JP3199639B2 - Insulation tube for wire branch connection - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a covering tube for a branch connection part of an electric wire for performing moisture proof, electrical insulation, and mechanical protection processing on the branch connection part of the electric wire.

[0002]

2. Description of the Related Art Conventionally, an electric wire conductor exposed at a connection portion between electric wires (cables) or a connection portion between an electric wire and another conductive terminal member is covered with a coating for the purpose of moisture proofing, electrical insulation, and mechanical protection. For this purpose, various methods have been used. For example, a method of winding a waterproof pressure-sensitive adhesive tape on a connection portion, a method of covering the connection portion with a separate pipe member and then sealing an end of the tube member with a waterproof pressure-sensitive adhesive tape, a paste of mastic or the like on the connection portion A method of winding a waterproof pressure-sensitive adhesive tape on a coated member is well known as a simple and inexpensive method. However, the process of winding the waterproof pressure-sensitive adhesive tape tends to cause a difference in finished state depending on an operator. However, there is a problem that it is difficult to perform uniform and stable processing.

[0003] In order to easily and stably impart sufficient moisture-proofing properties, electrical insulation properties, and mechanical protection properties to a wire connection part, an inner diameter dimension exceeding an outer diameter dimension of the connection part and a total length of the connection part are exceeded. A covering tube (hereinafter, referred to as a shrinkable tube) is known in which a tube member having a length is shrunk by some means after being arranged so as to surround the connecting portion, and the shrinking force tightly covers the connecting portion. . This type of shrinkable tube includes a heat shrinkable tube (see Japanese Patent Application Laid-Open No. 1-295614) in which a tube member made of a polymer material having high heat shrinkability is heated and shrunk using an external heat source, and a tube having a small permanent elongation. The entire length of the tubular member made of an elastomer is elastically expanded (radially expanded) in advance by a cylindrical core member made of a hard plastic or the like, and is elastically contracted by removing the core member at the time of attachment to the connection portion. Elastic shrinkable tube with core to be made (see JP-A-3-143217)
There is.

[0004] All of the above-mentioned shrinkable tubes can shorten the working time and stabilize the finished state.
Since the pipe member adheres to the wire conductor and the wire jacket by its own contraction force, the advantage that sufficient moisture-proof, electrical insulation and mechanical protection properties can be provided to the connection portion without using a waterproof adhesive tape. Having. However, the heat-shrinkable tube has the problem of requiring a heat source such as a burner at the time of work, and has a problem that the heat-shrinkage work requires skill to obtain a uniform shrink shape. On the other hand, an elastic shrink tube with a core (generally referred to as a PST (pre-stretched tube)) does not require skill for shrinking work, but it takes more time to remove the core member as the entire length of the tube member increases, The pipe member cannot be bent at the time of attachment to the electric wire connection part, making it difficult to perform the attachment work, and squeezing the tubular wall of the pipe member with a finger to make the relative connection of the electric wire connection part within the pipe member. The pipe member could not be attached to the connection portion while checking the position, and the reliability of the coating treatment tended to decrease.

[0005] To solve such a problem of the elastically shrinkable tube with a core, Japanese Patent Application Laid-Open No. Hei 7-57798 discloses a coated tube having a PST structure seal portion only in a region near the tube opening end. Is disclosed.
That is, this covering tube includes a tubular sleeve portion having a plurality of open ends, and a tubular seal portion provided at each open end of the sleeve portion, and each seal portion is integrally connected to the sleeve portion. It is formed from a tube element and a removable core element arranged radially inside the tube element to hold the tube element in an elastically expanded state. Therefore, in this covered tube, the total length of the core element provided in each seal portion is reduced as compared with the case where the entire tube has the PST structure, and thus the work time required for removing the core element is reduced. Further, since the core element is not arranged on the sleeve portion covering the electric wire connection portion, the sleeve portion can be flexed freely in the mounting operation, so that the mounting workability can be improved and the position of the electric wire connection portion in the sleeve portion can be improved. The covering tube can be mounted at an appropriate position while confirming the tactile sensation.

[0006]

Problems to be Solved by the Invention Japanese Patent Application Laid-Open No. 7-57798
The covering tube disclosed in Japanese Patent Application Laid-Open Publication No. H10-15064 can be applied to a Y-branch connection portion of an electric wire by forming a sleeve portion into a Y-branch tube shape. In this application, when the covering tube is attached to the Y-branch connection portion, the two seal portions for the branch electric wire are attached to the Y-branch portion.
A total of two branch wires inserted into the sleeve portion are pulled out from one seal portion for the main wire, and both branch wires are connected to one main wire, and then the sheath tube is shifted to sleeve the wire connection portion. The pipe element is brought into close contact with the outer jacket of each electric wire by removing the core element of each seal part in that state. Therefore, the main wire seal portion of the covering tube must be greatly expanded by using a core member having a larger diameter than the branch line side open end. When the main electric wire and the branch electric wire have substantially the same diameter, the pipe element in the main electric wire side seal portion having such a large diameter is removed from the branch electric wire side having a smaller diameter after removing the core element. Similar to the pipe element in the seal portion, it is required to be able to contract to substantially the same diameter, and to exert the same sealing performance on the main wire as on the branch wire side. Therefore, when manufacturing such a branch-type coated tube, as the material of the tube element, a material having a permanent elongation property capable of exhibiting a sufficient sealing ability at the main wire side sealing portion having a larger diameter is used. As a matter of choice, such a material has an excessive capacity with respect to the pipe element of the branch wire side seal portion, and there is a problem that the material cost is unnecessarily increased.

[0007] Further, in the coated tube disclosed in Japanese Patent Application Laid-Open No. 7-57798, when the core element is arranged in each seal portion in the manufacturing process, the core element is expanded in a state in which the pipe element is expanded by a predetermined jig. Work to insert the element into the tube element. At this time, since the sleeve portion and the tube element are generally made of an opaque material, it has been difficult to arrange the core element at an appropriate position of the seal portion.

A main object of the present invention is to provide a sheathing tube for a wire branch connection part in which a PST structure is provided only in a region near an opening end to improve mounting workability and covering reliability. An object of the present invention is to provide a covering tube for an electric wire branching / connecting portion capable of suppressing an increase in material cost by being able to impart the above sealing ability. Another object of the present invention is to provide a covering tube in which a core element can be arranged at an appropriate position at an open end in such a covering tube of a wire branch connection portion.

[0009]

To achieve the above object, the present invention provides a Y-branched tubular sleeve made of an electrically insulating elastomer having three open ends, and each of the open ends of the sleeve. And a tubular seal portion having electrical insulation provided at each of the seal portions. Each of the seal portions is disposed radially inside the tube element connected to the sleeve portion, and the tube element is elastically expanded. In the sheath tube of the electric wire branch connection part formed from the removable core element held in the radial state, the core element of one seal part on the main electric wire side is provided with each of the other two seal parts on the branch electric wire side. A first elastic element having a larger inner diameter than the core element, wherein the pipe element of the seal portion on the main electric wire side is integrally extended from the sleeve portion;
A second elastic element sandwiched between the elastic element and the core element, wherein the second elastic element is made of an elastomer having a smaller permanent elongation than the first elastic element. Provide a coated tube.

Further, according to the present invention, in the above-mentioned covering tube of the electric wire branch connection portion, the first elastic element has a permanent elongation of 1%.
There is provided a coated tube having a permanent elongation of the second elastic element in a range of 0% to 30% and less than 10%.

[0011] Further, the present invention provides the above-described sheathed tube of the electric wire branch connection portion, in which the outer surfaces of all the seal portions are provided.
A first mark defining the position of the axial edge of the core element is provided, and a second mark defining the position of the axial edge of the second elastic element is provided on the outer surface of the seal portion on the main electric wire side. To provide a coated tube.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on preferred embodiments with reference to the accompanying drawings. In the multiple drawings, the same or similar components are denoted by common reference numerals. 1 to 3 show a sheath tube 10 of a wire branch connection part according to an embodiment of the present invention. The coating tube 10 is formed of a substantially Y-shaped cylindrical tubular member having three open ends, and mainly coats Y-branch connection portions of wires having substantially the same outer diameter for the purpose of moisture proof, electrical insulation, and mechanical protection. To accommodate. The coating tube 10 includes three electric wires 40a,
Exposed and interconnected conductor portion 42 at the end of 40b
And a Y-branch tubular sleeve 12 having a length capable of surrounding the end portions of the electric wire jacket 44 adjacent to the conductor portions 42 of the electric wires 40a and 40b. Sleeve part 1
2 is a conductor portion 42 and an electric wire jacket 44 as described later.
It is preferable to have a larger inner diameter than the outer diameter of the end portion of the. The sleeve portion 12 is essentially made of an elastomer having electrical insulation and flexibility, and is freely deformable in accordance with the bending of the electric wire to be covered.

A seal portion 14a of a PST structure having a two-layer pipe element is formed at one of the three open ends of the sleeve portion 12 through which the main electric wire 40a passes. That is, the seal portion 14 a is a tubular element connected to the sleeve portion 12, and is a tubular first elastic element 16 integrally formed from the sleeve portion 12, and is fixed to the inside of the first elastic element 16 in the radial direction. And a tubular second elastic element 18 to be arranged. The first elastic element 16 and the second elastic element 18 are made of elastomers having different characteristics as described later.
Further, the seal portion 14 a includes a large-diameter tubular core element 20 which is disposed removably on the radial inside of the second elastic element 18. The core element 20 has an inner diameter that is sufficiently larger than the sum of the outer diameters of the wire jackets 44 of the two branch wires 40b as described later, and makes the first elastic element 16 and the second elastic element 18 elastic. The first elastic element 16 and the second elastic element 18 are maintained in an elastically expanded state while maintaining the inner diameter of the core element itself against the elastic recovery (shrinkage) force thereof.

[0014] Of the three open ends of the sleeve portion 12, the other two open ends through which the branch wire 40b passes are provided with a seal portion 14b of a PST structure having a single-layer pipe element similar to the prior art.
Is formed. That is, each seal portion 14b includes a tube element 22 integrally formed from the sleeve portion 12 and a small-diameter tubular core element 24 disposed removably inside the tube element 22 in the radial direction. Each core element 24 has an inner diameter sufficiently larger than the outer diameter of the electric wire jacket 44 of one branch electric wire 40b, expands the tube element 22 elastically, and has an elastic recovery (shrinkage) force. The tube element 22 is maintained in an elastically expanded state while maintaining the inner diameter of the core element itself.

When the sheath tube 10 is mounted on the branch connection of the electric wire, the sleeve 12 covers and accommodates the branch connection.
First elastic element 16 and second elastic element 1 of seal portion 14a
8 and the pipe element 22 of the seal portion 14b
When the wires 0 and 24 are removed, the wires 40a and 40b are elastically contracted and adhere to the portions of the electric wires 40a and 40b near the ends of the electric wire jacket 44 under the tightening force due to the contraction. The sleeve 1
2. The first elastic element 16 of the seal portion 14a and the seal portion 1
The tube element 22 of 4b is preferably formed by an injection molding process.
They are integrally formed from the same material. Thereby, the covering tube 10 is provided with excellent moisture-proof action, electrical insulation action and mechanical protection action for the wire branch connection portion at low cost.

In the covering tube 10, as will be described later, it is necessary to mount the main electric wire 40 on the branch connection portion of the electric wire.
The seal portion 14a through which a is extended by the core element 20 to a larger diameter than each seal portion 14b through which the branch electric wire 40b passes. After the core element 20 is removed, the outer diameter of the seal portion 14a is substantially the same as that of the branch electric wire 40b. It is required that the main electric wire 40a exhibit a sealing effect equivalent to that of each seal portion 14b. Therefore, if the prior art is applied to such a branch-type coated tube, a material having an excellent permanent elongation property capable of exhibiting a sufficient sealing ability in a main wire side seal portion having a larger diameter is obtained. Is selected as the main material (i.e., the material of the sleeve portion and the tube element of each seal portion), but such a material is excessive for each seal portion on the branch electric wire side, and the material cost of the sheath tube is unnecessary. Growing challenges arise.

On the other hand, in the present embodiment, the main material of the coated tube 10 is selected based on the permanent elongation characteristics required for each of the seal portions 14b whose diameters are relatively small and the material cost of the coated tube 10 is reduced. The seal portion 14a to be suppressed and greatly expanded has a two-layer structure, and an expensive material having a permanent elongation characteristic superior to the main material is used for the inner layer side, so that the seal portion 14a This is a configuration that can exhibit the same sealing performance as.

Accordingly, the first elastic element 16 constituting the outer layer of the tube element of the seal portion 14a is made of an elastomer having physical properties such as electric insulation, high elastic recovery, and excellent permanent elongation, which are preferable as PST. Specific examples of the material of the first elastic element 16 include ethylene propylene rubber (especially EPDM), chloroprene rubber, butyl rubber, silicone rubber, natural rubber, fluorine rubber, silicone-modified EPDM, and the like. Of these, EPDM
Is a particularly preferred material because it is excellent in weather resistance, electrical insulation and water resistance and is inexpensive.

More specifically, the first portion of the seal portion 14a
The elastic element 16 is made of EPDM having a permanent elongation in a range of 10% to 30% based on a measuring method according to JIS-K6301. An elastomer having a permanent elongation of less than 10% is an appropriate material that can be produced by current technology in consideration of the anti-tracking property required for an electric wire covering material. Generally, it is expensive, and there is a concern that the material cost of the coated tube 10 will increase. On the other hand, the permanent elongation is 1
EPDM in the range of 0% to 30% can be made cheaply and easily. If the permanent elongation exceeds 30%, the tightening force due to the elastic contraction of the first elastic element 16 of the seal portion 14a deteriorates with time, and the moisture-proof and electrical insulation functions of the seal portion 14a tend to decrease. .

The second elastic element 18 constituting the inner layer of the tube element of the seal portion 14a is made of an elastomer having physical properties preferable as PST similarly to the first elastic element 16, and in particular, measured in accordance with JIS-K6301. Based on the method, silicone rubber having a permanent elongation of less than 10% is a preferred material. If the permanent elongation is 10% or more,
Since only the sealing ability equivalent to the elastic element 16, that is, the sealing ability equivalent to the pipe element 22 of each seal portion 14 b on the branch electric wire side can be exerted, the second elastic element 18 is used in the main electric wire side seal portion 14 a having a larger diameter. The tightening force due to the elastic shrinkage of the seal member 14 deteriorates with the passage of time, and the moisture-proof and electrical insulation functions of the seal portion 14a tend to be reduced. Such a silicone rubber is a very expensive material as compared with the EPDM. However, in the covering tube 10, only the one sealing portion 14 a needs to be disposed, so that the covering tube 10 is entirely formed of such a silicone rubber. In comparison, soaring material costs can be suppressed.

The first elastic element 16 of the seal portion 14a
Other physical properties (for example, 300% tensile stress, hardness, etc.) of the second elastic element 18 are arbitrary within a range suitable for PST.
However, the second elastic element 18 that comes into contact with the electric wire jacket can be formed of a material having a lower hardness than the first elastic element 16 exposed to the surrounding environment. Since the elastic element 18 can easily follow, the sealing portion 14
The sealing ability of a is further improved.

The first elastic element 16 of the seal portion 14a
And the axial length of the second elastic element 18 and the sealing portion 1
The axial length of the tube element 22 of 4b is appropriately set in accordance with the sealing distance (the length required to obtain a reliable seal) determined by the voltage applied to the applicable electric wire of the covering tube 10. Are preferably at least 10 mm in size. Similarly, the radial thickness of the tube element combining the first elastic element 16 and the second elastic element 18 of the seal portion 14a and the radial thickness of the tube element 22 of the seal portion 14b are appropriately determined in accordance with the seal distance. Although they are set, each is preferably 3 mm or more.

Each core element 2 of the seal portions 14a and 14b
Reference numerals 0 and 24 denote cylindrical members made of, for example, hard plastic, which elastically expand the first elastic element 16, the second elastic element 18, and the tube element 22 against the elastic recovery (shrinkage) force thereof. It has sufficient rigidity to keep it in a diameter state. Suitable materials for the core elements 20, 24 include cellulose acetate or butyrate, polypropylene, polyethylene, polyvinyl chloride, and the like.

The core elements 20, 24 extend in a strip at an end located adjacent to the sleeve portion 12 with a groove or weakening line 26 extending helically over the entire length of the cylindrical wall. An extension 28 is provided. The extension part 28 is passed through the inside of the core elements 20 and 24, and the tip is pulled out from the axial outside end of each seal part 14a and 14b. The core elements 20 and 24 are continuously broken along the line of weakness 26 by pulling the extension 28 from the outside of the seal portions 14a and 14b when the sheath tube 10 is mounted on the wire branch connection portion. Removed from 14a, 14b.
To that end, each core element 20, 24 has a sealing portion 14a,
It is preferable to have an inner diameter dimension that allows the extension portion 28 to be easily pulled using the gap between the electric wire jacket 44 and the core elements 20 and 24 in a state where the electric wires 40a and 40b are accommodated in the 14b.

As described above, in the covering tube 10, the core elements 20 disposed in the seal portions 14a and 14b at the respective open ends are provided.
24 only needs to have a length corresponding to the sealing distance required for the applicable electric wire, irrespective of the entire length of the coating tube 10. As a result, the time required for removing the core elements 20 and 24 is significantly reduced as compared to a coated tube having a PST structure over the entire length. Also, the core elements 20, 24
Reduces material costs and waste.

As an example of the manufacturing process of the coated tube 10 having the above configuration, the first elastic element 16 and the pipe element 22
And a second elastic element 18
And the core elements 20 and 24 are formed in separate steps. Then, after attaching the second elastic element 18 to the outer surface of the core element 20 while increasing the diameter, attaching the first elastic element 16 to the outer surface of the second elastic element 18 on the core element 20 while increasing the diameter. I do. Further, each pipe element 22 is attached to the outer surface of the core element 24 while expanding its diameter. At this time, the sleeve portion 12, the first elastic element 1
6. Since the second elastic element 18 and the pipe element 22 are generally made of an opaque material, it is difficult to arrange the second elastic element 18 and the core elements 20 and 24 at appropriate positions of the respective seal portions 14a and 14b. Is predicted. Therefore, in the covering tube 10, the core element 2 is provided on the outer surface of the seal portion 14a.
A first mark 30 defining the position of the axial edge of
Second mark 3 defining the position of the axial edge of elastic element 18
2 is provided. A first mark 34 that defines the position of the axial edge of the core element 24 is provided on the outer surface of the seal portion 14b.

In the illustrated embodiment, each first landmark 30, 34
Is composed of a pair of linear marks provided in the boundary region between the sleeve portion 12 and the seal portions 14a and 14b in a direction parallel to each other and separated by a predetermined distance in the axial direction. At the time of assembling the coating tube 10, one axial edge of each of the core elements 20 and 24 is
By disposing between the pair of linear marks constituting each of the first marks 30 and 34 and projecting the other end in the axial direction slightly outward from the open ends of the first elastic element 16 and the pipe element 22. The respective core elements 20, 24 are positioned at appropriate positions in the respective seal portions 14a, 14b.

Further, the second mark 32 is substantially parallel to the first mark 30 at a predetermined position between the linear mark of the first mark 30 remote from the sleeve portion 12 and the open end of the first elastic element 16. In one linear mark. When assembling the covering tube 10, one end in the axial direction of the second elastic element 18 is disposed between the linear mark of the first mark 30 on the side remote from the sleeve portion 12 and the second mark 32, and By arranging the other end edge at a position where it does not protrude outward from the opening end of the first elastic element 16, the second elastic element 18 is positioned at an appropriate position in the seal portion 14a. The first marks 30 and 34 and the second marks 32 can have various shapes such as a curved shape, a dotted line shape, and a dotted shape.
Various forms such as printing can be adopted.

Next, the coated tube 10 having the above configuration
The operation and effect of will be described. As shown in FIG. 2, at the Y-branch connection portion of the electric wires, three electric wires 40a, 40b to be connected are connected.
The conductor 42 exposed by removing the jacket 44 and the insulator (not shown) is connected to each other by a connector 46. First, three electric wires 40 are provided in the coating tube 10.
Prior to the interconnection of a and 40b, each of the small diameter seals 1
4b, one branch wire 40b is connected to the sleeve 1
2, the exposed conductors 42 are drawn out of the covering tube 10 from the large-diameter seal portion 14a,
The connector 46 connects to the exposed conductor 42 of the main electric wire 40a. Next, the sheath tube 10 is moved to position the connector 46 substantially at the center of the sleeve portion 12, and the end portions of the sheaths 44 of the electric wires 40 a and 40 b and the exposed conductor 4.
2, and the connector 46 is arranged at a preparation position surrounding the connector 46.

At this time, the inner diameter of the sleeve portion 12 is set so that gaps 48 are formed between the inner surface thereof and the outer surfaces of the conductor 42, the outer cover 44, and the connector 46, so that the sleeve portion 12 is covered. The frictional resistance when inserting the electric wires 40a and 40b into the tube 10 is reduced, and the tube 10 can be easily inserted. Alternatively, the gap 48 may be reduced as much as possible so that the sleeve portion 12 does not tighten the wire connection portion.
Furthermore, by forming the sleeve portion 12 from a flexible material as described above, it is possible to squeeze the cylindrical wall of the sleeve portion 12 with a finger to confirm the position of the connector 46 in the coating tube 10. Become.

The covering tube 10 is arranged at the above-mentioned preparation position, and the core elements 20 and 24 of the sealing portions 14a and 14b are
By pulling the tips of the extension portions 28, the seal portions 14a, 1a are broken while being spirally broken along the line of weakness 26.
Remove from 4b. Thereby, the first elastic element 16 and the second elastic element 18 of the seal portion 14a and the seal portion 14
b of the tube element 22 under the tightening force due to their elastic shrinkage,
0b is in close contact with the outer surface of the jacket 44 (see FIG. 3). At this time, the second elastic element 18 of the seal portion 14a made of an elastomer having a permanent elongation of less than 10%
Despite having been expanded to about twice the inner diameter of the pipe element 22 of FIG.
(a) closely adheres to the outer surface of the jacket 44; In addition, each seal portion 1
Since the diameter of the tube element 22 of 4b has been expanded to the extent that the required sealing ability can be sufficiently exhibited, the tube element 22 is elastically contracted favorably and closely adheres to the outer surface of the jacket 44 of the branch electric wire 40b.

Here, the first elastic element 1 of the seal portion 14a
6 has a larger diameter than the pipe element 12 of the seal portion 14b, but since the second elastic element 18 is disposed radially inward, the amount of expansion of the first elastic element 16 in the circumferential direction when the diameter is expanded. Is smaller than the same elongation of the second elastic element 18. Therefore, even though the first elastic element 16 is formed of a material having a permanent elongation property that is inferior to the second elastic element 18, the first elastic element 16 and the second elastic element 16 contract well by removing the core element 20. 18 to provide the required sealing action. Also, as described above, even when the two seal portions 14a and 14b seal an electric wire having the same diameter, the first elastic element 16 sets the initial inner diameter when the diameter is not expanded by the thickness of the second elastic element 18. The pipe element 22 can be designed larger than the pipe element 22 and the inner diameter in the sealed state after contraction can be set to be larger than the pipe element 22 by the thickness of the second elastic element 18. Second elastic element 18
To provide the required sealing action. In this way, the sealing portion 14a can exhibit the same sealing ability as each sealing portion 14b.

The first elastic element 16 and the second elastic element 1
If there is a risk that the sealing action between the first elastic element 16 and the second elastic element 18 will be insufficient, the permanent elongation of the material of the first elastic element 16 should be as close as possible to 10%.
It is desirable to fix the gap between them with an appropriate means such as an adhesive.

The first elastic element 16 and the second elastic element 18 of the seal part 14a and the pipe element 22 of the seal part 14b
The magnitude of the tightening force due to elastic contraction depends on the value of so-called seal stress (%). In the present embodiment, 5% of the first elastic element 16 and the pipe element 22 correspond to the outer diameter of the jacket 44 of the electric wires 40a and 40b.
In order to obtain the above-mentioned sealing stress, the diameter of the sheath tube 10, especially the seal portions 14 a and 14 b when the diameter is not expanded (that is, the first elastic element 16 and the pipe when the diameter is not expanded except for the core elements 20 and 24). Of the element 22). Thereby, necessary and sufficient moisture proof, electrical insulation, and mechanical protection effects can be obtained for the electric wires 40a and 40b. Note that the seal stress is calculated by the following equation. Seal stress = [(outer diameter of wire sheath 44−inner diameter of first elastic element 16 or pipe element 22 when non-expanded) / inner diameter of first elastic element 16 or pipe element 22 when not expanded] × 100

The moisture-proof and electrical insulating effects of the above-described coated tube 10 at the wire branch connection portion and the grounds for limiting the numerical values will be further clarified by the evaluation results of the following experiments.
The coated tube 10 to be tested has 1 as shown in Table 1.
From EPDM having a permanent elongation of 0% to 30%, the sleeve portion 12, the first elastic element 16 and the tube element 22 are integrally formed by die molding.
The second elastic element 18 was formed from a silicone rubber i, ii, iii for ST by die molding, and was disposed radially inside the first elastic element 16. The characteristic values in the table are
It is measured according to JIS-K6301.

[0036]

[Table 1]

The first elastic element 16 and each of the second elastic elements 18 are combined to form the seal portions 14a and 14b so that a sealing stress of 5% or more in the first elastic element 16 and the pipe element 22 can be obtained. The three types of coated tubes were attached to the Y branch connection portions of the electric wires 40a and 40b.
Thereafter, the connection portion was submerged, and the insulation resistance between the conductor 42 and water was measured with an insulation resistance meter under the condition of DC 1000 V,
The waterproof insulation properties were compared and evaluated (Experiment 1). In addition, air pressure was applied to the branch connection portion from the end of the wire away from the wire branch connection portion to which the covering tube 10 was attached, and the pressure at the time of occurrence of air leak was measured to compare and evaluate the airtightness (experiment). 2). Table 2 shows the evaluation results.

[0038]

[Table 2]

In this embodiment, when the waterproof insulation property of 2000 MΩ or more and the airtight property of 0.38 kgf / cm ² or more are obtained, the sealing performance required for the electric wires 40 a and 40 b is obtained. I do. Therefore, among the above materials, the combination of the first elastic element 16 made of EPDM and the second elastic element 18 made of silicone rubber ii (permanent elongation = 9%) or iii (5%) is excellent. It will be understood that a good sealing performance is exhibited.

Further, in order to compare the present invention with the prior art, a coated tube 10 composed of a combination of the first elastic element 16 and the second elastic element 18 shown in Table 2 was used. As an example of the coating process according to the prior art,
(1) The connection portion of the electric wire is covered by winding a waterproof tape. (2) The connection portion is covered with a plastic branch tube member, and both ends of the tube member are sealed with waterproof tape over 30 mm. And (3) a connection part insulated by a branched PST made of silicone rubber based on the prior art. Table 3 shows the evaluation results.

[0041]

[Table 3]

As can be seen from Table 3, the coated tube according to the present invention provides much better results in both waterproof insulation properties and airtightness as compared to the prior art waterproof tape treatment and tube member + waterproof tape treatment. Waterproof insulation properties and airtight properties equivalent to those of the conventional branched type PST made of silicone rubber were obtained. Further, with regard to the material cost, it can be manufactured at a much lower cost than the conventional branched type PST made of silicone rubber.

[0043]

As is apparent from the above description, according to the present invention, an electric wire having improved mounting workability and covering reliability by arranging a PST structure only in a seal portion near a plurality of open ends. In the covering tube of the branch connection part, the pipe element expanded by the core element at one seal part on the main electric wire side is made of a first elastic element made of an elastomer and an elastomer having a permanent elongation smaller than that of the first elastic element. Since it is formed from the second elastic element, it is possible to impart the same sealing ability as that of the branch wire side seal portion to the main wire side seal portion which is required to have more excellent permanent elongation characteristics. Therefore, according to the present invention, an inexpensive material can be used for the main part of the sheath tube including the first elastic element, so that it is possible to provide a sheath tube with a high-performance wire connection portion at low cost.

[Brief description of the drawings]

FIG. 1 is a partially cutaway front view of a coated tube according to an embodiment of the present invention.

FIG. 2 is a cross-sectional front view of the covering tube of FIG. 1 attached to the wire branch connection part, showing a state before a core element is removed.

FIG. 3 is a partially cutaway front view of the covering tube of FIG. 1 attached to the electric wire branch connection part, showing a state after a core element is removed.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Coated tube 12 ... Sleeve part 14a, 14b ... Seal part 16 ... 1st elastic element 18 ... 2nd elastic element 20, 24 ... Core element 22 ... Tube element 30, 34 ... 1st mark 32 ... 2nd mark

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Tsunehisa Nakamura 3-8-8 Minamihashimoto, Sagamihara City, Kanagawa Prefecture Sumitomo 3M Limited (72) Inventor Shingo Uchida 1-3-1 Uchisaiwaicho, Chiyoda-ku, Tokyo TEPCO (56) References JP-A-1-295614 (JP, A) JP-A-3-143217 (JP, A) JP-A-7-57798 (JP, A) JP-A 64-38773 (JP, A) U) Japanese Utility Model Hei 2-125527 (JP, U) Special Table 58-501303 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02G 15/00 H01R 4/00

Claims (3)

(57) [Claims] 1. A Y-branched tubular sleeve portion made of an electrically insulating elastomer having three open ends, and an electrically insulating tubular seal portion provided at each of the open ends of the sleeve portion. Wherein each of the seal portions is connected to the sleeve portion and a removable core element disposed radially inward of the tube element for holding the tube element in an elastically expanded state. Wherein the core element of one of the seal portions on the main wire side is larger than the core element of each of the other two seal portions on the branch wire side. A first elastic element integrally extending from the sleeve section, and a first elastic element extending between the first elastic element and the core element. And a second elastic element. But the wire branch connection portion of the covering tube, characterized in that, consisting of small elastomer having elongation than the first elastic element. 2. The permanent elongation of the first elastic element is 10% or more.
30%, and the permanent elongation of the second elastic element is 1
The coated tube of the electric wire branch connection part according to claim 1, which is less than 0%. 3. A first mark defining an axial edge of the core element is provided on an outer surface of all the seal portions, and a first mark is provided on an outer surface of the seal portion on the main electric wire side. 3. The sheath tube according to claim 1, wherein a second mark defining an axial position of the elastic element is provided. 4.