RU2117135C1 - Device for electric heating of oil well and cleaning it from paraffin - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: this relates to facilities for cleaning production strings and wells from paraffin and other depositions. Device has power transformer, thyristor converter with control system, current sensor and presetting unit, current regulator, source of voltage of preset frequency, and unit for protection from breaking of load current which is made in the form of successively connected rectifier and comparator. Controlling input of control system is connected with output of current regulator. Connected to input of current regulator are current sensor and presetting unit. Output of control system is connected with controlling input of thyristor converter. Input of thyristor converter is connected through current presetting unit with secondary winding of power transformer. Output of thyristor converter is connected to load. Current presetting unit is connected with source of voltage of required frequency. Application of aforesaid device allows for reduction of installed power of electrical equipment, and for widening functional potentialities of device together with improving reliability and efficiency of heating. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to the oil industry, and in particular to means for cleaning production casing wells from paraffin and other deposits.

 Known devices for the mechanical cleaning of production wells of oil wells from paraffin deposits [1]. These devices require additional labor.

 The most common are chemical cleaning methods, including the injection of a heated reagent into the well string to organize the removal of paraffin-containing deposits in the well with periodic pressure changes [2]. These methods are expensive and require additional labor.

 Well-known electric heaters are known for destroying frozen paraffins, which comprises a tubular body with long heating elements arranged in a spiral on its surface. Holes are made in the upper part of the casing, the heater is equipped with pin centralizers, four of which are mounted on the current lead sealed to the casing, and four in the central part of the casing between the turns of the heating element. The heater is powered by a load-carrying cable [3].

 The essence of the heater is that the heater is lowered into the column, voltage is applied to the heating element. Thermal energy from the heating element and the body is transferred to destructible hydrates, frozen paraffins. The latter are melted in the contact zone with the heater.

 The closest in technical essence and taken as a prototype is the installation "Paratrol" [4].

 This installation (Fig. 2) is intended for electric heating of the oil pumping (or pump and compressor) tubing and thereby preventing the deposition of paraffin.

The essence is that the internal oil pumping pipe (tubing) is electrically connected by a special submersible contact with the external casing of the well and electric current from the transformer 1 is passed between the pipes through a starting-regulating device 2, for example, a starter. As a rule, this contact is established below the beginning of the paraffin formation zone in order to allow the oil flowing through the internal (oil pumping) pipe to warm up before it enters the paraffin deposition zone. To avoid accidental contact between the pumping pipe and casing, insulators are installed. Electric current (up to 300 A) is obtained from transformer 1 with solders, which regulate the voltage and current in the electric circuit of the well that forms the load 3. The switching modes of the transformer are carried out by device 2, which sets up a cyclic or single continuous operation. This ensures the temperature of the pipeline above the cloud point of paraffin, which prevents the formation of paraffin crystals and its deposition in the pipe. When the unit is turned on, the amount of heat that is sufficient to heat the paraffin-forming areas is generated along the entire length of the pipeline. The temperature in the pipeline is brought to 36 - 40 ^o C, and the oil rising through the pipe is heated to the specified temperature, resulting in the melting of paraffin. For melting paraffin, 1 to 3-day work of the installation is enough.

 When the current disappears in the load circuit 3, the current element is activated - the relay 4 of the minimum current, which at a current less than the specified value disables the installation and gives a signal to the dispatcher.

The use of an electric heating installation is economically highly efficient and provides the following advantages:
increase in well production;
lack of violation of the operational properties of the oil reservoir;
lack of environmental pollution;
low operating cleaning costs compared to other methods;
compatibility with operating modes and repair work mode;
overall well maintenance costs are reduced;
can fundamentally work with all methods of lifting oil, including in conjunction with a rocking chair.

 The installation has the following disadvantages.

 1. Regulation of voltage and current is carried out discretely and mechanically by means of taps on the secondary winding of transformer 1, which complicates the transformer, creates inconvenience in operation and reduces the heating efficiency as the pipeline heats up and its resistance increases, as well as during mains voltage fluctuations. This is a consequence of an open-loop control system.

 2. When the electric circuit is bridged in the well (for example, due to malfunction of insulators, an intermediate connection between the tubing and the casing may form), the load resistance decreases, the current increases, and the transformer, equipment and oil well elements overheat.

3. Given that the current path has a total length of 1.5 - 2 km and is a long line, it contains a distributed value of the active R and inductive X _n = ω ₀ α resistance proportional to this length. Moreover, since the inductive resistance is proportional to the frequency of the network (ω ₀ ), to create the required current value (the value of i ² R determines the heating of the pipe), it is necessary to increase the secondary voltage and power of the transformer 1. To reduce the power of the transformer, it is necessary to ensure that ω ₀ α ≪ R, which is almost impossible in the specified installation, receiving power from an industrial network with a frequency of 50 Hz. Almost at a well depth of about 800 m, we have R ≈ 0.15 Ohm, ω ₀ λ - 0.8 Ohm (ω ₀ = 2πf ₀ = 2π50 = 314c ^-1 ).

 4. Skew (asymmetry) of the supply voltage on the low side. The specified network is formed using a step-down three-phase network transformer (usually 6 kV / 380 V) with a capacity of 40-100 kVA (depending on the well). The asymmetry is determined by the commensurate power of the transformer 1 and the mains, as well as the fact that the mains transformer is three-phase, and that of transformers 1 is single-phase, which, with load currents up to 300 A, creates an asymmetric load along the phases of the mains transformer.

 5. Lack of auto-regulation of the heating process.

 The technical result of the invention is the reduction of installed capacity, the expansion of functionality and increase the reliability of the installation for electric heating of oil wells and cleaning it from paraffin.

 The technical result is achieved by the fact that the device for heating the oil well and cleaning it from paraffin, comprising a power transformer and a load, is equipped with a thyristor converter with a control system, a sensor and a current regulator, a current regulator, a voltage source of a given frequency and a load current protection circuit breaker, made in the form of a series-connected rectifier and comparator, the input of the rectifier being the input of the load protection circuit and connected to the output of the current regulator, and the output of the comp The speaker is the output of the load protection circuit and is connected to the logical input of the control system, the control input of which is connected to the output of the current regulator, the input of which is connected to a sensor and current regulator, the output of the control system is connected to the control input of the thyristor converter, the input of which is via the current sensor connected to the secondary winding of the power transformer, and the output to the load, while the current master is connected to a voltage source of a given frequency.

 The essence of the invention lies in the fact that a device for heating an oil well and cleaning it from paraffin, comprising a power transformer and a load, is characterized in that it is equipped with a thyristor converter with a control system, a sensor and a current regulator, a current regulator, a voltage source of a given frequency and a protection unit from a break in the load current, made in the form of a series-connected rectifier and a comparator, and the input of the rectifier is the input of the protection against break in the load current and is connected to the output of the regulator current generator, and the comparator output is the output of the load protection circuit, and is connected to the logical input of the control system, the control input of which is connected to the output of the current regulator, to the input of which a sensor and current regulator are connected, the output of the control system is connected to the control input of the thyristor converter, whose input is connected through the current sensor to the secondary winding of the power transformer, and the output is connected to the load, while the current collector is connected to a voltage source of a given frequency. The decrease in the installed capacity of the installation for electric heating is achieved by reducing the inductive resistance X of the electric circuit between the tubing and the casing of the oil well. X is reduced by decreasing the current frequency, which is realized using a thyristor converter operating in the current regulator mode with a given frequency.

 In this case, you can change the frequency from 0 to 50 Hz with the possibility of transferring the converter from the rectifier mode to the frequency converter mode (a really good effect is achieved at 5 - 10 Hz). This allows you to sharply reduce the inductive component of the voltage, which at a given well current I = const allows you to reduce the secondary voltage and, consequently, the power of the power transformer and the installation as a whole.

 The introduction of a well current interruption protection unit made it possible to increase the reliability of the installation. The system of automatic regulation and maintenance of current has allowed to expand the functionality of the installation, which consists in the ability to automate its management. Improving reliability and expanding functionality is also achieved by using a 3-phase transformer and turning the output voltage of the installation into 2-phase of a certain frequency using a converter, which ensures uniform loading of the network in phases and eliminates network asymmetry. This is very important, since the reliable operation of the rest of the equipment is obtained, receiving power from the common network, in which phase imbalance is essentially eliminated, as is the case in the prototype when the unit is powered by a single-phase transformer.

 In FIG. 1 shows a functional diagram of the proposed devices, where the following notation: 1 - power transformer; 2 - thyristor converter; 3 - load, for example, a chain of an oil well pipeline; 4 - current element - current sensor; 5 - converter control system (SIFU) having control and logical inputs; 6 - current regulator; 7 - current setter; 8 - voltage source of a given frequency, which can be set from 0 to a value corresponding to the network frequency, for example 50 Hz; 9 - block of protection against breakage of load current; 10 - rectifier; 11 is a comparator.

 In the proposed device, the transformer 1 is connected to the thyristor converter 2, the output of which is connected to the load 3, and the input through the current sensor 4 is connected to the secondary winding of the transformer, the control circuits of the thyristors of the converter are connected to the control system 5, to the control input of which the current regulator 6 is connected, at this inputs of the latter are connected to the sensor 4 and the setter 7 of the current, which is connected to a voltage source 8 of a given frequency; unit 9 protection against breakage of the load current is made in the form of series-connected rectifier 10 and comparator 11, while the output of the unit is connected to the logical input of the control system 5.

 The installation works as follows (Fig. 1).

 In the electrical circuit formed by the oil well pipeline ("tubing - submersible contact - casing") of load 3, a certain current value and frequency I are set using thyristor converter 2. The current value is determined by the current setpoint 7 and the frequency of the current source 8 .

 The structure based on elements 1 - 8 is a current regulator that maintains a given current in the well in size and shape. At the same time, a direct current (f = 0) or an alternating current with frequencies lower than the network frequency can be set into the well.

 In order to eliminate the phenomenon of electrolysis in a well with the possibility of explosion, frequencies f = 5 - 10 Hz are used.

The use of a current regulator with a low frequency provides:
decrease in inductance and power of the transformer,
increases reliability in the event of a regime close to a short circuit in the well due to the shorting of the circuit along the insulators. In this case, the current controller maintains a predetermined current value regardless of the resistance value of the well circuit. In addition, due to the introduction of the block 9 protection against current loss of the voltage load, the unit is switched off when the current circuit disappears (open circuit). In this case, the converter 2 is locked, the installation is turned off and a signal is issued to the dispatcher about the disappearance of current.

 When the current disappears, the output signal of the sensor 4 is equal to zero, as a result, the signal at the output of the current regulator 6 has a maximum value that goes to the rectifier 10 and when it reaches the threshold of the comparator 11, the latter gives an alarm signal and disables the electric heating installation.

The advantages of the proposed device compared to the prototype are:
decrease in installed capacity of electrical equipment for heating a well;
elimination of asymmetry of the mains voltage, which ensures uniform loading of the phases of the common network transformer of the well; thereby eliminating its overheating and negative impact on co-operating other equipment receiving power from the specified mains transformer;
the set current is stably maintained regardless of the heating of the pipe, voltage fluctuations of the network and possible faults in the well;
increases the reliability and efficiency of heating due to protection against current breakdown in the load - well.

 The indicated effect of the claimed device is achieved through the use of a three-phase transformer connected through a thyristor converter with current regulators to the electrical clamps of the well; at the same time, the device is equipped with a current circuit break protection block.

 A prototype of a device for electric heating of oil wells was made and tests were carried out at one of the wells of Tatneft JSC, which confirmed a positive result.

Claims (1)

 A device for electric heating of an oil well and cleaning it from paraffin, containing a power transformer and a load, characterized in that it is equipped with a thyristor converter with a control system, a sensor and a current regulator, a current regulator, a voltage source of a given frequency and a load current protection circuit breaker, made in in the form of a series-connected rectifier and comparator, and the input of the rectifier is the input of the load protection circuit and is connected to the output of the current regulator, and the output of the comparator is it is connected to the output of the load protection circuit and is connected to the logical input of the control system, the control input of which is connected to the output of the current regulator, the input of which is connected to a sensor and current regulator, the output of the control system is connected to the control input of the thyristor converter, the input of which is connected through the current sensor with the secondary winding of the power transformer, and the output with the load, while the current master is connected to a voltage source of a given frequency.

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