RU2126885C1 - Device for monitoring performance of well in operation - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: device has unit for recording instantaneous parameters of pumping setup, circuit for determining and recording of dynamic levels, and indicators. Also provided are following components: survivability ensuring unit, unit for correcting efficiency factor of electric motor, multiplication units, adder, subtraction unit, integrators, and primary multiplication units. One of indicators operates as fluid flow rate indicator. Other indicator is for phase fault indication. Inputs of primary multiplication units are connected to outlets of corresponding current sensors and voltage sensors, thus creating unit for recording instantaneous parameters of pumping setup. Outlets of primary multiplication units are connected to inlets of corresponding integrators. Outlets of integrators are connected to inlets of adder. Second outlets of current sensors and voltage sensors are connected to corresponding inlets of unit for correcting efficiency factor of electric motor. Survivability ensuring unit is connected between inlet clamps of power supply system and electric motor. EFFECT: enhanced performance reliability; increased number and accuracy of measurements of recorded parameters. higher efficiency. 1 cl, 1 dwg

Description

 The invention relates to measuring equipment, and in particular to devices for monitoring wells during their operation (hydraulic systems).

 A device for operating wells is known, including a pump with a control unit, a pressure sensor characterizing a dynamic water level in a well, a pressure signal transducer and a recorder [1].

 The disadvantage of this device is that it does not allow to measure the flow rate and amount of fluid supplied from the wells, which reduces the functionality of the device and requires additional costs for measuring flow rate and amount of fluid. Also known is a control system for a well during drilling, containing a block for fixing the instantaneous parameters of the pumping unit, a scheme for determining and recording the dynamic level and indicators [2].

 In its technical essence, it is closest to the claimed device and is taken as a prototype. Significant disadvantages of the prototype is the impossibility of its functioning in non-phase modes of the supply network, the increased error with deviations of the supply voltage, in addition, the prototype does not provide measurement and registration of the amount of fluid supplied by the pump unit.

 The aim of the invention is to expand the functionality by ensuring the operability of the device at non-phase modes of the supply network, increasing accuracy with non-nominal operating modes of the electric motor, as well as measuring and recording the amount of liquid supplied by the pump unit.

 This goal is achieved by the fact that the device is additionally equipped with a survivability unit, an electric motor efficiency correction unit, multiplication units, an adder, a subtraction unit, integrators and m primary multiplication units, where m is the number of phases of the electric motor, and one of the indicators is an indicator of fluid flow, and the other is an indicator of phase damage, the unit for fixing the instantaneous parameters of the pump unit is made in the form of m phase current sensors and phase voltage sensors of the electric motor; the inputs of the primary blocks of multiplication of phase currents and voltages are connected to the outputs of the respective current sensors and voltage sensors, and the outputs are with the inputs of the corresponding integrators, the outputs of which are connected to the inputs of the adder, the output of which is connected to the first input of the first multiplication block, to the second input of which the first output of the indicator phase damage, and the output to the first input of the subtraction circuit and the second multiplication block, to the second input of which the second output of the phase damage indicator is connected, the output of the subtraction circuit the second multiplication unit is connected to the input of the liquid flow indicator and to the input of the dynamic level determination and registration circuit, the inputs of the phase damage indicator are connected to the corresponding m input terminals of the supply network, the second outputs m of the current sensors and m voltage sensors are connected to the corresponding inputs of the motor action efficiency block, the output of which is connected to the third input of the first multiplication unit, and the survivability unit is connected between the input terminals of the supply network and the electric motor.

 The device according to claim 1 is additionally equipped with an integrator, a comparator, a seventh parameter setting unit, an electric fluid amount counter and a third indicator of the amount of fluid supplied from the well, the input of the fluid flow indicator being connected to the first input of the comparator, the second input of which is connected to the seventh output parameter setting unit, the output of the comparator is connected to the second input of the integrator and to the input of the electric drive of the quantity counter, the output of which is connected to the input of the quantity indicator Liquids supplied from wells.

 A comparative analysis of the proposed technical solution with the prototype allows us to establish that the claimed device is distinguished by the presence of new units and their connections with the rest of the circuit elements, allowing to expand the range of the device in the field of non-phase and different from the nominal operating modes of the network, as well as to measure the amount of fluid pumped from the well .

 These differences allow us to conclude that the claimed technical solution meets the criterion of "Novelty." Signs that distinguish the claimed technical solution from the prototype, are not identified in other technical solutions when studying this and related areas of technology and, therefore, provide the claimed technical solution according to the criterion of "Significant differences".

 In FIG. 1 is a block diagram of a device for determining the flow rate and amount of fluid supplied from the well and the dynamic level of fluid in the well under non-rated and non-phase power modes of the electric motor.

 The device consists of a pump 1, driven by an electric motor 2, whose phase circuits include phase current sensors 5.1, 5.2, 5.3 and phase voltage sensors 6.1, 6.2, 6.3, the first outputs of the phase current and voltage sensors are connected to the inputs of the corresponding multiplication units 7.1, 7.2, 7.3, the outputs of which through integrators 9.1, 9.2, 9.3 are connected to the inputs of the adder 10. The output of the adder 10 is connected to the first input of the second block of multiplication 11, the second input of which is connected to the first output of the phase damage indicator 4, the third input of the second block of multiplication 11 is connected to the output of the motor efficiency correction block 8, the output of the second multiplication block is connected to the first input of the subtraction circuit and the third multiplication block 12, the second output of which is connected to the second output of the phase damage indicator 4, the output of the subtraction circuit and the third multiplication block 12 is connected to the indicator input flow 13 and with the input of the circuit for determining and recording the dynamic fluid level (blocks 14, 15, 16, 17, 18, 19, 20, 21), the second outputs of the current sensors 5.1, 5.2, 5.3 and voltage sensors 6.1, 6.2, 6.3 are connected to the inputs of the block correction efficiency 8 engine.

 The stator circuit of the electric motor 2 includes a survivability block 3, the corresponding inputs of the phase damage indicator 4 are connected to the input phase clamps of the supply circuit, the input of the first fluid flow indicator 13 is connected to the first input of the integrator with reset circuits 22, the output of which is connected to the first input of the comparator 23, the second input of which is connected to the output of the seventh task unit 25, the output of the comparator 23 is connected to the second input of the integrator 22 and to the input of the electric drive of the counter quantity 24, the output of which is connected to the third input its indicator of the amount of liquid 26. The output of the pressure sensor 27 is connected to the third inverse input of the second adder 20.

 The device operates as follows.

The pump 1, driven by an electric motor 2, supplies fluid to the pressure pipe from the well. In this case, phase current sensors 5.1, 5.2, 5.3 generate signals proportional to the instantaneous values of phase currents consumed by the motor from the network (i _a , i _b i _c ), phase voltage sensors 6.1, 6.2, 6.3 - signals proportional to the instantaneous values of phase voltages, supplied to the electric motor 2 (U _a , U _b , U _c ).

From the first outputs of the current sensors 5.1, 5.2, 5.3 and voltage sensors 6.1, 6.2, 63, the signals are fed to the inputs of the corresponding multiplication units 7.1, 7.2, 7.3 at the outputs of which the signals take the form
P _i = k ₁ • u _i • i _i
where 1 = a, b, c is the phase index of the supply network.

 The output signals of the primary multiplication blocks 7.1, 7.2, 7.3 are fed to the inputs of the corresponding phase integrators 9.1, 9.2, 9.3.

With sinusoidal forms of current and voltage curves, the integral of the product of the instantaneous current value by the instantaneous voltage value for a time multiple of an integer number of sinusoid periods is proportional to the active power consumed by the corresponding phase of electric motor 2, therefore, the signals at the outputs of the integrators 9.1, 9.2, 9.3 take the form
P _i = U _i • I _i • cosφ _i • k ₂ , (2)
at the output of the adder 10, to the m inputs of which the outputs of the integrators 9.1, 9.2, 9.3 are connected, there is a signal proportional to the active power consumed by the m-phase motor from the network,
P _{1 = m • U i • I i} • cosφ = P a + P b + P c, ( 3)
which goes to the first input of the second block of multiplication 11.

Multiplying the active power of the electric motor P ₁ efficiency η _dv , consumed from the network, which, in turn, is a function of the engine operating mode: full-phase or incomplete-phase - the information comes from the phase damage indicator 4, as well as from the values of the forward, reverse and zero sequences of phase voltages and currents of the electric motor (information is supplied to the third input of the second block of multiplication 11 from the output of the block for determining the correction of efficiency of the electric motor 8)
P ₁ = f (m, U ₁ , U ₂ , U ₀ , I ₁ , I ₂ , I ₀ ), (4)
as a result, at the output of the second multiplication block 11, a signal is obtained proportional to the power on the motor shaft,
P ₂ = (P _a + P _b + P _c ) • η _dv , (5)
where η _dv is the efficiency of the electric motor in the real (non-nominal) mode of operation.

From the output of the second multiplication block 11, a signal proportional to P ₂ is fed to the first input of the subtraction circuit and the third multiplication block 12, the second input of which receives a signal from the second output of the phase damage indicator 4, which sets the amount of pump power consumption at zero flow rate N ₀ , which as well as P ₂ is a function of the operating mode of the motor 2
N ₀ = f (m) (6)
The output signal of the subtraction circuit and the third block of multiplication 12, proportional to the flow rate of water Q
Q = K (P ₂ -N ₀ , (7)
where K is a scaling factor, is fed to the input of the flow indicator 13, where the indication and registration of the fluid flow occurs.

Thus, the device increases the accuracy of measuring hydraulic parameters by taking into account the functional characteristics of P ₂ and N ₀ in real (non-nominal) operating modes of the electric motor and pump.

At the same time, an output signal proportional to the flow rate Q supplied by the pump is supplied to the first input of the fifth multiplication block 17 and to the first input of the fourth multiplication block 17, to the second input of which a signal (a ₂ -A • l) is supplied from the fourth parameter setting unit 14. From the output of the fourth multiplication block 17, a signal proportional to (a ₂ -A • l) • Q is fed to the first input of the first adder 18, to the second input of which the signal a ₁ is supplied from the fifth parameter setting block 15. As a result, the signal proportional to [a ₁ + (a ₂ -A • l) • Q] is taken from the output of the first adder 18 and fed to the second input of the fifth multiplication block 19, the output of which produces a signal proportional to [a ₁ + (a ₂ -A • l) • Q] • Q. This signal is fed to the first input of the second adder 20, the second input of which receives the signal a from the sixth parameter setting unit 16, and the third inverse input receives the signal from the pressure sensor 27, which is proportional to the gauge pressure H _man . Thus, a proportional signal is generated at the output of the second adder 20. {a ₀ + [a ₁ + (a ₂ -A • l) • Q] • Q-N _man }, which is fed to the input of the secondary recording device 21 registration H _din .

In the second version of the device for monitoring wells during their operation, the signal from the input of the flow indicator 13 is additionally fed to the first input of the integrator with reset circuits 22, where the flow Q is integrated over time, as a result of which the flow rate characteristics of the fluid (Q) go to its quantity (W)
∫Qdt = W. (8)
From the output of the integrator 22, a signal proportional to the amount of liquid is fed to the first input of the comparator 23, to the second input of which a signal is supplied from the seventh task unit 25. Upon reaching the current value, the amount of liquid W is the value of a single signal from the task unit 25 corresponding to the unit for measuring the amount of liquid ( W _ass ), i.e. when the condition is met
W = W _ass
the comparator 23 is triggered, and a signal is given for a single actuation of the electric drive of the liquid quantity counter 24 and at the same time a pulse is sent to reset the integrator 22 - as a result, the amount of liquid supplied by the pump unit is displayed and recorded on the indicating device 26.

 Thus, in the proposed device, the operability of the pumping unit in non-phase operating modes of the supply network is additionally ensured, the measurement accuracy is improved. The number of registered hydraulic system parameters has increased.

 1. Copyright certificate of the USSR N 1211410, cl. E 21 B 47/00, 1986.

 2. US Patent, 3982432, E 21 B 47/00, 09/28/77.

Claims (2)

 1. A device for monitoring the well during its operation, containing a unit for fixing the instantaneous parameters of the pumping unit, a dynamic level determination and recording circuit and indicators, characterized in that it is equipped with a survivability unit, an electric motor efficiency correction unit, multiplication units, an adder, a subtraction unit, integrators and m primary multiplication blocks, where m is the number of phases of the electric motor, one of the indicators being an indicator of fluid flow, and the other an indicator of phase damage, the block is fixed The instantaneous parameters of the pump unit are made in the form of m-phase current sensors and motor voltage sensors, the inputs of the primary multiplication units are connected to the outputs of the corresponding current sensors and voltage sensors, and the outputs are connected to the inputs of the corresponding integrators, the outputs of which are connected to the inputs of the adder, the output of which is connected to the first input of the first multiplication block, the second input of which is connected to the first output of the phase damage indicator, and the output to the first inputs of the subtraction circuit and the second multiplication block, the second input of which the second output of the phase damage indicator is connected, the output of the subtraction circuit and the second multiplication unit is connected to the input of the liquid flow indicator and to the input of the dynamic level detection and recording circuit, the inputs of the phase damage indicator are connected to the corresponding m-input terminals of the supply network, the second outputs m current sensors and m voltage sensors are connected to the corresponding inputs of the motor efficiency correction block, the output of which is connected to the third input of the first multiplication block, and the supply unit survivability is connected between the input terminals for power supply and motor.  2. The device according to claim 1, characterized in that it is additionally equipped with an integrator, a comparator, a seventh parameter setting unit and an electric fluid amount counter, and the third indicator is an indicator of the amount of fluid supplied from the well, and the input of the fluid flow indicator is connected to the first input of the comparator, the second input of which is connected to the output of the seventh parameter setting unit, the output of the comparator is connected to the second input of the integrator and to the input of the quantity counter electric drive, the output is cerned connected to the input of the indicator liquid amount supplied from the borehole.