KR890003935B1 - Variable frequency power source operating system - Google Patents

Abstract

An airflow control apparatus includes a ventilator-actuating motor driven at a rotational speed corresponding to a power supply frequency, a VF (variable frequency) power source connected to the motor, a controller for feeding a control signal to the VF power source so as to determine to output frequency thereof, and an abnormal signal detector including means for detecting an abnormality relative to the control signal fed to the VF power source and producing an output characterised by a control signal generator provided in the controller for generating the control signal in the form of a pulse signal of predetermined fixed pulse magnitude and width or a frequency.

Description

Variable frequency power supply

1 is a schematic diagram of a motor speedometer using a variable frequency power supply.

2 and 3 are time charts illustrating the operation of the conventional variable frequency power supply driving method.

4 is a schematic system diagram of a motor speedometer using a variable frequency power source for explaining the present invention.

5 is a time chart illustrating a control signal to a variable frequency power supply according to the present invention.

6 is a supplementary explanatory diagram.

7 is a circuit diagram of a control signal generator.

8 is an explanatory diagram for explaining the operation of FIG.

9 is a block diagram showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: commercial power supply 2, 10, 11: switchgear

3: V power supply 3A, 3B: Signal error detector

4: electric motor 5: connector

6: Rotor 6 b: Runner of Rotor 6

7: control device 7B: control signal generator

8: control signal 9: signal line

12: wind-wind 14a: vane

The present invention relates to a V power supply system which drives a rotating body such as a fan or a pump with a variable frequency power supply (hereinafter abbreviated as V power supply). In particular, when the control signal to the V power supply becomes abnormal such as disconnection or short circuit The present invention relates to a variable frequency power supply operation method for dealing with the problem.

Conventionally, this kind of apparatus has been shown in the control 1 degree. In the same figure, in the figure, 1 is a commercial power supply, 2 is a switch, 3 is a V power supply, and the electric motor 4 is speed-controlled.

6 is a rotating body such as a fan or a pump, 5 is a connector of the electric motor 4 and the rotating body 6, 7 is a control device for transmitting a frequency control signal to the V power supply 3, 8 is a control device 7 The control signal input to 9 is a signal line connecting the control device 7 and the V power supply 3, and in FIGS. 2 and 3, t ₁ and t ₃ respectively increase and decrease the control signal 8; the decrease command timing start point, t ₂ is t ₄ is V power supply 3 timing output, respectively, complete the increase or decrease in the stop point, t ₅ or more generating time point of the signal line (9), t ₆ response after an error occurs V power The time point at which the output of (3) is completed is shown.

The following operation will be described.

To describe in detail, an example of a power plant in which the rotating body 6 is viewed as a fan and its output (air volume) is sent to a boiler (not shown) will be described.

That is, in FIG. 1, the V power supply 3 receives electric power from the use power supply 1 via the switch 2, and drives the electric motor 4 by the output of the V power supply 3. As shown in FIG. Here, the rotation speed n of the electric motor 4 is given by equation (1).

Stage F: Applied Power Frequency, P: Number of Poles of Motor

Therefore, the rotation speed n and the applied power source frequency F have a proportional relationship.

That is, when the output frequency F of the V power supply 3 changes, the rotation speed n of the electric motor 4 changes. The electric motor 4 is directly connected to the fan 6 by the connector 5, and the fan 6 supplies the air volume Q of the output to the boiler almost in proportion to the rotation speed n of the electric motor 4.

Also, in the example of the power plant, when the required power in the power system changes or the fuel supply state changes, the air volume Q required by the boiler also changes, and at this time, the change command of the air volume Q is a control command ( 8) and given to the control device (7). The change command of the air volume Q is given to the V power supply 3 via the signal line 9, and the V power supply 3 outputs a frequency F corresponding to the required air volume Q.

2 is an explanatory time difference art diagram when the conventional V power supply system shown in FIG. 1 is in normal operation.

That is, when the control command 8 requests the increase in the air volume Q at time t ₁ , and the reduction request for returning to the original value at time t ₃ , the output of the control device 7 is the signal line 9 of FIG. 2. Is given to the V power supply (3).

In general, the V power supply 3 is designed to change the output at a constant increase / decrease rate in response to a change request, so that the output frequency F of the V power supply 3 changes with respect to the request time point t ₁ (t ₃ ) of the change. It is delayed slightly, and the operation is completed at each (t ₂ ) (t ₄ ) time point.

In other words, when the output air volume Q of the fan 6 is to be changed, the output frequency F of the V power supply 3 is changed to cope by changing the rotation speed n of the electric motor 4.

3 is a time difference art when an abnormality occurs in the signal line 9 of FIG. 1 and shows an example in which the signal line 9 is disconnected (including looseness or deflection of the connection terminal). Here, of course, there is no change in the control signal 8, and a constant air volume Q is required.

Therefore, when the signal line 9 is disconnected at time t ₅ , the input signal to the V power supply 3 becomes zero. As shown in FIG. 2, the output frequency F of the V power supply 3 is slightly delayed to decrease to the lower limit value. As a result, the rotation speed n of the electric motor 4 also decreases, and the output air volume Q of the fan 6 also decreases.

The conventional driving method of a motor using a V power supply has been achieved as described above. When an abnormality such as disconnection or the like occurs on the control signal line of the V power supply 3, the output frequency of the V power supply 3 unnecessarily fluctuates, and as a result, the motor ( 4) The operating state of the rotating body 6 is unstable, and there is a defect such as developing into a system accident.

The present invention has been made to eliminate the drawbacks of the conventional ones as described above, and uses an intermittent wave of a constant amplitude as a frequency control signal to a V power supply (electricity other than the amplitude of the intermittent wave (pulse width, frequency, digital signal, etc.)). Is transmitted to the V power supply in response to an accident (disconnection, short circuit, etc.) of the signal line 9, i.e., by detecting an abnormality of the signal amplitude. By switching to the power supply, it is possible to eliminate an unnecessary V power output change even in the event of an accident of the signal line 9, and maintain the output of the V power so that a change in the output of the unnecessary V power even in the event of an accident of the signal line 9 does not occur. The aim is to provide a frequency operation.

One embodiment of the present invention will now be described with reference to the drawings.

In FIG. 4, the same part as FIG. 1 is shown using the same code | symbol, (10) (11) is a switch.

7B is a control signal generator and 3B is a signal anomaly detector. 5 shows an example of a signal flowing through the signal line 9 of FIG. 4, and the control signal 8 shows an example of two levels F ₁ (F ₂ ). The signal flowing through the signal line 9 again represents an intermittent wave whose amplitude becomes (H) at the pulse widths F ₁ (F ₂ ) corresponding to the control signal levels F ₁ (F ₂ ), respectively.

FIG. 6 is a diagram for supplementary explanation, which is an example of boiler air volume control, and 6a and 6b show a rotation shaft and a runner of the fan 6. 12 is the wind, 12a and 12b is the inlet and outlet of the wind (12), 13 is the wind direction to enter the wind, 14 is a mechanical air flow control mechanism, 14a is a vane, 14b is a driving rod, 15 is a wind flow control mechanism ( 14) Display the control input signal to the erotic.

FIG. 7 is an example of an input-frequency converter showing a circuit diagram of the control signal generator and forming an output having a pulse width Wp proportional to the magnitude of the input voltage E ₁ , and FIG. 8 is an explanatory diagram for explaining the operation of FIG.

In this figure, E ₁ is an input voltage, T ₁ T ₄ is a transistor, C ₁ , C ₂ is a capacitor, R ₁ , R ₇ is a resistor, ZD is a zener diode, Es is a power supply voltage, voltage Vc ₁ is a time constant When the voltage rises from C ₁ , R ₁ and the voltage Vc ₁ exceeds the input voltage E ₁ , the transistor T ₂ goes from "off" to "on", and thus the transistor T ₃ also turns off. It turns on.

The transistor (T ₃₎ continuing off the base current of the transistor (T ₁₎ via a Zener diode (ZD) flows transistor (T ₁₎ is turned on, the transistor (T ₂₎ (T ₃₎ when the on- do.

The capacitor C ₂ is provided to ensure the time required for discharging the charge of the capacitor C ₁ through the transistor T ₁ to return the voltage Vc ₁ to OV.

Considering the level E ₁₁ (small value) and the level E ₁₂ (large value) as shown in FIG. 8, the time for the voltage Vc ₁ to reach the input voltage E ₁ is (E ₁ ). In proportion to, it is possible to obtain an input-frequency converter having a pulse width proportional to the input voltage E ₁ , like the output signal 0 of FIG. 8.

Here, if a disconnection light is generated in the signal line 9, although no special change occurs in the control signal 9, the amplitude H of the intermittent wave flowing through the signal line 9 is small (zero) at the input side of the V power supply 3. Including). Therefore, the signal abnormality detector 3B which detects that the amplitude H of the signal line 9 is out of a normal value on the V power supply 3 side is determined, and it is judged whether the signal line 9 is in an abnormal state such as disconnection or the like. As a result, the voltage applied to the electric motor 4 is switched from the V power supply 3 to the commercial power supply 1 by turning off the switch 2 and 10 of FIG. 4 and turning on the switch 11. FIG. Switching from this V power supply 3 to the commercial power supply 1 performs the operation mentioned later.

The operation at this time will be described with reference to FIG.

6 illustrates the mechanical air flow control mechanism as an example, and when the motor is driven by the V power source 3, the rotation shaft 6a and the runner 6b of the fan 6 are rotated by the electric motor 4, By varying this rotation speed, the air volume to the boiler is controlled.

In general, the vane 14a is fixed in a fully expanded state because of energy saving operation.

If an abnormality occurs in the signal line 9 of FIG. 4 in such a state, the signal abnormality detector installed in the V power supply 3 is operated to drive the vane 14a through the driving rod 14b to the opening degree of the vane 14a. Follow 14a.

At the same time, the output of the V power supply 3 is raised to the vicinity of the rating of the V power supply 3, and the output frequency F is raised to make the rotation speed of the electric motor 4 close to the rating.

The switching of the V power supply 3 at this time is slowly raised slowly. In addition, the amount of air that increases with the increase in the number of revolutions is suppressed to a safe range by following the opening degree of the vane 14a in the direction of decreasing the amount of air.

Thus, when the output of the V power supply 3 rises to the rated vicinity, the switches 2 and 10 in FIG. 4 are turned off, and 11 is turned on so that the voltage applied to the motor 4 is changed to V power supply ( Switch from 3) to commercial power source (1). By controlling in this way, however, the signal abnormality detector of the signal line 9 immediately after the operation of the frequency applied to the motor (4) rather than switching the voltage applied to the motor (4) from the V power source (3) to the commercial power source (1) The sudden change in width is narrowed, and the air volume change at the time of switching is small.

In this way, even when the signal line 9 is abnormal, the drive power supply of the electric motor 4 is safely switched from the V power supply 3 to the commercial power supply 1.

9 is another embodiment of the present invention, where 7B is a signal abnormality detector 3A.

In operation of the control signal generator 7B, when the transistor T ₁ is turned off from on, as shown in FIG. 7, the voltage Vc ₁ increases at the time constant C ₁ R ₁ , and the voltage Vc ₁ is increased. When the input voltage E ₁ is exceeded, the transistor T ₂ is turned off to on, thus the transistor T ₃ is also turned off to on.

A transistor (T ₃₎ When the on the base current of the transistor (T ₁₎ via a Zener diode (ZD) flows through the transistor (T ₁₎ is turned ON, and makes still in the off the transistor (T ₂₎ (T ₃₎ . The capacitor C ₂ is provided to ensure the time necessary for discharging the charge of the capacitor C ₁ through the transistor T ₁ to return the voltage Vc ₁ to OV.

Considering the level E ₁₁ (small value) and the level E ₁₂ (large value) as shown in FIG. 8, when the voltage Vc ₁ reaches the input voltage E ₁ , the time is equal to E ₁ . As shown in the output signal E _{0 of} FIG. 7, an input-frequency having a pulse width proportional to the input voltage E ₁ is obtained.

When disconnection or the like occurs in the signal line 9, the amplitude H of the intermittent wave flowing through the signal line 9 is reduced to small (zero) at the input side of the V power supply 3 even though no special change occurs in the control signal 8. Included).

Therefore, since a signal abnormality detector for detecting that the amplitude H of the signal line 9 is out of the normal value is provided on the V power supply 3 side, the V power supply 3 determines whether the signal line 9 is in an abnormal state such as a disconnection light. It controls to keep the operation state of motor of phenomenon by preventing change of output signal.

In the above description, the fan speed control of the power generation plant and the like has been described as an example, but the same effect is applied to a rotating body such as a pump other than the fan, a system other than the power generation plant, and the like.

Although the above embodiment has been described taking the disconnection of the signal 9 as an example, other cases such as short circuits may be used.

Although the intermittent wave of FIG. 5 is shown as an example of the magnitude of the minimum value and the maximum value H, the reference amount is not limited to zero.

In the above description, the output frequency is raised to near the rated output of the V power supply 3, and the switching from the V power supply 3 to the commercial power supply 1 is not limited to this. It is not said that it is good by other methods such as switching soon.

In the above description, the frequency control input is explained in the example of inputting the pulse width of the intermittent wave to the V power supply 3, but the digitally-coated numerical signal may be used as the intermittent wave.

As described above, according to the present invention, a circuit is configured such that the signal supplied to the V power supply is used as an intermittent wave, and the amplitude of the intermittent wave is not used for frequency control. Since the power supply is switched from the V power supply to the commercial power supply, and the output frequency of the V power supply is prevented, the motor (V power supply) is stabilized even when the signal line is abnormal, so that operation continues.

In addition, by properly selecting the amplitude abnormality detection range, the amplitude of the control signal to the V power supply becomes small at the time of disconnection or short circuit of an incomplete signal line, and the frequency control signal is correctly supplied to the V power supply, thereby increasing the chance of continued operation. .

Claims (4)

The variable frequency power supply 3, the electric motor 4 fed and driven from this variable frequency power supply 3, the rotating body 6 rotated by this electric motor 4, and the said variable frequency power supply 3, the output frequency A control device 7 for outputting a control signal for changing a signal; a signal line 9 for supplying a control signal of the control device 7 to the variable frequency power supply 3; A signal line 9 for supplying a signal, a control output generator 7B provided on the side of the control device 7 and outputting the control signal as a constant width intermittent wave, and a side of the variable frequency power supply 3 Signal abnormality detector 3B that is operated when the control signal of the constant width intermittent wave is out of the predetermined range, and when the signal abnormality detector 3B is operated, the power supply of the motor 4 is supplied from the variable frequency power supply 3 to the commercial power supply. Variable frequency power supply with switchgear (2) (10) (11) . The commercial power supply according to claim 1, wherein when the signal abnormality detector 3B is operated, the output frequency of the variable frequency power supply 3 approaches the commercial power supply frequency, and then the power supply of the electric motor 4 is changed from the commercial variable power supply 3 to the commercial power supply. Variable frequency power supply operation characterized in that for switching to. A variable frequency power source 3, an electric motor 4 fed and driven from the variable frequency power source 3, a rotating body 6 rotated by the electric motor 4, and outputted to the variable frequency power source 3 A control device 7 for outputting a control signal for changing a frequency, a signal line 9 for supplying a control signal of the control device 7 to the variable frequency power supply 3, and a control line provided at the control device 7 side A control output generator 7B for outputting a control signal as a constant amplitude interruption wave, and a signal abnormality detector 3A installed on the side of the variable frequency band 3 to operate when the control signal of the constant amplitude interruption wave has an amplitude outside a predetermined range And, when the signal abnormality detector 3A is operated, the output of the variable frequency power supply 3 is maintained as an output when the signal abnormality detector 3A is operated. 4. The variable frequency power supply operation method according to claim 3, wherein an input value of the control device (7) and a pulse width of the control signal output from the control signal generator (7A) (7B) are proportional to each other.

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