RU192224U1 - Explosion-proof magnetic cable security detector - Google Patents

Abstract

The detector is a magnetically contact explosion-proof security cable belongs to the field of security alarm and is intended to supply an electrical alarm in fire alarm systems and can be used to control the position of moving parts of structures and mechanisms when performing various technological processes in hazardous areas of classes 0.1 and 2 according to GOST IEC IEC 60079-10-1-2011. In the detector, magnetically contact explosion-proof cable, containing a non-magnetic case in the form of a parallelepiped, with which the cable is fastened, a reed switch is located inside the case, parallel to its side wall, the cable cores are electrically connected to the reed leads, the cavity of the case is filled with a compound, and the case is equipped with fixing holes for installing it on one of the elements of the controlled object in the area of the magnet installed on another element of the controlled object, the reed switch is placed on the board parallel to plane, the board is equipped with two thermal fuses, connected in series with the reed switch, and elements for fixing its position in the body cavity, made in the form of elastic rings placed tightly in the grooves of the board, the mounting holes of the case are made in the form of hollow rivets fastening the cover and the bottom of the case, with reinforcement elements made of non-magnetic material are fastened with the inner surface of the cover, and the cable is additionally fixed in the cable entry, fastened to the housing, which together with the compound provides strength cable fastening in the housing exceeding the fivefold value of the body weight. Also, the insulation between non-galvanically connected electrical circuits inside the housing and between them and the housing is made reinforced. In addition, a second reed switch and two additional thermal guards are placed on the board, connected in series to the cable cores and separated from the first reed switch by a magnetic screen, and the board is made of two parts. The technical result of the improvement of the detector of a cable security magnetically contact explosion-proof is to increase the length of its cable and expand the range of cables used and how to lay them while maintaining the level of protection. 3 s.p. formulas, 2 ill.

Description

The inventive cable detector magnetically contact explosion-proof belongs to the field of burglar alarm and is intended to supply an electrical alarm in fire alarm systems and can be used to control the position of moving parts of structures and mechanisms when performing various technological processes in hazardous areas 0.1 and 2 classes according to GOST IEC IEC 60079-10-1-2011.

Known detector cable security magnetocontact two-unit, containing a unit with a reed switch, mounted on one of the elements of the monitored object in the area of the magnet, placed in another block mounted on another element of the monitored object, the housing of the unit with the reed switch is made with a permanently connected cable and has holes for mounting it at the facility of operation (Security magnetic point contact detector ИО 102-16 / 2 http://www.rmcip.ru/files/catalogue/io_102_16_2.pdf ")

A disadvantage of the known magnetic security contact detector is the impossibility of using it in hazardous areas due to the mismatch of its characteristics with the requirements for explosion-proof devices for cable fastening strength, housing strength and insulation resistance. The detector is also not protected from sabotage actions in the form of blocking the state of the reed switch by an external magnet.

Known detector cable security magnetocontact two-unit, containing a unit with a reed switch, mounted on one of the elements of the monitored object in the area of the magnet, placed in another block mounted on another element of the monitored object, The tubular housing of the block with the reed switch contains a reed switch located along the axis of the housing and connected with cable conductors through a printed circuit board, and the cable is fixed in a cable entry located at the end of the housing. Placement of the reed switch on the printed circuit board is made console. The internal space of the case is flooded with a compound before installing and tightening the cable entry without visual inspection and may contain voids. One of the cable cores is electrically connected to the internal ledge of the housing through the current path of the board and forms the internal grounding of the detector. (DETECTORS SECURITY POINT MAGNETIC CONTACT IO102-A "Aton", IO102-N "Aton" TU 43 72-127-8188893 5-2015 Operation manual. Passport. Https://smd-tlt.ru/image/db/files/ Pasp / Pasp_Aton-AN-Pr.pdf).

A disadvantage of the known magnetic security contact detector is the impossibility of using it in hazardous areas due to the mismatch of its characteristics with the requirements for explosion-proof devices: due to the lack of devices and measures to prevent possible overheating of the detector housing, and the absence of elements fixing the position of its conductive parts before filling the case with compound , which can lead to their displacement and violation of the normalized clearances and creepage distances for explosion-proof devices. Performing an internal ledge to organize the internal grounding of the detector coupled with an additional residential cable increases its cost, placing the reed switch coaxially to the housing reduces the sensitivity of the detector and requires the use of more powerful magnets. The detector is also not protected from sabotage actions in the form of blocking the state of the reed switch by an external magnet.

The closest in purpose, technical nature and the achieved result to the claimed detector is a magnetic security contact explosion-proof detector containing a non-magnetic case in the form of a parallelepiped with which the cable is fastened, a reed switch is located inside the case, parallel to its side wall, the cable conductors are electrically connected to the reed switch leads, and the cavity of the body is filled with a compound, the body is equipped with holes for mounting it on one of the elements of the controlled object in the area of the magnet, placed in another enclosure installed on another element of the controlled object. The strength of fastening the cable to the housing is ensured by the adhesion of the compound to the cable sheath. The detector is designed as an intrinsically safe circuit according to GOST R IEC 60079-11-2011 and is connected to the alarm system through an additional spark protection barrier and an additional junction box, and the cable is shielded with normalized values of its capacitance and inductance, and of limited length. (DETECTORS SECURITY POINT MAGNETIC CONTACT EXPLOSION-PROTECTED IO102-VZ "Aton" TU 4372-127-81888935-2015 Operation manual. Passport https://smd-tlt.ru/image/db/files/Pasp/Pasp_Adf-VZ-Vton-VZ.V.

A disadvantage of the known detector of a cable security magnetically contact explosion-proof is the high demands on the device for its connection to the facility’s alarm system, normalized by section 16 of GOST IEC 60079-14-2013 and GOST R IEC 60079-25-2012, which require the connection of intrinsically safe equipment through an intrinsically safe barrier, which limits the energy supplied to the detector and, accordingly, its overheating. The detector must be connected to the spark protection barrier, which is usually located outside the hazardous area, with shielded, grounded cables, inductance and capacitance, and accordingly the length and nomenclature, which are limited by the parameters of the intrinsically safe circuit, which generally makes the facility's alarm system more expensive. In addition, the detector design allows only open and unprotected laying of its cable at the facility, which does not allow the use of other effective types of laying allowed by GOST IEC 60079-14-2013 to protect the cable from external influences and fields, in particular cable laying in pipes and metal hoses. The detector is also not protected from sabotage actions in the form of blocking the state of the reed switch by an external magnet.

The problem solved by the magnetic security contact explosion-proof detector declared as a utility model is to reduce the cost of connecting it to the alarm system of the monitoring object.

The technical result of the improvement of the detector of a cable security magnetically contact explosion-proof is to increase the length of its cable and expand the range of cables used and how to lay them while maintaining the level of protection.

The specified technical result is achieved by the fact that in the detector is a magnetic magnetically contact explosion-proof security cable containing a non-magnetic case in the form of a parallelepiped with which the cable is fastened, a reed switch is located inside the case, parallel to its side wall, the cable conductors are electrically connected to the reed leads, the cavity of the case is filled with a compound, and the housing is equipped with mounting holes for mounting it on one of the elements of the controlled object in the area of the magnet installed on another element of the control object, the reed switch is placed on the board parallel to its plane, the board is equipped with two thermal fuses, connected in series with the reed switch, and elements for fixing its position in the body cavity, made in the form of elastic rings placed with an interference fit in the board grooves, the housing mounting holes are made in the form of hollow rivets fastening the cover and the bottom of the case, reinforcement elements of non-magnetic material are fastened to the inner surface of the cover, and the cable is additionally fixed in the cable entry, fastened to the case, otorrhea together with compound provides fixing strength of the cable in the housing exceeding the fivefold value of the body weight. Also, the insulation between non-galvanically connected electrical circuits inside the housing and between them and the housing is made reinforced. In addition, a second reed switch and two additional thermal guards are placed on the board, connected in series to the cable cores and separated from the first reed switch by a magnetic screen, and the board is made of two parts.

Providing the detector with two thermal fuses that are electrically connected in series with the first reed switch to the cores of the alarm cable allows fulfilling the requirement of explosion protection equipment with the type and level of protection "mb" in accordance with Clause 7.9.3 of GOST 31610.18-2016 / IEC 60079-18: 2014 with regard to its protection against possible overheating. Placing the reed switch on the board parallel to its plane allows it to be fixedly fixed at two spaced points and to reliably maintain this position with guaranteed gaps between other live parts during the compound filling process. The supply of the board with the elements of its fixation in the housing cavity before it is filled with a compound allows fulfilling the requirements of clause 7.2.4.2 of GOST 31610.18-2016 / IEC 60079-18: 2014 on the immutability of the normalized distances between current-carrying parts of the detector before and after filling with a compound. The implementation of the elements for fixing the position of the board in the cavity of the case in the form of elastic rings placed with an interference fit in the grooves of the board allows organizing this detector assembly required by the standard with the least cost and adjusting the sensitivity of the detector before filling the compound. Providing the detector housing with an additional cable entry (not necessarily expensive explosion-proof), which together with the compound ensures the fastening of the cable in the housing by a factor exceeding five times the weight of the housing, it allows fulfilling the requirements of clause 8.2.5 of GOST 31610.18-2016 / IEC 60079-18: 2014 for fixing cables of devices with the type of protection “sealing by compound”, expand the range of cable sheaths with different friction coefficients, reduce the requirements for the compound by adhesive indicators, and also expand the number of possible types of cable laying at a specific facility according to the requirements of GOST IEC 60079-14-2013, in particular laying in pipes and metal hoses, through the use of different cable entry designs. All of the above allows you to use the proposed detector with an explosion protection level of "mb" in hazardous areas of classes 1 and 2 according to GOST IEC IEC 60079-10-1-2011 with a type of explosion protection, without normalizing the capacitance and inductance of the connecting cable section, and thereby expand the range brands of cables used and not to limit their length, as well as methods of laying them for a particular object. The implementation of mounting holes in the form of hollow rivets passing through the body of the reed switch, in addition to reducing the detector’s dimensions, makes it possible to organize the filling of the detector’s body with the least cost and pre-checking it for voids and delamination, as well as fastening the lid to the bottom of the detector’s body, which together with reinforcement elements made of non-magnetic material pre-bonded to the inner surface of the lid, allows you to securely fasten the lid and protect the surface of the compound from air ystviya explosive atmosphere and moisture, thus fulfill the requirements given. 7.1 Standard IEC IEC 60079-10-1-2011 in part undesired presence in the detector sensitive nonmetallic membranes. The execution of the cable with double insulation, coupled with the insulation between unconnected galvanically connected electrical circuits inside the housing and between them and the housing reinforced, allows not to supply the housing of the explosion-proof detector with internal and external grounding studs in accordance with the requirements of clause 15.2 GOST 31610.0-2014 (IEC 60079 -0: 2011) and thereby reduce the cost of the detector and expand the range of cables used by the number of cores. Placement of a second reed switch and two additional thermal fuses on the board, connected in series to the cable cores and separated from the first (standard) reed switch by a magnetic screen, which eliminates the effect of the detector magnet on the second reed switch, can increase the detector's information content during sabotage actions in the form of blocking the signal of the first (regular) reed switch on the field of an external sabotage magnet, having fulfilled the requirements of clause 4.1.1.7 of GOST R 52435-2015 to the detector in the part "to provide automatic control of environmental parameters environment affecting the detection parameters ”and allow the use of the detector already in class 3 according to GOST R 52435-2015. The implementation of the circuit board in two parts, on each part of which there is a reed switch and thermal fuses, makes it structurally easier to use the internal space of the detector housing and the separation of the circuit board parts with a magnetic screen, which reduces the dimensions of the detector, and also makes it easier to make factory adjustments and settings.

An example implementation of the inventive detector is illustrated by drawings. In FIG. 1 shows a general view of the detector with cuts. In FIG. 2 is a view A of FIG. 1 The detector cable security magnetically contact explosion-proof contains a non-magnetic housing 1, for example, in the form of a rectangular stainless pipe, with the ends of which through its hollow rivets 2 sec fasten its bottom 3 and cover 4, forming a parallelepiped. A cable entry 5 is placed on the side of the housing 1, for example, non-explosion-proof cable entries of the ZETA plant, which have modifications for various cable routing, in particular in a metal sleeve, with cable 6 inserted into it, which has double insulation, and cable 6 is flexible stranded with a rubber or polyvinyl chloride sheath and has flame propagation characteristics that allow it to withstand tests in accordance with IEC 60332-1-2 or IEC 60332-2-27, which ensures its use in hazardous areas GOST IEC 60079-14-2013. Inside the housing 1, the first printed circuit board 7 is placed, on which the first (standard) normally open reed switch 8 and two thermal fuses 9 are located, connected in series and connected to the cores 10 of cable 6, each of which is additionally enclosed in a dielectric sheath (not shown) that provides cable 6 double insulation. The board 7 has at its ends grooves 11 in which an elastic seal 12 is installed with an interference fit, made, for example, in the form of a round rubber ring. The dimensions of the board 7 with grooves 11 and the diameter of the elastic seal 12 are selected so that the board 7 enters into the internal cavity of the housing 1 with an interference fit and is fixed there due to the friction force of the elastic seal 12 with the inner wall of the housing 1. Inside the housing 1, a second circuit 13 is placed on which has a second normally-closed reed switch 14 with two thermal fuses 15 connected in series to the other cores 10 of cable 6. Board 13 has grooves in which an elastic seal is placed., similar to grooves 11 and seal 12 on board 7 (on tezhe not shown). The second reed switch 14 with the card 13 is placed in the inner cavity of the housing 1, as far as possible from the first reed switch 8. The boards 7 and 13 are separated in the cavity of the housing 1 by a magnetic screen 16 made, for example, of low-carbon steel or permalloy, in the body of which holes are made (on not shown) for the passage of insulated cores 10 of cable 6 to the board 7. The distances between the current-carrying conductors of the boards 7 and 13. as well as the distances between them and the housing 1 and the cable entry 5 are equal to or greater than the distances required by GOST 31610.18-2016 / IEC 60079-18: 2014, and ensure ivayut when filling the internal cavity 17 of the housing 1 compound reinforced insulation between galvanically not connected circuits within the housing and between the housing and whose value depends on the supply voltage through the cable 6 and the temperature-humidity detector operating mode. The cable 6 is held in the housing 1 due to the adhesion (adhesion) of its sheath to the compound 17, which completely fills the housing 1, and the friction force created by the elastic seal 18 of the cable entry 5, which are selected so that the pulling force of the cable 6 from the housing 1 is not less than five times the weight of the housing 1 with the components inside it. On the inner surface of the lid 4 are reinforced, for example, by welding, elements of reinforcement 19 made, for example, of bent wires of non-magnetic stainless steel, which are immersed in compound 17 and form an additional fastening of the edges of the lid 4 to the housing 1. The housing 1 is fastened through holes 2, for example , non-magnetic screws (not shown), on the fixed element 20 of the control object, for example, the doorway. On another movable element 21 of the control object, for example, a door leaf, a magnet 22 is mounted placed in its non-magnetic case 23, for example, with screws (not shown in the drawing). To illustrate the operation of the detector, the sabotage external magnet 24 is shown in the drawing. The detector is assembled as follows: one of the ends of the hollow rivets 2 is riveted or tacked to the bottom 3 of the housing 1, then the bottom 3 is tacked or welded to the end of the housing 1 by welding, forming an integral connection between them. Additionally, the joints between the end of the housing 1 and the bottom 3 can be coated with sealant (not shown in the drawing). Insert the board 7 with the elastic seal 12 already installed in the slots 11 into the internal cavity of the housing 1 with elastic deformation of the seal 12 and install it so that the first normally open reed switch 8 is as close as possible to the side wall of the housing 1 facing the magnet 22, the second board 13 is installed in the same way, but so that the second normally-closed reed switch 14 is as far from the magnet 22 as possible. Between the boards 7 and 13 are installed and fixed, for example, with glue, a magnetic shield 16 and thermally protected reed switches are electrically connected using wires 10 of cable 6. I check the detector’s operability so that when magnet 22 is mounted close to housing 1, the first reed switch 8 is triggered and the second reed switch 14 does not work, and the second reed switch 14 is triggered when the sabotage magnet 24 is brought up to the housing 1, adjust if necessary by moving the boards 7 and 13 in the cavity of the housing 1. Check the insulation resistance between the electrical circuits of the first reed switch 8 and the second reed switch 14, as well as between them and the housing 1, fill the cavity of the housing 1 from the side of the cover 4 with compound 17, on Example by Wixint, visually check the quality of the fill and install the cover 4 with reinforcing elements 19 onto the rivets 2 and rivet the latter from the side of the cover 4 and press the cover 4 with an external load (not shown in the drawing) until the compound 17 solidifies.

The detector operates as follows. With a small distance between the buildings 1 and 23 (closed door), the magnet field 22 activates the first reed switch 8, translating it into a closed state. This is recorded by the control panel (not shown in the drawing) connected to cable 6. When the door is opened unauthorized, magnet 22 is removed from the first reed switch 8, which goes into its normally open state and the control panel generates an Alarm signal. When the intruder brings the sabotage magnet 24 to the housing 1 in order to maintain the closed state of the first reed switch 8 while removing the standard magnet 22 (opening the door), the second reed switch 14 switches from closed to open state and the control panel generates a “Sabotage” or “Alarm when series-connected electrical circuits of the first reed switch 8 and the second reed switch 14.

Claims (4)

1. The detector is a magnetically contact explosion-proof security cable containing a non-magnetic case in the form of a parallelepiped with which the cable is fastened, a reed switch is located inside the case, a reed switch is parallel to its side wall, the cable conductors are electrically connected to the reed leads and the case cavity is filled with a compound, the case is equipped with fixing holes for installing it on one of the elements of the controlled object in the area of the magnet installed on another element of the controlled object, characterized in that the reed switch is placed on the board parallel to its plane, the board is equipped with two thermal fuses connected in series with the reed switch, and elements for fixing its position in the body cavity, made in the form of elastic rings placed with interference in the grooves of the board, the mounting holes of the case are made in the form of hollow rivets fastening the cover and bottom case, reinforcement elements made of non-magnetic material are fastened to the inner surface of the lid, the cable is additionally fixed in the cable entry, fastened to the case, which together with the compound are both sintering the cable fastening strength in the housing in excess of five times the weight of the housing. 2. The detector is a magnetically contact explosion-proof security cable according to claim 1, characterized in that the cable has double insulation, and the insulation between the galvanically unconnected electrical circuits inside the housing and between them and the housing is made reinforced. 3. The detector is a cable security magnetically contact explosion-proof according to claim 1, characterized in that the circuit board has a second reed switch and two additional thermal arrester connected in series to the cable cores and separated from the first reed switch by a magnetic screen. 4. The detector is a cable security magnetocontact explosion-proof according to claim 4, characterized in that the board is made of a two-part component.

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