CN214885555U - Building shaping template reinforcing system's dragon detains subassembly - Google Patents

Abstract

The utility model provides a dragon buckle component of a building shaping template reinforcing system, which comprises a buckle core, a buckle ring, an auxiliary handle and a dragon pin; inserting the buckle core into the inner cavity of the buckle ring, assembling the buckle ring, the buckle core and the auxiliary handle into a dragon buckle body, wherein the auxiliary handle is buckled with the buckle core handle to form a rotation control part; after a pin head arranged on the dragon pin penetrates through a rodent connecting hole on the reinforcing component, the dragon pin enters an inner cavity of the buckle core through a buckle pin inlet and a buckle core pin inlet, the buckle core is rotated by the rotating control part, a pin neck is screwed into the buckle core pin inlet, the pin head is abutted against involute surfaces on two sides of the buckle core inner cavity pin inlet, the pin head gradually approaches to the axle center of the buckle core along with the rotation of the buckle core, so that the distance between the buckle base and the pin base is reduced, the restrained reinforcing component is gradually fastened, and the dragon pin component is rapidly unlocked through reverse action. The utility model discloses a characteristic of interference fit and the high stretching resistance of material forms class bolt structure, compares the bolt system simultaneously and improves work efficiency greatly.

Description

Building shaping template reinforcing system's dragon detains subassembly

Technical Field

The utility model belongs to the technical field of the fastening technique of building templates and specifically relates to a building typical forms adds fossil fragments subassembly of system.

Background

The building formwork is a temporary supporting structure, is manufactured according to design requirements, is a concrete structure and a member which are formed according to specified positions and geometric dimensions, keeps the correct positions of the concrete structure and the member, and bears the self weight of the building formwork and external loads acting on the building formwork.

In the field construction process, the building templates need to be assembled to form the assembled concrete pouring templates meeting the requirements. The connecting and fixing method has the technical defects that installation and disassembly are slow, the connecting at the corner part of the template becomes a hinged support, and deformation and failure are easily caused by the rigidity problem of a reinforcing rod piece.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a dragon detains subassembly is the dedicated coupling assembling of solution innovation reinforcement assembly, can the high-speed joint with demolish, can carry out the locking through the position of turning back the bend point position promptly novel reinforced structure internal bending moment for zero position again, the maximum efficiency that the performance is connected eliminates the template and consolidates the technical defect that the component became invalid in corner position.

In order to solve the technical problem, the utility model provides a technical scheme lies in:

the utility model provides a building design template adds keel assembly of system, include: the dragon buckle body and the dragon pin;

the dragon buckle body comprises a buckle ring and a buckle core;

the retaining ring comprises a retaining ring base and a retaining ring pin inlet;

the buckling core comprises a buckling core pin inlet, a pin inlet notch and a buckling core inner cavity;

the dragon pin comprises a pin head, a pin neck and a pin base;

the round pin head passes behind the rodent that sets up on reinforcing component even hole, through the buckle go into the round pin mouth with it gets into to detain the core inner chamber to detain the body, round pin neck screw in it is opening to go into the round pin, round pin head butt in go into on the involute face of round pin opening both sides, along with it is rotatory to detain the core the round pin head is close to gradually detain the axle center of core, cause the buckle base with round pin base interval diminishes, locks reinforcing component gradually, and quick unblock is realized to reverse action.

Furthermore, the dragon buckle body also comprises an auxiliary handle;

the retaining ring further comprises a retaining ring inner cavity;

the buckling core also comprises a buckling core clamping groove and a buckling core handle;

the opening end of the buckling core is inserted into the inner cavity of the buckling ring, the auxiliary handle is clamped with the buckling core clamping groove from the direction of the opening end of the buckling core, and the handle biting groove of the auxiliary handle is meshed with the buckling core biting groove of the buckling core handle.

Furthermore, the retaining ring also comprises a retaining ring inner cavity and a retaining ring base;

the buckling core is also provided with a buckling core sealing plate and a pin inserting limit;

the buckle core is inserted into the buckle inner cavity, and the outer wall of the buckle core is attached to the buckle inner cavity;

the bottom surface of the retaining ring base and the reinforcing component form a contact surface, and plane uniform distribution support counter force is formed in the locking process;

the buckle core sealing plate is supported by the buckle base station, the buckle base station is in limit abutting joint with the pin, the pin inlet of the buckle core is aligned with the central shaft of the pin inlet of the buckle core, and the pin head can be inserted into the inner cavity of the buckle core.

Furthermore, the buckling core pin inlet penetrates through the buckling core annular cylinder;

the pin inlet notch is positioned in the middle of one side of the ring axial side wall of the buckle core pin inlet, the pin inlet notch is communicated with the buckle core pin inlet, and the width of the pin inlet notch is smaller than the axial width of the buckle core pin inlet;

the pin head can be inserted into the inner cavity of the buckle core in an inserting state, the pin neck enters the pin inlet opening in a rotating and locking state, the pin head abuts against involute surfaces on two sides of the pin inlet opening, the buckle body forms effective restraint on the bolt, and then the reinforcing assembly is fastened.

Furthermore, the involute surface gradually reduces the shaft radius from the pin inlet of the buckle core, so that the pin head abutted against the involute surface drives the distance between the pin base and the buckle ring base to gradually reduce when the buckle core is screwed, the reinforcing component between the pin base and the buckle ring base is gradually locked, and otherwise, the locked component can be quickly unlocked.

Furthermore, the dragon buckle body is provided with a rotary control part;

the rotation control part comprises the auxiliary handle, a core buckling sealing plate and a core buckling handle;

the buckling core sealing plate is arranged on the end face of the buckling core, a pin inserting limit is arranged on the buckling core sealing plate, when the pin inserting limit abuts against a buckling ring base station arranged on the buckling ring, a pin inserting opening of the buckling ring coincides with the center of a pin inserting hole of the buckling core, and the pin head is inserted into the inner cavity of the buckling core.

Furthermore, the auxiliary handle is provided with a clamping section and a rotation control section, and the clamping section is matched with a buckling core clamping groove of the buckling core in an embedded clamping manner; the shape of the rotary control section is symmetrical to that of the buckling core handle, and the handle biting groove of the auxiliary handle and the buckling core biting groove of the buckling core handle are pressed and meshed with each other to enable the buckling core handle and the auxiliary handle to surround the two sides of the buckling ring, so that a whole body which cannot be separated without the help of external force is formed.

Still further, the dragon pin further comprises a pin body;

the pin base, the pin trunk, the pin neck and the pin head are connected in sequence; the pin base is vertically connected with the pin body, and a process hole is formed in the side face of the pin base, which is in the same direction with the pin head;

one end of the pin body is vertically connected with the pin base, the other end of the pin body is connected with the pin neck, the pin body is a rectangular cylinder, and a frustum-shaped limiting shoulder protruding out of the pin neck is arranged on one side, close to the pin neck, of two wide side faces; the pin neck is a rectangular cylinder, two opposite side surfaces of the cylinder are connected with the limiting shoulders and are retracted into the short side surfaces of the pin body in the same direction as the pin head, a raised column base of the pin head protrudes out of the pin neck from the short side surfaces, and the arc surface of the pin head, which is close to one side of the pin neck, is abutted to the involute surface of the buckling core.

Furthermore, the short and narrow side surface of the pin trunk is propped against the side wall of the connecting hole when the dragon pin passes through the connecting hole of the reinforcing component, so that a limiting effect is achieved;

two on the two faces of round pin truck the distance between the distal end of spacing shoulder is greater than two narrow face intervals of round pin truck, be greater than the width that reinforced subassembly rodent links the hole promptly, make spacing shoulder can't insert in rodent links the hole width direction.

Furthermore, the dragon buckle component of the building shaping template reinforcing system fastens the first reinforcing component and the second reinforcing component, and the rodent connecting holes in the first reinforcing component and the second reinforcing component meet the required size;

the pin head sequentially penetrates through the first reinforcing component, the second reinforcing component, the snap ring pin inlet and the buckle core pin inlet and is inserted into the buckle core inner cavity;

the dragon buckle body is rotated, the round pin neck is inserted and is located go into the round pin and open, the arc surface of round pin head slides on the face of gradually bursting at the involute of the round pin open both sides of income round pin of butt with it, can drive the round pin head is close to gradually detain the axle center of core, the round pin base is close to in step and detains the core axle center.

Synthesize above-mentioned technical scheme, the utility model discloses the technological effect analysis that can realize as follows:

building design template adds keel assembly of system includes: the dragon buckle body and the dragon pin; the dragon pin comprises a pin head, a pin neck and a pin base; the dragon buckle body comprises a buckle ring and a buckle core; the retaining ring comprises a retaining ring base and a retaining ring pin inlet; the buckling core comprises a buckling core pin inlet, a pin inlet notch and a buckling core inner cavity; after the pin head passes through the connecting hole of the grinding tooth arranged on the reinforcing component, the pin head enters the pin opening through the buckle and enters the pin opening through the buckle to enter the buckle core inner cavity, the body of the dragon buckle is rotated, the pin neck is screwed into the buckle opening, the pin head is abutted to involute surfaces on two sides of the buckle opening, the pin head is gradually close to the axis of the buckle core along with the rotation of the buckle core, so that the distance between the buckle base and the pin base is reduced, the reinforcing component is gradually locked, and the rapid unlocking is realized through the reverse action.

The dragon round pin passes and gets into the dragon and detains the body behind the rodent on the reinforcement assembly links the hole, and rotatory round pin head is close to the axle center of detaining the core gradually along with detaining the core, causes buckle base and round pin base interval to diminish, fastens reinforcement assembly gradually, realizes fastening fast. Reverse action can make the buckle base and the base of the round pin base interval grow, realize quick unblock. The connection innovation structure for solving the problem that a novel keel system exerts the maximum efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic perspective view of a dragon buckle body provided in an embodiment of the present invention;

FIG. 2 is a perspective view of the button core of FIG. 1;

FIG. 3 is a perspective view of the button core of FIG. 1, schematically illustrated at 2;

FIG. 4 is a perspective view of the buckle of FIG. 1;

FIG. 5 is a perspective view of the auxiliary handle of FIG. 1;

fig. 6 is a schematic perspective view of a dragon pin provided by the present invention;

fig. 7 is a schematic view of an assembly state of the latching assembly provided by the present invention;

FIG. 8 is an enlarged view of a portion of FIG. 7;

fig. 9 is a schematic perspective view of a dragon buckle assembly provided by an embodiment of the present invention.

Icon: 100-dragon buckle body; 110-a retaining ring; 120-a core; 130-an auxiliary handle; 121-core clasp handle; 122-core closing plate; 123-buckling core pin inlet; 124-entering a pin notch; 125-pin insertion and limiting; 126-an involute surface; 127-button core biting slot; 128-core snap groove; 129-core lumen; 111-a retaining ring base; 112-snap ring pin entry; 113-inner cavity of retaining ring; 114-a retaining ring abutment; 131-a clamping section; 132-a transfer control section; 133-handle bite groove; 134-docking flag; 140-a transfer control part; 200-dragon pin; 201-pin head; 202-pin neck; 203-pinning the torso; 204-a pin base; 205-a spacing shoulder; 206-a fabrication hole; 310-reinforcement element one; 320-reinforcing component two.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the product of the present invention is used, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific position, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Some embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

The utility model discloses to the innovative design of coupling assembling that novel fossil fragments system goes on, can optimize and connect the atress structure, can eliminate the slow defect of original connection structure efficiency again.

In view of this, the utility model provides a building typical forms consolidates dragon of system and detains subassembly, include: a dragon buckle body 100 and a dragon pin 200; the dragon pin 200 comprises a pin head 201, a pin neck 202 and a pin base 204; the dragon buckle body 100 comprises a buckle ring 110 and a buckle core 120; the retaining ring 110 comprises a retaining ring base 111 and a retaining ring pin inlet 112; the buckle core 120 comprises a buckle core pin inlet 123, a pin inlet notch 124 and a buckle core inner cavity 129; after the pin head 201 passes through the rodent connecting hole arranged on the reinforcing component, the pin head enters the buckle core inner cavity 129 through the buckle pin inlet 112 and the buckle core pin inlet 123, the dragon buckle body 100 is rotated, the pin neck 202 is screwed into the buckle core opening 124, the pin head 201 abuts against involute surfaces 126 on two sides of the buckle core opening 124, the pin head 201 is gradually close to the axis of the buckle core 120 along with the rotation of the buckle core 120, so that the distance between the buckle base 111 and the pin base 204 is reduced, the reinforcing component is gradually locked, and the rapid unlocking is realized through the reverse action.

The dragon pin 200 passes through the rodent connecting hole on the reinforcing component and then enters the dragon buckle body 100, and the pin head 201 gradually approaches to the axis of the buckle core 120 along with the rotation of the buckle core 120, so that the distance between the buckle ring base 111 and the pin base 204 is reduced, the reinforcing component is fastened gradually, and the rapid fastening is realized. The reverse action can increase the distance between the buckle base 111 and the pin base 204, so as to realize quick unlocking. The technical problem that the installation and the removal are slow in the prior art is solved.

The shape and structure of the dragon buckle body 100 will be described in detail below:

in an alternative embodiment, please refer to fig. 1, the dragon buckle body 100 includes a buckle ring 110, a buckle core 120 and an auxiliary handle 130. The open end of the button core 120 is inserted into the retaining ring 110, the auxiliary handle 130 is pressed in from the open end of the button core 120 and combined with the button core 120 to form a rotation control part 140, and the pin neck 202 can be screwed in/out of the pin notch 124 of the button core 120 by rotating the rotation control part 140.

The shape and structure of the button core 120 are explained in detail below:

in an alternative embodiment, please refer to fig. 2 and fig. 3, an outer wall of the core 120 encloses a core cavity 129 for accommodating the dragon pin 200, the pin head 201 is inserted into the core cavity 129, and preferably, the body of the core 120 is configured as an annular cylinder. The buckling core pin inlet 123 is arranged on the outer wall of the buckling core 120, penetrates through the annular cylinder of the buckling core 120 and is communicated with the buckling core inner cavity 129; the insert notch 124 is located at a position intermediate one side of the axial side wall of the ring and communicates with the core cavity 129. Further, the core pin entrance 123 is in communication with the core pin notch 124, and the width of the core pin notch 124 is less than the axial width of the core pin entrance 123.

In an alternative of this embodiment, the buckle core 120 further includes a buckle core closing plate 122, and the buckle core closing plate 122 is disposed on a side surface of the buckle core 120 and is attached to a side end surface of an outer wall of the buckle core 120. Preferably, the plunger closure plate 122 is configured to be circular. Furthermore, a pin inserting limit 125 is convexly arranged on the core closing plate 122, and the protruding direction of the pin inserting limit 125 is consistent with the depth direction of the pin inserting notch 124. The rotation of the button core 120 drives the pin insertion limit 125 to rotate, and the user can determine the rotation angle of the button core 120 according to the position of the pin insertion limit 125.

In an alternative embodiment, the stem 120 further includes a stem slot 128, and the stem slot 128 is located on the other side of the stem 120 opposite the stem cover plate 122. The auxiliary handle 130 can be inserted into the core slot 128.

In an alternative of this embodiment, the clasp core 120 further includes a clasp core handle 121, and the clasp core handle 121 is located at an end of the clasp core 120 where the clasp core closing plate 122 is located. Preferably, the stem handle 121 is configured as a strip, and one end of the stem handle 121 is connected to the stem sealing plate 122. Further, the side of the shank 121 abuts the side of the pin insertion stop 125. Furthermore, the shank 121 is provided with a shank engaging groove 127, and when a portion of the auxiliary handle 130 is inserted into the shank engaging groove 128, another portion of the auxiliary handle 130 is connected to the shank engaging groove 127 in a manner of a snap structure.

In an optional scheme of this embodiment, the button core 120 further includes an involute surface 126, the involute surface 126 is disposed on both sides of the pin entering notch 124, and when the pin head 201 abuts against the involute surface 126, the dragon button body 100 forms an effective constraint on the dragon pin 200, thereby fastening the reinforcing component. Furthermore, the radius of the shaft of the involute surface 126 from the buckle core pin inlet 123 is gradually reduced, so that the force direction of the mechanical contact surface of the buckle core 120 and the pin head 201 always passes through the center of the buckle core 120, the self-locking of the pin head 201 can be always ensured, and simultaneously, the basic friction surface of the buckle core 120 and the buckle ring 110 is always greater than the sliding friction force formed by the release of the pin head 201 and the buckle core 120, thereby preventing the unlocking.

The shape and structure of the retaining ring 110 are described in detail below:

in an alternative embodiment, please refer to fig. 4, the outer wall of the retaining ring 110 defines a retaining ring inner cavity 113 for accommodating the buckle core 120, the buckle core 120 is inserted into the retaining ring inner cavity 113, and the outer wall of the buckle core 120 is attached to the inner wall of the retaining ring inner cavity 113, preferably, the outer wall of the retaining ring 110 is rounded.

In an alternative of this embodiment, the retaining ring 110 further includes a retaining ring base 111, and the retaining ring base 111 is located below the outer wall of the retaining ring 110 and attached to the outer wall of the retaining ring 110. Further, the lower surface of the retaining ring base 111 is flat and planar for engaging the upper surface of the reinforcement member. Further, a retaining ring base 114 is provided on the retaining ring base 111 so as to protrude along both side surfaces of the retaining ring 110. The retaining ring abutment 114 protrudes from the retaining ring cavity 113, and after the buckle core 120 is inserted into the retaining ring cavity 113, the buckle core sealing plate 122 is attached to an end surface of the outer wall of the retaining ring 110, and the pin insertion limit 125 provided on the buckle core sealing plate 122 can abut against the retaining ring abutment 114.

In an alternative embodiment, the retaining ring 110 further includes a retaining ring pin-in opening 112, and the retaining ring pin-in opening 112 extends from the lower surface of the retaining ring base 111 to the retaining ring inner cavity 113. Further, the pin head 201 can be smoothly inserted into the core cavity 129 through the buckle pin-in opening 112 and the core pin-in opening 123 by aligning the buckle pin-in opening 112 with the core pin-in opening 123.

The shape and structure of the auxiliary handle 130 will be described in detail below:

in an alternative embodiment, referring to fig. 5, the auxiliary handle 130 is a strip-shaped structure, and includes a clamping section 131 and a rotation control section 132, and one end of the clamping section 131 is attached to the right end of the rotation control section.

In an alternative embodiment, the shape of clamping section 131 is the same as the shape of core clamping slot 128, and both can be clamped. The outer surface of the clamping section 131 is also provided with a positioning mark 134 in a protruding manner, and preferably, the positioning mark 134 is triangular. When clamping section 131 is clamped in core clamping slot 128, one corner of positioning mark 134 points in the same direction as the depth direction of core pin inlet 123.

In an alternative of this embodiment, the shape of the rotary control section 132 is symmetrical to the shape of the shank 121, the rotary control section 132 is also provided with a shank engaging groove 133, and the shank engaging groove 133 of the rotary control section 132 and the shank engaging groove 127 of the shank 121 are pressed and engaged with each other to form an integral body which cannot be separated without external force.

The installation manner of the dragon buckle body 100 is explained in detail as follows:

the open end of the buckle core 120 is inserted into the buckle cavity 113, the clamping section 131 of the auxiliary handle 130 is pressed into the buckle core clamping groove 128 from the open end of the buckle core 120, meanwhile, the handle biting groove 133 of the rotation control section 132 of the auxiliary handle 130 is meshed with the buckle core biting groove 127 of the buckle core handle 121, the auxiliary handle 130 and the buckle core handle 121 are combined and encircled at two sides of the buckle ring 110 to form a rotation control part 140 which cannot be separated by means of external force, and the rotation control part 140 can rotate around the axis of the buckle ring 110. When the rotation control portion 140 rotates and the pin insertion limit 125 provided on the core closing plate 122 abuts against the retaining ring base 114 provided on the retaining ring 110, the retaining ring pin insertion opening 112 and the core pin insertion opening 123 are centered and overlapped, and the pin head 201 can smoothly enter the core cavity 129 through the pin insertion opening.

The shape and structure of the dragon pin 200 will be described in detail below:

in an alternative embodiment, referring to fig. 6, the dragon pin 200 includes a pin base 204, a pin trunk 203, a pin neck 202 and a pin head 201 connected in sequence. Further, the pin base 204 is vertically connected to the pin trunk 203, and a process hole 206 is provided on a side end surface of the pin base 204.

The pin trunk 203 is connected to the pin base 204 at one end thereof and to the pin neck 202 at the other end thereof, and preferably, the pin trunk 203 is formed as a rectangular cylinder. Furthermore, the two wide sides of the pin body 203 near the pin neck 202 are provided with a pillar-shaped spacing shoulder 205 protruding from the outer surface of the pin body 203, and the distance between the distal ends of the two spacing shoulders 205 on the two sides of the pin body 203 is greater than the distance between the two narrow sides of the pin body 203, i.e. greater than the width of the engaging hole of the connected reinforcement component, so that the spacing shoulder 205 cannot be inserted in the width direction of the engaging hole, see fig. 8.

One end of the pin neck 202 is connected with the pin trunk 203, the other end is connected with the pin head 201, preferably, the pin neck 202 is a rectangular cylinder, two opposite side surfaces of the pin neck 202 are connected with the limiting shoulder 205 in an opposite direction, two side surfaces in the same direction with the pin head 201 are retracted into the short side surface of the pin trunk 203, and the raised pillar stand of the pin head 201 protrudes out of the pin neck 202 from the two side surfaces. Further, the side of the pin head 201 near the pin neck 202 is provided with an arc-shaped surface, and the arc-shaped surface can abut against the involute surface 126 of the buckle core 120.

The installation and disassembly modes of the dragon buckle assembly of the building shaping template reinforcing system are explained in detail as follows:

in an alternative embodiment, referring to fig. 7 and 9, the first reinforcing member 310 and the second reinforcing member 320 are fastened by the dragon-fastener elements of the building sizing form reinforcement system, and the rodent connecting holes of the first reinforcing member 310 and the second reinforcing member 320 meet the required size.

The construction forming template reinforcing system adopts the installation mode of the dragon buckle assembly:

firstly, combining a buckle core 120, a buckle ring 110 and an auxiliary handle 130 to form a dragon buckle body 100;

thirdly, the pin head 201 sequentially passes through the rodent connecting hole of the first reinforcing component 310, the rodent connecting hole of the second reinforcing component 320, the buckle ring pin inlet 112 and the buckle core pin inlet 123 and is inserted into the buckle core inner cavity 129;

finally, the rotation control part 140 of the dragon buckle body 100 is rotated, the pin neck 202 is inserted into the pin entering notch 124 on the buckle core 120, the arc surface of the pin head 201 slides on the involute surfaces 126 at two sides of the pin entering notch 124 which is abutted with the arc surface, the pin head 201 is driven to gradually approach the axis of the buckle core 120, and the pin base 204 is driven to approach the axis of the buckle core 120. The first reinforcing element 310, the second reinforcing element 320 and the buckle base 111 of the dragon buckle body 100 jointly form a reaction force for resisting the base of the dragon pin 200, and the dragon pin 200 base and the buckle base 111 gradually approach with the rotation of the rotation control part 140, so that the first reinforcing element 310 and the second reinforcing element 320 are fastened.

The construction forming template reinforcing system adopts a dragon buckle assembly dismounting mode:

first, the rotation control portion 140 of the dragon buckle body 100 is rotated in the opposite direction, and the arc surface of the pin head 201 slides on the involute surfaces 126 on both sides of the pin insertion notch 124 in contact therewith, thereby driving the pin head 201 to be gradually away from the axis of the buckle core 120 and driving the pin base 204 to be away from the axis of the buckle core 120.

Next, the pin head 201 is removed from the shank cavity 129, the shank pin opening 123, the shank pin opening 112, the rodent hole of the second reinforcement member 320, and the rodent hole of the first reinforcement member 310.

Finally, the dragon buckle body 100 is disassembled.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A dragon buckle assembly of a building shaping template reinforcing system is characterized by comprising a dragon buckle body (100) and a dragon pin (200):

the dragon buckle body (100) comprises a buckle ring (110) and a buckle core (120); the retaining ring (110) comprises a retaining ring base (111) and a retaining ring pin inlet (112); the buckle core (120) comprises a buckle core pin inlet (123), a pin inlet notch (124) and a buckle core inner cavity (129);

the dragon pin (200) comprises a pin head (201), a pin neck (202) and a pin base (204);

after the pin head (201) passes through a rodent connecting hole arranged on the reinforcing component, the pin head (201) enters the buckling core inner cavity (129) through the buckling ring and the buckling core enters the pin opening (123), the dragon buckle body (100) is rotated, the pin neck (202) is screwed into the buckling pin opening (124), the pin head (201) abuts against involute surfaces (126) on two sides of the buckling pin opening (124), and along with the rotation of the buckling core (120), the pin head (201) is gradually close to the axis of the buckling core (120), so that the distance between the buckling ring base (111) and the pin base (204) is reduced, the reinforcing component is gradually locked, and the reverse action is realized to realize quick unlocking.

2. The rongeur assembly of a building sizing form reinforcement system according to claim 1, wherein the rongeur body (100) further comprises an auxiliary handle (130);

the retaining ring (110) further comprises a retaining ring inner cavity (113);

the core (120) further comprises a core clamping groove (128) and a core handle (121);

the opening end of the buckling core (120) is inserted into the buckling ring inner cavity (113), the auxiliary handle (130) is clamped with the buckling core clamping groove (128) from the opening end direction of the buckling core (120), and a handle biting groove (133) arranged on the auxiliary handle (130) is meshed with a buckling core biting groove (127) arranged on the buckling core handle (121).

3. The dragon's buckle assembly of a building sizing template reinforcement system of claim 2, wherein the buckle (110) further comprises a buckle cavity (113), a buckle abutment (114); the buckle core (120) is also provided with a buckle core closing plate (122) and a pin inserting limit (125); the buckle core (120) is inserted into the buckle inner cavity (113), and the outer wall of the buckle core (120) is attached to the buckle inner cavity (113);

the bottom surface of the retaining ring base (111) forms a contact surface with the reinforcing component, and plane uniform support counter force is formed in the locking process;

the buckle core closing plate (122) is supported by the buckle ring base (114), when the buckle ring base (114) is abutted to the pin inserting limit (125), the central shaft of the buckle ring pin inserting opening (112) is aligned to the central shaft of the buckle core pin inserting opening (123), and the pin head (201) can be inserted into the buckle core inner cavity (129).

4. The dragon's buckle assembly of a building sizing formwork reinforcement system of claim 2, wherein the buckle core entry pin opening (123) extends through the buckle core (120) annular cylinder;

the pin inlet notch (124) is positioned in the middle of one side of the ring axial side wall of the buckle core pin inlet (123), the pin inlet notch (124) is communicated with the buckle core pin inlet (123), and the width of the pin inlet notch (124) is smaller than the axial width of the buckle core pin inlet (123);

the bolt head (201) can be inserted into the buckle core inner cavity (129) in an inserting state, the bolt neck (202) enters the bolt entering notch (124) in a rotation locking state, the bolt head (201) abuts against involute surfaces (126) on two sides of the bolt entering notch (124), and the buckle body (100) forms effective constraint on the bolt (200) so as to fasten the reinforcing component.

5. The toggle assembly of the building sizing template reinforcement system of claim 4,

the involute surface (126) starts to reduce the shaft radius gradually from the buckling core pin inlet (123) so that the pin head (201) abutted against the involute surface drives the distance between the pin base (204) and the buckle ring base (111) to gradually reduce when the buckling core (120) is screwed, the reinforcing component between the pin base (204) and the buckle ring base (111) is gradually locked, and otherwise, the locked component can be quickly unlocked.

6. The toggle assembly of the building sizing template reinforcement system of claim 4,

the dragon buckle body (100) is provided with a rotary control part (140);

the rotation control part (140) comprises the auxiliary handle (130), a buckle core sealing plate (122) and the buckle core handle (121);

the buckle core sealing plate (122) is arranged on the end face of the buckle core (120), a pin inserting limit (125) is arranged on the buckle core sealing plate (122), when the pin inserting limit (125) is abutted to a buckle base (114) arranged on a buckle ring (110), the center of a pin inserting hole (112) of the buckle core (120) coincides with the center of a pin inserting hole of the buckle core, and the pin head (201) is inserted into the inner cavity (129) of the buckle core.

7. The dragon buckle assembly of the building sizing formwork reinforcement system according to claim 6, wherein the auxiliary handle (130) is provided with a clamping section (131) and a rotation control section (132), and the clamping section (131) is in embedded clamping fit with a buckle core clamping groove (128) of the buckle core (120); the shape of the rotary control section (132) is symmetrical to that of the buckling core handle (121), and the handle biting groove (133) of the auxiliary handle (130) and the buckling core biting groove (127) of the buckling core handle (121) are pressed and meshed with each other to enable the buckling core handle (121) and the auxiliary handle (130) to encircle the two sides of the buckling ring (110), so that an integral body which cannot be separated without external force is formed.

8. The dragon's buckle assembly of a building sizing template reinforcement system of claim 1, wherein the dragon pin (200) further comprises a pin torso (203);

the pin base (204), the pin trunk (203), the pin neck (202) and the pin head (201) are connected in sequence; the pin base (204) is vertically connected with the pin body (203), and a process hole (206) is formed in the side surface of the pin base (204) in the same direction as the pin head (201);

one end of the pin body (203) is vertically connected with the pin base (204), the other end of the pin body is connected with the pin neck (202), the pin body (203) is a rectangular cylinder, and a frustum-shaped limiting shoulder (205) protruding out of the pin neck (202) is arranged on one side of two wide side faces, close to the pin neck (202); the pin head (201) is connected to pin trunk (203) one side, the other side, pin neck (202) is rectangular cylinder, two opposite side faces of cylinder are connected with limiting shoulder (205), two side faces in the same direction with pin head (201) are retracted to the short side face of pin trunk (203), the protruding base of pin head (201) protrudes from the short side face of pin neck (202), the arc face of one side of pin head (201) close to pin neck (202) is abutted to involute face (126) of buckle core (120).

9. The toggle assembly of the building sizing template reinforcement system of claim 8,

the short narrow side face of the pin trunk (203) is abutted against the side wall of the connecting hole when the dragon pin (200) penetrates through the rodent connecting hole of the reinforcing component, so that a limiting effect is achieved;

two on the two faces of round pin trunk (203) the distance between the distal end of spacing shoulder (205) is greater than the two narrow face intervals of round pin trunk (203), be greater than the width that reinforced subassembly rodent links the hole promptly, make spacing shoulder (205) link the unable insertion of hole width direction at the rodent.

10. The dragon's buckle assembly of the building sizing form reinforcement system of claim 2, wherein the dragon's buckle assembly of the building sizing form reinforcement system fastens a first reinforcement member (310) and a second reinforcement member (320), and the rodent connection holes of the first reinforcement member (310) and the second reinforcement member (320) meet a desired size;

the pin head (201) sequentially penetrates through the first reinforcing component (310), the second reinforcing component (320), the buckle ring pin inlet (112) and the buckle core pin inlet (123) and is inserted into the buckle core inner cavity (129);

the dragon buckle body (100) is rotated, the pin neck (202) is inserted into the pin inserting opening (124), the arc surface of the pin head (201) slides on involute surfaces (126) on two sides of the pin inserting opening (124) which is abutted against the arc surface, the pin head (201) can be driven to gradually approach to the axis of the buckle core (120), and the pin base (204) is synchronously close to the axis of the buckle core (120).

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