KR102337643B1 - Sheath module for installing utp cable - Google Patents

Abstract

The present invention relates to a sheath module for installing an unshielded twisted pair (UTP) cable to minimize internal and external interference. According to the present invention, the sheath module comprises: a first cylindrical sheath part including a first separator dividing the inner space of the first sheath into first to fourth zones through a structure in which four partitions extend in a mutually perpendicular direction from the center of the first sheath part, and first to fourth twist guides provided in the first to fourth zones, respectively, and guiding an insulated cable pair so that the insulated cable pair inserted thereinto is arranged in a twisted structure in the longitudinal direction of the first sheath part; and a second cylindrical sheath part having the same diameter and length as those of the first sheath part and including a second separator dividing the inner space of the second sheath into fifth to eight zones through a structure in which four partitions extend in a mutually perpendicular direction from the center of the second sheath part, and first to fourth twist guides provided in the first to fourth zones, respectively, and guiding the insulated cable pair so that the insulated cable pair inserted thereinto is arranged in a twisted structure in the longitudinal direction of the second sheath part. The first sheath part and the second sheath part are coupled adjacent to each other.

Description

Sheath module for UTP cable laying {SHEATH MODULE FOR INSTALLING UTP CABLE}

The present invention relates to a sheath module for UTP cable laying.

UTP cable (Unshielded Twisted Pair Cable), which is generally used as a communication cable, is an unshielded twisted pair cable widely used for the construction of communication networks such as LAN. A part is made, and a plurality (eg, four) of these stranded wire parts are collected and built into the sheath part.

Recently, high-frequency signals have been used for high-capacity transmission of 1 Gbps and 10 Gbps. When such high frequency is used, internal interference (PSNEXT: Power Sum Near End Cross Talk) and extraterrestrial interference (Alein Cross Talk) occur between each twisted pair inside the UTP cable, and It is known that the twisted pair part is greatly affected by internal and external interference between cables.

Conventionally, as a method for reducing internal interference and extraterrestrial interference in the twisted pair twisted at the longest pitch, a method of providing a separator in the sheath to further space the distance between the twisted pair included in each adjacent cable is applied. is becoming

However, in the conventional case, the operation of twisting an insulated cable to form a stranded portion having a predetermined pitch is performed manually by an operator, so errors in the pitch design of the stranded portion for minimizing the interference frequently occur, and through the separator The method of spacing the stranded part apart has limitations in that the thickness of the partition wall of the separator or the cross-sectional area of the sheath itself must be increased, and consequently the cost and sheath size required for UTP cable installation are increased.

The present invention has been devised to solve the above problems, and an object according to one aspect of the present invention is to minimize internal and external interference by eliminating a feature design error caused when a twisted wire part is formed by twisting a conventional insulated insulated cable. It is an object to provide a sheath module for UTP cable laying, which makes it easier to design a pitch for the purpose and minimizes internal and external interference without causing an increase in the size of the separator and the sheath portion, thereby allowing the UTP cable to be installed.

The sheath module for UTP cable installation according to an aspect of the present invention is a cylindrical first sheath portion, and the inner space of the first sheath portion through a structure in which four bulkheads extend in a mutually perpendicular direction from the center of the first sheath portion a first separator dividing the ? into first to fourth zones, and a pair of insulated cables that are provided in the first to fourth zones, respectively, and inserted therein, are arranged in a twisted structure in the longitudinal direction of the first sheath A first sheath including first to fourth twisted guide pairs for guiding the insulated cable pair; and a second cylindrical sheath portion having the same diameter and length as the first sheath portion, wherein the inner space of the second sheath portion is formed through a structure in which four partition walls extend in a mutually perpendicular direction from the center of the second sheath portion a second separator partitioning into fifth to eighth zones, and an insulated cable pair inserted into the fifth to eighth zones, respectively, arranged in a twisted structure in the longitudinal direction of the second sheath and a second sheath portion comprising a fifth to eighth twisted guide pair for guiding the insulated cable pair, wherein the first sheath portion and the second sheath portion are coupled adjacent to each other.

In the present invention, when each of the first to eighth twisted guide pairs is defined as the first to the eighth parallel pitch, the first to fourth alternate pitches have different values, respectively, and the fifth to the fifth The eight major rolling pitches have different values, respectively, and the first to fourth alternating pitches are characterized in that they have the same value as the fifth to eighth alternating pitches, respectively.

In the present invention, the size of the first to fourth interlocking pitch has a large value according to the order of the first to fourth intersecting pitch, and the size of the fifth to eighth interstitial pitch is the fifth to eighth interstitial pitch. It is characterized in that it has a large value according to the order.

In the present invention, three or more of the first sheath portion is provided and configured to be laminated and coupled coaxially in the longitudinal direction, and three or more second sheath portions are provided to be laminated and coupled coaxially in the longitudinal direction.

In the present invention, the three sequentially stacked first sheath portions are defined as 1-1 to 1-3 sheath stacks, respectively, and the three first sheath stacks are adjacently coupled to the first 1-1 to 1-3 sheath stacks. When the second sheath portion is defined as the 2-1 to 2-3th sheath stack, the first to fourth regions of each of the 1-1 to 1-3 sheath stacks are misaligned with each other. It is characterized in that the stacks are coaxially stacked in a state where they are in the same state, and the 2-1 to 2-3 sheath stacks are coaxially stacked in a state in which each of the fifth to eighth regions are misaligned with each other.

In the present invention, the first to fourth regions of the 1-1 sheath stack correspond to an upper left region, a lower left region, a lower right region, and an upper right region of the 1-1 sheath stack, respectively, which are partitioned by a first separator. and the first to fourth regions of the 1-2 sheath stack correspond to a lower-left region, an upper-left region, an upper-right region, and a lower-right region, respectively, of the 1-2 sheath stack partitioned by a first separator, The first to fourth regions of the 1-3 sheath stack respectively correspond to an upper-left region, a lower-left region, a lower-right region, and an upper-right region of the 1-3 sheath stack partitioned by a first separator, respectively. do.

In the present invention, the fifth to eighth regions of the 2-1 sheath stack correspond to the lower right region, the upper right region, the upper left region, and the lower left region of the 2-1 sheath stack, respectively, which are partitioned by a second separator. and the fifth to eighth regions of the 2-2 sheath stack correspond to an upper right region, a lower right region, a lower left region, and an upper left region of the 2-2 sheath stack partitioned by a second separator, respectively, The fifth to eighth regions of the 2-3th sheath stack correspond to the lower-right region, the upper-right region, the upper-left region, and the lower-left region of the 2-3th sheath stack, respectively, partitioned by a second separator do.

In the present invention, the two unit twist guides constituting each of the first to fourth twisted guide pairs are formed to protrude from the inner peripheral surface of the first sheath portion, and constitute the fifth to eighth twisted guide pairs, respectively. The two unit twist guides are formed to protrude from the inner circumferential surface of the second sheath portion.

According to one aspect of the present invention, in the present invention, by forming a twisted guide pair for guiding the insulated cable pair to be arranged in a twisted structure in four zones partitioned within the sheath by a separator, the operator manually twists the cable and twists the stranded wire As the UTP cable is laid in such a way that the insulated cable is inserted into the twisted guide pair whose pitch design has been completed at the time of forming the UTP cable, it is possible to eliminate the inconvenience of operation caused by the construction of the part and to provide convenience when configuring the stranded part. The pitch design precision of the cable to minimize internal interference and extraterrestrial interference can be improved.

In addition, according to an aspect of the present invention, a structure in which a plurality of two sheath parts are stacked in a state where they are adjacently coupled to each other, the pitch of the twist guide pair of the top and bottom stacked sheath stacks is misaligned with each other As much as possible, the high-capacity transmission capability of the UTP cable can be secured by minimizing the internal and external interference between cables.

1 and 2 are perspective views showing the structures of first and second sheath units in the sheath module for UTP cable installation according to an embodiment of the present invention.
3 is an exemplary view showing a laminated structure of the sheath portion in the sheath module for UTP cable installation according to an embodiment of the present invention.
4 and 5 are exemplary views illustrating a center-to-center distance between a first twisted guide pair and a second twisted guide pair in a sheath module for UTP cable installation according to an embodiment of the present invention.

Hereinafter, an embodiment of a sheath module for UTP cable laying according to the present invention will be described with reference to the accompanying drawings. In the process of describing the sheath module for UTP cable laying, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 and 2 are perspective views showing the structures of first and second sheath parts in the sheath module for UTP cable installation according to an embodiment of the present invention, and FIG. 3 is a sheath for UTP cable installation according to an embodiment of the present invention. It is an exemplary view showing the stacked structure of the sheath part in the module, and FIGS. 4 and 5 show the center-to-center distance between the first twisted guide pair and the second twisted guide pair in the sheath module for UTP cable laying according to an embodiment of the present invention It is an example diagram.

Referring to FIG. 1 , a sheath module (hereinafter, referred to as a sheath module) for UTP cable laying according to the present embodiment includes first and second sheath units 100 and 200 . The first and second sheath portions 100 and 200 have a cylindrical structure, have the same diameter and length, and are coupled adjacent to each other (a known coupling method such as a band tie method may be applied as a coupling method) ( Since the first and second sheath portions 100 and 200 have the same structure, only one sheath portion is illustrated in FIG. 1 ).

A first separator S1 is provided in the inner space of the first sheath part 100 , and the first separator S1 may be integrally formed with the outer surface of the first sheath part 100 . The first separator S1 divides the inner space of the first sheath part 100 in the first to fourth regions A1- through a structure in which four partition walls extend in a mutually perpendicular direction from the center of the first sheath part 100 . It is divided into A4).

A twist guide pair TGP is provided in each area A1 - A4 partitioned by the first separator S1 . One twist guide pair (TGP) takes a form in which two unit twist guides (TGU) are configured in a mutually twisted structure as shown in FIG. 1, and the unit twist guide (TGU) is an insulated cable (C) It is formed in a hollow structure to be inserted therein. Accordingly, the twist guide pair (TGP) guides the insulated cable pair so that the insulated cable pair inserted therein is arranged in a twisted structure in the longitudinal direction of the first sheath part 100, and the insulated cable pair is one As it is inserted into the twist guide pair (TGP) of the one stranded part is configured. In the present embodiment, each of the twisted guide pairs TGP provided in the first to fourth zones A1-A4 is defined as first to fourth twisted guide pairs TGP1-TPG4, respectively. On the other hand, the two unit twist guides TGU constituting the first to fourth twisted guide pairs TGP1-TPG4, respectively, are the inner peripheral surface of the first sheath portion 100 as shown in FIGS. 1, 4 and 5 . It is formed in a structure protruding from the , and this structure functions as a structure for maximizing the center-to-center distances PT1 to PT2 between the first twisted guide pair TGP1 and the fifth twisted guide pair TGP5, as will be described later.

A second separator S2 is provided in the inner space of the second sheath portion 200 . The second separator S2 divides the inner space of the second sheath 200 in the fifth to eighth regions A5- through a structure in which four partition walls extend in a mutually perpendicular direction from the center of the second sheath 200 . A8). The structure of the second sheath portion 200 is the same as that of the first sheath portion 100, and accordingly, fifth to eighth twisted guide pairs TGP5-TGP8 are provided in the fifth to eighth zones A5-A8, respectively. and two unit twist guides TGU constituting the fifth to eighth twisted guide pairs TGP5-TGP8 are formed to protrude from the inner circumferential surface of the second sheath portion 200 .

When the first to eighth twisted guide pairs (TGP1-TPG8) of the first and second sheath parts 100 and 200 are defined as the first to eighth parallel pitches P1 to P8, FIG. 2 As shown in, the first to fourth intersecting pitches (P1 to P4) have different values, and the fifth to eighth intersecting pitches (P5 to P8) have different values, respectively, and the first to fourth intersecting pitches (P1 - P4) has the same value as the fifth to eighth interstitial pitches (P5 - P8), respectively.

That is, based on the first sheath part 100 , as the first to fourth parallel pitches P1 - P4 have different values, it is formed by the first to fourth twisted guide pairs TGP1-TPG4. The first to fourth twisted-paired parts may have different pitches (P1 - P4), so that extraterrestrial interference between the respective twisted-pair parts may be reduced, which is equally applied to the second sheath part 200 . In addition, the first to fourth intersecting pitches (P1 to P4) are formed to have the same value as the fifth to eighth intersecting pitches (P5 to P8), respectively, so that the first and second sheath parts (100, 200) are formed. The forming process can be reduced.

In this embodiment, the sizes of the first to fourth intersecting pitches (P1 - P4) have large values according to the order of the first to fourth intersecting pitches (P1 - P4) (P1 > P2 > P3 > P4), and the fifth The magnitudes of the eighth to eighth parallel pitches P5 to P8 have a larger value according to the order of the fifth to eighth parallel pitches P5 to P8 (P5 > P6 > P7 > P8). This pitch value is a premise for minimizing the internal interference between cables in the laminated structure of the sheath.

As described above, in this embodiment, when the sheath module is molded, the first to eighth twisted guide pairs (TGP1-TPG8) into which the insulated cable is inserted are provided in the first and second sheath parts 100 and 200, The operator can form the twisted pair by inserting the insulated cable into each twist guide pair (TGP) without the need to manually form the twisted pair by twisting the insulated cable, so that work convenience can be secured. In addition, since the first to eighth twisted guide pairs (TGP1-TPG8) are formed to have a twisted pitch having a specific value, a pitch design error caused by an operator twisting an insulated cable to artificially configure a twisted pitch is eliminated. and the pitch design precision of cables to minimize internal and extraterrestrial interference can be improved.

On the other hand, the first and second sheath portions 100 and 200 of the present embodiment may be provided in plurality (at least three or more) and stacked and coupled on the same axis (to have the same center) in the longitudinal direction thereof. The number of the first and second sheath parts 100 and 200 to be laminated is selected according to the laying length of the UTP cable. Explain.

Referring to FIG. 3 , first, three first sheath portions 100 sequentially stacked are defined as 1-1 to 1-3 sheath stacks 100_1 to 100_3, respectively, and 1-1 to th The 1-3 sheath stacks 100_1 - 100_3 and the three second sheath units 200 adjacently coupled to each other are defined as 2-1 through 2-3 sheath stacks 200_1 - 200_3.

At this time, the 1-1 to 1-3 sheath stacks 100_1 to 100_3 are coaxially stacked in a state in which each of the first to fourth regions A1-A4 are misaligned with each other, The 2-1 to 2-3 sheath stacks 200_1 to 200_3 are coaxially stacked with each of the fifth to eighth regions A5-A8 misaligned with each other.

First, the stacked structure of the first sheath part 100 will be described.

The first to fourth regions A1 to A4 of the 1-1 sheath stack 100_1 include an upper left region and a lower left region of the 1-1 sheath stack 100_1 partitioned by the first separator S1, respectively; It corresponds to the lower-right area and the upper-right area. That is, the first twisted guide pair (TGP1), the second twisted guide pair (TGP2), and the third twisted guide pair are in the upper left section, the lower left section, the lower right section, and the right section of the 1-1 sheath stack 100_1, respectively. (TGP3) and a fourth twisted guide pair (TPG4) are arranged.

The first to fourth regions A1 to A4 of the 1-2 sheath stack 100_2 include a lower left region and an upper left region of the 1-2 sheath stack 100_2 partitioned by the first separator S1, respectively; It corresponds to the upper right area and the lower right area. That is, a first twisted guide pair (TGP1), a second twisted guide pair (TGP2), and a third twisted guide pair are respectively in the lower left section, the upper left section, the upper right section, and the lower right section of the 1-2 sheath stack 100_2 . (TGP3) and a fourth twisted guide pair (TPG4) are arranged.

The first to fourth regions A1 to A4 of the 1-3 sheath stack 100_3 include an upper left region and a lower left region of the 1-3 sheath stack 100_3 partitioned by the first separator S1, respectively; It corresponds to the lower-right area and the upper-right area. That is, the first twisted guide pair (TGP1), the second twisted guide pair (TGP2), and the third twisted guide pair are in the upper left section, the lower left section, the lower right section, and the right section of the 1-3 sheath stack 100_3, respectively. (TGP3) and a fourth twisted guide pair (TPG4) are arranged.

According to the above arrangement structure, twist guide pairs as shown in Table 1 below are disposed in each region of the 1-1 to 1-3 sheath stacks 100_1 - 100_3.

upper left area lower left area lower right area upper right area 1-3 cis stack TGP1 (P1) TGP2 (P2) TGP3 (P3) TGP4 (P4) 1-2 sheath stack TGP2 (P2) TGP1 (P1) TGP4 (P4) TGP3 (P3) 1-1 cis stack TGP1 (P1) TGP2 (P2) TGP3 (P3) TGP4 (P4)

That is, in the upper-left region/lower-left region of the 1-1 to 1-3 sheath stacks 100_1 - 100_3, a first twisted guide pair TGP1 having a first intersecting pitch P1, and a second intersecting pitch ( The second twisted guide pairs TGP2 having P2) are alternately arranged, and in the lower right section / upper right section of the 1-1 to 1-3 sheath stacks 100_1 - 100_3, a third interleaved pitch P3 A third twisted guide pair (TGP3) having a, and a fourth twisted guide pair (TGP4) having a fourth intersecting pitch (P4) are alternately arranged.

Accordingly, in the prior art, when a UTP cable is installed, the effect of reducing internal interference is limited because the same UTP cable has the same twist pitch in the longitudinal direction. Since a different parallel pitch is formed for each sheath stack, a phenomenon in which interference noise is oscillated and amplified by overlapping harmonics is eliminated, thereby maximizing the effect of reducing internal interference.

Next, the stacked structure of the second sheath portion 200 will be described.

The fifth to eighth regions A5-A8 of the 2-1 th sheath stack 200_1 include a lower right region and an upper right region of the 2-1 th sheath stack 200_1 partitioned by the second separator S2, respectively; It corresponds to the upper left area and the lower left area. That is, the fifth twisted guide pair (TGP5), the sixth twisted guide pair (TGP6), and the seventh twisted guide pair are in the lower right section, the upper right section, the upper left section, and the lower left section of the 2-1 sheath stack 200_1, respectively. (TGP7), an eighth twisted guide pair (TGP8) is arranged.

The fifth to eighth regions A5-A8 of the 2-2 sheath stack 200_2 include an upper right region and a lower right region of the 2-2 second sheath stack 200_2 partitioned by the second separator S2, respectively; It corresponds to the lower left area and upper left area. That is, the fifth twisted guide pair (TGP5), the sixth twisted guide pair (TGP6), and the seventh twisted guide pair are in the upper right section, the lower right section, the lower left section, and the upper left section of the 2-2 sheath stack 200_2, respectively. (TGP7), an eighth twisted guide pair (TGP8) is arranged.

The fifth to eighth regions A5-A8 of the 2-3th sheath stack 200_3 include a lower right region and an upper right region of the 2-3th sheath stack 200_3 partitioned by the second separator S2, respectively; It corresponds to the upper left area and the lower left area. That is, the fifth twisted guide pair (TGP5), the sixth twisted guide pair (TGP6), and the seventh twisted guide pair are in the lower right section, the upper right section, the upper left section, and the lower left section of the 2-3 sheath stack 200_3, respectively. (TGP7), an eighth twisted guide pair (TGP8) is arranged.

According to the arrangement structure, twist guide pairs as shown in Table 2 below are disposed in each region of the 2-1 to 2-3 sheath stacks 200_1 - 200_3.

lower right area upper right area upper left area lower left area 2-3 sheath stack TGP5 (P5) TGP6 (P6) TGP7 (P7) TGP8 (P8) 2-2 sheath stack TGP6 (P6) TGP5 (P5) TGP8 (P8) TGP7 (P7) 2-1 sheath stack TGP5 (P5) TGP6 (P6) TGP7 (P7) TGP8 (P8)

That is, in the lower right section / upper right section of the 2-1 to 2-3 sheath stacks 200_1 - 200_3, a fifth twist guide pair TGP5 having a fifth intersecting pitch P5, and a sixth intersecting pitch ( A sixth twisted guide pair (TGP6) having P6) is alternately disposed, and in the upper left region/lower left region of the 2-1 to 2-3 sheath stacks 200_1 - 200_3, a seventh interleaved pitch (P7) A seventh twisted guide pair (TGP7) having a , and an eighth twisted guide pair (TGP8) having an eighth intersecting pitch (P8) are alternately arranged. Accordingly, in the related art, when UTP cables are installed, Although the twisted pitch is different from each other, the same UTP cable has the same twisted pitch in the longitudinal direction, so there is a limit to the reduction effect of internal interference. Since different pitches are formed, a phenomenon in which interference noise is oscillated by overlapping harmonics and amplified is eliminated, thereby maximizing the effect of reducing internal interference.

On the other hand, it is known that the influence of extraterrestrial interference caused in the UTP cable is reduced as the distance between the twisted-pair parts having the largest twist pitch increases. When examining the arrangement of the first twisted guide pair (TGP1) and the fifth twisted guide pair (TGP5) having the largest parallel pitch in this embodiment, the first twisted guide pair (TGP1) in the 1-1 sheath stack (100_1) ) is arranged in the upper left region, and the fifth twisted guide pair TGP5 in the 2-1 sheath stack 200_1 is arranged in the lower right region, and is arranged to have the largest separation distance among the distances between each twisted guide pair (Fig. 4, PT1 to PT2). In addition, in the 1-2 sheath stack 100_2, the first twisted guide pair TGP1 is disposed in the lower left region, and in the 2-2 sheath stack 200_2, the fifth twisted guide pair TGP5 is in the upper right region It is arranged to have the largest separation distance among the distances between each twisted guide pair (FIG. 5, PT1 to PT2). In addition, in the 1-3 sheath stack 100_3 , the first twisted guide pair TGP1 is disposed in the upper left region, and in the 2-3 sheath stack 200_3 , the fifth twisted guide pair TGP5 is disposed in the lower right region and is arranged to have the largest separation distance among the distances between each twisted guide pair (FIG. 4, PT1 to PT2).

That is, according to the above arrangement structure, the distance between the center PT1 of the first twisted pair portion having the first wide twisting pitch P1 and the center PT2 of the fifth twisted wire section having the fifth wide twisted pitch P5 is the distance between each stranded wire Since it is formed to have the largest separation distance among the distances between sub-centers, extraterrestrial interference can be effectively reduced, and two unit twist guides (TGU) constituting the twist guide pair (TGP), respectively, have the first and second sheaths. The structure protruding from the inner circumferential surface of the portions 100 and 200 (that is, the structure protruding from the inner circumferential surface of the sheath portion, not the structure protruding from the separator) includes the center of the first stranded portion having the first wide pitch P1, and the fifth Since it functions to further increase the distance between the centers of the fifth stranded part having the large twisted pitch P5, the effect of reducing extraterrestrial interference can be maximized.

As described above, this embodiment forms a twisted guide pair that guides the insulated cable pair to be arranged in a twisted structure in the four zones partitioned within the sheath by a separator, so that the operator manually twists the cable to form the twisted pair. It is possible to eliminate the inconvenience of being inconvenient and to provide work convenience when constructing the stranded part, and when forming the UTP cable by inserting the insulated cable into the twisted guide pair whose pitch design has been completed, internal and external interference is reduced as the UTP cable is installed. To minimize the pitch design precision of the cable can be improved.

In addition, this embodiment takes a structure in which two sheath parts are stacked in plurality in a state where they are adjacently coupled to each other, and the pitch of the twist guide pair of the sheath stack stacked up and down is misaligned with each other so that the cables between the cables By minimizing internal and extraterrestrial interference, it is possible to secure the high-capacity transmission capability of the UTP cable.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely an example, and those skilled in the art to which various modifications and equivalent other embodiments are possible. will understand Accordingly, the true technical protection scope of the present invention should be defined by the claims.

100: first sheath portion
100_1, 100_2, 100_3: 1-1 to 1-3 cis stack
200: second sheath portion
200_1, 200_2, 200_3: 2-1 to 2-3 cis stack
S1, S2: first and second separators
A1-A8: Zones 1 to 8
TGP1-TGP8: first to eighth twisted guide pairs
TGU: unit twist guide
C: insulated cable

Claims (2)

A cylindrical first sheath, comprising:
a first separator dividing the inner space of the first sheath into first to fourth zones through a structure in which four partition walls extend in a mutually perpendicular direction from the center of the first sheath; and
First to fourth twist guides provided in the first to fourth zones, respectively, for guiding the insulated cable pair so that the insulated cable pair inserted therein is arranged in a twisted structure in the longitudinal direction of the first sheath A first sheath comprising a pair; and
A cylindrical second sheath portion having the same diameter and length as the first sheath portion,
a second separator dividing the inner space of the second sheath into fifth to eighth zones through a structure in which four partition walls extend in a mutually perpendicular direction from the center of the second sheath; and
Fifth to eighth twist guides provided in the fifth to eighth zones, respectively, for guiding the insulated cable pair so that the insulated cable pair inserted therein is arranged in a twisted structure in the longitudinal direction of the second sheath A second sheath comprising a pair;
including,
The first sheath portion and the second sheath portion are coupled adjacent to each other,
When each of the first to eighth twist guide pairs is defined as a first to eighth cross-connection pitch, the first to fourth cross-connection pitches have different values, respectively, and the fifth to eighth cross-connection pitches are Each has a different value, and the first to fourth intersecting pitches have the same value as the fifth to eighth intersecting pitch, respectively,
The size of the first to fourth interstitial pitches has a large value according to the order of the first to fourth intersecting pitches, and the size of the fifth to eighth interstitial pitches is large according to the fifth to eighth interstitial pitch order. have a value,
Three or more first sheath parts are provided so as to be laminated and coupled coaxially in the longitudinal direction, and three or more second sheath parts are provided to be laminated and coupled coaxially in the longitudinal direction,
Three sequentially stacked first sheath portions are defined as 1-1 to 1-3 sheath stacks, respectively, and three second sheath portions coupled adjacent to each other with the 1-1 to 1-3 sheath stacks are formed. When defined as 2-1 to 2-3 cis stack,
The 1-1 to 1-3 sheath stacks are coaxially stacked with each of the first to fourth regions misaligned with each other, and the 2-1 to 2-3 sheath stacks The stack is coaxially stacked with each of the fifth to eighth zones misaligned with each other,
The first to fourth regions of the 1-1 sheath stack correspond to an upper left region, a lower left region, a lower right region, and an upper right region of the 1-1 sheath stack, respectively, partitioned by a first separator,
The first to fourth regions of the 1-2 sheath stack correspond to a lower left region, an upper left region, an upper right region, and a lower right region of the 1-2 sheath stack, respectively, partitioned by a first separator,
The first to fourth regions of the 1-3 sheath stack correspond to an upper-left region, a lower-left region, a lower-right region, and an upper-right region, respectively, of the 1-3 sheath stack partitioned by a first separator,
The fifth to eighth regions of the 2-1 sheath stack correspond to a lower right region, an upper right region, an upper left region, and a lower left region, respectively, of the 2-1 sheath stack partitioned by a second separator,
The fifth to eighth regions of the 2-2 sheath stack correspond to an upper right region, a lower right region, a lower left region, and an upper left region of the 2-2 sheath stack partitioned by a second separator, respectively;
The fifth to eighth regions of the 2-3th sheath stack correspond to the lower-right region, the upper-right region, the upper-left region, and the lower-left region of the 2-3th sheath stack, respectively, partitioned by a second separator sheath module for UTP cable laying. delete

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