CN209880269U - Novel three-half type cable cabling mold - Google Patents

Abstract

A novel three-half type cable stranding die comprises a first half die, a second half die and a third half die, wherein the three-half type cable stranding die is not easy to deviate under external force (such as vibration) in the cable stranding process through mutual limiting of a second T-shaped boss and a first T-shaped groove, a third T-shaped boss and a second T-shaped groove and mutual limiting of the first T-shaped boss and the third T-shaped groove, so that fine displacement generated at the joint of the three-half type cable stranding die is effectively avoided, no dead angle is generated in the process that the first half die, the second half die or the third half die are inserted into or pulled out of the three-half type cable stranding die, a first transition curved surface, a first die cavity and a second transition curved surface of the three-half type cable stranding die are kept smooth and flat, a plurality of cables and cables after stranding are ensured not to generate burrs after passing through the three-half type cable stranding die, and the cable stranding quality is favorably improved, the smoothness and the conductivity of the cable conductor surface after cabling meet the design requirements.

Description

Novel three-half type cable cabling mold

Technical Field

The utility model relates to a transposition stranding mould technical field especially relates to a novel three half formula cable stranding moulds.

Background

During cabling of cables (such as copper cables, copper alloy cables, aluminum alloy cables and the like), a plurality of single cables need to be twisted together according to a certain rule and direction, and a plurality of single cable conductors are twisted and cabled into one cable. In the cabling process, the two half-type cable cabling molds are generally adopted to limit a plurality of single cables so as to ensure the stable twisting action in the cabling process and promote the compression and sizing of the plurality of single cables. Two half formula cable stranding moulds simple structure fixes it through outside die table, lack spacing between half cable stranding mould and the other half cable stranding mould, at the actual stranding in-process of cable, because two half formula cable stranding moulds receive external force (like vibration) easily to produce the skew, arouse two half formula stranding mould combination department to produce slight displacement, cause the die cavity of two half formula stranding moulds unsmooth, the cable that causes behind the stranding easily produces the burr, influence the smoothness and the electric conductivity of cabling back cable conductor surface.

Disclosure of Invention

In view of the above, it is necessary to provide a novel three-half cable-forming mold.

The utility model provides a novel half three formula cable stranding moulds, includes half first mould, half second mould, half third mould, half first mould one side is connected with half second mould one side, half first mould opposite side is connected with half third mould one side, half second mould opposite side is connected with half third mould opposite side, sets up the self-locking piece in adjacent two halves mould junction to make half first mould, half second mould, half third mould constitute closed cable stranding mould, the inside first die cavity that is provided with of cable stranding mould, the cable stranding mould is provided with first transition curved surface along the one end of first die cavity, the cable stranding mould is provided with second transition curved surface along the other end of first die cavity, so that the cable loops through from cable stranding mould's first transition curved surface, first die cavity, second transition curved surface.

Preferably, first half mould, second half mould, third half mould structure are the same, first half mould is fan-shaped solid component, fan-shaped solid component is solid component, fan-shaped solid component one side is provided with first T type recess along fan-shaped solid component length direction with the another side junction, fan-shaped solid component another side is provided with first T type boss along fan-shaped solid component length direction, fan-shaped solid component one side is provided with first arcuation opening with the another side junction along fan-shaped solid component length direction, fan-shaped solid component one end terminal surface is excessively connected for the arcwall face with first arcuation opening junction, the arcwall face is first cambered surface, fan-shaped solid component other end terminal surface excessively connects for the arcwall face with first arcuation opening junction, the arcwall face is the second cambered surface.

Preferably, the surface area of the first cambered surface is larger than that of the second cambered surface.

Preferably, one end of the first half mold close to the first cambered surface is further provided with a first clamping table.

Preferably, the second half mold is a fan-shaped solid member, the fan-shaped solid member is a solid member, a second T-shaped groove is formed at the junction of one side of the fan-shaped solid member and the other side of the fan-shaped solid member along the length direction of the fan-shaped solid member, the second T-shaped boss is formed on the other side of the fan-shaped solid member along the length direction of the fan-shaped solid member, the second T-shaped groove is complementarily matched with the second T-shaped boss, the second T-shaped groove and the second T-shaped boss form the self-locking part, a second arc-shaped opening is formed at the junction of one side of the fan-shaped solid member and the other side of the fan-shaped solid member along the length direction of the fan-shaped solid member, the junction of one end face of the fan-shaped solid member and the second arc-shaped opening is in arc-shaped surface transition connection, the arc-shaped face is a third arc-, the surface area of the third cambered surface is larger than that of the fourth cambered surface, and a second clamping table is further arranged at one end, close to the third cambered surface, of the second half die.

Preferably, the third half die is a fan-shaped solid member, the fan-shaped solid member is a solid member, a third T-shaped groove is formed at the junction of one surface of the fan-shaped solid member and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the third T-shaped boss is formed on the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the third T-shaped groove is complementarily matched with the third T-shaped boss, the third T-shaped groove and the third T-shaped boss form the self-locking part, a third arc-shaped opening is formed at the junction of one surface of the fan-shaped solid member and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the junction of one end surface of the fan-shaped solid member and the third arc-shaped opening is in arc-shaped surface transition connection, the arc-shaped surface is a fifth arc-shaped surface, the junction of the other end surface of the, and a third clamping table is further arranged at one end, close to the fifth cambered surface, of the third half mould.

Preferably, the first arc-shaped notch, the second arc-shaped notch and the third arc-shaped notch are connected to form a first die cavity.

Preferably, the first cambered surface, the third cambered surface and the fifth cambered surface are connected to form a first transition curved surface.

Preferably, the second cambered surface, the fourth cambered surface and the sixth cambered surface are connected to form a second transition cambered surface.

Preferably, the central axes of the first die cavity, the first transition curved surface and the second transition curved surface are overlapped, and the diameter of the first die cavity is equal to the diameter of the small end of the first transition curved surface cavity and the diameter of the small end of the second transition curved surface cavity.

The utility model discloses be provided with first half mould, second half mould, third half mould, through second T type boss and first T type recess, third T type boss and second T type recess, mutual spacing of first T type boss and third T type recess, for current two half formula cable stranding moulds, three half formula cable stranding moulds receive external force (like vibration) to be difficult for appearing the skew in the cable stranding in-process, can effectively avoid the slight displacement that three half formula cable stranding mould combination department produced, second T type boss and first T type recess, third T type boss and second T type recess, first T type boss and third T type recess match each other simultaneously, in order to ensure that first half mould or second half mould or third half mould insert or extract the in-process no dead angle from three half formula cable stranding moulds, make the first transition curved surface of three half formula cable stranding moulds, the first transition curved surface of three half formula cable stranding moulds, The first die cavity and the second transition curved surface are kept smooth and flat, so that burrs are not generated after a plurality of single cables and the cabled cables pass through the three-half type cable cabling die, the cable cabling quality is improved, and the smoothness and the conductivity of the cable conductor surface after cabling meet the design requirements.

Drawings

Fig. 1 is a side view of a novel three-half type cable-forming mold in one direction.

Fig. 2 is an axial view of the novel three-half type cable forming die in the other direction.

Fig. 3 is an isometric view of the first mold half in one direction.

Fig. 4 is an isometric view of the first mold half in another orientation.

FIG. 5 is an isometric view of the second mold half.

FIG. 6 is an isometric view of the third mold half.

Fig. 7 is a schematic sectional view of a novel three-half type cable-forming mold.

In the figure: the die comprises a first half die 10, a first T-shaped groove 11, a first T-shaped boss 12, a first arc opening 13, a first arc surface 14, a second arc surface 15, a first clamping table 16, a second half die 20, a second T-shaped groove 21, a second T-shaped boss 22, a second arc opening 23, a third arc surface 24, a fourth arc surface 25, a second clamping table 26, a third half die 30, a third T-shaped groove 31, a third T-shaped boss 32, a third arc opening 33, a fifth arc surface 34, a sixth arc surface 35 and a third clamping table 36; a first mold cavity 100, a first transition surface 200, and a second transition surface 300.

Detailed Description

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

Referring to fig. 1 to 7, the present invention provides a novel triple-half type cable-laying mold, including a first half mold 10, a second half mold 20, and a third half mold 30, one side of the first half mold 10 is connected to one side of the second half mold 20, the other side of the first half mold 10 is connected to one side of the third half mold 30, the other side of the second half mold 20 is connected to the other side of the third half mold 30, a self-locking member is disposed at the joint of the two adjacent half molds, so that the first half mold 10, the second half mold 20, and the third half mold 30 form a closed cable-laying mold, a first mold cavity 100 is disposed inside the cable-laying mold, a first transition curved surface 200 is disposed along one end of the first mold cavity 100, and a second transition curved surface 300 is disposed along the other end of the first mold cavity 100, so that a cable can be laid from the first transition curved surface 200, the third transition curved surface 300, and the third half mold can be used as a cable-laying, The first cavity 100 and the second transition curved surface 300 are sequentially passed through.

It is specific, set up the self-locking piece in adjacent two halves mould junction, for current two halves formula cable stranding mould, three halves formula cable stranding moulds receive external force (if vibration) difficult appearance skew at the cable stranding in-process, can effectively avoid the slight displacement that three halves formula cable stranding mould combination department produced, make three half formula cable stranding mould's first transition curved surface 200, first die cavity 100, second transition curved surface 300 keeps smooth, level and smooth, it does not produce the burr to ensure the cable behind a plurality of single cables and the stranding behind through three halves formula cable stranding mould, be favorable to improving cable stranding quality, so that smoothness and the conductivity on cable conductor surface satisfy the designing requirement behind the stranding.

Specifically, the second T-shaped boss 22 of the second half mold 20 is inserted into the first T-shaped groove 11 of the first half mold 10, the third T-shaped boss 32 of the third half mold 30 is inserted into the second T-shaped groove 21 of the second half mold 20, the first T-shaped boss 12 of the first half mold 10 is inserted into the third T-shaped groove 31 of the third half mold 30, and the first half mold 10, the second half mold 20 and the third half mold 30 are urged to form a complete three-half type cable cabling mold by the mutual spacing between the second T-shaped boss 22 and the first T-shaped groove 11, between the third T-shaped boss 32 and the second T-shaped groove 21, and between the first T-shaped boss 12 and the third T-shaped groove 31.

Specifically, the first T-shaped groove 11, the second T-shaped groove 21 and the third T-shaped groove 31 have the same structure; the first T-shaped boss 12, the second T-shaped boss 22 and the third T-shaped boss 32 have the same structure, the second T-shaped boss 22 is matched with the first T-shaped groove 11, the third T-shaped boss 32 is matched with the second T-shaped groove 21, and the first T-shaped boss 12 is matched with the third T-shaped groove 31, so that no dead angle exists in the process of inserting or extracting the first half mold 10 or the second half mold 20 or the third half mold 30 from the three-half cable-forming mold, and meanwhile, the gaps at the joint of the second T-shaped boss 22 and the first T-shaped groove 11, the third T-shaped boss 32 and the second T-shaped groove 21, and the first T-shaped boss 12 and the third T-shaped groove 31 are reduced as much as possible, so that the first mold cavity 100 formed by connecting the first arc-shaped notch 13, the second arc-shaped notch 23 and the third arc-shaped notch 33 has a smooth and flat inner surface, and the cable-forming quality is improved.

Specifically, in the process of arranging a cable in a three-half type cable cabling mold or replacing any one half of the mold, only the first half mold 10 or the second half mold 20 or the third half mold 30 needs to be pulled out of the three-half type cable cabling mold, the cable is arranged in the three-half type cable cabling mold or any one half of the mold in the three-half type cable cabling mold is replaced, compared with the existing two-half type cable cabling mold, a limiting effect is achieved between any two half molds in the three-half type cable cabling mold, after the cable is arranged or any one half of the mold is replaced, only the first half mold 10 or the second half mold 20 or the third half mold 30 needs to be inserted into a gap where the three-half type cable cabling mold is pulled out again, extra recalibration is not needed in the inserting process, and the work efficiency is improved; the two half-type cable stranding dies have no limiting effect, one half die is easily taken out under external force, the other half die is directly taken out or the two half dies are completely taken out in the process of arranging the cable in the two half-type cable stranding dies or replacing the dies, after the cable is arranged or any half die is replaced, the two half dies are required to be calibrated again to be fixed, the die replacement efficiency is low, and if the two half dies are not calibrated accurately, burrs can also appear in the cable stranding process.

Referring to fig. 3 and 4, further, the first half mold 10, the second half mold 20, and the third half mold 30 have the same structure and have smooth and flat surfaces, the first half mold 10 is a fan-shaped solid member, the fan-shaped solid member is a solid rigid member, a first T-shaped groove 11 is formed at a junction of one surface and the other surface of the fan-shaped solid member along a length direction of the fan-shaped solid member, a first T-shaped boss 12 is formed at the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the first T-shaped groove 11 is complementarily fitted with the first T-shaped boss 12, the first T-shaped groove 11 and the first T-shaped boss 12 form the self-locking part, a first arc-shaped notch 13 is formed at the junction of the one surface and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, and a junction of one end surface of the fan-shaped solid member, the arc-shaped surface is a first arc-shaped surface 14, the joint of the end surface at the other end of the fan-shaped solid component and the first arc-shaped opening 13 is in arc-shaped surface transition connection, and the arc-shaped surface is a second arc-shaped surface 15.

Referring to fig. 3, further, the surface area of the first cambered surface 14 is larger than that of the second cambered surface 15.

Specifically, the first cambered surface 14 is the inlet end of a plurality of single cables, the larger the surface area of the first cambered surface 14 is, the more single cables can be arranged on the first cambered surface 14, and the second cambered surface 15 is the outlet end of the plurality of single cables after cabling.

Referring to fig. 3 and 4, further, a first clamping table 16 is further disposed at one end of the first half mold 10 close to the first cambered surface 14.

Specifically, first ka tai 16 is the arcuation, first ka tai 16 one end is connected with the one end that first half mould 10 is close to first cambered surface 14, the other end of first ka tai 16 extends to the outside that first half mould 10 is close to first cambered surface 14 one end, first ka tai 16 is located same horizontal plane with the one end that first half mould 10 is close to first cambered surface 14. The first clamping table 16 is used to prevent the first half mould 10 from sliding on the external fixed seat.

Specifically, the first clamping table 16, the second clamping table 26 and the third clamping table 36 are connected to form a circular ring, and the circular ring and one end of the third half type cable-forming mold close to the first transition curved surface 200 are located on the same horizontal plane and used for preventing the third half type cable-forming mold from sliding on the external fixed seat.

Referring to fig. 5, further, the second half mold 20 is a fan-shaped solid member, the fan-shaped solid member is a solid member, a second T-shaped groove 21 is formed at a junction of one surface and the other surface of the fan-shaped solid member along a length direction of the fan-shaped solid member, a second T-shaped boss 22 is formed at the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the second T-shaped groove 21 and the second T-shaped boss 22 are complementarily matched, the second T-shaped groove 21 and the second T-shaped boss 22 form the self-locking part, a second arc-shaped notch 23 is formed at a junction of one surface and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, a junction of one end surface of the fan-shaped solid member and the second arc-shaped notch 23 is an arc-shaped surface transition connection, the arc-shaped surface is a third arc-shaped surface 24, and a, the arc-shaped surface is a fourth arc-shaped surface 25, the surface area of the third arc-shaped surface 24 is larger than that of the fourth arc-shaped surface 25, and a second clamping table 26 is further arranged at one end, close to the third arc-shaped surface 24, of the second half die 20.

Referring to fig. 6, further, the third half mold 30 is a fan-shaped solid member, the fan-shaped solid member is a solid member, a third T-shaped groove 31 is formed at a junction of one surface and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, a third T-shaped boss 32 is formed at the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, the third T-shaped groove 31 is complementarily matched with the third T-shaped boss 32, the third T-shaped groove 31 and the third T-shaped boss 32 form the self-locking part, a third arc-shaped notch 33 is formed at a junction of one surface and the other surface of the fan-shaped solid member along the length direction of the fan-shaped solid member, a junction of one end surface of the fan-shaped solid member and the third arc-shaped notch 33 is an arc-shaped surface transition connection, the arc-shaped surface is a fifth arc-shaped surface 34, and a, the arc-shaped surface is a sixth arc surface 35, the surface area of the fifth arc surface 34 is larger than that of the sixth arc surface 35, and a third clamping platform 36 is further arranged at one end, close to the fifth arc surface 34, of the third half mold 30.

Referring to fig. 1 and 2, the first arc-shaped notch 13, the second arc-shaped notch 23 and the third arc-shaped notch 33 are connected end to form a first mold cavity 100.

Specifically, the first arc-shaped notch 13, the second arc-shaped notch 23 and the third arc-shaped notch 33 have the same structure, a first mold cavity 100 without an obvious gap is formed on the inner surface of the notches after connection, the cross section of the first mold cavity 100 is circular, the diameters of the cross sections are the same, and the length of the first mold cavity 100 is smaller than that of the three-half type cable forming mold.

Specifically, when the plurality of single cables on the surface of the first curved transition surface 200 pass through the first mold cavity 100, the first mold cavity 100 compresses, twists and shapes the plurality of single cables into one cable.

Specifically, the diameter of the first mold cavity 100 is the same as the diameter of the end with the small cross section of the first transition curved surface 200, and is the same as the diameter of the end with the small cross section of the second transition curved surface 300, the inner wall of the cavity formed by connecting the first transition curved surface 200, the first mold cavity 100 and the second transition curved surface 300 is smooth and flat, so that cables formed by a plurality of single cables through the first transition curved surface 200, the first mold cavity 100 and the second transition curved surface 300 always pass through the smooth and flat cavity, and burrs are not generated.

Referring to fig. 1, the first cambered surface 14, the third cambered surface 24 and the fifth cambered surface 34 are connected end to form a first transition cambered surface 200.

Specifically, first cambered surface 14, third cambered surface 24, fifth cambered surface 34 are the entry end of a plurality of single cables, evenly set up a plurality of single cables in the first transition curved surface 200 surface that first cambered surface 14, third cambered surface 24, fifth cambered surface 34 constitute according to certain rule and direction, effectively avoid scraping, wearing and tearing between a plurality of single cables to ensure that a plurality of single cables do not produce unfavorable operating modes such as burr before getting into first die cavity 100.

Referring to fig. 2, further, the second cambered surface 15, the fourth cambered surface 25 and the sixth cambered surface 35 are connected end to form a second transition curved surface 300.

Specifically, the diameter of the end of the second transition curved surface 300 with a small cross section is the same as the diameter of the first die cavity 100, so that the cable compressed, twisted and shaped by the first die cavity 100 is not affected by the inner wall of the second transition curved surface 300 when passing through the second transition curved surface 300, and burrs are prevented from being generated on the cable; meanwhile, the end with the large cross section of the second transition curved surface 300 reduces the contact surface between the cable and the second transition curved surface 300 when the cable is conveyed to the outside, so that the cable after cabling is prevented from contacting and vibrating with the end with the large cross section of the second transition curved surface 300 due to external force, and the cable after cabling is ensured not to generate undesirable working conditions such as burrs and the like through the second transition curved surface 300.

Referring to fig. 7, further, the central axes of the first mold cavity 100, the first transition curved surface 200, and the second transition curved surface 300 are overlapped, and the diameter of the first mold cavity 100 is equal to the diameter of the small end of the first transition curved surface 200 and the diameter of the small end of the second transition curved surface 300, so that the inner wall of the cavity formed by connecting the first transition curved surface 200, the first mold cavity 100, and the second transition curved surface 300 is smooth and flat, so as to ensure that cables formed by a plurality of single cables passing through the first transition curved surface 200, the first mold cavity 100, and the second transition curved surface 300 always pass through the cavity with the same diameter, and no burr is generated.

The embodiment of the utility model provides a module or unit in the device can merge, divide and delete according to actual need.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Claims (10)

1. The utility model provides a novel three half formula cable stranding moulds which characterized in that: including first half mould, second half mould, third half mould, first half mould one side is connected with second half mould one side, first half mould opposite side is connected with third half mould one side, second half mould opposite side is connected with third half mould opposite side, sets up the self-locking piece in adjacent two halves mould junction, the inside first die cavity that is provided with of cable stranding mould, the cable stranding mould is provided with first transition curved surface along the one end of first die cavity, the cable stranding mould is provided with second transition curved surface along the other end of first die cavity.

2. The novel three-half cable-laying mold of claim 1, wherein: the first half die, the second half die and the third half die are identical in structure, the first half die is a fan-shaped solid component, the fan-shaped solid component is a solid component, a first T-shaped groove is formed in the joint of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, a first T-shaped boss is arranged on the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the first T-shaped groove is in complementary fit with the first T-shaped boss, the first T-shaped groove and the first T-shaped boss form the self-locking piece, a first arc-shaped opening is formed in the joint of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the joint of one end face of the fan-shaped solid component and the first arc-shaped opening is in arc-shaped face transition connection, the arc-shaped surface is a second arc surface.

3. The new three-half cable-laying mold of claim 2, wherein: the surface area of the first cambered surface is larger than that of the second cambered surface.

4. The new three-half cable-laying mold of claim 2, wherein: and a first clamping table is further arranged at one end, close to the first cambered surface, of the first half die.

5. A novel three-half cable-laying mould as claimed in claim 1 or 2, wherein: the second half die is a fan-shaped solid component, the fan-shaped solid component is a solid component, a second T-shaped groove is formed in the junction of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, a second T-shaped boss is arranged on the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the second T-shaped groove is in complementary fit with the second T-shaped boss, the second T-shaped groove and the second T-shaped boss form the self-locking piece, a second arc-shaped opening is formed in the junction of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the junction of one end face of the fan-shaped solid component and the second arc-shaped opening is in arc-shaped face transition connection, the arc-shaped face is a third arc, the surface area of the third cambered surface is larger than that of the fourth cambered surface, and a second clamping table is further arranged at one end, close to the third cambered surface, of the second half die.

6. A novel three-half cable-laying mould as claimed in claim 1 or 2, wherein: the third half die is a fan-shaped solid component, the fan-shaped solid component is a solid component, a third T-shaped groove is formed in the junction of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, a third T-shaped boss is arranged on the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the third T-shaped groove is in complementary fit with the third T-shaped boss, the third T-shaped groove and the third T-shaped boss form the self-locking piece, a third arc-shaped opening is formed in the junction of one side of the fan-shaped solid component and the other side of the fan-shaped solid component along the length direction of the fan-shaped solid component, the junction of one end face of the fan-shaped solid component and the third arc-shaped opening is in arc-shaped face transition connection, the arc-shaped face is a fifth arc, the surface area of the fifth cambered surface is larger than that of the sixth cambered surface, and a third clamping table is further arranged at one end, close to the fifth cambered surface, of the third half mould.

7. The new three-half cable-laying mold of claim 2, wherein: the first arc-shaped notch, the second arc-shaped notch and the third arc-shaped notch are connected end to form a first die cavity.

8. The new three-half cable-laying mold of claim 2, wherein: the first cambered surface, the third cambered surface and the fifth cambered surface are connected end to form a first transition curved surface.

9. The new three-half cable-laying mold of claim 2, wherein: the second cambered surface, the fourth cambered surface and the sixth cambered surface are connected end to form a second transition cambered surface.

10. The novel three-half cable-laying mold of claim 1, wherein: the central axes of the first die cavity, the first transition curved surface and the second transition curved surface are overlapped, and the diameter of the first die cavity is equal to the diameter of the small end of the first transition curved surface cavity and the diameter of the small end of the second transition curved surface cavity.