RU2700269C1 - Device for separation of cathodic protection circuits and protective grounding and lightning protection circuits - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: device for separation of cathodic protection circuits and circuits of protective grounding and lightning protection is made in the form of power diodes unit, overvoltage limiters unit actuated at potential difference over 1 kV, and unit for indication of state and mode of operation. Power diodes are connected anti-parallel, their number and type depends on required voltage drop on device and required voltage on diode.EFFECT: increased safety and convenience of equipment operation.1 cl, 3 dwg

Description

The invention relates to the field of energy saving and increasing the efficiency of electrochemical protection of underground metal structures from soil corrosion and can be used, in particular, in the oil and gas industry when operating tanks or underground pipelines that are electrically connected to electrical installations connected to protective ground and / or lightning protection grounding , for example, on the territory of industrial sites of pumping and compressor stations.

A device is known for separating the cathodic protection loops and the protective grounding and lightning protection loops, made in the form of an insulating insert that electrically delimits the aboveground and underground parts of pipelines (BCH 39-1.22-007-2002; Instructions for the use of insulating inserts for gas pipelines; RF patent
No. 2588346, publ. 06/27/2016). The disadvantages of the known device include the following: the high cost of electrically insulating inserts and their installation, lower reliability of electrically insulating inserts relative to the pipe, due to the complexity of the design and a large number of elements, low resistance to decompression, and the possibility of using electrically insulating inserts only during new construction or reconstruction of operated pipelines or tanks.

In practice, most often, to reduce the influence of protective earths on the operation of cathodic protection, coatings of protective grounding elements made of electronegative metals (for example, aluminum, zinc, magnesium) are used. The disadvantage of this solution is its low efficiency, because, due to a number of reasons, not pure metals are used, but their alloys, which allows shifting the protective grounding potential to the negative side by a value of the order of 0.5-1.0 V, but in some cases this is not enough to ensure effective cathodic protection of underground structures.

A device for separating the cathodic protection loops and the protective grounding and lightning protection loops is made using series-parallel and parallel connected varistors and containing a heat dissipating case, taken by us as a prototype (RF patent No. 104394, publ. 10.05.2011). The disadvantage of this device is the relatively high voltage value necessary for the varistor to operate, so it is possible that on the equipment case (for example, a tank or pipeline) the potential relative to the ground will be insufficient for the varistor to operate, but dangerous to the life and health of personnel, for example, 100 V. In addition, the disadvantage of this device is the lack of indicators, which does not allow timely detection of a malfunction of the device in the event of an open circuit between the protected weapons and protective grounding, which is a danger to personnel servicing electrical installations.

The objective of the invention is to provide a device for separating the cathodic protection circuits and the protective grounding and lightning protection circuits, the voltage drop of direct and alternating current at which is up to 3 Volts, having an overvoltage protection system and an indication system, which generally ensures the safety and convenience of equipment operation.

In the process of solving this problem, a technical result is achieved, which consists in increasing the efficiency of the electrochemical protection of underground structures from corrosion by using the proposed device for separating the cathodic protection circuits and the protective grounding and lightning protection circuits, made in the form of a block of semiconductor elements, a block of surge arresters that operates at a difference potentials over 1 kV, while the device contains a block indicating the status and operating mode, and as of semiconductor elements, power diodes are used, connected in parallel, the number and type of which depends on the required voltage drop across the device, due to the difference in the potential of the structure and the material potential of the protective ground electrodes in the ground and the proximity of the protective ground to the anode ground, as well as the required voltage drop on a diode, which depends on its type.

The invention is illustrated in FIG. 1-3:

- in FIG. 1 shows an example of a circuit block consisting of four power diodes, which is two counter-parallel connected chains of two power diodes connected in series;

- in FIG. 2 shows a block diagram of a device,

- in FIG. 3 is a diagram explaining the operation of the device for separating the cathodic protection loops and the protective ground loops and lightning protection loops, where 1 is a cathodically protected structure; 2 - electrical installation subject to grounding; 3 - installation of cathodic protection; 4 - a device for separating the cathodic protection loops and protective earth loops and lightning protection loops; 5 - protective grounding; 6 - anode grounding.

The device consists of three blocks made in one housing and connected in parallel to each other:

- The block of power diodes, which provides the required voltage drop between the cathode-protected structure (1) and protective ground (5) (about 1-3 Volts), which minimizes the effect of protective earths on the efficiency of cathodic protection, reduces the energy consumption for cathodic protection, reduces the load on the converters of the cathodic protection stations and the wear of the anode earths. Moreover, if an alternating or direct current voltage of more than 1-3 volts appears on the electrical installation (2), the current flowing through the diodes and through the protective ground increases sharply, which does not allow the appearance of voltage hazardous to life and health of the personnel at the cathode-protected structure (one).

The diodes are turned on in parallel, which, on the one hand, allows an alternating or pulsating current to pass through the device (4), as well as a direct current of arbitrary polarity, and on the other hand, it allows you to change the voltage drop across the device by changing the number of diodes connected in series. The number and type of diodes is selected depending on the required voltage drop across the device and the required voltage on the diode. The required voltage drop across the device is due to the difference between the building potential and the material potential of the protective grounding electrodes in the ground, as well as the location of the protective grounding relative to the anode grounding and the protective grounding material. Depending on the material of the protective ground and the proximity of its location to the anode ground, the required minimum voltage drop across the device is selected, which may be due to the type and number of diodes connected in series.

- A block of varistors or surge arresters, triggered by a significant potential difference (over 1 kV), which can damage the diodes of the power diode block, for example, during a lightning strike.

- Indication unit, consisting of two LED signaling devices, allowing to evaluate the status and operation mode of the device. The device display unit can be in one of three modes. Mode 1: when the DC voltage drops due to the cathodic protection current, the first LED lights up. Mode 2: when alternating current flows through the device, a second LED lights up, which signals an abnormal operation of electrical equipment. Mode 3: the absence of the glow of both LEDs when the cathodic protection station is operating means a breakdown of the power elements of the device, for example, when a lightning current of high strength flows.

The operation of the device is illustrated in FIG. 3.

There is a cathode-protected structure (1), electrically connected to an electrical installation (2) having protective grounding (5). In this case, the protective ground (5) is located on the ground (not shown in Fig. 3) between the cathode-protected structure (1) and the anode ground (6), which causes the cathode current to flow both on the cathode-protected structure (1), so and protective earth (5), i.e. the effect of shielding the cathodic protection currents is shown by the protective ground circuit.

A device for separating the cathodic protection loops and the protective earth and lightning protection loops (4) is installed in an open protective earth circuit. The power diode block provides the required voltage drop between the protected structure and the protective ground loop (about 1-3 volts), which minimizes the effect of protective earths on the efficiency of cathodic protection, reduces the energy consumption of the cathodic protection, reduces the load on the converters of the cathodic protection stations and the wear of the anode grounding. After connecting the device, it is determined that connecting the protective earth through the device does not lead to a change in the operation modes of the cathodic protection with respect to an open circuit of the protective earth. If the device operates in the normal mode, that is, a DC voltage drop due to the cathodic protection current is observed, the first LED lights up on the device display unit.

Example.

During commissioning, the commissioning of electrochemical protection means for the pipelines of the compressor station revealed that the pipelines did not provide polarization in accordance with GOST R 51164-98 due to leakage of cathodic protection current to the protective earth made of galvanized steel. Protective grounding is located between the protected pipeline and the anode grounding and is equidistant from them. The converters of the cathodic protection station operate with a load factor of about 90% in power, accelerated wear of the anode earths and an excessive consumption of electricity occur.

Temporarily disconnect the protective grounding circuit and measure the imposed potential "pipe-to-ground", which began to meet the requirements of GOST R 51464-98 and amounted to minus 1.0 V. Moreover, the power consumed by the converters decreased by 10 times. The required voltage drop on the device for separating the cathodic protection loops and the protective earth loops and lightning protection loops is selected taking into account the material and the location of the protective earth relative to the anode ground, for example, according to the following formula

U = k · (U _{of T} - U _ss) (one)

where U _t-s is the potential difference "pipe-to-ground" with the protective earth disconnected, V;

U _ЗЗ - intrinsic potential of protective grounding material
in the ground, B;

k - coefficient taking into account the proximity of the protective ground to the anode ground, k = 1 ... 5.

The coefficient k is determined by the point system: the higher the score, the closer the protective ground to the anode, the lower the score, the closer the protective ground to the pipe and further from the anode.

In this example, the coefficient k takes into account that protective grounding is located between the protected pipeline and the anode grounding and is equidistant from them, therefore, k = 2.5.

Given the possible values of the current strength in the protective earth circuit, diodes D161-320 are selected for the manufacture of the device according to TU U 32.1-30077685-018: 2006. The characteristics of the diode: a voltage drop of 0.85 V at a temperature of 25 ° C, the maximum shock current of 8.8 kA.

Then, to ensure a voltage drop of more than 2.0 V, it is necessary to connect three diodes D161-320 in series. The total voltage drop will be 2.55 V. Such a diode assembly can withstand a reverse voltage of about 3 kV.

To prevent failure of the diodes at reverse voltages exceeding the permissible values, the device contains a block of varistors. In the varistor block, an overvoltage limiter OPN-P-1 / 1.5 / 5/550 UHL1 was selected with the following characteristics: operating voltage –1 kV, lightning impulse current - up to 10 kA.

The device is installed in an open protective earth circuit. It is established that the connection of the protective earth through the device did not lead to a change in the operation modes of the cathodic protection with respect to an open circuit of the protective earth. The indication of the device indicates the presence of only direct current cathodic protection, i.e. the system is operating normally.

Claims (1)

A device for separating the cathodic protection loops and the protective grounding and lightning protection loops, made in the form of a block of semiconductor elements, a block of surge arresters operating at a potential difference of more than 1 kV, characterized in that it contains a block for indicating the state and operating mode, and as a semiconductor the elements are used power diodes connected in counter-parallel, the number and type of which depends on the required voltage drop across the device, due to the spacing and building constructions and building material protective grounding electrodes in the ground, as well as the close proximity of the protective earth grounding to the anode, and the desired voltage drop across the diode, which depends on its type.

Images