CN210053116U

CN210053116U - Induction type high-voltage cable peeling device

Info

Publication number: CN210053116U
Application number: CN201921087094.5U
Authority: CN
Inventors: 柳明贤; 杜金钟; 李继标; 段雪柱; 和德刚; 单春雷; 和学坤; 李凯; 时正雄; 胡金殿
Original assignee: Lijiang Power Supply Bureau of Yunnan Power Grid Co Ltd)
Current assignee: Lijiang Power Supply Bureau of Yunnan Power Grid Co Ltd)
Priority date: 2019-07-12
Filing date: 2019-07-12
Publication date: 2020-02-11
Anticipated expiration: 2029-07-12

Abstract

The utility model discloses an induction type high tension cable device of skinning contains mould, gyrator and the metal induction system of skinning, the metal induction system contains the setting and is in metal inductive probe and metal inductive probe battery on the mould of skinning, metal inductive probe with metal inductive probe battery electricity is connected. The clamping range can be changed along with the thickness of the cable by adopting a mode of clamping the bidirectional screw and the clamping block, so that the clamping of cables with different thicknesses can be finished without replacing different stripping molds; meanwhile, a metal induction probe is arranged beside the clamping block to prompt an operator whether the skin is completely removed or not, so that the cutter is prevented from continuously cutting into the skin to hurt the core. The utility model has the advantages that: the cable stripping device can be suitable for stripping high-voltage cables with different wire diameters, and ensures that the core is not damaged, and is convenient to operate and high in universality.

Description

Induction type high-voltage cable peeling device

Technical Field

The utility model relates to a cable device of skinning, specific saying so relates to an induction type high tension cable device of skinning.

Background

With the continuous development of power technology and the continuous improvement of requirements of social demands on power supply safety and stability, safe operation is more and more important for each power enterprise. When electric power overhauls, regard the cable conductor as connecting wire's wiring in-process, in order to guarantee the connection effect of cable, need peel the processing to the cable usually, peel off one section epidermis of cable head and connect again, just so can guarantee cable junction's electric conductivity. Therefore, workers often need to face the situation of stripping operation of the high-altitude live cable, the surface of the lead is made of hard insulating materials, and the lead is difficult to strip by using common props.

Most of the existing cable strippers in the market at present adopt a manual cable stripper stripping mode, and are only suitable for the power-off operation environment, and the safety of operators is difficult to ensure when the requirements of live-line operation exist; in addition, a few strippers for live working of high-voltage cables are available on the market, but these strippers mainly have two problems: firstly, when cables with different wire diameters are stripped, different die assemblies need to be replaced, the stripping requirements of the cables with different wire diameters cannot be met, and the operation efficiency is low; secondly, under the condition of live working, the cable in the air is generally subjected to peeling treatment, so that whether the skin is completely removed is difficult to judge, and the core is easily damaged due to over-cutting.

Based on this problem, a peeler is needed that can adapt to the needs of skinning of different wire diameters to can in time remind operating personnel to stop the feed after the insulating layer is got rid of completely in order to prevent hindering the core.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an induction type high tension cable device of skinning for solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides an induction type high tension cable device of skinning, contains mould and the gyrator of skinning, still includes metal induction system, metal induction system contains the setting and is in metal inductive probe and metal inductive probe battery on the mould of skinning, metal inductive probe with metal inductive probe battery electricity is connected.

In the technical scheme, the peeling mold comprises an upper clamping block, a lower clamping block, a gear shell, a bidirectional screw and a peeling knife screw;

the upper end of the peeling knife screw is fixedly connected with the upper clamping block, and the lower end of the peeling knife screw sequentially penetrates through the lower clamping block and the gear shell from top to bottom and is connected with the lower clamping block and the gear shell in a sliding fit manner;

the upper end of the bidirectional screw rod sequentially penetrates through the gear shell, the lower clamping block and the upper clamping block from bottom to top and is respectively in threaded sliding fit connection with the lower clamping block and the upper clamping block, the lower end of the bidirectional screw rod extends to be arranged at the lower part of the gear shell and is fixedly connected with a rotating ring exposed at the lower part of the gear shell,

a clamping opening used for clamping a cable to be stripped is arranged between the upper clamping block and the lower clamping block, and a stripping knife fastened on a stripping knife screw rod through a stripping knife fixing frame is arranged beside the clamping opening;

the upper part of the upper clamping block is also provided with a battery mounting groove for mounting the metal induction probe battery, and the top of the battery mounting groove is covered with a battery cover matched with the battery mounting groove;

and a boss with a threaded hole for mounting the metal induction probe is also arranged on one side of the upper clamping block connected with the peeling knife screw rod.

Among the above-mentioned technical scheme, the mould of skinning still includes linkage gear train, linkage gear train is including first linkage gear, second linkage gear, third linkage gear and the fourth linkage gear that meshes the connection in proper order, first linkage gear cover is established at the lower extreme of skinning knife screw rod to lie in gear shell's upper strata groove, second linkage gear and third linkage gear are all fixed in gear shell's upper strata groove through a first bolt, fourth linkage gear is fixed in gear shell's upper strata groove through a second bolt the lower extreme of fourth linkage gear still is equipped with the connecting axle the cover is equipped with first bevel gear on the connecting axle, first bevel gear is located gear shell's lower floor groove to with be located the circular arc bevel gear meshing transmission on the gyrator and be connected.

Among the above-mentioned technical scheme, the circulator contains gear drive case and bevel gear drive case, gear drive case's left side is through connecting plate and the gear housing fixed connection of mould of skinning, and is connected with the first bevel gear that is located gear housing lower floor's inslot meshes the transmission mutually through circular arc bevel gear, gear drive case's right side pass through the screw with the fixed connection of bevel gear drive case, and be connected with the bevel gear transfer line transmission that is located on the bevel gear drive case through the gear transfer line.

In the technical scheme, the gear transmission box comprises a left shell and a right shell, the left shell and the right shell are fastened through bolts, and the left shell and the right shell are both fastened and connected with a connecting plate positioned on the left side of the gear transmission box through screws; the C-shaped gear is arranged on the upper portion of a gear transmission box cavity defined by the left shell and the right shell, a cam assembly, a gear assembly and a gear transmission rod are arranged on the lower portion of the gear transmission box cavity defined by the left shell and the right shell, the cam assembly and the gear assembly are sleeved on the gear transmission rod, the upper portion of the gear assembly is meshed with the lower portion of the C-shaped gear, one end of the gear transmission rod extends into the left shell and is sleeved with the cam assembly and the gear assembly, and the other end of the gear transmission rod extends out of the right shell and is in transmission connection with a bevel gear transmission rod located in the bevel gear transmission box.

In the technical scheme, the upper parts of the left shell and the right shell are both provided with first C-shaped openings, and the C-shaped gear is provided with a second C-shaped opening which is matched and corresponding to the first C-shaped openings on the left shell and the right shell;

a C-shaped gear buckle is further arranged at the opening of the second C-shaped opening, one end of the C-shaped gear buckle is in lap joint with one end of the opening of the second C-shaped opening, and the other end of the C-shaped gear buckle is fastened with the other end of the opening of the second C-shaped opening through a screw;

a left C-shaped cover shell matched with the first C-shaped opening is further arranged on the left side of the left outer shell, and the left C-shaped cover shell and the left outer shell are connected and fastened with the left side of the C-shaped gear through bolts;

the right side of the right shell is also provided with a right C-shaped cover shell matched with the first C-shaped opening, and the right C-shaped cover shell and the right shell are connected and fastened with the right side of the C-shaped gear through bolts.

In the technical scheme, a groove is formed in the lower portion of the end face of one side, facing the peeling die, of the left shell, an arc bevel gear is arranged in the groove, and the gear tooth portion of the arc bevel gear protrudes out of the left shell and is meshed with a third bevel gear located in a lower-layer groove of the gear shell;

an open slot is further formed in the lower portion of the end face of the left shell, facing one side of the peeling die, and is communicated with the groove, an L-shaped sliding block is arranged at the top of the open slot, and a spring seat is arranged at the bottom of the open slot;

one end of the L-shaped sliding block abuts against the top of the open slot and abuts against the cam component, the other end of the L-shaped sliding block extends into the groove of the left shell and abuts against the back of the arc bevel gear, and the back of the arc bevel gear also abuts against the gear component through a first spring;

the bottom of the spring seat is flush with the bottom of the left shell and fixedly connected with the left shell through screws, a second spring is arranged between the top of the spring seat and the bottom of the L-shaped sliding block, one end of the second spring is abutted against the top of the spring seat, and the other end of the second spring is abutted against the bottom of the L-shaped sliding block.

In the technical scheme, the gear assembly comprises a pawl transmission rod sleeve, a gear sleeve and a hexagon socket gear, the pawl transmission rod sleeve is sleeved on the gear transmission rod, the gear sleeve is sleeved on the pawl transmission rod sleeve, the hexagon socket gear is sleeved on the gear sleeve, and the upper part of the hexagon socket gear is meshed with the lower part of the C-shaped gear;

the cam component comprises a one-way bearing and a cam, the one-way bearing is sleeved on the gear transmission rod, and the cam is sleeved on the one-way bearing and attached to the left end face of the inner hexagonal gear.

In the technical scheme, the bevel gear transmission box comprises a bevel gear shell, a bevel gear cover plate, a bevel gear transmission rod, a second bevel gear and a third bevel gear, wherein the bevel gear shell is fastened on the right side of the gear transmission box through a screw, the bevel gear cover plate is fastened on the top of the bevel gear shell through a screw, one end of the bevel gear transmission rod extends into the bevel gear shell and is connected with the second bevel gear, the other end of the bevel gear transmission rod is exposed at the bottom of the bevel gear shell, and the third bevel gear is sleeved on the end part of the gear transmission rod extending into the bevel gear transmission box and is meshed with the second bevel gear; and a bearing is further arranged below the second bevel gear, is sleeved on the bevel gear transmission rod and is in interference fit with the bevel gear transmission rod.

In the technical scheme, an upper thread and a lower thread with opposite thread directions are arranged on the bidirectional screw rod, the upper thread on the bidirectional screw rod is in thread fit with the upper clamping block, and the lower thread on the bidirectional screw rod is in thread fit with the lower clamping block;

the lower part of the upper clamping block and the upper part of the lower clamping block are respectively provided with a notch which is opposite to each other and used for clamping a V-shaped clamping groove of a cable to be stripped.

The utility model provides a pair of induction type high tension cable device of skinning's theory of operation does:

the clamping range can be changed along with the thickness of the cable by adopting a clamping mode of the bidirectional screw and the clamping block, so that the cables with different thicknesses can be clamped without replacing different moulds; meanwhile, a metal induction probe is arranged beside the clamping block to prompt an operator whether the skin is completely removed or not, so that the cutter is prevented from continuously cutting into the core; when using promptly the utility model provides a barker strips the back with high tension cable's insulating layer completely, and the metal core of cable can appear out, and metal inductive probe can sense the metal this moment to do not stop the scintillation and give out light, suggestion operating personnel has got rid of the epidermis completely.

Compared with the prior art, the utility model discloses an advantage and beneficial effect are:

(1) under the condition of facing to the cable high-altitude live working with different wire diameters, the stripping die is not required to be replaced to strip different cables, so that the cable stripping machine has stronger universality and is more convenient and faster to operate;

(2) after the high-voltage cable is peeled, the metal induction probe can induce the exposure of the metal core of the high-voltage cable and continuously twinkles to emit light, so that an operator can be timely reminded that the insulating layer of the high-voltage cable is completely peeled, and the condition that the cutter is continuously cut into the metal core of the high-voltage cable to cut the metal core is avoided.

Drawings

Fig. 1 is a perspective view of one of the viewing angles of the induction type high-voltage cable stripping device of the present invention;

fig. 2 is a perspective view of another viewing angle of the induction type high-voltage cable stripping device of the present invention;

fig. 3 is a partial exploded view of the induction type high-voltage cable stripping device of the present invention;

fig. 4 is an embodiment of a peeling mold in the induction type high-voltage cable peeling device of the present invention;

FIG. 5 is an exploded view of the stripping die of FIG. 4;

fig. 6 is a schematic view of an embodiment of a gyrator in the induction type high voltage cable peeling apparatus of the present invention;

FIG. 7 is a perspective view of the left housing of FIG. 6;

FIG. 8 is a partial exploded view of the gear box of FIG. 6;

FIG. 9 is an exploded view of FIG. 6;

description of reference numerals: 1. peeling the mould; 1.1, mounting a clamping block; 1.2, a lower clamping block; 1.3, gear housing; 1.4, a bidirectional screw; 1.4a, screwing; 1.4b, lower thread; 1.5, a peeling knife screw; 1.6, rotating the ring; 1.7, a skinning knife fixing frame; 1.8, a skinning knife; 1.9, a battery cover; 1.10, a boss; 1.11, a first linkage gear; 1.12, a second linkage gear; 1.13, a third driving gear; 1.14, a fourth linkage gear; 1.15, a first bolt; 1.16, a second bolt; 1.17, a connecting shaft; 1.18, a first bevel gear; 1.19, connecting plates; 2. a gyrator; 2.1, a gear transmission case; 2.1.1, a left shell; 2.1.2, right housing; 2.1.3, screw; 2.1.4, C-shaped gear; 2.1.5, a cam assembly; 2.1.5a, a one-way bearing; 2.1.5b, cam; 2.1.6, gear assembly; 2.1.6a, a pawl transmission rod sleeve; 2.1.6b, gear sleeve; 2.1.6c, inner hexagonal gear; 2.1.7, a gear transmission rod; 2.1.8, C-shaped gear buckle; 2.1.9, left C-shaped cover shell; 2.1.10, right C-shaped cover shell; 2.1.11, arc bevel gear; 2.1.12, L-shaped slider; 2.1.13, spring seats; 2.1.14, a first spring; 2.1.15, a second spring; 2.2, a bevel gear transmission case; 2.2.1, a bevel gear housing; 2.2.2, bevel gear cover plate; 2.2.3, a bevel gear transmission rod; 2.2.4, a second bevel gear; 2.2.5, a third bevel gear; 2.2.6, a bearing; 3. a metal inductive probe; 4. a metal inductive probe battery;

m, a first C-shaped port; n, a second C-shaped port; p, clamping the opening; q, V-shaped card slots; r, a battery mounting groove; s, a groove; t, an open slot.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the functions of the present invention easy to understand and understand, how to implement the present invention is further explained below with reference to the accompanying drawings and the detailed description.

Referring to fig. 1 to 3, the utility model provides an induction type high-voltage cable stripping device, which comprises a stripping mold 1, a gyrator 2 and a metal induction device; wherein, metal induction system contains metal inductive probe 3 and the metal inductive probe battery 4 of setting on the mould 1 of skinning, and metal inductive probe 3 is connected with metal inductive probe battery 4 electricity for the metal core of the high tension cable of sensing treatment of waiting to skin, so that in time indicate operating personnel whether the insulating layer of high tension cable has peeled off completely, avoided the cutter to continue to cut into and cut the metal core of high tension cable.

As the utility model discloses induction type high tension cable device of skinning's an embodiment:

as shown in fig. 4, the peeling mold 1 comprises an upper clamping block 1.1, a lower clamping block 1.2, a gear housing 1.3, a bidirectional screw 1.4 and a peeling knife screw 1.5; wherein: the upper end of a peeling knife screw rod 1.5 is fixedly connected with an upper clamping block 1.1, and the lower end of the peeling knife screw rod 1.5 sequentially penetrates through a lower clamping block 1.2 and a gear shell 1.3 from top to bottom and is connected with the lower clamping block 1.2 and the gear shell 1.3 in a sliding fit manner; the upper end of a bidirectional screw 1.4 sequentially penetrates through a gear shell 1.3, a lower clamping block 1.2 and an upper clamping block 1.1 from bottom to top and is respectively in threaded fit connection with the lower clamping block 1.2 and the upper clamping block 1.2, the lower end of the bidirectional screw 1.4 extends to be arranged at the lower part of the gear shell 1.3 and is in fastening connection with a rotating ring 1.6 exposed at the lower part of the gear shell 1.3, a clamping opening P for clamping a cable to be stripped is arranged between the upper clamping block 1.1 and the lower clamping block 1.6, and a stripping knife 1.8 fastened on a stripping knife screw 1.5 through a stripping knife fixing frame 1.7 is arranged beside the clamping opening P; the upper part of the upper clamping block 1.1 is also provided with a battery mounting groove R for mounting a metal induction probe battery 4, and the top of the battery mounting groove R is covered with a battery cover 1.9; a boss 1.10 with a threaded hole for installing a metal induction probe 3 is also arranged on one side of the upper clamping block 1.1 connected with the peeling knife screw rod 1.5.

In this embodiment, as shown in fig. 5, the peeling mold 1 further includes a linkage gear set, the linkage gear set includes a first linkage gear 1.11, a second linkage gear 1.12, a third linkage gear 1.13 and a fourth linkage gear 1.14 which are sequentially engaged with each other, the first linkage gear 1.11 is sleeved on the lower end of the screw rod 1.5 of the peeling knife, and is positioned in the upper groove of the gear housing 1.3, the second linkage gear 1.12 and the third linkage gear 1.13 are both fixed in the upper groove of the gear housing 1.3 through a first bolt 1.15, the fourth linkage gear 1.14 is fixed in the upper groove of the gear housing 1.3 through a second bolt 1.16, the lower end of the fourth linkage gear 1.14 is also provided with a connecting shaft 1.17, a first bevel gear 1.18 is sleeved on the connecting shaft 1.17, the first bevel gear 1.18 is positioned in the lower layer groove of the gear shell 1.3, and is in meshing transmission connection with a circular arc bevel gear 2.1.11 on the gyrator 2.

In the present embodiment, as shown in fig. 6 to 9, the gyrator 2 comprises a gear transmission case 2.1 and a bevel gear transmission case 2.2, the left side of the gear transmission case 2.1 is fixedly connected with the gear housing 1.3 of the peeling die 1 through a connecting plate 1.19, and is in meshing transmission connection with a first bevel gear 1.18 positioned in a lower layer groove of the gear housing 1.3 through an arc bevel gear 2.1.11, the right side of the gear transmission case 2.1 is fixedly connected with the bevel gear transmission case 2.2 through a screw, and is in transmission connection with a bevel gear transmission rod 2.2.3 positioned on the bevel gear transmission case 2.2 through a gear transmission rod 2.1.7.

In the present embodiment, as shown in fig. 8 and 9, the gear box 2.1 includes a left housing 2.1.1 and a right housing 2.1.2, the left housing 2.1.1 and the right housing 2.1.2 are fastened by bolts, and the left housing 2.1.1 and the right housing 2.1.2 are also fastened and connected to a connecting plate 1.19 located on the left side of the gear box 2.1 by a screw 2.1.3; the C-shaped gear 2.1.4 is arranged on the upper part of a cavity of the gear transmission box enclosed by the left shell 2.1.1 and the right shell 2.1.2, the cam component 2.1.5, the gear component 2.1.6 and the gear transmission rod 2.1.7 are arranged on the lower part of the cavity of the gear transmission box enclosed by the left shell 2.1.1 and the right shell 2.1.2, the cam component 2.1.5 and the gear component 2.1.6 are sleeved on the gear transmission rod 2.1.7, the upper part of the gear component 2.1.6 is also meshed with the lower part of the C-shaped gear 2.1.4, one end of the gear transmission rod 2.1.7 is extended in the left shell 2.1.1 and sleeved with the cam component 2.1.5 and the gear component 2.1.6, and the other end thereof is extended out of the right shell 2.1.2 and is in transmission connection with the bevel gear transmission rod 2.2.3 in the bevel gear transmission box 2.2.

In this embodiment, as shown in fig. 8 and 9, the upper portions of the left casing 2.1.1 and the right casing 2.1.2 are both provided with a first C-shaped opening M, and the C-shaped gear 2.1.4 is provided with a second C-shaped opening N corresponding to the first C-shaped opening M on the left casing 2.1.1 and the right casing 2.1.2; a C-shaped gear buckle 2.1.8 is further arranged at the opening of the second C-shaped opening N, one end of the C-shaped gear buckle 2.1.8 is in lap joint with one end of the opening of the second C-shaped opening N, and the other end of the C-shaped gear buckle is fastened with the other end of the opening of the second C-shaped opening N through a screw;

in this embodiment, as shown in fig. 8 and 9, a left C-shaped cover 2.1.9 matching with the first C-shaped opening M is further disposed on the left side of the left outer casing 2.1.1, and both the left C-shaped cover 2.1.9 and the left outer casing 2.1.1 are connected and fastened to the left side of the C-shaped gear 2.1.4 through bolts;

in this embodiment, as shown in fig. 8 and 9, a right C-shaped cover 2.1.10 matching with the first C-shaped opening M is further disposed on the right side of the right outer casing 2.1.2, and the right C-shaped cover 2.1.10 and the right outer casing 2.1.2 are both connected and fastened to the right side of the C-shaped gear 2.1.4 through bolts.

In this embodiment, as shown in fig. 7, a groove S is provided in the lower portion of the end surface of the left housing 2.1.1 facing the side of the peeling die 1, in which groove S a circular arc bevel gear 2.1.11 is fitted, and the gear tooth portion of the circular arc bevel gear 2.1.11 protrudes from the left housing 2.1.1 and is engaged with the first bevel gear 1.18 located in the lower groove of the gear housing 1.3;

an open slot T communicated with the groove S is further formed in the lower portion of the end face of the side, facing the peeling die 1, of the left shell 2.1.1, an L-shaped sliding block 2.1.12 is arranged at the top of the open slot T, and a spring seat 2.1.13 is arranged at the bottom of the open slot T; one end of the L-shaped sliding block 2.1.12 abuts against the top of the open slot T and abuts against the cam component 2.1.5, the other end of the L-shaped sliding block extends into the groove S of the left shell 2.1.1 and abuts against the back of the arc bevel gear 2.1.11, and the back of the arc bevel gear 2.1.11 also abuts against the gear component 2.1.6 through the first spring 2.1.14; the bottom of spring holder 2.1.13 is the same level with the bottom of left shell 2.1.1 to through screw and left shell 2.1.1 fixed connection, be equipped with second spring 2.1.15 between the top of spring holder 2.1.13 and the bottom of L shape slider 2.1.12, second spring 2.1.15 one end and the top butt of spring holder 2.1.13, the other end and the bottom butt of L shape slider 2.1.12.

In this embodiment, as shown in fig. 9, the gear assembly 2.1.6 includes a pawl transmission rod sleeve 2.1.6a, a gear sleeve 2.1.6b and a hexagon socket gear 2.1.6C, the pawl transmission rod sleeve 2.1.6a is sleeved on the gear transmission rod 2.1.7, the gear sleeve 2.1.6b is sleeved on the pawl transmission rod sleeve 2.1.6a, the hexagon socket gear 2.1.6C is sleeved on the gear sleeve 2.1.6b, and the upper portion of the hexagon socket gear 2.1.6C is engaged with the lower portion of the C-shaped gear 2.1.4;

in this embodiment, as shown in fig. 9, the cam assembly 2.1.5 includes a one-way bearing 2.1.5a and a cam 2.1.5b, the one-way bearing 2.1.5a is sleeved on the gear transmission rod 2.1.7, and the cam 2.1.5b is sleeved on the one-way bearing 2.1.5a and is attached to the left end face of the hexagon socket gear 2.1.6 c.

In this embodiment, as shown in fig. 9, the bevel gear transmission case 2.2 includes a bevel gear housing 2.2.1, a bevel gear cover plate 2.2.2, a bevel gear transmission rod 2.2.3, a second bevel gear 2.2.4 and a third bevel gear 2.2.5, the bevel gear housing 2.2.1 is fastened to the right side of the gear transmission case 2.1 by screws, the bevel gear cover plate 2.2.2 is fastened to the top of the bevel gear housing 2.2.1 by screws, one end of the bevel gear transmission rod 2.2.3 extends into the bevel gear housing 2.2.1 and is connected to the second bevel gear 2.2.4, the other end is exposed at the bottom of the bevel gear housing 2.2.1, and the third bevel gear 2.2.5 is sleeved on the end of the gear transmission rod 2.1.7 extending into the bevel gear transmission case 2.2 and is engaged with the second bevel gear 2.2.4; a bearing 2.2.6 is also arranged below the second bevel gear 2.2.4, and the bearing 2.2.6 is sleeved on the bevel gear transmission rod 2.2.3 and is in interference fit with the bevel gear transmission rod 2.2.3.

In this embodiment, as shown in fig. 5, an upper thread 1.4a and a lower thread 1.4b with opposite thread directions are provided on the bidirectional screw 1.4, the upper thread 1.4a on the bidirectional screw 1.4 is in thread fit with the upper clamping block 1.1, and the lower thread 1.4b on the bidirectional screw 1.4 is in thread fit with the lower clamping block 1.2; a notch is also formed in the lower portion of the upper clamping block 1.1 and the upper portion of the lower clamping block 1.2, and the notches are opposite to each other and used for clamping a V-shaped clamping groove Q of a cable to be stripped.

The utility model provides a pair of induction type high tension cable device of skinning's concrete working process as follows:

(1) firstly, an insulating operating rod is connected with a bevel gear transmission rod 2.2.3 of a peeling device, the peeling device is lifted to the position of a high-voltage cable to be peeled by the insulating operating rod, then a crank on the insulating operating rod is shaken clockwise (or anticlockwise) to drive a bevel gear transmission rod 2.2.3 on the peeling device to rotate, then the bevel gear transmission rod 2.2.3 drives a second bevel gear 2.2.4 on the insulating operating rod to rotate, then the second bevel gear 2.2.4 drives a third bevel gear 2.2.5 to rotate, the third bevel gear 2.2.5 drives a gear transmission rod 2.1.7 to rotate, finally the gear transmission rod 2.1.7 drives a gear assembly 2.1.6 and a cam assembly 2.1.5 to rotate, then the gear assembly 2.1.6 drives a C-shaped gear 2.1.4 to rotate, and a C-shaped gear 2.1.8 at a C-shaped opening of the C-shaped gear 2.1.4 is opened, and the peeling device is hung on the high-voltage cable to be peeled;

(2) then the crank on the insulating operating rod is shaken anticlockwise (or clockwise) to drive a bevel gear transmission rod 2.2.3 on the peeling device to rotate, then a second bevel gear 2.2.4 drives a third bevel gear 2.2.5 to rotate, the third bevel gear 2.2.5 drives a gear transmission rod 2.1.7 to rotate, finally the gear transmission rod 2.1.7 drives a gear assembly 2.1.6 and a cam assembly 2.1.5 to rotate, and then the gear assembly 2.1.6 drives a C-shaped gear 2.1.4 to rotate, and the C-shaped gear 2.1.8 at the C-shaped opening of the C-shaped gear 2.1.4 is buckled again, and the high-voltage cable is locked in the C-shaped opening of the peeling device;

(3) the stripping device moves to a position to be stripped along a high-voltage cable through an insulating operating rod, a clamping port P of the stripping device is aligned to the position to be stripped of the high-voltage cable, then a rotating ring 1.6 is screwed clockwise (or anticlockwise) through an insulating hook rod, and a bidirectional screw rod 1.4 is driven to rotate, so that an upper clamping block 1.1 and a lower clamping block 1.2 are gradually folded under the action of an upper thread 1.4a and a lower thread 1.4b which are opposite threads to each other, the high-voltage cable to be stripped is clamped, after the high-voltage cable to be stripped is clamped, a stripping knife 1.8 just abuts against an insulating skin layer of the cable to be stripped, at the moment, a rotator 2 is rotated, the rotator 2 sequentially drives a fourth linkage gear 1.14, a third linkage gear 1.13, a second linkage gear 1.12 and a first linkage gear 1.11 to rotate through the mutual meshing transmission of an arc bevel gear 2.1.11 and a first bevel gear 1.18 of a stripping die 1, and then drives the stripping knife screw rod 1.5 to rotate, because the peeling knife screw 1.5 is in threaded connection with the peeling knife screw fixing frame 1.7 (not shown in the figure), when the peeling knife screw 1.5 is rotated, the peeling knife screw fixing frame 1.7 can be driven to move downwards, so that the peeling knife 1.8 carries out cable peeling treatment downwards layer by layer until an operator observes that an indicator lamp on the metal induction probe 3 flickers, namely the insulation skin layer of the high-voltage cable to be peeled is completely peeled, and the work of the gyrator 2 is stopped;

(4) then the insulating hook rod is screwed clockwise (or anticlockwise) to the rotating ring 1.6 and drive the bidirectional screw rod 1.4 to rotate, so that the upper clamping block 1.1 and the lower clamping block 1.2 are gradually opened under the action of an upper thread 1.4a and a lower thread 1.4b which are opposite threads to each other until the clamping opening P is completely opened, then the crank on the insulating operating rod is shaken clockwise (or anticlockwise) to drive the bevel gear transmission rod 2.2.3 on the peeling device to rotate, and then the bevel gear transmission rod 2.2.3 drives the second bevel gear 2.2.4 on the peeling device to rotate, then the second bevel gear 2.2.4 drives the third bevel gear 2.2.5 to rotate, the third bevel gear 2.2.5 drives the gear transmission rod 2.1.7 to rotate, finally the gear transmission rod 2.1.7 drives the gear assembly 2.1.6 and the cam assembly 2.1.5 to rotate, and then the gear assembly 2.1.6 drives the C-shaped gear 2.1.4 to rotate, so that the C-gear clasp 2.1.8 at the C-shaped opening of the C-gear 2.1.4 is reopened and finally the stripping device is removed from the high voltage cable.

Finally, the above description is only the embodiments of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes that are used in the specification and the attached drawings or directly or indirectly applied to other related technical fields are included in the patent protection scope of the present invention.

Claims

1. The utility model provides an induction type high tension cable device of skinning, contains skinning mould (1) and gyrator (2), its characterized in that: still include metal induction system, metal induction system contains the setting and is in metal inductive probe (3) and metal inductive probe battery (4) on peeling die utensil (1), metal inductive probe (3) with metal inductive probe battery (4) electricity is connected.

2. The inductive high-voltage cable stripping device as claimed in claim 1, characterized in that: the peeling die (1) comprises an upper clamping block (1.1), a lower clamping block (1.2), a gear shell (1.3), a bidirectional screw (1.4) and a peeling knife screw (1.5);

the upper end of the peeling knife screw rod (1.5) is fixedly connected with the upper clamping block (1.1), and the lower end of the peeling knife screw rod (1.5) sequentially penetrates through the lower clamping block (1.2) and the gear shell (1.3) from top to bottom and is connected with the lower clamping block (1.2) and the gear shell (1.3) in a sliding fit manner;

the upper end of the bidirectional screw (1.4) sequentially penetrates through the gear shell (1.3), the lower clamping block (1.2) and the upper clamping block (1.1) from bottom to top and is respectively in threaded fit connection with the lower clamping block (1.2) and the upper clamping block (1.2), the lower end of the bidirectional screw (1.4) extends to be arranged at the lower part of the gear shell (1.3) and is fixedly connected with a rotating ring (1.6) exposed at the lower part of the gear shell (1.3),

a clamping opening (P) for clamping a cable to be stripped is arranged between the upper clamping block (1.1) and the lower clamping block (1.6), and a stripping knife (1.8) which is fastened on a stripping knife screw (1.5) through a stripping knife fixing frame (1.7) is arranged beside the clamping opening (P);

the upper part of the upper clamping block (1.1) is also provided with a battery mounting groove (R) for mounting the metal induction probe battery (4), and the top of the battery mounting groove (R) is covered with a battery cover (1.9);

a boss (1.10) with a threaded hole for installing the metal induction probe (3) is also arranged on one side of the upper clamping block (1.1) connected with the peeling knife screw rod (1.5).

3. The inductive high-voltage cable stripping device as claimed in claim 2, characterized in that: the peeling die (1) further comprises a linkage gear set, the linkage gear set comprises a first linkage gear (1.11), a second linkage gear (1.12), a third linkage gear (1.13) and a fourth linkage gear (1.14) which are sequentially connected in a meshed manner, the lower end of a peeling knife screw rod (1.5) is sleeved with the first linkage gear (1.11) and is positioned in an upper groove of a gear shell (1.3), the second linkage gear (1.12) and the third linkage gear (1.13) are fixed in the upper groove of the gear shell (1.3) through a first bolt (1.15), the fourth linkage gear (1.14) is fixed in the upper groove of the gear shell (1.3) through a second bolt (1.16), the lower end of the fourth linkage gear (1.14) is further provided with a first bevel gear (1.17), the connecting shaft (1.17) is sleeved with a first bevel gear (1.18), and the first bevel gear (1.18) is positioned in the lower groove of the gear shell (1.3), and is engaged and connected with a circular arc bevel gear (2.1.11) on the gyrator (2) in a transmission way.

4. The inductive high-voltage cable stripping device as claimed in claim 3, characterized in that: gyrator (2) contain gear drive case (2.1) and bevel gear drive case (2.2), the left side of gear drive case (2.1) is through connecting plate (1.19) and gear housing (1.3) fixed connection of mould (1) of skinning, and through circular arc bevel gear (2.1.11) with be located gear housing (1.3) lower floor inslot first bevel gear (1.18) mesh transmission connection mutually, the right side of gear drive case (2.1) through the screw with the fixed connection of bevel gear drive case (2.2), and through gear drive pole (2.1.7) with be located bevel gear drive pole (2.2.3) transmission connection on bevel gear drive case (2.2).

5. The inductive high-voltage cable stripping device as claimed in claim 4, characterized in that: the gear transmission case (2.1) comprises a left shell (2.1.1) and a right shell (2.1.2), the left shell (2.1.1) and the right shell (2.1.2) are fastened through bolts, and the left shell (2.1.1) and the right shell (2.1.2) are also fastened and connected with a connecting plate (1.19) positioned on the left side of the gear transmission case (2.1) through screws (2.1.3);

the C-shaped gear (2.1.4) is arranged at the upper part of a gear transmission box cavity defined by the left shell (2.1.1) and the right shell (2.1.2), the cam component (2.1.5), the gear component (2.1.6) and the gear transmission rod (2.1.7) are arranged at the lower part of the gear transmission box cavity defined by the left shell (2.1.1) and the right shell (2.1.2), the cam component (2.1.5) and the gear component (2.1.6) are sleeved on the gear transmission rod (2.1.7), the upper part of the gear component (2.1.6) is also meshed with the lower part of the C-shaped gear (2.1.4), one end of the gear transmission rod (2.1.7) extends in the left shell (2.1.1), the cam component (2.1.5) and the gear transmission rod (2.1.6) are sleeved, and the other end of the gear transmission rod extends out of the right shell (2.1.2) and is connected with the bevel gear transmission rod (2.2.1.2).

6. The inductive high-voltage cable stripping device as claimed in claim 5, characterized in that: the upper parts of the left shell (2.1.1) and the right shell (2.1.2) are respectively provided with a first C-shaped opening (M), and the C-shaped gear (2.1.4) is provided with a second C-shaped opening (N) which is matched and corresponding to the first C-shaped openings (M) on the left shell (2.1.1) and the right shell (2.1.2);

a C-shaped gear buckle (2.1.8) is further arranged at the opening of the second C-shaped opening (N), one end of the C-shaped gear buckle (2.1.8) is in lap joint with one end of the opening of the second C-shaped opening (N), and the other end of the C-shaped gear buckle is fastened with the other end of the opening of the second C-shaped opening (N) through a screw;

a left C-shaped cover shell (2.1.9) matched with the first C-shaped opening (M) is further arranged on the left side of the left outer shell (2.1.1), and the left C-shaped cover shell (2.1.9) and the left outer shell (2.1.1) are connected and fastened with the left side of the C-shaped gear (2.1.4) through bolts;

the right side of the right shell (2.1.2) is also provided with a right C-shaped cover shell (2.1.10) matched with the first C-shaped opening (M), and the right C-shaped cover shell (2.1.10) and the right shell (2.1.2) are connected and fastened with the right side of the C-shaped gear (2.1.4) through bolts.

7. The inductive high-voltage cable stripping device as claimed in claim 5, characterized in that: a groove (S) is formed in the lower portion of the end face of one side, facing the peeling die (1), of the left shell (2.1.1), an arc bevel gear (2.1.11) is arranged in the groove (S), and the gear tooth portion of the arc bevel gear (2.1.11) protrudes out of the left shell (2.1.1) and is meshed with a first bevel gear (1.18) located in a lower-layer groove of the gear shell (1.3);

an open slot (T) is further formed in the lower portion of the end face of one side, facing the peeling die (1), of the left shell (2.1.1), the open slot (T) is communicated with the groove (S), an L-shaped sliding block (2.1.12) is arranged at the top of the open slot (T), and a spring seat (2.1.13) is arranged at the bottom of the open slot (T);

one end of the L-shaped sliding block (2.1.12) abuts against the top of the open slot (T) and abuts against the cam component (2.1.5), the other end of the L-shaped sliding block extends into the groove (S) of the left shell (2.1.1) and abuts against the back of the arc bevel gear (2.1.11), and the back of the arc bevel gear (2.1.11) abuts against the gear component (2.1.6) through the first spring (2.1.14);

the bottom of spring holder (2.1.13) with the bottom parallel and level of left shell (2.1.1) to through screw and left shell (2.1.1) fixed connection be equipped with second spring (2.1.15) between the top of spring holder (2.1.13) and the bottom of L shape slider (2.1.12), second spring (2.1.15) one end and the top butt of spring holder (2.1.13), the other end and the bottom butt of L shape slider (2.1.12).

8. The inductive high-voltage cable stripping device as claimed in claim 7, characterized in that:

the gear assembly (2.1.6) comprises a pawl transmission rod sleeve (2.1.6a), a gear sleeve (2.1.6b) and a hexagon socket gear (2.1.6C), the pawl transmission rod sleeve (2.1.6a) is sleeved on the gear transmission rod (2.1.7), the gear sleeve (2.1.6b) is sleeved on the pawl transmission rod sleeve (2.1.6a), the hexagon socket gear (2.1.6C) is sleeved on the gear sleeve (2.1.6b), and the upper part of the hexagon socket gear (2.1.6C) is meshed with the lower part of the C-shaped gear (2.1.4);

cam subassembly (2.1.5) contain one-way bearing (2.1.5a) and cam (2.1.5b), one-way bearing (2.1.5a) cover is established on gear drive pole (2.1.7), cam (2.1.5b) cover is established on one-way bearing (2.1.5a), and with the left side terminal surface of hexagon socket gear (2.1.6c) is laminated mutually.

9. The inductive high-voltage cable stripping device as claimed in claim 5, characterized in that: the bevel gear transmission box (2.2) comprises a bevel gear shell (2.2.1), a bevel gear cover plate (2.2.2), a bevel gear transmission rod (2.2.3), a second bevel gear (2.2.4) and a third bevel gear (2.2.5), the bevel gear shell (2.2.1) is fastened on the right side of the gear transmission box (2.1) through screws, the bevel gear cover plate (2.2.2) is fastened on the top of the bevel gear shell (2.2.1) through screws, one end of the bevel gear transmission rod (2.2.3) extends into the bevel gear shell (2.2.1) and is connected with the second bevel gear (2.2.4), the other end of the bevel gear cover plate is exposed at the bottom of the bevel gear shell (2.2.1), and the third bevel gear (2.2.5) is sleeved on the end of the gear transmission rod (2.1.7) extending into the bevel gear transmission box (2.2) and is meshed with the second bevel gear (2.2.2.4); a bearing (2.2.6) is further arranged below the second bevel gear (2.2.4), and the bearing (2.2.6) is sleeved on the bevel gear transmission rod (2.2.3) and is in interference fit with the bevel gear transmission rod (2.2.3).

10. The inductive high-voltage cable stripping device as claimed in claim 2, characterized in that: an upper thread (1.4a) and a lower thread (1.4b) with opposite thread directions are arranged on the bidirectional screw (1.4), the upper thread (1.4a) on the bidirectional screw (1.4) is in thread fit with the upper clamping block (1.1), and the lower thread (1.4b) on the bidirectional screw (1.4) is in thread fit with the lower clamping block (1.2);

the lower part of the upper clamping block (1.1) and the upper part of the lower clamping block (1.2) are respectively provided with a notch which is opposite to each other and used for clamping a V-shaped clamping groove (Q) of a cable to be stripped.