JPS6212876Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an automatic operation device for a pump equipped with a pressure tank.

[Conventional technology]

In order to downsize a pressure tank connected to the discharge side of a pump, an automatic pump operation device is known that is equipped with a pressure switch, a flow rate switch, and a timer. In this type of device, the pressure switch is closed to start the pump when the internal pressure of the pressure tank drops below a predetermined value, and is opened when the internal pressure reaches a predetermined value. Further, the flow rate switch is configured such that after the internal pressure of the pressure tank increases and the pressure switch is opened, the pump is stopped when the flow rate outflow from the pressure tank decreases to a predetermined value or less. Once the pump is started, the timer keeps the pump in operation until a predetermined period of time has elapsed, regardless of the flow rate outflow from the pressure tank.

[Problem that the invention attempts to solve]

In the conventional device described above, the control circuit of the electromagnetic switch, the timer, and the like that start and stop the motor for driving the pump are powered by the same commercial AC power source as the motor. Therefore, since a small-capacity flow rate switch cannot directly control the above-mentioned switch, it must be controlled via an electric valve such as a triax.
Further, a timer having a CR circuit requires a rectifier circuit, and there is a problem in that the size and price ratio of the control circuit is too large, especially for automatic operation of a small-capacity pump.

Moreover, since the conventional device described above uses a flow rate switch to control the start and stop of the pump, when the pump is stopped due to sudden closing of a water tap, for example, momentary instability due to water hammer etc. may occur. The fluctuation affected the flow rate switch, causing the flow rate switch to repeatedly open and close in a vibratory manner, which adversely affected the operation of the pump drive motor.

[Means for solving problems]

Therefore, the purpose of the present invention is to provide a device that requires less space and can be manufactured at low cost.
Not only is it particularly suitable for small capacity pumps, but
An object of the present invention is to provide an automatic operation device for a pump that is capable of stable operation even when the pump is started or stopped.

That is, the present invention includes an electric motor connected to an AC power source, a pump driven by the electric motor,
A switch provided between the electric motor and the AC power supply, a pressure tank provided on the discharge side of the pump, and a switch that closes when the internal pressure of the pressure tank drops below a predetermined value and maintains the predetermined internal pressure. A pressure switch that opens when the pressure exceeds the specified value, a DC power source that converts the AC power source to DC, and a flow rate switch that closes when the amount of water flowing out from the pressure tank is above a predetermined value and opens when it is below a predetermined value. and a control circuit that receives output signals from the pressure switch and the flow rate switch to control on/off of the electric motor of the pump.

Furthermore, in the present invention, the control circuit includes a self-holding contact connected in parallel to the pressure switch, an excitation coil connected in series to the pressure switch and the flow rate switch to drive the switch and the self-holding contact to open and close, and the control circuit configured to control the flow rate. and a timer having an output switch section connected in parallel to the switch.

Further, the timer is connected to the DC power supply section, and alternately repeats a time count time of a predetermined length and a time-up time shorter than the time count time, and closes the output switch section during the time count. The output switch is configured to include a circuit that opens the output switch section during time-up.

When the pressure switch is closed, the excitation coil is energized to close the switch and start the motor, and at the same time closes the self-holding contact. The timer is configured to supply DC power to the timer via the holding contact to continue the timer operation, and to cut off the power to the excitation coil when the timer overlaps with the opening operation of the flow rate switch. This is an automatic pump operation device that is characterized by:

[Effect]

In the automatic pump operation device configured as described above, when the pressure switch and the flow rate switch are closed, the excitation coil is energized and the switch for driving the motor is closed, so that the pump is started and the self-holding contact is closed. Also, since DC power is supplied to the timer at the same time as the pressure switch is closed, the timer repeats time counting and time-up.

When the excitation coil is energized and the self-holding contact is closed as described above, even if the pressure switch is subsequently opened, the current will continue to be energized through the self-holding contact and the switch will remain closed, so the pump will not operate. The operation continues, and the DC power supply to the timer continues. During time counting, the output switch section of the timer is closed, so even if the flow rate switch is opened, the excitation coil continues to be energized. but,
Since the output switch section is in an open state during time-up, if the flow rate switch is opened during time-up, the power to the excitation coil is cut off and the pump is stopped.

〔Example〕

The automatic operation device shown in FIG.
, a driving electric motor 2, and a switch 3. The switch 3 is connected to an input terminal 4 of an AC power source. The DC power supply unit 5 includes a transformer 6 that converts the AC power supply into DC power and lowers the voltage, a rectifier 7, and a smoothing capacitor 8.

A pressure switch 9 is provided in a pressure tank (not shown) connected to the discharge side of the pump 1. This pressure switch 9 closes when the tank internal pressure drops below a predetermined value, and opens when the tank internal pressure reaches a predetermined internal pressure. Further, a flow rate switch 10 is provided on the outflow side flow path of the pressure tank. The flow rate switch 10 is closed when the amount of water flowing out from the pressure tank exceeds a predetermined value, and opens when the amount of water falls below a predetermined value.

The pressure switch 9 and the flow rate switch 10
is connected in series with the excitation coil 11 that drives the switch 3 to open and close. A self-holding contact 12 which is driven to open and close by an excitation coil 11 is connected in parallel with the pressure switch 9.

The timer 13 includes a transistor 14 used as an output switch, a protective diode 15, a bias resistor 16, a diode 17, a time constant setting resistor 18 and a capacitor 19, and a protective resistor 2.
0, voltage dividing resistors 21, 22, PUT 23, etc. That is, by the excitation coil 11, self-holding contact 12, timer 13, etc.
A control circuit 25 is configured.

Next, the operation of the automatic driving device having the above configuration will be explained.

If the internal pressure of the pressure tank is high and the amount of water flowing out from the faucet or the like is below a predetermined value, the pressure switch 9 and the flow rate switch 10 are open. In this case, since the excitation coil 11 is in a de-energized state, the switch 3 and the self-holding contact 12 are both opened, and the motor 2
is in a stopped state. That is, the pump 1 is stopped.

In this state, if the amount of water flowing out from the pressure tank exceeds a predetermined value, the flow rate switch 1 will be activated.
0 is closed, both the pressure switch 9 and the self-holding contact 12 are open, so the excitation coil 11
is not energized. Therefore, the switch 3 is opened,
Pump 1 remains stopped. In this way, the flow rate switch 10 is closed when water continues to flow out from the pressure tank in an amount higher than a predetermined value, so when the tank internal pressure falls below the predetermined value and the pressure switch 9 is closed, the excitation The coil 11 is energized and the switch 3 and self-holding contact 12 are closed, so the electric motor 2 is activated and the pump 1 starts operating. As a result, if the internal pressure of the pressure tank rises above a predetermined value, the pressure switch 9 is opened, but since the self-holding contact 12 is closed, the excitation coil 11 remains energized. Therefore, since the switch 3 remains closed, the pump 1 does not stop.

On the other hand, when the pressure switch 9 is closed, the transistor 14 in the timer 13 becomes conductive, so in this state, even if the flow rate switch 10 is opened, the transistor 14, that is, the output switch section is in the closed state, so it is excited. The coil 11 remains energized, and the pump 1 continues to operate. However, as soon as the pressure switch 9 is closed, charging of the capacitor 19 via the resistor 18 begins. and resistor 18 and capacitor 1
When a predetermined time determined by the capacity of 9, that is, a relatively long time count time (for example, 10 seconds) has elapsed,
Since the capacitor 19 reaches a predetermined charging voltage,
Discharge is performed via PUT 23 in a short time (for example, 0.1 to 2.0 seconds). During this instantaneous time-up period, transistor 14 is reverse biased, so
Transistor 14 becomes non-conductive, ie, open. Therefore, if the flow rate switch 10 is also opened at this time, the excitation coil 11 becomes non-conductive, the switch 3 and the self-holding contact 12 are both opened, and the pump 1 is stopped.

In this manner, the timer 13 repeatedly charges and discharges the capacitor 19 during pump operation, thereby alternately repeating a relatively long time count time and a short time up time. It goes without saying that the above-mentioned time count period is set longer than a sufficient time for the operation of the flow rate switch 10 to stabilize. On the other hand, the time-up time is set longer than the time sufficient to ensure that the contacts of the switch 3 are restored.

FIG. 2 shows a general water supply pattern using the device of this embodiment. In the same figure, the amount of water used is Q ₁
When the flow rate switch 10 is reached, the flow rate switch 10 is closed. Further, when the internal pressure of the pressure tank drops to _H1 , the pressure switch 9 is closed. As can be seen from the figure, even if the timer output is turned off, the pump will not stop as long as the flow rate switch 10 is closed, but if the flow rate switch 10 is open when the timer output is turned off, the pump will not stop. 1 stops.

Fig. 3 shows a case where the amount of water flowing out from the pressure tank suddenly changes from large to small.As shown in this figure, when the flow rate switch 10 becomes unstable due to water hammer etc. Also, stable water supply is performed by the above-mentioned timer operation.

Moreover, according to the automatic operation device of the above configuration, the flow switch 10 that controls the switch 3 is supplied with power from the DC power supply unit 5 common to the timer 13, so a small capacity switch can be directly used for the flow switch 10, and there is no need to provide a protective electric valve for the flow switch 10 as in the case of using a conventional commercial AC power supply. Also, by sharing the power supply, the configuration of the power supply unit is simplified and can be manufactured at low cost. Furthermore, by sharing the power supply unit, the switch 3 can be used as an output relay for the timer 13. Therefore, it is possible to simplify the entire circuit, miniaturize the device, and reduce costs.

In addition, since the transistor 14 used as the output switch section and the flow rate switch 10 are connected in parallel with each other, the current is distributed to both switch elements, which reduces the burden on each switch element and improves the durability of the device. .

It should be noted that the present invention is not limited to the above-mentioned embodiments; for example, the electric motor 2 may be of a polyphase AC type. In addition, the DC power supply section 5 and the timer 13
etc., the design can be changed as appropriate.

[Effect of idea]

According to the present invention, stable starting and stopping operations are performed when starting and stopping the pump, so that unstable fluctuations in water hammer, etc. caused by sudden closing of a water faucet, for example, can cause the flow rate switch and pump to start and stop. This prevents any negative effects on water and provides a stable water supply.

In addition, a small-capacity flow rate switch can be used directly in the control circuit of the switch that starts and stops the pump drive motor, and the switch can also be used as a timer output relay, making the device more compact and structurally simple. It can contribute to simplification and cost reduction.

[Brief explanation of drawings]

Figure 1 is a circuit diagram showing one embodiment of the present invention;
3 and 3 are timing diagrams for explaining the operation of the apparatus shown in FIG. 1, respectively. 1... Pump, 2... Electric motor, 3... Switch,
5...DC power supply section, 9...Pressure switch, 10...
...Flow rate switch, 11...Excitation coil, 12...
Self-holding contact, 13...timer, 14...transistor (output switch section), 25...control circuit.

Claims (1)

[Claims for Utility Model Registration] An electric motor connected to an AC power source, a pump driven by the electric motor, a switch provided between the electric motor and the AC power source, and a discharge side of the pump. a pressure tank provided, a pressure switch that closes when the internal pressure of the pressure tank drops below a predetermined value and opens when it exceeds the predetermined internal pressure, and a DC power supply unit that converts the AC power supply to DC power; A flow rate switch that closes when the amount of water flowing out from the pressure tank is above a predetermined value and opens when it is below a predetermined value, and controls the electric motor of the pump on and off in response to output signals from the pressure switch and the flow rate switch. a control circuit, the control circuit comprising a self-holding contact connected in parallel to the pressure switch, and an excitation coil connected in series to the pressure switch and the flow rate switch to open and close the switch and the self-holding contact. and a timer having an output switch unit connected in parallel to the flow rate switch, the timer being connected to the DC power supply unit and having a time count time of a predetermined length and a timer having an output switch unit connected in parallel to the flow rate switch. A short time-up period is alternately repeated, and the circuit is configured to close the output switch section during time counting and open the output switch section during time-up, and the excitation coil is connected to the circuit when the pressure switch is closed. When the pressure switch is opened, it is energized to close the switch and start the motor, simultaneously closing the self-holding contact and supplying DC power to the timer through the self-holding contact even after the pressure switch is opened. automatic operation of the pump, characterized in that the pump is configured to supply electricity to continue the timer operation, and to cut off the energization to the excitation coil when the timer operation coincides with the opening operation of the flow rate switch. Device.