CN202818861U - Thermal-shrinkage electromagnetic shielding sheath - Google Patents

Abstract

The utility model discloses a thermal-shrinkage electromagnetic shielding sheath, comprising a thermal-shrinkage electromagnetic shielding sheath segment, a thermal-shrinkage connecting sheath segment and a thermal-shrinkage extension sheath segment, wherein the thermal-shrinkage electromagnetic shielding sheath segment and the thermal-shrinkage extension sheath segment are connected through the thermal-shrinkage connecting sheath segment; and the diameters of the thermal-shrinkage electromagnetic shielding sheath segment, the thermal-shrinkage connecting sheath segment and the thermal-shrinkage extension sheath segments are gradually increased. When in used, the thermal-shrinkage electromagnetic shielding sheath is sleeved on an object to be protected at the metal exposed part, the thermal-shrinkage extension sheath segment serving as a transition part and the thermal-shrinkage extension sheath segment are sleeved on the metal insulative part of the object to be protected together, and the thermal-shrinkage electromagnetic shielding sheath is shrunk on the object to be protected in a manner of heating; further, since the diameters of the thermal-shrinkage electromagnetic shielding sheath segment, the thermal-shrinkage connecting sheath segment and the thermal-shrinkage extension sheath segments are gradually increased, the metal exposed part and the insulative part of the object to be protected can be well jointed, so as to prevent the leakage of electromagnetic radiation at the metal exposed part of the line connecting ends and the electromagnetic interference from the external environment.

Description

A kind of pyrocondensation electromagnetic shielding sheath

Technical field

The utility model relates to the overlap between the junction of a kind of electronic circuit, communication wire circuit or end, electronic component, the sheath at shielding wire cable failure place, relates in particular to a kind of sheath shrinkable sleeve with electro-magnetic screen function.

Background technology

At present; in the junction of electronic circuit, communication wire circuit or the overlap of end, electronic component, shielding wire cable failure place etc. in order to protect exposed electric conductor, in work progress, usually twine the mask tape at exposed electric conductor place and at top layer wrap insulate adhesive tape conservation treatment.

Yet, because irregular, the operating personnel's of operating surface experience and materials is different, has caused realizing electromagnetic shielding or realized that effect is undesirable; Simultaneously because operating personnel's experience and materials different, and in work progress, vibrated, rub and collided the displacement that causes adhesive tape or peeled off, caused the protection effect reduction of insulating tape; In addition, because electromagnetic shielding and insulation protection need staged operation, reduced operating efficiency.

The utility model content

The purpose of this utility model is to provide a kind of pyrocondensation electromagnetic shielding sheath.

For achieving the above object, the utility model provides pyrocondensation electromagnetic shielding sheath to comprise that pyrocondensation electromagnetic shielding sheath segment, pyrocondensation connect sheath segment and sheath segment is extended in pyrocondensation, pyrocondensation electromagnetic shielding sheath segment is extended sheath segment with pyrocondensation and is connected the sheath segment connection by pyrocondensation, and the diameter that pyrocondensation electromagnetic shielding sheath segment, pyrocondensation connect sheath segment, pyrocondensation extension sheath segment becomes large successively.

Preferably, pyrocondensation electromagnetic shielding sheath segment comprises pyrocondensation screen and the hot melt adhesive layer that is positioned at pyrocondensation screen inboard.

Preferably, described pyrocondensation electromagnetic shielding sheath segment comprises pyrocondensation screen and pyrocondensation insulating barrier, and this pyrocondensation screen and this pyrocondensation insulating barrier from inside to outside are arranged in order.

Preferably, described pyrocondensation electromagnetic shielding sheath segment further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation screen.

Preferably, described pyrocondensation electromagnetic shielding sheath segment comprises pyrocondensation screen and pyrocondensation insulating barrier, and this pyrocondensation screen and this pyrocondensation insulating barrier are arranged in order from outside to inside.Pyrocondensation electromagnetic shielding sheath segment further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation insulating barrier.

Preferably, the hot melt adhesive layer that sheath segment includes the pyrocondensation screen and is positioned at pyrocondensation screen inboard is extended in described pyrocondensation connection sheath segment and pyrocondensation.

Preferably, described pyrocondensation connects sheath segment and pyrocondensation extension sheath segment includes pyrocondensation screen and pyrocondensation insulating barrier, and this pyrocondensation screen and this pyrocondensation insulating barrier from inside to outside are arranged in order.

Preferably, described pyrocondensation connects sheath segment and pyrocondensation extension sheath segment all further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation screen.

Preferably, described pyrocondensation connects sheath segment and the equal pyrocondensation screen of sheath segment and pyrocondensation insulating barrier are extended in pyrocondensation, and this pyrocondensation screen and this pyrocondensation insulating barrier are arranged in order from outside to inside.

Preferably, described pyrocondensation connects sheath segment and pyrocondensation extension sheath segment all further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation insulating barrier.。

As mentioned above; the utility model pyrocondensation electromagnetic shielding sheath comprises pyrocondensation electromagnetic shielding sheath segment; pyrocondensation connects sheath segment and sheath segment is extended in pyrocondensation; when using; pyrocondensation electromagnetic shielding sheath is placed on the object to be protected; wherein; pyrocondensation electromagnetic shielding sheath segment is placed in the exposed metal/bare metal place of object to be protected; pyrocondensation connects sheath segment and extends the metal-insulator place that sheath segment is placed in object to be protected as transition with pyrocondensation; then the mode by heating makes pyrocondensation electromagnetic shielding jacket shrinkage on protective; because pyrocondensation electromagnetic shielding sheath segment; pyrocondensation connects sheath segment; the diameter that sheath segment is extended in pyrocondensation becomes large successively; this can with the protection object the exposed metal/bare metal place; insulation position can be good at being connected, and prevents the leakage of exposed metal/bare metal place electromagnetic radiation and the electromagnetic interference of external environment.

Description of drawings

Fig. 1 is the axial, cross-sectional view of the embodiment 1 of the utility model pyrocondensation electromagnetic shielding sheath.

Fig. 2 is the axial, cross-sectional view of the embodiment 2 of the utility model pyrocondensation electromagnetic shielding sheath.

Fig. 3 is the axial, cross-sectional view of the embodiment 3 of the utility model pyrocondensation electromagnetic shielding sheath.

Fig. 4 is the axial, cross-sectional view of the embodiment 4 of the utility model pyrocondensation electromagnetic shielding sheath.

Fig. 5 is the axial, cross-sectional view of the embodiment 5 of the utility model pyrocondensation electromagnetic shielding sheath.

Fig. 6 is the axial, cross-sectional view of the embodiment 6 of the utility model pyrocondensation electromagnetic shielding sheath.

Each description of reference numerals is as follows among the figure:

Pyrocondensation electromagnetic shielding sheath segment 10/10 '/10 "/10 " '/10 " "/10 " " ', pyrocondensation screen 11, hot melt adhesive layer 12, pyrocondensation insulating barrier 13, pyrocondensation connects sheath segment 20, and sheath segment 30 is extended in pyrocondensation.

Embodiment

By describing technology contents of the present utility model, structural feature in detail, realized purpose and effect, below in conjunction with execution mode and cooperate that accompanying drawing is detailed to give explanation.

Embodiment 1

See also Fig. 1, the utility model pyrocondensation electromagnetic shielding sheath comprises that pyrocondensation electromagnetic shielding sheath segment 10, pyrocondensation connect sheath segment 20 and sheath segment 30 is extended in pyrocondensation, pyrocondensation electromagnetic shielding sheath segment 10 is extended sheath segment 30 with pyrocondensation and is connected sheath segment 20 connections by pyrocondensation, and the diameter that pyrocondensation electromagnetic shielding sheath segment 10, pyrocondensation connect sheath segment 20, pyrocondensation extension sheath segment 30 becomes large successively.

The utility model pyrocondensation electromagnetic shielding sheath is when using; pyrocondensation electromagnetic shielding sheath is placed on the object (not shown) to be protected; wherein; pyrocondensation electromagnetic shielding sheath segment 10 is placed in the exposed metal/bare metal place of object to be protected; pyrocondensation connects sheath segment 20 and extends the metal-insulator place that sheath segment 30 is placed in object to be protected as transition with pyrocondensation; then the mode by heating makes pyrocondensation electromagnetic shielding jacket shrinkage on protective; because pyrocondensation electromagnetic shielding sheath segment 10; pyrocondensation connects sheath segment 20; the diameter that sheath segment 30 is extended in pyrocondensation becomes large successively; this can with the protection object the exposed metal/bare metal place; insulation position can be good at being connected, and prevents the leakage of exposed metal/bare metal place electromagnetic radiation and the electromagnetic interference of external environment.

Here the device such as the overlap between said " object to be protected " junction that can be electronic circuit, communication wire circuit or end, electronic component, shielding wire cable failure place need to carry out the positions such as electromagnetic shielding, is specially adapted to the end of parts.

Embodiment 2

See also Fig. 2, it has disclosed the embodiment 2 of the utility model pyrocondensation electromagnetic shielding sheath, and present embodiment is similar to Example 1, and pyrocondensation electromagnetic shielding sheath segment 10 ' comprises pyrocondensation screen 11 ' and is positioned at the hot melt adhesive layer 12 of pyrocondensation screen 11 inboards.Hot melt adhesive layer 12 ' conveniently is adhered on the object to be protected.

Embodiment 3

See also Fig. 3, it has disclosed the embodiment 3 of the utility model pyrocondensation electromagnetic shielding sheath, present embodiment is similar to Example 1, its difference is: pyrocondensation electromagnetic shielding sheath segment 10 " comprise pyrocondensation screen 11 and pyrocondensation insulating barrier 13, this pyrocondensation screen 11 and this pyrocondensation insulating barrier 13 from inside to outside are arranged in order.

Embodiment 4

See also Fig. 4, it has disclosed the embodiment 4 of the utility model pyrocondensation electromagnetic shielding sheath, present embodiment is similar to Example 3, and its difference is: pyrocondensation electromagnetic shielding sheath segment 10 " ' comprise that further hot melt adhesive layer 12, hot melt adhesive layer 12 are positioned at pyrocondensation screen 11 inboards.

Embodiment 5

See also Fig. 5, it has disclosed the embodiment 3 of the utility model pyrocondensation electromagnetic shielding sheath, present embodiment is similar to Example 1, its difference is: pyrocondensation electromagnetic shielding sheath segment 10 " " comprise pyrocondensation screen 11 and pyrocondensation insulating barrier 13, this pyrocondensation screen 11 and this pyrocondensation insulating barrier 13 are arranged in order from outside to inside.

Embodiment 6

See also Fig. 6, it has disclosed the embodiment 4 of the utility model pyrocondensation electromagnetic shielding sheath, present embodiment is similar to Example 5, and its difference is: pyrocondensation electromagnetic shielding sheath segment 10 " " ' comprise that further hot melt adhesive layer 12, hot melt adhesive layer 12 are positioned at pyrocondensation insulating barrier 13 inboards.

1 to embodiment 6 pair of pyrocondensation shield sheath section 10/10 '/10 of above-described embodiment "/10 " '/10 " "/10 " " ' structure be illustrated, yet for pyrocondensation connect sheath segment 20 and pyrocondensation extend sheath segment 30 also all can adopt be similar to pyrocondensation shield sheath section 10/10 '/10 "/10 " '/10 " "/10 " " ' structure, for example pyrocondensation connects sheath segment 20 and pyrocondensation and extends the hot melt adhesive layer 12 that the structure of sheath segment 30 includes pyrocondensation screen 11 and is positioned at pyrocondensation screen 11 inboards.

Certainly, pyrocondensation connects sheath segment 20 and pyrocondensation extension sheath segment 30 also can include pyrocondensation screen 11 and pyrocondensation insulating barrier 13, and pyrocondensation screen 11 and pyrocondensation insulating barrier 13 from inside to outside are arranged in order.Pyrocondensation connects sheath segment 20 and pyrocondensation extension sheath segment 30 all can further comprise hot melt adhesive layer 12, and hot melt adhesive layer 12 is positioned at pyrocondensation screen 11 inboards.Pyrocondensation screen 11 and pyrocondensation insulating barrier 13 can also be arranged in order from outside to inside, and hot melt adhesive layer 12 is positioned at pyrocondensation insulating barrier 13 inboards.

The utility model is not limited to above-mentioned embodiment, and those skilled in the art that also can make multiple variation accordingly, but any and the utility model are equal to or similar variation all should be encompassed in the scope of the utility model claim.

Claims (11)

1. pyrocondensation electromagnetic shielding sheath, it is characterized in that: comprise that pyrocondensation electromagnetic shielding sheath segment, pyrocondensation connect sheath segment and sheath segment is extended in pyrocondensation, described pyrocondensation electromagnetic shielding sheath segment is extended sheath segment with described pyrocondensation and is connected the sheath segment connection by pyrocondensation, and the diameter that described pyrocondensation electromagnetic shielding sheath segment, pyrocondensation connect sheath segment, pyrocondensation extension sheath segment becomes large successively.

2. pyrocondensation electromagnetic shielding sheath according to claim 1 is characterized in that: described pyrocondensation electromagnetic shielding sheath segment comprises the pyrocondensation screen and is positioned at the hot melt adhesive layer of pyrocondensation screen inboard.

3. pyrocondensation electromagnetic shielding sheath according to claim 1, it is characterized in that: described pyrocondensation electromagnetic shielding sheath segment comprises pyrocondensation screen and pyrocondensation insulating barrier, this pyrocondensation screen and this pyrocondensation insulating barrier from inside to outside are arranged in order.

4. pyrocondensation electromagnetic shielding sheath according to claim 3, it is characterized in that: described pyrocondensation electromagnetic shielding sheath segment further comprises hot melt adhesive layer, it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation screen.

5. pyrocondensation electromagnetic shielding sheath according to claim 1, it is characterized in that: described pyrocondensation electromagnetic shielding sheath segment comprises pyrocondensation screen and pyrocondensation insulating barrier, this pyrocondensation screen and this pyrocondensation insulating barrier are arranged in order from outside to inside.

6. pyrocondensation electromagnetic shielding sheath according to claim 5, it is characterized in that: described pyrocondensation electromagnetic shielding sheath segment further comprises hot melt adhesive layer, it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation insulating barrier.

7. according to claim 1,2,3,4,5 or 6 described pyrocondensation electromagnetic shielding sheaths, it is characterized in that: described pyrocondensation connects sheath segment and the hot melt adhesive layer that sheath segment includes the pyrocondensation screen and is positioned at pyrocondensation screen inboard is extended in pyrocondensation.

8. according to claim 1,2,3,4,5 or 6 described pyrocondensation electromagnetic shielding sheaths, it is characterized in that: described pyrocondensation connects sheath segment and pyrocondensation extension sheath segment includes pyrocondensation screen and pyrocondensation insulating barrier, and this pyrocondensation screen and this pyrocondensation insulating barrier from inside to outside are arranged in order.

9. pyrocondensation electromagnetic shielding sheath according to claim 8 is characterized in that: described pyrocondensation connects sheath segment and pyrocondensation extends sheath segment and all further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation screen.

10. according to claim 1,2,3,4,5 or 6 described pyrocondensation electromagnetic shielding sheaths, it is characterized in that: described pyrocondensation connects sheath segment and the equal pyrocondensation screen of sheath segment and pyrocondensation insulating barrier are extended in pyrocondensation, and this pyrocondensation screen and this pyrocondensation insulating barrier are arranged in order from outside to inside.

11. pyrocondensation electromagnetic shielding sheath according to claim 10 is characterized in that: described pyrocondensation connects sheath segment and pyrocondensation extension sheath segment all further comprises hot melt adhesive layer, and it is inboard that described hot melt adhesive layer is positioned at described pyrocondensation insulating barrier.

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