RU2330993C2 - System to control air cooling devices - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to variable-capacity fans and can be used in gas transport units and power plants requiring a cooling of heat exchangers by air to keep up a required temperature of medium being cooled. The invention allows notable electric power savings in cooling, increasing the equipment life and reliability of control system. The said system incorporates a controller and a pickup of temperature of the medium being cooled, fans with drives, a set of heat exchangers, lines feeding cooling medium to the said heat exchangers and removing it into the manifold where from the cooled medium comes into the tailrace. The drives incorporate the rpm adjustment devices with the inputs receiving the signal from the temperature controller output. The controller first input receives the signal from the temperature pickup, its second inputs receives the signal on the required cooling medium temperature. Here, the fans are driven be asynchronous electric motors with the speed varied by the power supply frequency converter.

EFFECT: longer life; power savings; higher reliability of the control system.

4 cl, 1 dwg

Description

The invention relates to variable capacity fan units and can be used in gas transportation systems and power plants where cooling of heat exchangers with air is required to maintain the required temperature of the medium to be cooled.

A known system for controlling the performance of fans for cooling heat exchangers with an air cooling apparatus (ABO), comprising an adjustable fan with a constant speed electric motor, a device for positioning the impeller blades, a temperature sensor of the medium to be cooled (see RF patent No. 2183290, 2000). A disadvantage of the known system is the complexity of the mechanical system for changing the position of the impeller blades and its sensitivity to failure.

Closest to the claimed system is a system of partial (discrete) shutdown of the working fans of air-cooled devices, containing a control unit, a temperature sensor for the medium to be cooled, fans with an electric motor, a group of heat exchangers (see the book “Operation of Gas Pipelines in Western Siberia”, L .: Nedra, p. .152). The disadvantage of this system is the low accuracy of maintaining the temperature of the medium to be cooled, operation at maximum power modes and the occurrence of air recirculation zones when individual ABOs are turned off, which cause additional energy losses.

These disadvantages of the known systems are most pronounced when they are used to cool the gas at the outlet of the compressor stations. Due to the occurrence of air recirculation zones in heat exchangers and the operation of electric motors at maximum speed, their energy consumption increases. Frequent shutdowns / turning on of electric motors to ensure the required gas temperature leads to the premature development of their resource. When the ABO is turned on, increased over-currents occur, which requires the installation of expensive soft-start systems, etc.

The technical result achieved by the invention is to save electrical energy for cooling, increase the life of the equipment used, provide fault tolerance of the control system and the flexibility of changing control algorithms to ensure the required quality of temperature control of the refrigerated medium.

The specified result is achieved by the fact that in the control system of the air cooling apparatus, containing a controller and a temperature sensor of the medium to be cooled, fans with a drive, a group of heat exchangers, pipelines for supplying them to the cooled medium and its discharge to the collector, from which the cooled medium enters the discharge pipe, according to the invention, the drives have a device for changing their speed, the input of which receives a signal from the output of the temperature controller, the signal from the sensor perature and the second input - a signal of the desired temperature of the cooling medium, as the drive motors of fans are used, rotation frequency of which varies as a device current of the frequency converter the mains motors.

The indicated result is also achieved by the fact that the temperature controller has a dead zone proportional, integrating and differentiating circuits, and the temperature sensor of the medium to be cooled is installed in the outlet pipe.

The indicated result is also achieved by the fact that an ambient temperature sensor is installed, the signal from which is supplied to the third input of the temperature controller.

The indicated result is also achieved by the fact that for each drive a corrector is set for the set frequency of its rotation, the input of which receives a signal from the temperature sensor of the cooled medium installed at the output of the corresponding heat exchanger, and the signal from the output of the corrector is added to the output signal of the controller.

The drawing shows a structural diagram of a system for automatic control of air cooling devices (SAU ABO).

The control object for ACS ABO is a group of heat exchangers of "n" pieces - l ₁ , l ₂ , ..., l _n . In the drawing, heat exchangers are installed in parallel, but they can be arranged in parallel-series and have several fans. A cooled medium (air, oil, etc.) is supplied to the input of the heat exchangers. After it is cooled by air supplied by fans 2 ₁ , 2 ₂ , ..., 2 _n , it flows through pipelines 3 (3 ₁ , 3 ₂ , ..., 3 _n ) to collector 6, where it is mixed, and with an average temperature enters the outlet pipe 8. The rotation of each of the fans 2 ₁ , 2 ₂ , ..., 2 _n provides a corresponding drive 4 (asynchronous electric motor) with a device 5 for changing its speed, which is made in the form of a frequency converter for supplying electric motors with voltage Uc.

The temperature of the cooled medium is measured by a sensor 7 installed in the outlet pipe 8. The signal from the sensor 7 is fed to the first input (1 input) of the temperature controller 10, the second (2 input) - a signal about the required temperature of the cooled medium, and the third - signal from the ambient temperature sensor. The controller 10 has a dead zone 17 proportional to 12, integrating 13 and differentiating 14 circuits. It generates a signal for all drives proportional to the value of the rotational speed f _ass required at the given moment of time, which is supplied to the first input of the adders 20 ₁ , 20 ₂ , ..., 20 _n . The signal Δfi from the corresponding corrector 19 is received at their second input. The adders 20 ₁ , 20 ₂ , ..., 20 _n correct the value of the rotational speed of the drives f _ass , depending on the signals from the temperature sensors of the cooled medium 21 ₁ , 21 ₂ , .. ., 21 _n, which are installed in pipelines 3 _1, 3 _2, ..., 3 _n at the output of the heat exchangers 1 _1, 1 _2, ... 1 _n. The resulting signal from the output of the adders 20 is fed to the input of the corresponding devices 5 ₁ , 5 ₂ , ..., 5 _n , which change the value of the speed of the drives.

The functioning of the ACS ABO while maintaining the temperature of the refrigerated medium in the pipe 8 is as follows. The required temperature value (T _ass ) is supplied to the 2nd input of the controller 10, for example, from a higher-level control system. From the sensor 7 to the 1st input of the controller 10, a signal is received about the actual temperature of the medium to be cooled. Block 11 determines the deviation of the actual temperature from the set value - the error signal ΔT, which is input to the blocks 12, 13, 14 (control loops). To reduce the mismatch ΔT, the block 16 generates a correction signal for the rotational speed of the drives Δfk. In block 12, the proportional part Δfk is calculated (the product of the coefficient Кп and ΔT), in block 13, the integrating part (the product of Ki and the integral ∫ΔTdt), and in 14, the differentiating part (product of Кд and the derivative dΔT / dt). From the sensor 9 to the 3rd input of the controller 10 and further to the block 15, a signal about the ambient temperature is received to correct the Δfk value, for example, by changing the values of Кп, Ки, Кд or an equidistant shift Δfk. From block 16, the resulting signal Δfk enters block 17, which implements the deadband, and then to block 18, where a new value of the specified speed of the drives f _{ass is} calculated, equal to the sum of its previous value and Δfk. If necessary, the value of f _ass can be limited by the maximum and minimum values, as well as the rate of change of f _ass . Block 17 (deadband) may be located and / or behind block 11.

The signal proportional to f _ass , is fed to the first input of all adders 20 ₁ , 20 ₂ , ..., 20 _n , to their second input is the value of the correction signal ± Δf _i , and from the output of the adders, the adjusted value of f _ass goes to devices 5 (5 ₁ , 5 ₂ , ..., 5 _n ) changes in the speed of the drives. The value of the signal ± Δfi is determined by the readings of the sensors 21 in block 19. This signal allows us to establish the fact of unequal heat removal from the heat exchangers due to different values of the flow rate of the cooled medium flowing through them or due to changes in the values of heat transfer coefficients.

Devices 5 (frequency converters with internal speed feedback) implement a new value for the speed of drives 4 ₁ , 4 ₂ , ..., 4 _n , and all fans 2 rotate at the same speed close to f _back , providing unidirectional flow air through all the fans. With a positive ΔT value, devices 5 increase the fan speed and, therefore, increase the air supply to the heat exchangers (the value of the cooling heat flow increases), and with a negative ΔT they decrease. This leads to a decrease / increase in temperature behind the heat exchangers 1 ₁ , 1 ₂ , ..., 1 _n , and after mixing in the manifold 6 flows of the cooled medium from the pipelines 3 - and in the pipe 8. The process will continue until the specified and the actual value of the temperature of the cooled medium in the discharge pipe 8 does not equal, while the mismatch ΔT becomes equal to zero or close to zero at a different speed of rotation of the drives.

A characteristic feature of the operation of this control system is a decrease in the power consumed by the electric motors with a decrease in the rotational speed (ω _in ) of all “n” fans even in comparison with a discrete control system in which some of the fans are turned off and the “m” of the remaining fans operate at the maximum speed ω _max . To maintain the same temperature of the cooled medium, the supply of air fans in these systems should be the same. supply is proportional to the rotational speed, then nω _in / λ = mω _max and ω _in = ω _max λm / n, where λ <1 is the coefficient of change of heat transfer “air-cooled medium” with a change in the ratio of air flow rates to the cooled medium. For qualitative evaluations take λ = 1, as well as in the maintenance of constant speed motors of power is proportional to the cube of the rotational speed (N = kω ^3), then the power ratio equals NK systems (ω _max m / n ³⁾ / (mkω ³ _max) = (m / n) ² . Those. despite the greater number of fans operating in this system, due to their operation at lower speeds, the power consumed by electric motors decreases, because m <n and (m / n) ² << 1.

The obtained ratios for the power consumed by the electric motors show that the most efficient operation of the control system takes place while reducing the rotational speeds of all the fans, which is provided by the regulator 10, giving the same signal f _ass to the devices 5. As you know, the resource of the electric motors increases when they work at lower speeds, which is implemented in this control system.

By changing the value of the coefficients Kp, Kd, Ki and / or turning off the individual blocks for generating the signal Δfk (the corresponding coefficient Kp, Kd, Ki is equal to zero), the required quality of controlling the temperature of the cooled medium is ensured. The presence in the controller of the dead zone for the correction signal Δfk (block 17) eliminates its fluctuations and, ultimately, eliminates parasitic alternating fluctuations in the frequency of rotation of the drives, reducing the life of electric motors.

Introduction to the controller 10 with a sensor 9 of the ambient temperature allows you to proactively adjust the value of Δfk. For example, at the same negative ΔT value, when it is necessary to reduce the fan speed to reduce the heat flow of the fans, a decrease in air temperature provides an increase in heat removal and the value of Δfk can be reduced. This will lead to a reduction in the duration of transients in the temperature of the medium.

Measurement by the sensors 21 of the temperature of the cooled medium behind the Ti heat exchangers allows you to use these readings as a diagnostic sign of degradation of the characteristics of the heat exchangers (clogging of the annular channels for air passage, etc.) and to equalize the Ti temperatures to reduce the time of transients in the temperature in the pipeline 8. , at a temperature Ti above the required value, the correction unit 19 determines the amount of correction + Δfi, which enters the adder 20 and the rotation speed f _ass increases. The amount of correction may be limited.

As a rule, the flow rate of the cooled medium through the heat exchangers and its temperature at the inlet to the heat exchangers differ insignificantly and an increase in temperature behind the i-th heat exchanger above the permissible value indicates the degradation of the heat transfer coefficients and the need for routine maintenance. The average temperature of the working medium for the sensors 21 can be used as a backup for the temperature controller in case of failure of the sensor 7. This ensures the fault tolerance of the control system.

Thus, the use in the ABO control system of current converters of the current frequency of the supply network for changing the frequency of rotation of electric motors, a temperature controller of the cooled medium having a dead zone, reconfigurable proportional, integrating and differentiating circuits, temperature sensors of the ambient air and the cooled medium in the exhaust pipe and at the outlet of the heat exchangers when regulating the temperature of the refrigerated medium provides energy savings due to the operation of electric motors at lower rotational speeds, their resource is increased, system fault tolerance and the flexibility of changing algorithms are provided to ensure the required quality of temperature control of the cooled medium.

Claims (4)

1. The control system of air-cooled apparatuses, comprising a controller and a temperature sensor for the medium to be cooled, fans with a drive, a group of heat exchangers, pipelines for supplying them to the cooled medium and its discharge into the collector, from which the cooled medium enters the discharge pipe, characterized in that the drives have a device for changing their speed, the input of which receives a signal from the output of the temperature controller, the signal from the temperature sensor is supplied to the first input of the controller, and the signal of demand is sent to the second input emoy coolant temperature, wherein as the drive motors of fans are used, rotation frequency of which varies as a device current of the frequency converter the mains motors. 2. The system according to claim 1, characterized in that the temperature controller has a dead zone proportional, integrating and differentiating circuits, and the temperature sensor of the medium to be cooled is installed in the outlet pipe. 3. The system according to claim 1, characterized in that an ambient temperature sensor is installed, the signal from which is supplied to the third input of the temperature controller. 4. The system according to claim 1, characterized in that for each drive a corrector of a set frequency of its rotation is installed, the input of which receives a signal from a temperature sensor of the cooled medium installed at the output of the corresponding heat exchanger, and the signal from the output of the corrector is added to the output signal of the controller.