the grouting body can be improved, the anchoring strength and reliability of the anchor rod are greatly improved, and the using effect and safety of the anchor rod are reliably ensured. And because the characteristic that flexible intermediate layer itself has, can overcome the machining error of the stock body of rod and supporting body fitting surface, make closely laminating between the stock body of rod, flexible intermediate layer, the supporting body, its effectual bonding area increases, and then has improved the occlusal force of supporting body on the stock body of rod, has improved the withdrawal resistance and the reliability of stock.

By adopting the carrier anchor rod and the anchor rod with the bag, the defects caused by stress concentration of the occlusal surface of the anchor rod body and the carrier and unbalanced stress of the carrier can be overcome, and the defects caused by unbalanced pressure between the carrier and the grouting body can be overcome.

Drawings

Fig. 1A is a schematic view of the anchor rod body structure of the present invention;

FIG. 1B is a schematic view of the structure of the supporting body of the present invention;

FIG. 2 is a schematic view of the prior art bearing body in a stressed and engaged state when the bearing body is sleeved on the anchor rod body;

FIG. 3 is a schematic view showing the stress and the fitting state of the supporting body of the present invention when the supporting body is fitted over the anchor rod body;

fig. 4 is a schematic structural view of an embodiment of the anchor rod of the supporting body of the present invention;

fig. 5 is a schematic structural view of a second embodiment of the anchor rod of the supporting body of the present invention;

fig. 6 is a schematic view of the third structure of the anchor rod of the supporting body of the present invention;

fig. 7A is a schematic view of an embodiment of a supporting body of a fourth splicing structure according to an embodiment of the supporting body anchor rod of the present invention;

fig. 7B is a schematic view of an embodiment of a supporting body of a fourth splicing structure according to an embodiment of the supporting body anchor rod of the present invention;

fig. 7C is a schematic view of a fourth embodiment of the supporting body anchor rod of the present invention in a third splicing structure;

fig. 8 is a schematic structural view of an embodiment of a carrier anchor rod of the present invention;

fig. 9 is a schematic view of a sixth embodiment of the anchor rod of the supporting body of the present invention;

fig. 10 is a schematic structural view of an embodiment of a support anchor of the present invention;

fig. 11 is an eight-structural schematic view of the embodiment of the anchor rod of the supporting body of the present invention;

fig. 12 is a schematic view of three different external rib structures on the outer surface of the anchor rod body of the carrier body of the present invention;

wherein,

1-anchor rod body;

11-external ribbing; 1101-external ribbed sole; 1102 — outer rib crest; 1103 — outer rib side;

111-external rib spiral; 112-external rib crescent; 113-outer rib chevron;

2-a carrier;

21-a carrier plate; 211-half carrier plate; 212- -an arc plate;

22-cylinder body; 221-half cylinder; 222-an arc plate;

23-internal ribbing; 2301-inner rib crest; 2302-inner ribbed sole; 2303 — inner rib side;

231-inner rib spiral; 232-inner rib crescent;

24-a connecting portion; 25-a connector;

26-reinforcing ribs; 27- -outer cylinder; 28-steel wire or rope;

3-a flexible interlayer; 4-a pouch; 5, reinforcing the framework; 6-corrosion-resistant sleeve.

Detailed Description

Referring to fig. 3, fig. 4, fig. 5, fig. 6, fig. 8, the utility model provides a supporting body stock at first, including the stock body of rod 1 and an at least supporting body 2 that can arrange the anchor hole in, 2 registrates on the stock body of rod 1 of supporting body, at the surface of the stock body of rod 1, is equipped with outer rib line 11, 2 supporting bodies on be equipped with interior rib line 23, interior rib line 23 sets up on the registrate face that corresponds with the stock body of rod 1 surface, its shape and position correspond and match with outer rib line 11 on the stock body of rod 1, make 2 registrates of supporting body install on the stock body of rod 1 to through the interlock of the outer rib line 11 on the interior rib line 23 that sets up on it and the stock body of rod 1 for bear the pulling force. The utility model discloses the innovation point lies in, between the outer rib 11 of the stock body of rod 1 and the interior rib 23 of supporting body 2, still be provided with flexible intermediate layer 3.

The above structure of the present invention is designed based on repeated research and multiple tests and verifications by the applicant. In the actual use of the pressure type anchor rod, the tensile force borne by the anchor rod body 1 is transmitted to the supporting body 2 through the occlusion of the outer rib 11 and the inner rib 23 on the supporting body 2, the bearing surface of the supporting body 2 extrudes (cement) grouting body forwards to transmit the force to the grouting body, the grouting body transmits the force to the rock-soil body through the frictional resistance of the rock-soil body on the wall of the anchor hole, and thus the anchor rod body 1 obtains the anchoring force of the rock-soil body. As shown in fig. 1A and 1B, the external rib 11 of the anchor rod body 1 is composed of an external rib bottom 1101. An outer rib top 1102 and outer rib sides 1103 located at both sides of the outer rib top 1102; the inner ribs 23 on carrier 2 consist of an inner rib base 2302, an inner rib top 2301 and inner rib sides 2303 on either side of the inner rib top 2301. The outer rib 11 on the anchor rod body 1 and the inner rib 23 on the supporting body 2 are engaged in a force transmission mode: the occlusion of the outer rib 11 on the anchor rod body 1 and the inner rib 23 on the supporting body 2 is matched through the concave-convex occlusion of the inner rib and the outer rib, when the anchor rod body 1 is under tension, the outer rib 11 of the anchor rod body 1 and the inner rib 23 on the supporting body 2 transmit force through occlusion, namely, the outer rib side 1103 and the inner rib side 2303 generate pushing and blocking extrusion force transmission, and the contact is direct contact and rigid. Referring to fig. 2, in the actual use of the anchor rod, the outer ribs 11 of the anchor rod body 1 are relatively coarse, most of the supporting body 2 is cast by cast iron or engineering plastics, the inner ribs 23 are also relatively coarse, and certain processing errors exist in all parts. Therefore, when the anchor rod is subjected to upward tension, because the anchor rod body 1 and the carrier body 2 are in rigid contact, the outer rib 11 of the anchor rod body 1 and the inner rib 23 of the carrier body 2 are in meshing contact, if the meshing contact parts a and b of the outer rib side 1103 and the inner rib side 2303 cannot be completely attached according to design requirements, the outer rib side 1103 of the anchor rod body 1 and the inner rib side 2303 of the carrier body 2 are in macroscopic surface contact, and actually are in point contact, so that stress concentration easily occurs, and the carrier body 2 is easy to crack and break when stressed. The applicant has made a lot of experiments to find that the breaking load of the supporting body 2 is much smaller than the theoretical calculated value, and the reason is that the contact stress of the occlusion parts a and b of the outer rib 11 and the inner rib 23 is concentrated, and the result finally causes the drawing bearing capacity of the anchor rod to be greatly reduced, namely the anchoring force is reduced, so that the anchor rod fails. Meanwhile, the bearing body 2 is also subjected to pushing, blocking and extruding stress of the bearing surface and the grouting body. Receive the influence of multiple factor during the stock construction, the position of the stock body of rod 1 in the anchor eye is not totally in the centering position, more or less can have certain skew, and some slopes also can appear in the stock axis, and the supporting body 2 also can have with the not very accurate problem of stock body of rod 1 cooperation. Thus, the carrier 2 is mounted on the anchor rod 1, the bearing of the carrier 2The pressure at which the carrier surface pushes against the grout is also not completely uniform. When the anchor is pulled upwards, the grout creates a greater resistance pressure P (load) on the carrier 2, which however is not the same throughout, which results in different loads being carried by different locations of the carrier 2. As shown in fig. 2, the resistance pressure (load) P on both sides of the carrier 2₁' and P₂' are not equal. Because the bearing area of the bearing body 2 is limited by the diameter of the anchor hole to be smaller, the grouting body is formed by cement paste or cement mortar after being injected into the anchor hole and then solidified, the strength is lower, and the grouting body is a key factor for restricting the pulling resistance of the pressure type anchor rod, the unbalanced load easily causes stress concentration and local damage to the grouting body, so that the anchoring force is reduced, and even the anchor rod fails.

Referring to fig. 3, 4, 5, 6 and 8, the present invention is based on the above-mentioned researches, and a flexible interlayer 3 is disposed between the outer rib 11 of the anchor rod body 1 and the inner rib 23 of the supporting body 2. Because the existence of flexible intermediate layer 3 makes no longer be rigid contact between the stock body of rod 1 and the supporting body 2, the clearance that the coarse cooperation of stock body of rod 1 and supporting body 2 and machining error produced can compensate through flexible intermediate layer 3, the stress that interlock department a, b produced originally between the supporting body 2 and the stock body of rod 1 can accept through flexible intermediate layer 3 and produce corresponding deformation (see fig. 3), thereby avoid producing stress concentration between the supporting body 2 and the stock body of rod 1, the destruction load of supporting body can generally improve more than one time. And because the setting of flexible intermediate layer 3, the good deformability of flexible intermediate layer 3 can fill the fit clearance between the stock body of rod 1 and the supporting body 2, guarantees closely laminating between stock body of rod 1, flexible intermediate layer 3, the supporting body 2, and its effectual faying face increases, and the atress is more even, and is more comprehensive, has improved the interlock power of supporting body 2 on the stock body of rod 1, has improved the bearing capacity of supporting body 2. Pressure P on both sides of the carrier 2₁And P₂At different times, the side with higher pressure will absorb or absorb some of the force by deforming the flexible interlayer 3, so as to coordinate the load P on the supporting body 2₁And P₂So that the pressure finally acting on the bearing body 2 tends to be balanced, and the cement paste on the side with larger stress of the bearing body 2 can be prevented from being crushed in advanceTherefore, after the flexible interlayer 3 is arranged, when the rib side of the outer rib 11 of the anchor rod body 1 pushes the rib side of the inner rib 23 of the bearing body 2, the phenomenon of uneven pressure is obviously improved due to the coordination effect of buffering and deformation of the flexible interlayer 3, and the pulling resistance of the anchor rod is improved. Through multiple tests, the applicant repeatedly draws after the cement slurry is solidified to reach the design age, observes and records the cracking condition of the surface of the grouting body, and finds that the anchor rod provided with the flexible interlayer 3 improves the test load by more than 50%. The utility model discloses a set up flexible intermediate layer 3 between the outer rib line 11 of the stock body of rod 1 and the interior rib line 23 of supporting body 2, the clearance when can compensate outer rib line 11 and interior rib line 23 cover, and have higher appearance tolerance and warp coordination ability when receiving unbalanced pressure, need not carry out secondary finish machining to outer rib line 11 and interior rib line 23 and improve the cooperation precision, and is with low costs, economical and practical, easy to operate.

In the specific structural design, a certain gap can be reserved between the outer rib 11 of the anchor rod body 1 and the inner rib 23 of the bearing body 2. The gap can be selected according to the material of the flexible interlayer 2, so that transition fit is formed between the outer rib 11 of the anchor rod body 1 and the inner rib 23 of the bearing body 2, namely, a gap which is slightly smaller than or slightly larger than or equal to the thickness of the flexible interlayer 2 is reserved between the outer rib 11 and the inner rib 23, thereby being beneficial to the deformation of the flexible interlayer 2 and not reducing the bite force of the bearing body 2 due to the overlarge fit gap between the outer rib 11 and the inner rib 23.

The utility model discloses in the above structural design, flexible intermediate layer 3 is located the intermediate level between the outer rib 11 of the stock body of rod 1 and the interior rib 23 of supporting body 2, and flexible intermediate layer 3 sets up multiple form: (1) the outer rib 11, the flexible interlayer 3 and the inner rib 23 of the anchor rod body 1 are completely attached, namely, the outer rib top 1102, the flexible interlayer 3 and the inner rib bottom 2302, the inner rib top 2301, the flexible interlayer 3 and the outer rib bottom 1101, the outer rib side 1103, the flexible interlayer 3 and the inner rib side 2303 are completely contacted and attached with each other, as shown in fig. 3, 4 and 8; (2) the flexible interlayer comprises an outer rib top 1102, a flexible interlayer 3 and an inner rib bottom 2302, wherein the inner rib top 2301, the flexible interlayer 3 and the outer rib bottom 1101, and an outer rib side 1103 and a flexible interlayer 3 in one direction are attached to the inner rib side 2303 in one direction (namely, the rib side of one direction of the outer rib 11 and the inner rib 23 is attached to the flexible interlayer 3, and the flexible interlayer 3 is not arranged on the rib side in the other direction); (3) as shown in fig. 5, the flexible interlayer 3 is provided between the outer rib side 1103 and the inner rib side 2303 in only one direction, and the three are attached, and the flexible interlayer 3 is not provided between the outer rib top 1102 and the inner rib bottom 2302, and between the inner rib top 2301 and the outer rib bottom 1101, and may have a gap; (4) as shown in fig. 6, the flexible interlayer 3 is provided between the outer rib side 1103 and the inner rib side 2303 in both directions, and the three are bonded, and there may be a gap between the outer rib top 1102 and the inner rib bottom 2302, and between the inner rib top 2301 and the outer rib bottom 1101, without providing the flexible interlayer 3. In each of the above cases, the flexible interlayer 3 should be disposed between at least one occlusal surface of the rib side of the outer ribs 11 and the rib side of the inner ribs 23, i.e. the flexible interlayer 3 should be disposed between at least one occlusal surface when the two outer rib sides 1103 and the two inner rib sides 2303 are engaged with each other (as shown in fig. 5). This is because the outer rib side 1103 and the inner rib side 2303 are the actual force-bearing surfaces for transferring the load when the outer rib 11 of the bolt body 1 engages with the inner rib 23 of the carrier 2. During specific construction, in the (1) and (2) cases, the flexible interlayer 3 can be attached to the anchor rod body 1, and then the inner ribs 23 of the bearing body 2 are sleeved and pressed on the flexible interlayer 3 to be meshed with the outer ribs 11 of the anchor rod body 1; in the cases (3) and (4), the flexible material (strip) is sprayed along the outer rib side 1103 or/and the inner rib side 2303 of the anchor rod body 1 by a fixed-point rolling spraying method or the like to form a layer of thin film material by coagulation. Since the anchor tension is axial and mainly comprises the engagement and abutting force of the outer rib side 1103 and the inner rib side 2303, the structural design can completely ensure the effective engagement of the outer rib side 1103 and the inner rib side 2303, the outer rib top 1102 can not abut against the inner rib bottom 2302, the outer rib bottom 1101 can not abut against the inner rib top 2301, the problem that the engagement of the outer rib side 1103 and the inner rib side 2303 is unreliable due to the abutment of the outer rib top 1102 against the inner rib bottom 2302 and the abutment of the outer rib bottom 1101 against the inner rib top 2301 can be avoided, the diameter of the anchor rod body 1 can be reduced, and the increase of the rib depth of the anchor rod body 1 for ensuring the effective engagement with the carrier 2 is not needed during the anchor rod body processing.

Referring to fig. 3, 4, 5, 6 and 8, in a specific structure design, the external ribs 11 on the outer surface of the anchor rod body 1 can be spiral threads, the supporting body 2 has a through hole, the inner surface of the through hole has internal ribs 23, the internal ribs 23 are spiral threads matched with the spiral threads of the anchor rod body 1, and the supporting body 2 is sleeved on the anchor rod body 1 through a spiral method. With the structure, the supporting body 2 can be directly screwed and sleeved on the anchor rod body 1 in the field installation, so that the installation is convenient and fast. It can be understood that the structure is only required to have an inner surface of the carrier 2, and the inner surface is processed with the spiral thread matching with the spiral thread on the anchor rod body 1, so as to ensure that the carrier 2 is screwed on the anchor rod body 1, which is the protection scope of the structure.

As shown in fig. 12, the outer ribs 11 and the inner ribs 23 of the present invention can be paired to form herringbone, crescent or spiral lines according to the matching structure of the supporting body 2 and the anchor rod body 1 or the actual requirement. For the convenience of understanding, the external rib spiral lines 111 shown in the description and the drawings of the present invention are the spiral lines on the anchor rod body 1, the external rib crescent lines 112 are the crescent lines on the anchor rod body 1, and the external rib herringbone lines 113 are the herringbone lines on the anchor rod body 1; accordingly, the inner rib spiral pattern 231 (see fig. 7A) is a spiral pattern on the carrier body 2, the inner rib crescent pattern 232 (see fig. 7B) is a crescent pattern on the carrier body 2, and the inner rib chevron pattern (not shown) is a chevron pattern on the carrier body 2. It will be understood that the above designations are not intended to limit the rib configuration of the anchor rod body 1 and carrier 2 of the present invention, and that the shapes of the external ribs 11 and internal ribs 23 are not limited to the three forms listed above, but may be other shapes. In addition, the outer rib spiral line 111, the outer rib crescent 112 and the outer rib herringbone 113 arranged on the anchor rod body 1 are all convex structures as shown in the figures, and the inner rib spiral line 231, the inner rib crescent 232 and the inner rib herringbone corresponding to the inner rib 23 on the supporting body 2 are groove structures, based on the cognition of the general technical personnel in the field, the outer rib 11 can also be concave structures, and the inner rib 23 can also be convex structures, as long as the supporting body 2 can be ensured to be effectively sleeved in the position set by the anchor rod body 1 and to be effectively engaged, the protection scope of the utility model is that.

Referring to fig. 3, fig. 6, fig. 7A, fig. 7C and fig. 8, as a structural form of the supporting body 2 of the present invention, the supporting body 2 may include a cylinder 22 and a bearing plate 21 disposed on the cylinder 22, a plane of the bearing plate 21 is perpendicular to an axis of the cylinder 22 and an axis of the anchor rod body 1, has a certain radial width, and can be integrally formed with the cylinder 22, and is located at an upper end of the cylinder 22 during installation to bear load and provide an anchoring force; the inner wall (inner surface) of the cylinder body 22 is provided with inner ribs 23 matched with the outer ribs 11 on the anchor rod body 1. The cylinder 22 is mainly used for being connected and installed with the anchor rod body 1 so as to ensure that the supporting body 2 is matched with the anchor rod body 1 and is fixed at a designed position.

Referring to fig. 4, 5 and 7B, as another structure of the supporting body 2 of the present invention, the supporting body 2 includes a cylinder 22, the inner wall (inner surface) of the cylinder 22 is provided with an inner rib 23 matching with the outer rib 11 on the anchor rod body 1, and the structures of the outer rib 11 and the inner rib 23 can also be the above three structures. The cylinder 22 is used for being connected with the anchor rod body 1 to ensure that the bearing body 2 is matched with the anchor rod body 1 and is fixed at a designed position, and meanwhile, the wall thickness of the cylinder 22 is large, so that the design requirement of bearing load is met, the cylinder can be used for bearing load, and anchoring force is provided.

The supporting body 2 with the three different inner rib 23 structures can be of an integral structure, or can be formed by splicing at least two splicing units arranged in a row along the circumferential direction (see fig. 7A-7C), and the splicing units are integrated through connecting pieces or other modes and are occluded on the anchor rod body 1 through the flexible interlayer 3. The carrier 2 formed by the split structure may be in the structural form shown in fig. 3, 6, 7A, 7C and 8, the structural form shown in fig. 4, 5 and 7B, or other structural forms, and the split units may be two (as shown in fig. 7A and 7B), or three or four (as shown in fig. 7C). This kind of adopt amalgamation structural design's supporting body 2, simple structure, the machine-shaping is convenient, need not close soon on the stock body of rod 1 through the spiral mode, and the position of directly setting for on the stock body of rod 1 is bound, makes the outer rib 11 on the stock body of rod 1 pass through the direct interlock of flexible intermediate layer 3 on the inner rib 2 of supporting body 2, reuse connecting piece connect the locking can, can install the position that the supporting body 2 set for at the stock body of rod 1 fast at the job site. The supporting body 2 of this kind of structure, because have certain clearance between each concatenation unit, the interlock degree between supporting body 2 and the stock body of rod 1 is adjusted to the accessible concatenation mode, makes between each concatenation unit through external force locking, guarantees between supporting body 2, flexible intermediate layer 3 and the stock body of rod 1 three that the combination inseparabler, improves the bite-force to further improve the anchoring power. Referring to fig. 7A and 7B, when the cylinder 2 is formed by splicing two splicing units, the splicing units include a left half cylinder and a right half cylinder 221, wherein one side of the left half cylinder and the other side of the right half cylinder 221 can be hinged, and the other side can be connected by a connecting piece 25 or fixed by clamping (not shown); or, the left half cylinder body and the right half cylinder body 221 are connected at both sides through the connecting piece 25 (see fig. 7A), or fixed through clamping (not shown), or bound and fixed through a rope or iron wire 28 (see fig. 7B), so that the left half cylinder body and the right half cylinder body 221 are integrated. When the number of the splicing units is 2-4, the splicing units can be fixedly spliced into an integral cylinder body (not shown) through binding of ropes or iron wires, or an outer cylinder or a circular ring 27 can be sleeved outside the splicing units, and when a plurality of splicing units are surrounded on the periphery of the anchor rod body 1, the splicing units are hooped by the outer cylinder 27 or the circular ring, so that the splicing units are spliced into the integral cylinder body (see fig. 7C).

The flexible interlayer 2 of the utility model is made of flexible material, the flexibility and thickness of the flexible material can be selected according to the concrete structural performance of the anchor rod, and the flexible interlayer can be a flexible pipe sleeved on the outer rib 11 of the anchor rod body 1, and the pipe wall of the flexible pipe is in concave-convex shape along with the shape of the outer rib 11 of the anchor rod body 1 and is attached to the outer rib 11; or, the geotextile is wound on the outer rib 11 of the anchor rod body 1; or a heat-shrinkable film attached to the outer ribs of the anchor rod body 1 or/and the inner ribs 23 of the supporting body 2. Of course, other flexible materials can be used as long as the flexible materials can be closely attached to the outer ribs 11 of the anchor rod body 1 and the inner ribs 23 of the supporting body 2, can bear certain pressure and can generate certain deformation, and the protection range of the utility model is that.

The utility model discloses the result of use is relevant with flexible intermediate layer 3's thickness and flexibility. Generally speaking, rigid connection is all between prior art supporting body 2 and the stock body of rod 1 to guarantee that both pass direct, reliable of power, avoid influencing the stock anchor power. The hardness of the flexible sandwich 3 should be significantly lower than the hardness of the anchor shaft 1 and the carrier 2, but too low a thickness is required to ensure its effect. Therefore, the hardness and the deformation of the material of the flexible interlayer 3 can be selected according to actual requirements such as the meshing structure between the outer surface of the anchor rod body 1 and the supporting body 2, the anchor rod drawing force, the allowable displacement of the anchor rod and the like, and the thickness of the flexible interlayer 3 cannot exceed 7mm to the maximum extent due to the action of pressure and frictional resistance of the anchor rod of the supporting body, so that the two forces can achieve a better coordination effect. In a specific structure design, the thickness of the flexible interlayer 2 is 300 μm-7mm, wherein the selectable thickness of the plastic spraying layer is 300 μm-2mm, the selectable thickness of the thermal shrinkage film and the geotextile is 0.5-7mm, and the selectable thickness of the flexible pipe is 1-7 mm.

As another embodiment of the present invention, the present invention further provides a bag-containing anchor rod, wherein the bag-containing anchor rod is added with a bag 4 on the basis of the above-mentioned anchor rod, and the bag 4 is spaced from the supporting body 2. Referring specifically to fig. 9 and 10, the bladder 4 is located below the anchor rod 1 of the anchor rod, and may be located below the lowermost supporting body 2, and is spaced from the lowermost supporting body 2 of the anchor rod 1 by a certain distance. By injecting cement slurry into the bag 4, the cement slurry can be concentrated in the bag 4, the cement slurry is prevented from diffusing outwards, and an anchor rod which takes the anchor rod body 1 as the center and is provided with the bearing body 2 on the upper surface and the bag 4 on the lower surface is formed. The utility model discloses take stock of bag has improved the interlock performance between the supporting body 2 and the stock body of rod 1 on the one hand owing to still set up flexible intermediate layer 3 between the supporting body 2 and the stock body of rod 1, can avoid stress concentration, makes the supporting body 2 atress balanced, and on the other hand has increased the diameter of stock anchor section owing to the setting of bag 4, and its mechanical strength can increase substantially, has further improved the withdrawal resistance of stock. Moreover, due to the deformation of the flexible interlayer 3, the supporting body 2 can bear a part of force to the bag 4 when stressed, so that the supporting body 2 and the bag 4 are stressed uniformly, the uplift bearing capacity of the whole anchor rod can be improved, and the reliability is correspondingly improved.

Further, the utility model discloses take stock of bag still can be equipped with anticorrosive sleeve 6 on the stock body of rod 1. Referring specifically to fig. 10, a corrosion resistant sleeve 6 may be provided on the anchor rod 1 between the carrier 2 and the bladder 4. This is because the anchor rod 1 is generally a metal member, and when the anchor rod is grouted in site, the anchor rod 1 between the lowermost supporting body 2 and the bladder 4 may not be completely covered by cement slurry, and the anchor rod 1 may be easily eroded by groundwater or other environment for a long time. The anchor rod body 1 of the part is wrapped by the anti-corrosion sleeve 6, so that the anchoring effect and the anti-corrosion performance of the whole anchor rod after long-time use are further comprehensively ensured.

Referring to fig. 11, the utility model discloses take stock of bag on the stock body of rod 1, also can all overlap and establish the sleeve pipe 6 that has deformation and anticorrosive multiple function concurrently, improve the corrosion protection performance of the stock body of rod 1. At the sleeve section of the bearing body 2 and the anchor rod body 1, the pipe wall of the sleeve 6 is used as the flexible interlayer 3 to improve the deformation coordination performance between the bearing body 2 and the anchor rod body 1, so that stress concentration is avoided, and the bearing body 2 is stressed in a balanced manner. If the thickness and the deformation performance of the sleeve 6 can not meet the requirements, a layer of flexible interlayer 3 can be additionally arranged at the sleeved part of the supporting body 2 and the anchor rod body 1 and is arranged on the outer side or the inner side of the pipe wall of the sleeve 6.

As a further mode of the above structure, the anti-corrosion sleeve 6 can be sleeved on the whole outer surface of the anchor rod body 1, the flexible interlayer 3 is then wrapped on the outer surface of the anti-corrosion sleeve 6, and the supporting body 2 presses the flexible interlayer 3 and the anti-corrosion sleeve 6 to be occluded on the anchor rod body 1, so that the overall anti-corrosion performance of the anchor rod body 1 can be ensured, and the purpose of balancing the stress of the supporting body 2 can be realized. Or the flexible interlayer 3 can be arranged at the position of the anchor rod body 1 where the supporting body 2 is arranged, then the anchor rod body 1 is sleeved with the anti-corrosion sleeve 6, and the supporting body 2 is occluded on the anchor rod body 1 through the anti-corrosion sleeve 6 and the flexible interlayer.

Further, the utility model discloses still can encircle to set up on the stock body of rod 1 and strengthen skeleton 5, it can be spring, spiral hoop or tube-shape wire net to strengthen skeleton 5, can also be other structural style. Referring to fig. 10 and 11, an anti-corrosion sleeve 6 is sleeved on the anchor rod body 1 between the supporting body 2 and the bag 4, and a reinforcing framework 5 is further sleeved on the anti-corrosion sleeve 6, so that a reinforced cement paste body formed by solidifying the reinforcing framework 5 and cement paste and centering on the anchor rod body 1 is formed around the anchor rod body 1. Of course, when the corrosion-proof sleeve 6 is not arranged, the reinforcing framework 5 can be directly sleeved on the anchor rod body 1. The mechanical strength of the ribbed cement paste is several times higher than that of plain cement paste, the bonding strength of the rod body and the cement paste grouting body is also much higher, the mechanical strength of the anchor rod can be greatly improved, and the anchoring reliability is also enhanced.

It can be understood that any similar peripheral skeleton structure that can be sleeved on the periphery of the anchor rod body 1 and can be located between the supporting body 2 and the sac 4 is the protection scope of the present invention.

The present invention will be described in detail with reference to the following examples.

The first embodiment is as follows:

as shown in fig. 4, the carrier anchor provided by the first embodiment includes an anchor rod body 1 and a carrier 2, the outer surface of the anchor rod body 1 has an outer rib 11, the carrier 2 has a through hole, the inner wall of the through hole is provided with an inner rib 23, the inner rib is matched with the outer rib 11 of the anchor rod body 1, and a flexible interlayer 3 is arranged between the inner rib 23 and the outer rib 11.

In this embodiment, the outer rib 11 and the inner rib 23 are spiral threads with mutually matched threads, but have a suitable gap, and after the flexible interlayer 3 is arranged on the outer rib 11 of the anchor rod body 1, the supporting body 2 can be screwed on the anchor rod body 1 through the spiral threads.

Example two:

referring to fig. 5, the carrier anchor rod provided by the second embodiment includes an anchor rod body 1 and a carrier 2, the outer surface of the anchor rod body 1 is provided with an outer rib 11, the carrier 2 has a through hole, and the inner surface of the through hole is provided with an inner rib 23 matching with the outer rib 11 of the anchor rod body 1. The supporting body 2 is sleeved on the anchor rod body 1. The outer rib 11 of the anchor shaft 1 consists of an outer rib bottom 1101, an outer rib top 1102, and outer rib sides 1103 on both sides of the outer rib top 1102, and the inner rib 23 of the carrier 2 consists of an inner rib top 2301, an inner rib bottom 2302, and inner rib sides 2303 on both sides of the inner rib top 2301. In this embodiment, a flexible interlayer 3 is provided between the occlusal surfaces of the upward outer rib side 1103 and the downward inner rib side 2303. While flexible interlayers 3 are not provided between the downward facing outer rib side 1103 and the upward facing inner rib side 2303, between the outer rib top 1102 and the inner rib bottom 2302, and between the inner rib top 2301 and the outer rib bottom 1101. When the anchor rod is subjected to upward tension, the upward outer rib side 1103 and the downward inner rib side 2303 are meshed and stressed, the flexible interlayer 3 becomes a force transmission layer between the two, and other parts of the outer ribs 11 and the inner ribs 23 are not stressed. Therefore, the flexible interlayer 3 is arranged on the occlusion stress surface most directly, the required using amount of the flexible interlayer 3 is minimum, and the mechanical effect is good.

Example three:

referring to fig. 6, the outer surface of the anchor rod body 1 of the supporting body provided in the third embodiment is provided with external ribs 11, the supporting body 2 is composed of a supporting plate 21 and a cylinder 22, the inner wall of the cylinder 22 is provided with internal ribs 23, and the supporting body 2 is sleeved on the anchor rod body 1 through the cylinder 22. The external ribs 11 of the anchor rod body 1 and the internal ribs 23 of the supporting body 2 are the same in structure as those of the embodiment. In this embodiment, the outer rib side 1103 of the outer rib 11 facing upward and downward is respectively marked as an outer rib upper rib side 11031 and an outer rib lower rib side 11032, the inner rib side 1103 of the inner rib 23 facing upward and downward is respectively marked as an inner rib upper rib side 23031 and an inner rib lower rib side 23032, and the flexible interlayer 3 is respectively arranged between the occlusal surfaces of the outer rib upper rib side 11031 and the inner rib lower rib side 23032 and between the outer rib lower rib side 11032 and the inner rib upper rib side 23031, that is, the flexible interlayer 3 is respectively arranged between the two occlusal surfaces of the outer rib side 1103 and the inner rib side 2303 facing upward and downward. However, the flexible interlayers 3 are not provided between the outer rib top 1102 and the inner rib bottom 2302, nor between the inner rib top 2301 and the outer rib bottom 1101. With the structure, when the anchor rod is subjected to the circulating action of upward and downward forces, the two groups of rib sides in different directions of the outer rib 11 and the inner rib 23 can be respectively engaged and stressed, so that the anchor rod has better stress effect and wide adaptability.

In this embodiment, the outer ribs 11 and the inner ribs 23 are spiral structures, and the supporting body 2 can be screwed on the anchor rod body 1 through the spiral structures. The bearing plate 21 and the cylinder 22 of the bearing body 2 can be integrally formed, and the bearing body is convenient to process and install on site. It can be understood that the bearing plate 21 and the cylinder 22 can be separately disposed and connected to form a whole, which is the protection scope of the present invention.

Example four:

the supporting body 2 of the present embodiment is formed by splicing at least two splicing units arranged in a row along the circumferential direction into a whole, and the inner rib 23 of the whole is matched with the outer rib 11 of the anchor rod body 1.

Referring to fig. 7A, the supporting body 2 of the first split structure of this embodiment is formed by combining a supporting plate 21 and a cylinder 22, the supporting plate 21 receives a load, an inner rib 23 is provided on the cylinder 22, the inner rib 23 is an inner rib spiral 231, and is matched with the outer rib spiral 111 on the anchor rod body 1 and is fixed on the anchor rod body 1 in an engaged manner. The whole bearing body 2 comprises two splicing units, each splicing unit comprises a left half bearing body and a right half bearing body, the left half bearing body comprises a left half bearing plate 211 and a left half cylinder 221, and the right half bearing body is formed by the left half bearing plate and the right half cylinder 221. The left half bearing body and the right half bearing body surround the anchor rod body 1 to be spliced into a whole. The joint of the left half cylinder and the right half cylinder 221 is provided with a connecting part 24. The connecting portion 24 of this embodiment is the lugs that are set up respectively in the concatenation department of left half barrel and right half barrel 221 and extend outward and can mutually support, and the lug of each concatenation department superposes each other and transversely runs through there is the connecting hole, wears to be equipped with connecting piece 25 on the connecting hole. The connecting member 25 may be a bolt, a cotter pin or a steel wire which can be wound, and the connecting member 25 is a bolt in this embodiment. After the flexible interlayer 3 is coated on the periphery of the anchor rod body 1, the two splicing units (the left half bearing plate and the right half bearing plate 211 and the left half cylinder and the right half cylinder 221) can be spliced and tightly pressed against the flexible interlayer 3 through the connecting piece 25, so that the bearing body 2 is occluded on the anchor rod body 1. Between the outer walls of the left half bearing plate and the right half bearing plate 211 and the left half cylinder and the right half cylinder 221, a reinforcing rib 26 is further connected to improve the strength of the bearing plate 21 and prevent the bearing plate 21 and the cylinder 22 from being broken.

Referring to fig. 7B, the supporting body 2 of the second split structure of this embodiment is composed of a cylindrical body 22, and the cylindrical body 22 is supported and engaged with and fixed on the anchor rod body 1 and is composed of two split units. The splicing unit comprises a left half cylinder body and a right half cylinder body 221, and the left half cylinder body and the right half cylinder body surround the periphery of the anchor rod body 1 in a half-and-half mode. An annular groove is formed in the middle of the peripheries of the left half cylinder body and the right half cylinder body 221, the left half cylinder body and the right half cylinder body 221 are hooped tightly by surrounding steel wires or ropes 28 in the groove, and the left half cylinder body and the right half cylinder body 221 are fixed on the anchor rod body 1 in a holding manner.

Referring to fig. 7C, the supporting body 2 of the third splicing structure of this embodiment is formed by combining a supporting plate 21 and a cylinder 22, the supporting plate 21 supports a load, the cylinder 22 is engaged and fixed on the anchor rod body 1, the supporting body 2 is integrally formed by three splicing units, each splicing unit is formed by combining three arc units 222 and an arc 212, a plane where the arc 212 is located is perpendicular to an axis of the arc unit 222, and the combined splicing units are engaged and enclosed at the periphery of the anchor rod body 1 to form the whole supporting body 2 and are engaged on the anchor rod body 1. Then the outer cylinder 27 is sleeved on the periphery of the carrier 2 which is spliced into a whole and is compressed, so that the outer cylinder 27 and each splicing unit are fixed. And a reinforcing rib 26 is arranged between the arc-shaped plates 212 and the periphery of the arc-shaped unit 222, so that the strength of the bearing plate 21 can be improved, and the bearing plate 21 and the cylinder 22 can be prevented from being broken.

When the carrier 2 of this embodiment adopts the above-mentioned split structure, the external rib 11 disposed on the outer surface of the anchor rod body 1 may be an external rib spiral 111 (see fig. 12), and the internal rib 23 disposed on the inner surface of the cylinder 22 corresponds to an internal rib spiral 231 (see fig. 7A) matching with the external rib spiral 111; or, the external rib 11 arranged on the outer surface of the anchor rod body 1 is an external rib crescent 112 (as shown in fig. 7C), and the internal rib 23 arranged on the inner wall of the cylinder body 22 is an internal rib crescent 232 (as shown in fig. 7B) matched with the external rib crescent 112; alternatively, the outer ribs 11 provided on the outer surface of the bolt shank 1 are outer rib chevrons 113, and the corresponding inner ribs 23 provided on the inner wall of the barrel 22 are corresponding inner rib chevrons (not shown) matching the outer rib chevrons 113. The external rib of the steel bar commonly used in the engineering mainly has three forms of the spiral line, the crescent line and the herringbone line. Therefore, the anchor rod body 1 of the present embodiment can directly adopt the reinforcing steel bars without additionally processing external ribs.

This embodiment supporting body 2 adopts the amalgamation structure, can be suitable for various rib structures such as spiral line, crescent line or chevron-shaped line, can make things convenient for the quick installation of supporting body 2 at the job site, especially to the situation that needs a plurality of supporting bodies 2 of installation on the stock body of rod 1, is favorable to reducing stock whole installation and engineering time, improves the efficiency of construction.

It can be understood that the splicing structure of the supporting body 2 can also be formed by splicing and combining three or four petals, as long as the supporting body can be quickly sleeved on the anchor rod body 1 and can be fixed at a set position.

Example five:

as shown in fig. 8, the carrier 2 of the present embodiment is composed of a bearing plate 21 and a cylinder 22, the bearing plate 21 bears the load, and the cylinder 22 is engaged and fixed on the anchor rod 1. The carrier 2 of this embodiment is provided with at least two, and the interval sets up from the top down along the stock body of rod 1.

In the case of multiple carriers 2, the uppermost carrier 2 is generally first stressed and the load P applied thereto₃Under a load P than the lower carrier 2₄To be larger, i.e. P₃>P₄This can result in excessive force being applied to the uppermost carrier 2. In this embodiment, the flexible interlayer 3 is disposed between the uppermost supporting body 2 and the anchor rod body 1, so that the load of the uppermost supporting body 2 can be reduced, and the stress of the upper and lower supporting bodies 2 tends to be uniform.

It can be understood that the flexible interlayer 3 can be disposed between the uppermost supporting body 2 and the anchor rod body 1 as shown in fig. 8, or between all the supporting bodies 2 and the anchor rod body 1, and meanwhile, the flexible interlayer 3 with different thicknesses and deformation amounts can be disposed between the supporting bodies 2 and the anchor rod bodies 1 at different positions according to the stress state of the supporting bodies 2. Generally, the thickness and deformation of the flexible interlayer 3 arranged between the uppermost supporting body 2 and the anchor rod body 1 are the largest, and the thickness and deformation of the flexible interlayer 3 arranged between the lowermost supporting body 2 and the anchor rod body 1 are the smallest or no flexible interlayer 3 is arranged.

Example six:

referring to fig. 9, the present embodiment provides a carrier anchor with a pocket. The outer surface of the anchor rod body 1 is provided with outer ribs 11, the supporting body 2 is composed of a supporting plate 21 and a cylinder body 22, inner ribs 23 are arranged on the inner wall of the cylinder body 22, the supporting body 2 is sleeved on the anchor rod body 1, and the flexible interlayer 3 is located between the outer ribs 11 and the inner ribs 23, so that the supporting body 23 is meshed on the anchor rod body 1 through the flexible interlayer 3. In this embodiment, the bag 4 is disposed below the supporting body 2 and spaced from the supporting body 2. The diameter of the anchoring section of the anchor rod is increased by the bag 4, and the anchoring force is enhanced.

In order to enhance the corrosion resistance of the anchor rod body 1, on the basis of the present embodiment, a corrosion-resistant sleeve 6 may be further sleeved on the anchor rod body 1 between the supporting body 2 and the bladder 4.

Example seven:

referring to fig. 10, another carrier anchor with a bladder is provided in accordance with an embodiment of the present invention. The anchor rod body 1 is provided with a supporting body 2, the structure of the supporting body 2 is the same as that of the sixth embodiment, a flexible interlayer 3 is arranged between the anchor rod body 1 and the supporting body 2, and a bag 4 is arranged below the supporting body 2.

In this embodiment, an anti-corrosion sleeve 6 is sleeved on the anchor rod body 1 between the supporting body 2 and the bag 4 to improve the anti-corrosion property of the anchor rod body 1. Meanwhile, a reinforcing framework 5 is arranged around the anti-corrosion sleeve 6. The reinforcing frame 5 of the present embodiment is a spring, and is disposed around the periphery of the anchor rod body 1, one end of the spring abuts against the bottom surface of the bearing plate 21 of the bearing body 2, and the other end abuts against the upper end of the bag 4, so that a cement paste with a frame is formed around the anchor rod body 1, and the cement paste and the bag 4 act in cooperation, so that the mechanical strength of the anchor rod is greatly improved, and the reliability of anchoring is also enhanced.

Example eight:

referring to fig. 11, the embodiment of the present invention provides a third supporting body anchor rod with a bladder, a supporting body 2 is arranged on the anchor rod body 1, and the structure of the supporting body 2 is the same as that of the sixth embodiment.

In the embodiment, the outer surface of the anchor rod body 1 is sleeved with the anti-corrosion sleeve 6 in the whole length, and the anti-corrosion sleeve 6 has deformation and anti-corrosion functions. The supporting body 2 can be used as the flexible interlayer 3 by means of the pipe wall of the anti-corrosion sleeve 6, and if necessary, the flexible interlayer 3 can be additionally arranged on the periphery of the anti-corrosion sleeve 6 at the position where the supporting body 2 is installed or in the anti-corrosion sleeve 6.

In this embodiment, a reinforcing frame 5 is also arranged between the supporting body 2 and the bag 4, the reinforcing frame 5 is also a spring, and is sleeved around the periphery of the anti-corrosion casing 6, one end of the reinforcing frame abuts against the bottom end of the supporting plate 21 of the supporting body 2, and the other end of the reinforcing frame abuts against the upper end of the bag 4, so that a cement paste body with a frame is formed around the anchor rod body 1, and the cement paste body and the bag 4 act in cooperation with each other, so that the mechanical strength of the anchor rod is greatly improved, and the anchoring reliability is also enhanced.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (12)

1. A carrier anchor rod comprises an anchor rod body and at least one carrier sleeved on the anchor rod body, and is characterized in that,

the outer surface of the anchor rod body is provided with external ribs;

the nesting surface of the supporting body and the anchor rod body is provided with inner ribs matched with the outer ribs, and the supporting body is used for being nested in the anchor rod body and meshed with the outer ribs;

and a flexible interlayer is arranged between the outer rib of the anchor rod body and the inner rib of the bearing body.

2. The carrier anchor of claim 1, wherein the flexible interlayer is disposed between at least one mating surface of the rib side of the outer rib and the rib side of the inner rib.

3. A carrier anchor according to claim 1, wherein the external ribs of the outer surface of the anchor shaft are spiral threads, the carrier has a through hole, the internal ribs are provided on the inner surface of the through hole, the internal ribs are spiral threads matching the spiral threads of the outer surface of the anchor shaft, and the carrier is fitted onto the anchor shaft by a screwing method.

4. A carrier anchor according to claim 1, in which the external ribs on the outer surface of the anchor body are herringbone, crescent or spiral ribs, the carrier comprising a cylindrical body having an internal surface provided with herringbone, crescent or spiral ribs matching the external ribs of the anchor body; the barrel is provided with a bearing plate.

5. A carrier anchor according to claim 1, in which the external ribs of the anchor body are herringbone, crescent or spiral, the carrier comprises a cylindrical body, the inner surface of the cylindrical body is provided with herringbone, crescent or spiral matching with the external ribs of the anchor body, and the cylindrical body is formed by splicing at least two splicing units arranged in a row along the circumferential direction into a whole.

6. A carrier anchor rod according to claim 5, wherein the splicing unit is two, namely a left half cylinder body and a right half cylinder body, wherein one side of the left half cylinder body and one side of the right half cylinder body are hinged, and the other side of the left half cylinder body and the other side of the right half cylinder body are connected into a whole through a connecting piece or fixed into a whole through clamping; or the two sides of the left half cylinder body and the right half cylinder body are connected into a whole through connecting pieces, or are fixed into a whole through clamping, or are fixed into a whole through binding of ropes or iron wires.

7. The carrier anchor rod of claim 5, wherein the number of the splicing units is 2-4, the splicing units are fixedly spliced into a whole by binding ropes or iron wires, or an outer cylinder or a circular ring is sleeved outside the splicing units, and the splicing units are hooped by the outer cylinder or the circular ring so as to be spliced into a whole.

8. A carrier anchor rod according to any one of claims 1 to 7, wherein the flexible interlayer is a flexible tube fitted over the outer rib of the anchor rod, the wall of the flexible tube fitting to the outer rib in a concavo-convex shape according to the shape of the outer rib of the anchor rod; or, the geotextile is wound on the outer rib of the anchor rod body; or the heat-shrinkable film is attached to the outer ribs of the anchor rod body or/and the inner ribs of the bearing body.

9. A carrier anchor according to claim 8, in which the flexible interlayer is 300 μm-7mm thick.

10. A carrier anchor with a bladder, wherein the anchor body of the carrier anchor of any one of claims 1-9 is further provided with a bladder, and the bladder is spaced from the carrier.

11. A carrier anchor with a pocket according to claim 10, further provided with a corrosion-resistant sleeve on the anchor rod body.

12. A carrier anchor with a sack according to claim 10 or 11 characterised in that a reinforcing skeleton is also looped around the anchor rod body, the reinforcing skeleton being a spring, a spiral hoop or a cylindrical steel mesh.

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