JP3637982B2 - Inverter-driven pump control system - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a control system for a pump driven by an inverter connected to a commercial AC power supply (hereinafter referred to as a commercial power supply) via a power line, and more particularly, an inverter driven pump capable of remotely monitoring and controlling the operation state by power line conveyance. It relates to a control system.
[0002]
[Prior art]
An inverter that can convert the frequency of a commercial power source to a desired frequency and voltage with little power loss is capable of smoothly controlling the rotation speed of an induction motor, etc., so it is widely used as an energy-saving device for rotating machines such as pumps, fans, and compressors. It's being used. Even in such inverter-driven pumps and the like, the installation location of the pump and the monitoring control location are often separated. In such a case, an attempt has been made to transmit a signal using a power line instead of providing a separate dedicated wiring for a signal for monitoring and operation control.
[0003]
However, when a signal carrier wave is superimposed and carried on a power line by power line carrier, if noise is mixed into the power line from the outside, it becomes difficult to discriminate between the carrier wave signal and noise, and it is difficult to exchange the carrier wave signal accurately.
[0004]
Therefore, for example, according to Japanese Patent Application Laid-Open No. 3-91327, in order to easily discriminate the carrier wave and noise carried on the power line, a cycle for carrying data is set in synchronization with the phase of the commercial frequency voltage on the power line. It has been studied to use a carrier wave separated for each partial conveyance cycle.
[0005]
[Problems to be solved by the invention]
However, according to the related art, since the high frequency carrier wave is superimposed and conveyed on the power line in synchronization with the voltage phase of the commercial frequency, the inverter drive pump that is likely to generate noise when the disturbance noise is mixed in the commercial power source is connected to the power line. In the case of using the load, it is difficult to set the synchronization timing, and there is a problem that communication by the power line carrier is likely to be impossible.
[0006]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a control system for an inverter-driven pump that can stably convey various control signals of the inverter-driven pump using a power line with a simple configuration. To do.
[0007]
[Means for Solving the Problems]
In order to achieve the above-described object, an inverter-driven pump control system according to the present invention is based on an inverter-driven pump driven by an inverter connected to a commercial AC power source via a power line, and an operating state of the inverter-driven pump. A carrier signal combining unit that generates a carrier signal and superimposes the carrier signal on a power line; and a coupling unit that couples to the power line and receives the carrier signal, wherein the carrier signal is generated based on a clock pulse of the inverter. It is characterized by being a pulse signal.
[0008]
The control system for an inverter-driven pump according to the present invention is characterized in that the pulse signal is generated based on the clock pulse and a pulse formed by dividing the clock pulse. is there.
[0009]
The inverter drive pump control system of the present invention generates an inverter drive pump driven by an inverter connected to a commercial AC power source via a power line, and generates a conveyance signal based on the operating state of the inverter drive pump. A carrier signal coupling means for superimposing on the power line; and a coupling means for coupling to the power line and receiving the carrier signal, wherein the carrier signal is a pulse signal generated based on a PWM signal of the inverter. It is a feature.
[0010]
[Action]
According to the present invention having the above-described configuration, since the carrier signal generated from the carrier signal coupling means is a pulse signal generated based on the clock pulse of the inverter, the clock pulse is generated by the inverter drive pump on the receiving side. Whether it is out can be detected. Further, since the carrier signal is a clock pulse, it is difficult to be affected by the harmonic noise present in the power line, and the power line can be carried stably.
[0011]
Further, since the carrier signal is formed by modulating a pulse formed by dividing the clock pulse of the inverter by the control signal, various control signals can be easily multiplexed and transmitted. Since this carrier pulse signal is a frequency-divided signal that is an integral multiple of the clock pulse of the inverter, it is similarly less susceptible to harmonic noise and can be stably carried on the power line.
[0012]
Further, since the carrier signal is a pulse signal generated based on the PWM signal of the inverter, it is possible to directly detect the operating state such as the operating frequency and operating voltage of the inverter on the receiving side. Since this carrier signal is also the output signal itself of the inverter, the signal formation is very easy and is hardly affected by the harmonic noise present in the power line.
[0013]
【Example】
Embodiments according to the present invention will be described below with reference to the drawings. In the following description of the embodiments, the same elements are denoted by the same reference numerals, and duplicate descriptions thereof are omitted.
[0014]
FIG. 1 is a block diagram showing a configuration of an embodiment of an inverter drive pump according to the present invention.
The control system for the inverter-driven pump according to this embodiment includes a power line 2 connected to the commercial AC power source 1 and an inverter-driven pump 3 connected to the power line 2 as a load. In addition, an inverter 31 that converts the frequency into an arbitrary voltage and frequency, and a pump 32 that includes a motor such as an induction motor driven by the inverter 31 are included. The inverter drive pump 3 is connected to a carrier signal coupling means 4 coupled to the power line 2.
[0015]
Further, a coupling means 5 is provided between the power source 1 and the power line 2 to separate and extract the carrier signal coupled to the power line 2. The carrier signal received by the carrier signal coupling means 5 is input to the operation monitoring control means 6 and demodulated, and signals indicating various operation states of the inverter drive pump 3 are taken out. Also, a carrier signal for controlling the operation of the inverter-driven pump 3 is transmitted from the monitoring control means 6 side via the coupling means 5, and this is received by the coupling means 4, and the start / stop of the pump 32, the operation speed, etc. You can also control it. Moreover, the control part of the inverter drive pump 3, the carrier signal coupling | bonding means 4, and the receiving means 5 are electrically connected to the commercial power source 1, and each is supplied with power.
[0016]
The inverter drive pump 3 configured as described above receives supply of commercial power from the commercial AC power supply 1 via the power line 2, and the inverter 31 generates a clock pulse inside the inverter 31, and PWM based on the clock pulse. (Pulse Width Modulation) signal is generated. AC power having a desired frequency and voltage value is supplied to a motor such as an induction motor built in the pump 32 by the PWM signal, and the operation state such as the rotation speed and torque of the pump 32 is controlled.
[0017]
At this time, the clock pulse is generated when the inverter 31 receives supply of commercial power, and the clock pulse does not stop even when the operation state of the inverter 31 or the pump 32 is abnormal. When the supply of commercial power is cut off, the clock pulse is also stopped. In addition, when an abnormality is detected in the operation state of the inverter-driven pump, only the output of AC power by PWM control is stopped by the abnormality signal without stopping the clock pulse.
[0018]
According to the configuration of the above embodiment, the commercial power of the commercial AC power supply 1 is supplied to the inverter drive pump 3 via the power line 2, the inverter 31 generates a clock pulse inside, and the pump 32 is PWM (pulse width). Modulation) control. The clock pulse C of the inverter 31 is input to the carrier signal coupling unit 4 and superimposed on the power line 2 as the carrier signal P. Further, the clock pulse C is frequency-divided to a desired frequency by the carrier signal coupling means 4, and coupled and superimposed on the power line 2 as a carrier signal P modulated by the signals of the pump operating states S1, S2,. The carrier signal P propagates on the power line 2, is separated and detected from the power line 2 by the coupling unit 5, and is input to the monitoring control unit 6.
[0019]
At this time, since the presence / absence of the clock pulse C in the carrier signal P corresponds to the presence / absence of supply of commercial power to the inverter 31, the carrier signal based on the clock pulse of the inverter 31 supplies the commercial power of the inverter drive pump 3 itself. This corresponds to information on the presence or absence of. Further, by receiving a carrier signal P on which pulses of various frequencies obtained by dividing the clock pulse by the monitoring control means 6 are received via the coupling means 5, the operating states S1, S2,. It can be detected and demodulated by the monitoring control means 6.
[0020]
1, signals S1, S2,... Sn regarding the operating state of the inverter drive pump 3 are input to the coupling means 4 from the inverter drive pump 3 together with the clock pulse C, as indicated by a broken line L in FIG. Signals S1, S2,... Sn include basic information such as motor voltage, current, and pump rotation speed, as well as excess and deficiency of water level, wear of bearings, temperature rise of windings, presence or absence of water immersion, phase loss Also, abnormal state signals such as reverse phase and leakage are included.
[0021]
FIG. 2 is a circuit diagram showing a specific example of the circuit configuration of the main part of the carrier signal coupling means 4, and a frequency dividing circuit 41 to which a clock pulse C is supplied and frequency-divided clock pulses f1, f2,. fn and the operation condition signal S1, S2, ... Sn are constituted by the gate 42 _1, 42 ₂ connected to the input unit, and ... 42 _n, a coupling circuit 43 connected to these gate output. A signal S1, S2,... Sn indicating the operation state of the inverter drive pump 3 and a carrier signal P, which is a series of modulation signals generated based on the frequency-divided signal of the clock pulse C, are superimposed on the power line from the coupling means 4. The
[0022]
In the coupling means 5 for receiving the carrier signal, clock pulses of various frequency division frequencies are formed from the received clock pulse by the procedure reverse to the circuit shown in FIG. 2, and demodulated by the gate circuit, and the state signals S1, S2,. ... Sn is taken out and input to the monitoring control means 6.
[0023]
According to the configuration of the above embodiment, whether or not the commercial power is supplied to the inverter drive pump 3 can be detected by the monitoring control means 6 via the coupling means 5 depending on the presence or absence of the clock pulse C. Further, when electric power is supplied to the inverter-driven pump 3, the clock pulse C is divided into multiples according to the types of variables related to the operating state of the inverter-driven pump, so that the operating state signals S1, S2,. On the basis of this, the carrier signals P at the respective frequency divisions are received and demodulated, so that the operating states S1, S2,... Sn corresponding to the frequencies f1, f2,. The state can be detected.
[0024]
In the configuration of the above embodiment, the carrier signal P modulated by the state signals S1, S2,... Sn is supplied from the carrier signal coupling means 4 based on the clock pulse C from the inverter 31 of the inverter drive pump 3. However, it is not limited to this. For example, a PWM signal can be supplied from the inverter 31 to the carrier signal coupling means 4.
[0025]
According to this, in addition to the rotational speed of the pump and the supply voltage, the PWM signal includes information on various operating states according to the load state of the inverter 31 and the rotational speed of the motor. Therefore, the carrier signal generated by the carrier signal coupling unit 4 based on the PWM signal also includes these operating state information. As a result, information corresponding to the operating state of the inverter drive pump 3 is sent to the monitoring control unit 6 as a power line. Can be transported.
[0026]
In particular, in submersible pumps and rooftop cooling towers, inverter-driven pumps are located far away from the power supply. Therefore, when monitoring or controlling inverter-driven pumps separated from the power supply by power line conveyance, harmonic noise Malfunctions can lead to unexpected accidents. In the present invention, as described above, the clock signal of the inverter and the pulse frequency based on the frequency of the inverter or the pulse signal based on the PWM signal are used as the carrier signal. Therefore, the carrier signal is hardly affected by the harmonic noise existing on the power line. Therefore, the operating state of the inverter-driven pump can be transmitted to a monitoring control station that is stably separated using a power line to which power electronics equipment such as an inverter is connected. Therefore, the present invention is extremely useful from the viewpoint of safety measures.
[0027]
In addition, although the above-mentioned embodiment demonstrated the example of the inverter drive pump, it is needless to say that the gist of the present invention can be widely applied not only to the pump but also to various inverter drive fluid machines such as a fan, a compressor, or a blower. It is.
[0028]
【The invention's effect】
As described above, according to the control system for an inverter-driven pump of the present invention, the inverter driving pump operating state signal based on the clock frequency of the inverter, or its divided frequency, or the PWM signal is separated by power line conveyance. Sent to the monitoring control means. Therefore, the operation state of the inverter drive pump can be sent to the monitoring control device separated from the inverter drive pump with a simple configuration. Since the carrier signal coupling means based on the clock pulse of the inverter is provided in this way, even when the inverter drive pump is connected as a load to the power line, regardless of the noise of the commercial AC power supply or the change of the clock pulse frequency of the inverter The operation state of the inverter-driven pump can be reliably transmitted and received by power line conveyance, and an excellent effect can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of an inverter-driven pump according to the present invention.
FIG. 2 is a circuit diagram showing a configuration of a main part of the carrier signal coupling means of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Commercial AC power source 2 Power line 3 Inverter drive pumps 4 and 5 Carrier signal coupling means 6 Monitoring control means 31 Inverter 32 Pump C Clock pulse P Carrier signal

Claims (3)

An inverter driven pump driven by an inverter connected to a commercial AC power source via a power line;
A carrier signal coupling means for generating a carrier signal based on the operating state of the inverter-driven pump and superimposing it on the power line;
Coupling means for coupling to the power line and receiving the carrier signal;
The inverter drive pump control system, wherein the carrier signal is a pulse signal generated based on a clock pulse of the inverter. 2. The control system for an inverter drive pump according to claim 1, wherein the pulse signal is generated based on the clock pulse and a pulse formed by dividing the clock pulse. An inverter driven pump driven by an inverter connected to a commercial AC power source via a power line;
A carrier signal coupling means for generating a carrier signal based on the operating state of the inverter-driven pump and superimposing it on the power line;
Coupling means for coupling to the power line and receiving the carrier signal;
The inverter drive pump control system, wherein the carrier signal is a pulse signal generated based on a PWM signal of the inverter.

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