CZ306452B6 - A communication cable insulated with foamed silicone rubber - Google Patents

Abstract

The communication cable insulated with foamed silicone rubber is particularly useful in the electronics industry, especially where there are increased requirements for maximum operating capacity while maintaining the fire safety and equipment functionality. The communication cable consists of the elements (3) formed by twisting the cores consisting of the conductive copper core (1), or the tinned copper core (1), insulated with the continuous insulation layer (2) made of the foamed silicone rubber (2). The elements (3) of the cable are twisted into the cable core (4) which is wrapped with the tapes (5) serving as cable shielding. Over the tapes (5), there is the continuous layer (6) of the extruded mixture and the cable sheath (7). In a convenient version, the layer (6) of the extruded mixture and/or the cable sheath (7) are made from halogen-free flame retardant materials. The communication cable reaches operational capacity of C.sub.P.n. < 49 nF/km.

Description

Communication cable with foamed silicone rubber insulation

Field of technology

The invention relates to a communication cable with foamed silicone rubber insulation and is particularly useful in the electrical industry, especially where there are increased requirements for maximum operating capacity while maintaining fire safety and equipment functionality.

Prior art

In recent years, emphasis has been placed on the development of halogen-free fire retardant (HFFR) energy cables with the functionality of insulation and the functionality of the entire cable system. This development took place across all cable companies in the Czech Republic (hereinafter referred to as the Czech Republic) and was based on the requirements of both domestic and foreign demand.

Requirements for the development of HFFR external communication cables paired and quadrupled with functional capabilities have long been neglected in the Czech Republic. Traditional manufacturers of telephone cables PRAKAB PRAŽSKÁ KABELOVNA, s.r.o. and KABELOVNA Děčín Podmokly, s.r.o. are currently able to offer HFFR external communication cables paired and quadrupled only in the version without functional capability.

PRAKAB has in its production program of external communication HFFR cables only cables in the design without functional capability (TCEKH-R, TCEKFLHZH-R). Solid polyethylene (hereinafter referred to as PE) is used to insulate these cables, which has good transmission properties (low dielectric constant ε _Γ «2.1). In general, the lower this dielectric constant and the greater the symmetry of the pair or quadruple, the lower the operating capacity of the core of each pair, respectively. four and the better the electrical signal transmission. The dielectric constant can be reduced to ε _Γ * 1.7 due to the use of foamed PE.

PE itself generally has very poor behavior in the event of a fire. It has no fire retarding effects, rather it spreads fire. This is its major disadvantage, which prevents the use of PE as insulation for cables with functional insulation during a fire.

In the case of paired communication cables, where there are no such high requirements for the transmission of an electrical signal with functional capability (eg SXKFH-V180), a combination of cross-linked PE (XLPE) and glass-mica tape is used to insulate the core. XLPE has better mechanical and electrical properties than PE, but also does not contain any flame retardants that would prevent the spread of fire. Cables with only XLPE insulation cannot carry the signal during a fire. In the case of this cable, it is the glass-mica tape that serves as insulation in the event of a fire. This tape contains small layers of mica which, due to the high temperature, saliva and thus form a glass tube around the copper core, which prevents a short circuit between the veins even at high temperature.

In the case of the use of glass-mica tape ensuring the functional capability of the cable, this is a conventional technology. At present, however, a new technology is used, which consists in the use of silicone rubber insulation, which in the event of an accident-fire ceramises and ensures the functionality of the cable (transmission of electricity or information).

In addition to good workmanship, silicone rubber for insulating energy safety cables also shows good behavior in the event of a fire. Its great negative for use as insulation of paired and quadrupled communication cables is its high dielectric constant e _r «4.5, which has a fundamental influence on the value of operating capacity, which is an important transmission parameter. At first glance, this handicap eliminates silicone from the game.

-1 CZ 306452 B6

The prior art is described in the following documents:

GB 1 414 486 A (BICC LTD), 19.11.1975

On page 2, lines 54 to 62, there is a reference to the manufacturer and type of foamed silicone rubber. There is no connection with communication cables made of foamed silicone rubber and with fire-resistant halogen-free cables with the functionality of the cable system.

JP 2000243152 A (HITACHI CABLE), 08/09/2000

According to paragraph, it is a single core cable intended for medium (MV) and high voltage (HV) with layered insulation with Al or Cu core, core type RE (solid wire) or RM (braided core of multiple wires).

According to paragraphs [0010] and [0011], it is a fire-resistant cable, which, however, may contain halogen insulating wrappers, see vinyl chloride or insulating wrappers made of polyethylene, polypropylene, which are not fire retardant per se.

According to paragraph, fire resistance is achieved using an older technological process, where the conductive core is longitudinally wrapped or braided with a mineral refractory tape, the main component of which is mica and a silicone binder.

US 2012/0 000 690 A1 (GEN CABLE TECHNOLOGIES CORP [US]; VAN DER MEER HARRY [US]), 05.01.2012

According to paragraphs [0019] - [0021], [0027], [0033] it is a data cable with water-blocking materials. These materials protect the cable / cable core against water penetrating the cable. If water enters the cable, the transmission parameters could deteriorate. The term referred to in paragraph "foam" is a general term that is related to the element 104 in Fig. 1. As shown and describes the "foam" located above the conductor / core 102.

There is no mention in said patent application of fire-resistant and halogen-free cables with the functionality of a cable system.

Paragraph [0043] lists possible types of materials 102 structurally located above the conductor / core 102 (covering the conductors 102). From the total list of possible types, the material is silicone and silicone tape.

GB 1 486 355 A (SCHWEIZERISCHE ISOLAWERKE), 21.09. 1977

According to claim 1, page 3, lines 25 to 44, a conductor / core of the type and material mentioned on page 3, lines 25 to 29 is wrapped at least twice with tape. It is a laminated tape, where one layer is formed by a glass-mica layer (mica paper) and the other layer by fibers heat-resistant up to 300 ° C. The binder between these layers is a silicone layer.

The following is a glass-mica tape, page 2, as a conventional technology used to ensure the functionality of the cable.

The essence of the invention

The essence of the invention lies in the use of insulation made of foamed silicone rubber. Due to the presence of air bubbles in the insulation of the foamed silicone, the dielectric constant can be significantly reduced to almost half the value of the non-foamed (full) silicone insulation used for power cables.

-2EN 306452 B6

The halogen-free external communication cable with the functional capability of the entire cable system consists of a conductive copper or tinned copper core or possibly a silver core, insulated with continuous insulation of foamed silicone rubber. Insulated veins are twisted into pairs, consisting of two cores, or into so-called "fours", composed of four cores. Couples, resp. the fours are wound into a cable core, which is wrapped with tapes performing the function of shielding the cable. Above the tapes is a continuous extruded filler mixture and the outer sheath of the cable.

The filling mixture and the sheath of the cable are made of halogen-free fire-retardant materials so that the cable itself as a whole further meets the reaction to fire class B2ca sldO according to the European Directive 2006/751 / EC. Thanks to the use of insulation made of foamed silicone rubber with a permittivity ε _Γ <2.5, the cable also achieves the operating capacity of the finished cable C _P <49 nF / km and meets the transmission category CAT 3 according to the ANSI-TIA-EIA 568 standard.

Explanation of terms:

Internal communication cables - these are cables intended for buildings, which are used for distribution of information and security systems with a bandwidth up to 16 MHz. In most cases, these are cables where the basic element is the cores twisted into a pair.

External communication cables - used to create long-distance data and communication transmissions. The basic element of these cables are cores twisted into pairs or into fours.

Relative permittivity - a physical quantity describing the insulating properties of insulating materials in relation to vacuum.

Operating capacity - this is the electrical capacity between adjacent cores in pairs or fours. Electrical capacity expresses the ability of a conductor to store an electric charge. In the case of communication cables, the lower the operating capacity, the better the electrical signal transmission.

HFFR cables without functional capability - these are halogen-free fire retardant cables meeting the following properties in case of fire:

- does not spread flame,

- the gases released during combustion are non-toxic and non-corrosive,

- have low smoke emissions.

HFFR cables with functional capability - cables which, in addition to the properties of HFFR cables without functional capability, in addition to fire conditions, are able to conduct electric current in the case of power cables or transmit electrical signals and information in the case of communication cables.

These cables are tested according to the ČSN IEC 60331 standard, in which one sample of the cable connected to the nominal voltage is tested and in which the cable is thermally stressed at a constant temperature.

HFFR cable with the functionality of the entire cable system - this is another superstructure in terms of higher demands on the functionality of the cable in the event of a fire.

In addition, the cables are tested according to the test regulation ZP 27/2008, resp. standards STN 92 0205 or DIN VDE 4102-12.

During the test, the entire cable system is tested, ie. cables and cable support structures. The test result thus depends not only on the properties of the cables, but also on the resistance of all elements used in the actual cable installation.

The test is performed in a chamber in which the cables are tested on supporting systems (cable trays, ladders, individual clamps). During the test, the cables are connected to the rated voltage

-3 CZ 306452 B6 and together with the load-bearing systems are exposed to increasing thermal loads, which cause deformation of the load-bearing systems.

The test is very demanding and approaches the real conditions in case of fire. This is the most demanding fire safety test, which is performed on cables together with load-bearing systems.

Fire reaction class - the cable in case of fire releases a small amount of heat and smoke according to European Directive 2006/751 / EC.

Explanation of drawings

Figure 1 is a side view and cross-section of a paired communication cable.

Figure 2 is a side view and cross-section of a four-way communication cable.

Examples of embodiments of the invention

Example 1

The paired communication cable in Fig. 1 consists of elements 3 formed by twisting two cores consisting of a conductive copper core 1 insulated by a continuous insulation 2 of foamed silicone rubber. The elements 3 of the cable are wound into a cable core 4, which is wrapped with tapes 5 performing the function of shielding the cable. Above the strips 5 is a layer 6 of a continuous extruded mixture and a cable sheath 7.

Example 2

The communication cable quadrupled in Fig. 2 is composed of elements 3 formed by twisting four cores consisting of a conductive tinned copper core 1 insulated by a continuous insulation 2 of foamed silicone rubber. The elements 3 of the cable are wound into a cable core 4, which is wrapped with tapes 5 performing the function of shielding the cable. Above the strips 5 is a continuous layer 6 of extruded mixture and a cable sheath 7.

Industrial applicability

The invention is industrially applicable in the electrical engineering industry.

Claims (6)

PATENT CLAIMS A communication cable comprising at least one element (3) formed by twisting at least two cores of conductive copper core (1) and insulated by continuous insulation (2), wherein the cable element / elements (3) are twisted into a cable core (4) which is wrapped with tapes (5) fulfilling the function of cable shielding, characterized in that the insulation (2) of the core (1) is made of foamed silicone rubber and above the tapes (5) is a continuous layer (6) of extruded mixture and cable sheath (7). Communication cable according to Claim 1, characterized in that the foamed silicone rubber insulation (2) has a permittivity ε _Γ <2.5. -4CZ 306452 B6 Communication cable according to Claim 1 or 2, characterized in that the cable has an operating capacity C _P <49 nF / km. Communication cable according to one of Claims 1 to 3, characterized in that the layer (6) of extruded mixture and / or the cable sheath (7) are made of halogen-free fire-retardant materials. Communication cable according to one of Claims 1 to 4, characterized in that the copper core (1) is tinned. 6. Use of foamed silicone rubber to insulate (2) the conductive core (1) of the communication cable.