JP2832384B2 - Automatic operation device of submersible pump for drainage - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an automatic operation device of a submersible pump for drainage.

(Prior art)

Conventionally, automatic operation devices for this type of submersible pump for drainage include:
There is a so-called automatic operation device in which automatic operation is performed by one pump, and an automatic alternating parallel operation device in which two pumps are automatically and alternately operated in combination with the automatic operation device of one pump.

FIG. 4 is a diagram showing the configuration of an automatic operation device with one pump. In the figure, reference numeral 32 denotes a starting flow switch, reference numeral 33 denotes a stop float switch, and reference numeral Tr denotes a transformer for lowering the voltage of the power supply AC to a power relay control voltage.

Since the detection water level of the starting water level detection sensor 32 is set to a higher level than the detection water level of the stop flow switch 33, the water level rises, the stop float switch 33 closes,
Further, when the starting float switch 32 is closed, the power relay LY is operated, and the contacts LY-1 and LY-2 are closed. As a result, the power relay LY is self-held, the pump driving motor 31 is started, and the drainage submersible pump is started.
Drainage proceeds and the water level drops, and the start-up float switch 32
Even when the stop float switch 33 is ON, the power relay LY continues to operate because the stop float switch 33 is ON, and the power relay LY does not operate when the water level drops further and the stop float switch 33 is OFF. Operation and the contacts LY-1, LY
-2 is turned off, and the pump driving motor 31 stops.

Although not shown, the automatic alternating parallel type operation device performs automatic alternating parallel type operation of two submersible pumps for drainage with a circuit configuration completely different from that of FIG. 4 using a power relay.

[Problems to be solved by the invention]

As described above, the conventional automatic operation device with one pump and the automatic alternate parallel operation device with two pumps have completely different circuit configurations using a power relay. Or an automatic alternating parallel operation of two units, it is necessary to use an operation control circuit of a completely different configuration, and the automatic operation device of the submersible pump for drainage becomes expensive as a whole. there were.

The present invention has been made in view of the above points, and has been made in consideration of the problems described above.
An automatic operation device for a submersible pump for drainage that is inexpensive and easy to assemble by providing a combination of two automatic operation devices and two automatic alternate parallel operation devices with appropriate control circuits. Is to do.

[Means for solving the problem]

The invention according to claim (1) for solving the above-mentioned problem is based on a detection signal of a water level detection sensor that detects a water level.
In the automatic operation device of the submersible pump for drainage that automatically starts and stops the submersible pump for drainage via a power relay or a solid state relay that starts and stops the pump drive motor, When the water level reaches the pump start water level in response to the detection signal of the water level detection sensor, the pump drive motor is started via the power relay or the solid state relay, and when the water level reaches the pump stop water level, the power drive or the solid state relay is used. An automatic operation device having a first control circuit for stopping a pump drive motor, and when two pumps are automatically and alternately operated in parallel, one of the pumps is an automatic operation device having a first control circuit, The other pump receives the detection signal of the water level detection sensor, and when the water level reaches the pump start water level, the power relay or A second control circuit for activating the pump drive motor via the solid state relay and stopping the pump drive motor via the power relay or the solid state relay when the water level reaches the pump stop water level; The second control circuit is integrated into one separate circuit configuration, and the second control circuit is automatically operated by one pump.
In the case of automatic operation on a stand, an automatic operation device is configured by appropriately selecting the first control circuit or the second control circuit integrated into one unit and using the first control circuit or the second control circuit.

According to a second aspect of the present invention, in the automatic operation device of the submersible pump for drainage according to the first aspect, the first control circuit and the second control circuit are each configured as a separate circuit. As a uniting means, the first control circuit and the second control circuit are collectively mounted on separate boards, respectively, and when one pump is operated automatically, the first control circuit and the second control circuit are automatically mounted using the board on which the first control circuit is mounted. When an operating device is configured and two pumps are automatically and alternately operated in parallel, one of the pumps is the first pump.
An automatic driving device is constituted by using the board on which the control circuit is mounted, and the other pump is constituted by using the board on which the first control circuit is mounted and the board on which the second control circuit is mounted. It is characterized by having done.

[Action]

As described above, the first control circuit and the second control circuit are combined into one separate circuit configuration, and are combined into one when the automatic operation is performed by one pump and when the automatic operation is performed by two pumps. Since the automatic operation device is configured by appropriately selecting the first control circuit and the second control circuit, the first control circuit and the second control circuit are appropriately installed inside or outside the submersible pump for drainage. In addition, an automatic operation device for automatically operating with one pump and an automatic operation device for automatically and alternately performing parallel operation with two pumps can be configured very easily and inexpensively.

〔Example〕

 Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

1 and 2 are diagrams showing a control circuit configuration of an automatic operation device of a submersible pump for drainage of the present invention, and FIG.
FIG. 1 is a diagram showing a control circuit configuration of one automatic operation device, and FIG. 1 is a diagram showing a control circuit configuration of an automatic operation device of the other pump when two pumps are automatically and alternately operated in parallel.

In FIG. 2, reference numeral 11 denotes a start float switch, and reference numeral 12 denotes a stop float switch. The start float switch 11 is provided above, and the stop float switch 12 is provided below it. Tonransu Tr is to lower the power source AC voltage, 16 full-wave rectifier, C ₀ denotes a capacitor.

In FIG. 2, when the water level rises, the stop float switch 12 closes first, and when the water level further rises, the start float switch 11 closes. Start-up float switch 11
There comes a ON, resistor R _1, through the diode D _1, the trigger signal is supplied to the thyristor 13, the thyristor 13 is rendered conductive, the power relay 14 is actuated, the contacts 14-1 turned ON. As a result, the pump driving motor 15 starts, and the submersible pump for drainage starts. Drainage by the drainage submersible pump proceeds, the water level drops, and the stop float switch 12
When turned off, the power relay 14 becomes inactive and its contact 1
4-1 turns off, and the pump driving motor 15 stops.

Here, a thyristor 13, a resistor _{R 1, R 2, R 3} , diode
A circuit including D ₁ and the capacitor C _{1 is referred} to as a first control circuit 19.

In FIG. 1, portions denoted by the same reference numerals as those in FIG. 2 indicate the same or corresponding portions. The first control circuit 19 is the same as the first control circuit 19 shown in FIG. 2, and the description of the operation is omitted. 17 is a float switch for abnormality. Reference numeral 18 denotes an IC circuit (IC4013) composed of a one-shot circuit and a flip-flop circuit, which receives an ON signal of the start-up float switch 11 and includes a circuit composed of the IC circuit 18 and diodes D ₂ , D ₃ and D _4. The trigger signal of the thyristor 13 is output every other time based on the truth table of the IC circuit 18 shown in FIG.

Here, the control circuit 20 including the IC circuit 18 and the diodes D ₂ , D ₃ , D _{4 and the} like is defined as a second control circuit.

The first control circuit 19 and the second control circuit 20 are mounted together on separate boards and shared to provide an automatic operation device for one of the pumps when two pumps are automatically and alternately operated in parallel. As shown in FIG. 2, only the board on which the first control circuit 19 is mounted is used, and the automatic operation device for the other pump is connected to the board on which the first control circuit 19 is mounted, as shown in FIG. And a substrate on which the control circuit 20 is mounted. Accordingly, the first control circuit can perform both the automatic operation using one pump and the automatic alternate parallel operation using two pumps.
By simply preparing a substrate on which the substrate 19 is mounted and a common substrate on which the second control circuit 20 is mounted, an automatic operation device for the submersible pump for drainage can be easily configured. In FIG. 1, R _{4 to} R ₁₀ are resistors, ZD is a Zener diode, and C _{2 to} C
₄ is a capacitor.

FIG. 5 is a diagram for explaining the operation of the automatic alternating operation. In the figure, reference numeral 51 denotes a submersible pump for drainage of No. 1 equipped with the automatic operation device shown in FIG. 1, and reference numeral 52 denotes a submersible pump for drainage of water of No. 2 equipped with the automatic operation device shown in FIG.

As shown in the figure, the No. 1 drainage submersible pump 51 includes a start float switch 11, a stop float switch 12, and an abnormal float switch 17, and a No. 2 drainage submersible pump 52.
Is the start float switch 11 and the stop float switch
12 is provided. In addition, WL ₁ indicates the No. 1 pump stop water level, WL ₂ indicates the No. 2 pump stop water level, WL ₃ indicates the No. 1 pump start water level, WL ₄ indicates the No. 2 pump start water level, and WL ₅ indicates the abnormally increased water start water level.

In normal automatic alternate operation, the water level and reaches to No. 1 pump start water level WL ₃ increases (a point), activated float switch 11 is turned ON in Figure 1, through the diode D ₄ from the IC circuit 18, the thyristor A trigger signal is applied to 13, a power relay 14 is activated, and a pump driving motor 15
The No. 1 drainage submersible pump 51 operates.

When the water level drops and the No. 1 pump stop water level WL ₁ is reached (point b), the stop float switch 12 is turned off, the power relay 14 is disabled, and the pump drive motor 15 and the No. 1 drainage submersible pump 51 are turned off. Stop.

The water level rises due to the stop of the pump, and the water level at which the No. 2 pump starts
To reach WL ₄ (c point), activated float switch 11 of FIG. 2 is turned ON, the pump driving motor 15 is No. 2 for drainage water pump 52 starts to operate. At this time, the float switch 11 for starting the first submersible pump 51 is also turned on.
As shown in FIG. 3, the IC circuit 18 shown in FIG.
No. 1 is output only every other time, so that the No. 1 drainage submersible pump 51 does not operate.

Water stops, No. 2 pump stop water level WL ₂ is reached, (d point) stop float switch 12 of FIG. 2 is turned OFF No. 2 for drainage water pump 52 is stopped.

Then the water level rises, to reach No.1 pump start water level WL ₃ (e point), water pump 51 is operated for 1 No. drainage.

Next, the case of abnormal water increase will be described. When the water level rises and reaches the No. 2 pump starting water level WL ₄ (point f), the No. 2 drainage submersible pump 52 operates, but the water level still rises and reaches the abnormally high water starting water level WL ₅ (point g). , The abnormality float switch 17 shown in FIG.
Trigger signal is applied to the power relay 14
When the pump driving motor 15 is started, the first drainage submersible pump 51 also operates.

As a result, when the water level decreases and the No. 2 pump stop water level WL ₂ is reached (point h), the No. 2 drainage submersible pump 52 stops,
Furthermore the water level is lowered, to reach No.1 pump stop water level WL ₁ (i point), it is also stopped No.1 for drainage water pump 51.

Thereby the water level rises and reaches the No. 1 pump start water level WL ₃ 1 No. drainage water pump 51 is operated and further the water level reaches No. 2 pump start water level WL ₄ rises (k point), 2
The submersible water pump 52 operates.

When the water level drops and the No. 2 pump stops and reaches the water level WL ₂ (one point), the No. 2 drainage submersible pump 52 stops, and
When the No. ₁ pump stop water level WL ₁ is reached (point m), the No. 1 drainage submersible pump 51 stops.

Next, the operation in the case where the second drainage submersible pump 52 stops due to a failure will be described. When the water level rises and reaches the No. 2 pump starting water level WL ₄ (point n), the No. 2 drainage submersible pump 5
2 operates, but if the No. 2 drainage submersible pump 52 stops on the way due to a failure, the water level rises again,
When it reaches WL ₆ (point o), the abnormal float switch 17 shown in FIG. 1 is turned on, and the submersible pump 51 for drainage No. 1 is operated.

As a result, when the water level drops and reaches the _first pump stop water level WL1 (point p), the first drainage submersible pump 51 stops. Water level rises, to reach No.1 pump start water level WL ₃ (q point), operates the No. 1 for drainage water pump 51, the water level reaches to No.1 pump stop water level WL ₁ drop (r point), The No. 1 drainage submersible pump 51 stops.

Then the water level rises, is reached (s point) to No. 1 pump start water level WL _3, because the IC circuit 18 does not output a trigger signal of the thyristor 13 only once every other as described above, No. 1 Drainage water the medium pump 51 does not operate at this time, to reach the abnormal swollen start water level WL ₅ (t point), abnormal float switch 17 of FIG. 1 is is turned oN No.1 for drainage water pump 51 operates. As described above, while the No. 2 drainage submersible pump 52 is stopped due to a failure, only the No. 1 drainage submersible pump 51 is operated.

By configuring the automatic driving device as shown in FIGS. 1 and 2, the self-holding of the power relay is performed not by the relay contact but by a thyristor as shown in FIG. Can be downsized.

The first control circuit 19 used for the automatic type and the second control circuit 20 used for the automatic alternating type can be formed as a hybrid circuit by combining a thyristor, a diode, a resistor, and the like, so that assembly is facilitated.

The configurations of the first control circuit 19 and the second control circuit 20 are not limited to the above. For example, the first control circuit 19 receives the ON / OFF signals of the start float switch 11 and the stop float switch 12, and receives the power relay ON / OFF signal.
The second control circuit 20 may turn off the power relay and turn on the power relay every other ON signal of the start float switch 11 so that the stop float is turned on. If the power relay is turned off by the OFF signal of the switch 12, the pump drive motor 15 is started and stopped, and the power relay is turned on by the ON signal of the abnormality float switch 17, the pump drive motor 15 is turned on. Good. In the above example, the case where the normally open contact of the power relay is used to start the pump driving motor 15 has been described, but it is needless to say that the normally closed contact may be used.

In the above embodiment, the pump driving motor 15
Is configured to stop and start by turning on and off the contacts of the mechanical power relay 14. Instead, a solid state relay is used to stop and start by turning on and off. Is also good.

The start float switch 11, the stop float switch 12, and the abnormal float switch 17 are examples of a water level sensor for detecting a start water level, a stop water level, and an abnormal water level. ,
Various water level sensors can be used.

〔The invention's effect〕

As described above, according to the inventions described in claims (1) and (2), the first control circuit and the second control circuit are respectively combined into one separate circuit configuration, and one pump is automatically operated by one pump. The first control circuit and the second control circuit that are combined into one unit are appropriately selected in the case of operation and the case of automatic operation with two pumps, and an automatic operation device is configured using the first control circuit and the second control circuit. By automatically incorporating the second control circuit inside or outside the submersible pump for drainage, an automatic operation device for automatic operation with one pump and an automatic operation device for automatic parallel operation with two pumps are provided. An excellent effect that it can be formed very easily and at low cost is obtained.

[Brief description of the drawings]

FIG. 1 is a diagram showing a control circuit configuration of an automatic operation device for the other pump when two pumps are automatically and alternately operated in parallel.
Fig. 3 is a diagram showing a control circuit configuration of an automatic operation device with one pump, Fig. 3 is a diagram showing a truth table of an IC circuit, Fig. 4 is a diagram showing a configuration of the automatic operation device with one pump, FIG. 5 is a diagram for explaining the operation of the automatic alternating operation. In the figure, 11 ... Float switch for starting, 12 ... Float switch for stopping, 13 ... Thyristor, 14 ... Power relay, 15 ... Pump driving motor, 16 ... Full-wave rectifier, 17
... Abnormal float switch, 18 IC circuit, 19 first control circuit, 20 second control circuit.

Claims (2)

(57) [Claims] 1. A drainage water pump for automatically starting / stopping a drainage water pump via a power relay or a solid state relay for starting / stopping a pump drive motor in response to a detection signal of a water level detection sensor for detecting a water level. In the automatic operation device of the pump, when the automatic operation is performed by one pump, the pump driving motor is started via the power relay or the solid state relay when the water level reaches the pump starting water level in response to the detection signal of the water level detection sensor. When the water level reaches the pump stop water level, the automatic operation device has a first control circuit that stops the pump drive motor via the power relay or the solid state relay, and the two pumps are automatically and alternately operated in parallel. In this case, one of the pumps is an automatic operation device having the first control circuit, and the other pump is the water level detection device. When the water level reaches the pump start water level in response to the detection signal of the sensor, the pump drive motor is started every other time via the power relay or the solid state relay, and when the water level reaches the pump stop water level, the power relay or the solid state is started. Providing a second control circuit for stopping the pump drive motor via a relay, combining the first control circuit and the second control circuit into separate circuit configurations, and automatically operating with one pump; In the case of automatic operation with two pumps, the first
An automatic operation device for a submersible pump for drainage, wherein an automatic operation device is configured by appropriately selecting the control circuit or the second control circuit. 2. The automatic operation device for a submersible pump for drainage according to claim 1, wherein the first control circuit and the second control circuit are integrated into separate single circuit configurations. When the first control circuit and the second control circuit are collectively mounted on separate boards, respectively, and the automatic operation is performed by one pump, an automatic operation device is configured using the board on which the first control circuit is mounted. When the two pumps are automatically and alternately operated in parallel, one of the pumps constitutes an automatic operation device using a substrate on which the first control circuit is mounted, and the other pump comprises the first pump. An automatic operation device for a submersible pump for drainage, wherein an automatic operation device is configured using a substrate on which a control circuit is mounted and a substrate on which the second control circuit is mounted.