JP2021038730A - Submersible pump - Google Patents

Abstract

To provide a submersible pump that allows operation of a plurality of float switches to be easily checked.SOLUTION: A submersible pump comprises a plurality of float switches arranged at different heights from one another in a tank. The plurality of float switches include at least a first float switch capable of detecting a stopping water level for stopping operation of the submersible pump, and a second float switch capable of detecting a starting water level for starting the operation of the submersible pump, and higher than the stopping water level. The plurality of float switches include light emitting parts respectively. The light emitting parts of the plurality of float switches have different light emitting colors from one another.SELECTED DRAWING: Figure 4A

Description

The present invention relates to a submersible pump, particularly a submersible pump including a float switch.

Conventionally, for example, in a sewage tank where sewage is temporarily stored, a submersible pump may be installed for transferring or discharging sewage. As such a submersible pump, a submersible pump including a float switch for detecting the water level in the sewage tank and a control unit capable of starting / stopping the pump in response to a water level signal of the float switch is known.

The float switch comprises a float portion fixed to, for example, a vertical support rod of the submersible pump via a flexible cable. By changing the posture or position of the float portion according to the water level in the sewage tank, the reed switch as the water level detection unit provided in the float portion is turned on and off. The float switch can be provided, for example, corresponding to the starting water level at which the pump motor is started and the stopping water level at which the pump motor is stopped. When the water level in the sewage tank exceeds the starting water level, the control unit can start the pump motor by the on signal from the reed switch corresponding to the starting water level. Further, when the water level in the sewage tank falls below the stop water level, the control unit can be configured to stop the pump motor by an off signal from the reed switch corresponding to the stop water level (Patent Document 1).

It is necessary to check the operation of the float switch when installing the submersible pump. In addition, the operation of the float switch may be confirmed during the operation of the submersible pump. That is, it is confirmed whether the float switch is operated so that the pump motor can be started and stopped appropriately according to the water level in the sewage tank. The operating status of the pump motor can be confirmed by the amount of water discharged from the submersible pump, the drive current of the pump motor, or the like. This can be easily done by a control panel or the like arranged outside the sewage tank.

On the other hand, it is not easy to confirm the position of the float switch. The float switch is arranged in the vicinity of the submersible pump in the sewage tank (Patent Document 2). The sewage tank may have a depth of about 4 m, and in this case, it is difficult to visually recognize the float switch from the outside of the sewage tank. The float switch, which moves according to the water level in the sewage tank, changes its position in the vertical direction. Even if the inside of the sewage tank is illuminated from above the sewage tank using a lighting device such as a flashlight, it is difficult to visually recognize the vertical position of the float switch.

JP-A-2018-76850 JP-A-2018-62831

An object of the present invention is to provide a submersible pump capable of easily confirming the operation of a plurality of float switches.

According to one embodiment of the present invention, it is possible to provide a submersible pump including a plurality of float switches arranged at different heights in a tank. The plurality of float switches are at least a first float switch capable of detecting a stop water level for stopping the operation of the submersible pump and a second float switch capable of detecting a start water level higher than the stop water level for starting the operation of the submersible pump. Including switches. Each of the plurality of float switches includes a light emitting part, and the light emitting parts of the plurality of float switches have different emission colors from each other.

It is a vertical sectional view which shows an example of the submersible pump to which one Embodiment of this invention is applied. It is a schematic diagram which shows the pump device which includes the 1st and 2nd submersible pumps to which one Embodiment of this invention is applied. It is a timing chart which shows the operation of the pump device shown in FIG. 2 and the change of the water level in a tank. It is sectional drawing which shows an example of the structure of the float switch by one Embodiment of this invention, and is the figure which shows the upward posture of the float part. It is sectional drawing which shows an example of the structure of the float switch by one Embodiment of this invention, and is the figure which shows the downward posture of the float part. It is a block diagram which shows the schematic structure of the control part of the 1st submersible pump. It is a block diagram which shows the schematic structure of the control part of the 2nd submersible pump. It is a chart which shows the state of the float switch and the motor in the case where the 1st submersible pump is operated normally. It is a chart which shows the state of the float switch and the motor when the 2nd submersible pump is operated normally. It is a chart which shows the state of the float switch and the motor of the 1st submersible pump at the time of abnormal flooding. 6 is a chart corresponding to FIG. 6A showing a modified example of the embodiment of the present invention. It is a chart corresponding to FIG. 6B which shows the modification of embodiment of this invention. It is a chart corresponding to FIG. 6C which shows the modification of the Embodiment of this invention. It is a partial figure which shows an example of the structure of the float switch corresponding to the modification. It is a figure which shows the example of the use form of the submersible pump by one Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following description is merely an example, and does not mean that the technical scope of the present invention is limited to the following embodiments. Further, in the drawings, the same or corresponding components are designated by the same reference numerals, and duplicate description will be omitted. In the following description, the terms indicating the directions such as "up" and "down" mean the directions in the installed state of the submersible pump shown in FIG. 1 and the like.

FIG. 1 is a vertical sectional view showing an example of a submersible pump to which one embodiment of the present invention can be applied. The submersible pump 10 shown in FIG. 1 includes a motor unit 100 containing a motor inside and a pump unit 104 containing an impeller 102 inside. A spindle 106 of the motor is inserted inside the motor unit 100 and the pump unit 104, and an impeller 102 that rotates integrally with the spindle 106 is attached to the lower end of the spindle 106. As a result, the power of the motor unit 100 is transmitted to the impeller 102 of the pump unit 104.

The pump unit 104 includes an upper casing 108 having a discharge port 108a and a lower casing 110 having a suction port 110a, and the upper casing 108 and the lower casing 110 are fixed by, for example, a tapping screw 112. The impeller 102 described above is housed inside the pump chamber 112 formed by the upper casing 108 and the lower casing 110.

The upper surface of the motor unit 100 is covered with a motor cover 116, and a plurality of float switches 118 are attached to the motor cover 116 via a rod-shaped cable support 117. In the example of FIG. 1, two float switches 118 are provided, but the number of float switches 118 is not limited. The submersible pump 10 can be arranged, for example, in a sewage tank. The plurality of float switches 118 are arranged at different heights in the tank so that a plurality of water levels in the tank can be detected. Reference numeral 120 denotes a power cable for supplying electric power from an external power source (not shown) to the motor. Power is supplied to the motor via an external control device (not shown) connected to an external power source. The control device has a control unit that controls the operation of the motor, and is configured such that a cable 122 extending from the float switch 118 is connected to the control unit. However, the control unit may be installed inside the submersible pump 10 instead of the external control device.

FIG. 2 is a schematic view showing a pump device 200 including a plurality of submersible pumps to which one embodiment of the present invention is applied. In this example, a pump device 200 including two submersible pumps 201 and 202 for discharging water in a tank (not shown) to the outside is shown. However, the number of submersible pumps in the pump device 200 is not particularly limited. The submersible pumps 201 and 202 each include a plurality of float switches. Specifically, the first submersible pump 201 has three float switches (first float switch 210, second float switch 220, and third float switch 230). The second submersible pump 202 has two float switches (a fourth float switch 240 and a fifth float switch 250). However, the number of float switches provided in each of the submersible pumps 201 and 202 is not particularly limited. Further, the embodiment of the present invention can be applied to any of the first and second submersible pumps 201 and 202.

The first submersible pump 201 includes a first stop water level (hereinafter, stop water level) L1 at which the operation of the submersible pump 201 is stopped, and a first stop water level L1 at which the operation of the submersible pump 201 is started. A high first operation start water level (hereinafter, start water level) L2 and an abnormal water level L3 are set. In the second submersible pump 202, a second stop water level L4 at which the operation of the submersible pump 202 is stopped and a second start water level L5 at which the operation of the submersible pump 202 is started are set. The second starting water level L5 is set at a position higher than the first starting water level L2, and the second stop water level L4 is set at a position higher than the first stop water level L1. However, the second stop water level L4 and the first stop water level L1 may be set at the same position. However, at the first and second stop water levels L1 and L4, the first and second submersible pumps 201 and 202 are operated by air (specifically, air enters the pump chamber from the suction port of the pump). Is set to a height that does not have. The abnormal water level L3 is set at a position higher than the second starting water level L5.

As an example, when the water level in the tank in which the submersible pumps 201 and 202 are installed exceeds the first starting water level L2, the second float switch 220 is turned on (that is, the reed switch as the water level detector is turned on). Become). Upon receiving the ON signal of the second float switch 220, the control unit of the first submersible pump 201 starts the operation of the first submersible pump 201 once every predetermined number of times. In the present embodiment, the operation of the first submersible pump 201 is set to start once every two times with respect to the ON signal of the second float switch 220.

When the water level in the tank falls below the first stop water level L1, the first float switch 210 is turned off (that is, the reed switch as the water level detector is turned off), and the off signal of the first float switch 201 is turned off. The control unit of the first submersible pump 201 that has received the response stops the operation of the first submersible pump 201. When the water level in the tank exceeds the abnormal water level L3, the third float switch 230 is turned on (that is, the reed switch as the water level detection unit is turned on), and the on signal of the third float switch 230 is received. The control unit of the first submersible pump 201 starts operation if the first submersible pump 201 is stopped.

Further, when the water level in the tank exceeds the second starting water level L5, the fifth float switch 250 is turned on (that is, the reed switch as the water level detection unit is turned on), and the fifth float switch 250 Upon receiving the ON signal, the control unit of the second submersible pump 202 starts the operation of the second submersible pump 202. Further, when the water level falls below the second stop water level L4, the fourth float switch 240 is turned off (that is, the reed switch as the water level detection unit is turned off), and the off signal of the fourth float switch 240 is sent. The control unit of the second submersible pump 202 that has received it stops the operation of the second submersible pump 202.

Next, the basic operation of the pump device 200 having such a configuration will be described with reference to FIG. FIG. 3 is a timing chart showing the operation of the pump device 200 shown in FIG. 2 and the change in the water level in the tank.

First, it is assumed that the water level in the tank in which the first and second submersible pumps 201 and 202 are installed is below the first stop water level L1. In this state, when a liquid such as sewage flows into the tank and the water level in the tank rises and exceeds the first starting water level L2, the second float switch 220 is turned on and the first submersible pump 201 The operation is started (P1). By operating the first submersible pump 201, the water in the tank is discharged, and the water level in the tank drops. When the water level in the tank falls below the first stop water level L1, the first float switch 210 is turned off and the operation of the first submersible pump 201 is stopped (P2).

In this state, when the liquid flows into the tank and the water level in the tank rises to exceed the first starting water level L2, the second float switch 220 is turned on, but in the present embodiment, the second float switch 220 is turned on. Since the operation of the first submersible pump 201 is set to start once every two times with respect to the ON signal of the float switch 220, the operation of the first submersible pump 201 is not started this time ( P3). When the water level further rises and exceeds the second starting water level L5, the fifth float switch 250 is turned on and the operation of the second submersible pump 202 is started (P4). By operating the second submersible pump 202, the liquid in the tank is discharged, and the water level in the tank drops. When the water level in the tank falls below the second stop water level L4, the fourth float switch 240 is turned off and the operation of the second submersible pump 202 is stopped (P5).

In this state, when the liquid flows into the tank and the water level in the tank rises and exceeds the first starting water level L2, the second float switch 220 is turned on and the first submersible pump is turned on in the same manner as described above. The operation of 201 is started (P6). In this way, the first submersible pump 201 and the second submersible pump 202 are automatically operated alternately.

As described above, when the water level in the tank exceeds the second starting water level L5, the operation of the second submersible pump 202 is started, but the inflow amount of the liquid into the tank is due to the second submersible pump 202. If it exceeds the discharge, the water level in the tank will continue to rise. When the water level in the tank exceeds the abnormal water level L3, the third float switch 230 is turned on and the operation of the first submersible pump 201 is started (P7). Therefore, both the first submersible pump 201 and the second submersible pump 202 are operated, and the liquid in the tank is discharged.

When the water level in the tank drops due to the operation of these two submersible pumps 201 and 202 and falls below the second stop water level L4, the fourth float switch 240 is turned off and the operation of the second submersible pump 202 is stopped. (P8). The first submersible pump 201 is operated as it is, and when the water level falls below the first stop water level L1, the first float switch 210 is turned off and the operation of the first submersible pump 201 is stopped (P9). In this way, when the water level in the tank exceeds the abnormal water level L3, the two submersible pumps 201 and 202 are operated at the same time, and a large amount of liquid can be discharged from the tank.

4A and 4B are cross-sectional views showing a configuration example of a float switch used in the first and second submersible pumps 201 and 202 together with a usage state. Here, the float switch 210 will be described as an example, but the float switches 210, 220, 230, 240, and 250 have substantially the same configuration. The float switch 210 includes a float portion having an upper case 302 made of a transparent or translucent material and a lower case 304. The float portion has a base end portion having a substantially conical outer shape formed mainly by the lower case 304 and a tip portion having a substantially hemispherical outer shape formed by the upper case 302. One end of the flexible cable 314 is arranged at the base end. The other end of the cable 314 is connected to a control device that controls the operation of the submersible pumps 201 and 202. The cable 314 is fixed to the submersible pumps 201, 202 via an appropriate support (see 117 in FIG. 1). A movable magnet 310 is arranged on the outer circumference of the inner case 312 that houses the detection unit 308 of the reed switch. In the inner case 312, the detection unit 308 is electrically connected to the cable 314 via the substrate 316 and is positioned and fixed in the inner case 312 by an appropriate means. A light emitting portion (LED in this embodiment) 318 is arranged inside the tip portion of the float portion. In the present embodiment, the light emitting unit 318 is fixed to the inner case 312 at a position facing the inner surface of the upper case 302. The light emitting unit 318 is electrically connected to the control device via the substrate 316 by a signal line separate from the detection unit 308. However, in other embodiments, the light emitting unit 318 may be electrically connected to the control device via the substrate 316 by the same signal line as the detection unit 308 (ie, connected in series in the same circuit). .. Reference numeral 306 is a floating member such as polyethylene foam.

The posture or position of the float switch 210 changes as the float portion tilts upward (FIG. 4A) or downward (FIG. 4B) according to the water level in the tank. Specifically, when the float switch 210 is floating or submerged in water, the float switch 210 tilts upward so that the tip end portion of the float portion is located above the base end portion. Further, when the float switch 210 is exposed to the air, the float switch 210 is tilted downward so that the tip end portion of the float portion is located below the base end portion.

In the illustrated example, the magnet 310 is configured to be slidable along the inner case 312. Therefore, when the water level in the tank exceeds a predetermined water level, the magnet 310 moves downward toward the base end portion of the float portion in the float portion that is upward as shown in FIG. 4A, and the detection unit 308. Adjacent to. As a result, the detection unit 308 generates an ON signal. Further, when the water level in the tank falls below a predetermined water level, the magnet 310 moves downward toward the tip of the float portion and separates from the detection portion 308 in the float portion which is downward as shown in FIG. 4B. .. As a result, the detection unit 308 generates an off signal. In this embodiment, the reed switch is configured as a so-called a contact type (normally open contact) type. However, the reed switch may be a so-called b-contact type (normally closed contact) type.

As will be described later, in the present embodiment, the light emitting units 318 of the float switches 210, 220, 230, 240, and 250 have different light emitting colors. Further, the light emitting unit 318 can be switched between a lighting state and an extinguishing state, or a lighting state, a blinking state, and an extinguishing state according to the water level in the tank.

The light emitting unit 318 and the detection unit 308 of the float switches 210, 220, 230, 240, 250 of the submersible pumps 201 and 202 are electrically connected to the control unit of the control device that controls the motors of the submersible pumps 201 and 202, respectively. Has been done. 5A and 5B are block diagrams showing a configuration example of a control unit of the submersible pumps 201 and 202 according to the present embodiment. FIG. 5A shows a configuration example of the first submersible pump 201, and FIG. 5B shows a configuration example of the second submersible pump 202.

As shown in FIG. 5A, in the first submersible pump 201, the detection unit (reed switch in this embodiment) 308 and the light emitting unit (LED in this embodiment) 318 of the float switches 210, 220, and 230 are respectively. It is electrically connected to the control unit 400 of the control device that controls the motor 402 of the submersible pump 201. The control unit 400 includes a processing unit 404 that controls the motor 402 based on preset data such as a pump rated current value and a control program. The detection unit 308 and the light emitting unit 318 are each electrically connected to the processing unit 404. The control unit 400 also includes a recording unit 406 that can record various operation histories such as the start / stop of the motor 402, the current value, and the failure state.

The processing unit 404 is configured to process the signal from the detection unit 308 and output a drive signal for driving the motor 402. Further, the processing unit 404 sets the light emitting unit 318 in the lit state and the extinguished state, or in the lit state, the blinking state, and the extinguished state based on the signal from the detection unit 308 for each of the float switches 210, 220, and 230. It is configured to generate a signal for switching control between. The processing unit 404 can refer to the history information of the recording unit 406 for the switching control of the light emitting unit 318.

In the present embodiment, the processing unit 404 uses the light emitting unit 318 of the float switch 220 corresponding to the starting water level L2 and the float switch 230 corresponding to the abnormal water level L3 to record the history information of the motor 402 recorded in the recording unit 406. Switching control is performed while referring to it. Specifically, when an off signal is input from the float switch 220 (that is, when the water level in the tank falls below the starting water level L2), the processing unit 404 sends the light emitting unit 318 while the motor 402 is operating. It blinks, and then the light emitting unit 318 is turned off when the motor 402 is stopped. Further, when an off signal is input from the float switch 230 (that is, when the water level in the tank falls below the abnormal water level L3), the light emitting unit 318 blinks while the motor 402 is operating, and then the motor 402 blinks. When stopped, the light emitting unit 318 is turned off. For the input of the on signal, the processing unit 404 lights the light emitting unit 318 for each of the float switches 220 and 230 without referring to the history information of the motor 402. Regarding the float switch 210, when an on signal is input, the light emitting unit 318 is turned on, and when an off signal is input, the light emitting unit 318 is turned off.

Further, the control unit 500 of the second submersible pump 202 also has substantially the same configuration as the control unit 400. As shown in FIG. 5B, in the second submersible pump 202, the detection unit 308 and the light emitting unit 318 of the float switches 240 and 250 each electrify the control unit 500 of the control device that controls the motor 502 of the submersible pump 202. Is connected. The control unit 500 includes a processing unit 504 that controls the motor 502 based on preset data such as a pump rated current value and a control program. The detection unit 308 and the light emitting unit 318 are electrically connected to the processing unit 504, respectively. The control unit 500 also includes a recording unit 506 that can record various operation histories such as operation / stop, current value, and failure state of the motor 502.

The processing unit 504 is configured to process the signal from the detection unit 308 and output a drive signal for driving the motor 502. Further, for each of the float switches 240 and 250, the processing unit 504 sets the light emitting unit 318 between the lit state and the extinguished state, or between the lit state, the blinking state and the extinguished state, based on the signal from the detecting unit 308. It is configured to generate a signal for switching control. The processing unit 504 can refer to the history information of the recording unit 506 for the switching control of the light emitting unit 318.

In the present embodiment, the processing unit 504 switches and controls the light emitting unit 318 of the float switch 250 corresponding to the starting water level L5 with reference to the information of the motor 502 recorded in the recording unit 506. Specifically, when an off signal is input from the float switch 250 (that is, when the water level in the tank falls below the starting water level L5), the processing unit 504 sends the light emitting unit 318 while the motor 502 is operating. It blinks, and then the light emitting unit 318 is turned off when the motor 502 is stopped. In response to the input of the on signal of the float switch 250, the processing unit 504 lights the light emitting unit 318 without referring to the history information of the motor 502. Regarding the float switch 240, when the on signal is input, the light emitting unit 318 is turned on, and when the off signal is input, the light emitting unit 318 is turned off.

FIG. 6A shows the lighting state of the light emitting portions of the first, second and third float switches 210, 220 and 230 and the operation of the motor 402 according to the water level in the tank during the normal operation of the first submersible pump 201. It is a chart which shows the state. FIG. 6B is a chart showing the lighting state of the light emitting portions of the fourth and fifth float switches 240 and 250 and the operating state of the motor 502 according to the water level in the tank during the normal operation of the second submersible pump 202. Yes, in the figure, the reference numeral for the light emitting portion is the reference numeral of the corresponding float switch. Further, regarding the light emitting unit, ON means a lighting state, OFF means an extinguishing state, and ON / OFF means a blinking state. The emission color of the light emitting part is different from each other for all float switches. In the present embodiment, the emission color is determined as follows. However, the specific combination of emission colors is not particularly limited.

1st Float Switch 210 Red 2nd Float Switch 220 Blue 3rd Float Switch 230 Yellow 4th Float Switch 240 Green 5th Float Switch 250 Orange

When the water level in the tank is lower than the first stop water level L1, the motors 402 and 502 of the first and second submersible pumps 201 and 202 are stopped and all the float switches are turned off (FIG. FIG. State 1 of 6A, state 1) of FIG. 6B.

When the liquid flows into the tank in this state and the water level in the tank exceeds the first stop water level L1, an ON signal is input from the first float switch 210 to the processing unit 404 of the first submersible pump 201. , The processing unit 404 turns on the first float switch 210 (state 2 in FIG. 6A, state 1 in FIG. 6B). At this time, the inspector can easily visually recognize that the water level in the tank is between the first stop water level L1 and the second stop water level L4 (section A in FIG. 3) by the red emission color. it can. When the water level rises further and exceeds the second stop water level L4, an on signal is input from the fourth float switch 240 to the processing unit 504 of the second submersible pump 202, and the processing unit 504 receives the fourth float. The switch 240 is turned on (state 2 in FIG. 6A, state 2 in FIG. 6B). At this time, the green emission color allows the inspector to easily visually recognize that the water level is between the second stop water level L4 and the first start water level L2 (section B in FIG. 3). When the water level exceeds the first starting water level L2, an ON signal is input from the second float switch 220 to the processing unit 404 of the first submersible pump 201. The processing unit 404 starts the motor 402 of the first submersible pump 201 based on this ON signal. Further, the processing unit 404 lights the second float switch 220 based on the ON signal (state 3 in FIG. 6A, state 2 in FIG. 6B). The blue emission color allows the inspector to easily see that the water level is between the first starting water level L2 and the second starting water level L5 (section C in FIG. 3).

When the water level falls below the first starting water level L2 due to the operation of the first submersible pump 201, an off signal is input to the processing unit 404 from the second float switch 220. At this time, since the motor 402 is in the operating state from the information of the recording unit 406, the processing unit 404 blinks the second float switch 220 (state 4 in FIG. 6A, state 2 in FIG. 6B). By blinking blue, the inspector can confirm that the water level tends to decrease between the first starting water level L2 and the second stopping water level L4 (section B in FIG. 3) (temporarily the second). When the float switch 220 is turned off, the float switches 210, 220, and 230 are in the same lighting state as the state 2 of FIG. 6A described above, so that the water level is between the second stop water level L4 and the first start water level L2. It can be confirmed that there is, but it is not possible to confirm the tendency of the water level to increase or decrease).

When the water level continues to fall and falls below the second stop water level L4, the fourth float switch 240 generates an off signal, and the processing unit 504 turns off the fourth float switch 240 (state 4 in FIG. 6A, State 1) in FIG. 6B. Therefore, the inspector can confirm that the water level is between the second stop water level L4 and the first stop water level L1 (section A in FIG. 3) by the red emission color of the first float switch 210. The inspector can also confirm that the water level is decreasing due to the continuous blinking of blue.

When the water level falls below the first stop water level L1, the first float switch 210 generates an off signal, and the processing unit 404 stops the first submersible pump 201 and turns off the first float switch 210. .. Further, from the information of the recording unit 406, since the motor 402 is in the stopped state, the processing unit 404 turns off the blinking second float switch 220. As a result, all the float switches are turned off (state 5 in FIG. 6A, state 1 in FIG. 6B).

When the water level rises again, the light emitting unit lights up in the order of the first float switch 210 and the fourth float switch 240 (state 6 in FIG. 6A, state 2 in FIG. 6B). Then, when the water level exceeds the first starting water level L2, the second float switch 220 generates an on signal, but in the present embodiment, the first submersible pump 201 sends the on signal of the second float switch 220. On the other hand, it is set to be activated once every two times. Therefore, the motor 402 does not start, and the second float switch 220 lights up (state 7 in FIG. 6A, state 2 in FIG. 6B).

Since the motor 402 does not start, the water level continues to rise above the first starting water level L2. When the water level exceeds the second starting water level L5, the processing unit 504 of the second submersible pump 202 starts the motor 502 and lights the fifth float switch 250 in response to the ON signal of the fifth float switch 250. (State 7 in FIG. 6A, state 3 in FIG. 6B). The orange emission color allows the inspector to visually recognize that the water level is between the second starting water level L5 and the abnormal water level L3 (section D in FIG. 3). When the water level falls below the second starting water level L5 due to the operation of the motor 502, the fifth float switch 250 generates an off signal. At this time, since the motor 502 is in the operating state from the information of the recording unit 506, the processing unit 504 blinks the fifth float switch 250 (state 7 in FIG. 6A, state 4 in FIG. 6B). As a result, the inspector can confirm that the water level tends to decrease between the second starting water level L5 and the first starting water level L2 (section C in FIG. 3). When the water level is further lowered by the operation of the motor 502 and the water level falls below the first starting water level L2, the off signal of the second float switch 220 is input to the processing unit 404. At this time, since the motor 402 is in the stopped state from the information of the recording unit 406, the processing unit 404 turns off the second float switch 220 (state 8 in FIG. 6A, state 4 in FIG. 6B). As a result, the inspector can confirm that the water level is between the first starting water level L2 and the second stopping water level L4 (section B in FIG. 3). Further, since the fifth float switch 250 continues to blink, the inspector can confirm that the water level is decreasing.

When the water level further drops and the fourth float switch 240 generates an off signal, the processing unit 504 turns off the fourth float switch 240 and stops the motor 502. Further, based on the information of the recording unit 506, the processing unit 504 turns off the blinking fifth float switch 250 (state 8 in FIG. 6A, state 5 in FIG. 6B). Further, when the first float switch 210 generates an off signal, the processing unit 404 turns off the first float switch 210 (state 9 in FIG. 6A, state 5 in FIG. 6B), whereby all the float switches are turned off. Turns off. After that, this operation is repeated.

FIG. 6C shows the lighting state of the light emitting portion of the first submersible pump 201 and the operating state of the motor when the water level rises abnormally. While the second submersible pump 202 is in operation, the first submersible pump 201 is in a stopped state (states 13, 14, 15 in FIG. 6C). However, even though the second submersible pump 202 is started, the water level may continue to rise beyond the second starting water level L5. In that case, the first submersible pump 201 is also started. Specifically, when the water level exceeds the abnormal water level L3, an ON signal of the third float switch 230 is input to the processing unit 404 of the first submersible pump 201, and the processing unit 404 starts the motor 402. Further, the processing unit 404 turns on the third float switch 230 (state 16 in FIG. 6C). The yellow emission color allows the inspector to visually recognize that the water level has risen abnormally. When the water level drops due to the operation of the motors 402 and 502 and falls below the abnormal water level L3, an off signal of the third float switch 230 is input to the processing unit 404. From the information of the recording unit 406, since the motor 402 is in the operating state, the processing unit 404 blinks the third float switch 230 (state 17 in FIG. 6C). By blinking yellow, the inspector can visually recognize that the water level is decreasing from the abnormal water level.

When the water level falls below the second starting water level L5, an off signal of the fifth float switch 250 is input to the processing unit 504, but the motor 502 is in the operating state based on the information of the recording unit 506. Therefore, the processing unit 504 blinks the fifth float switch 250 (state 4 in FIG. 6B). By blinking orange, the inspector can visually recognize that the water level is decreasing from the second starting water level L5. When the water level falls below the first starting water level L2, the off signal of the second float switch 220 is input to the processing unit 404, but the motor 402 is in the operating state from the information of the recording unit 406. Therefore, the processing unit 404 blinks the second float switch 220 (state 18 in FIG. 6C). By blinking blue, the inspector can visually recognize that the water level is decreasing from the first starting water level L2.

When the water level falls below the second stop water level L4, the processing unit 504 turns off the fourth float switch 240 and stops the motor 502 based on the off signal of the fourth float switch 240. Further, when the motor 502 is stopped, the processing unit 504 turns off the blinking fifth float switch 250 (state 5 in FIG. 6B).

Further, when the water level falls below the first stop water level L1, the processing unit 404 turns off the first float switch 210 and stops the motor 402 based on the off signal of the first float switch 210. Further, the processing unit 404 turns off the blinking second and third float switches 220 and 230 when the motor 402 is stopped (state 19 in FIG. 6C). In this way, the motors 402 and 502 are stopped, and all the float switches are turned off.
In the above embodiment, the light emitting pattern of the light emitting unit 220 may be changed in each of the state 7 of FIG. 6A and the state 15 of FIG. 6C. Specifically, in each of the states 7 and 15, the display state of the light emitting unit 220 can be changed from the lighting state to the blinking state. In that case, the blinking light emission cycle can be changed to 1/2 cycle of the light emission cycle of the state 4.

7A to 7C are charts corresponding to FIGS. 6A to 6C showing the lighting state of the light emitting portion of each float switch and the operating state of the motor according to the modified example of the above embodiment. In this modification, in the first and second submersible pumps 201 and 202, the operation of the light emitting portion of the first float switch 210 and the fourth float switch 240 corresponding to the first and second stop water levels L1 and L4. The conditions are reversed. Specifically, when the float unit is in the upward posture shown in FIG. 4A (when the detection unit generates an ON signal), the light emitting unit is turned off, and when the float unit is in the downward posture shown in FIG. 4B (detection unit). The light emitting unit is configured to light up when an off signal is generated. During normal operation, the water level in the tank is often above the stop water level of the submersible pump. Therefore, by configuring the light emitting unit to turn off the light when the float unit is in the upward posture, the power consumption by the light emitting unit can be saved. In FIGS. 7A to 7C, it can be seen that the lighting states of the first and fourth float switches 210 and 240 are reversed with respect to FIGS. 6A to 6C.
In the above modified example, the light emitting pattern of the light emitting unit 220 may be changed in each of the state 7 of FIG. 7A and the state 15 of FIG. 7C. Specifically, in each of the states 7 and 15, the display state of the light emitting unit 220 can be changed from the lighting state to the blinking state. In that case, the blinking light emission cycle can be changed to 1/2 cycle of the light emission cycle of the state 4.

FIG. 8 is a partial view showing a configuration example of the first and fourth float switches 210 and 240 in the above modification. In FIG. 8, a detection unit 320 is provided in place of the detection unit 308 shown in FIGS. 4A and 4B. The detection unit 320 is arranged near the tip of the float unit. As a result, when the float portion is in the upward posture, the movable magnet 310 moves away from the detection portion 320 and moves to the base end portion side of the float portion, so that the detection unit 320 can be turned off. Further, when the float portion is in the downward posture, the movable magnet 310 moves to the tip end side of the float portion so as to be adjacent to the detection unit 320, so that the detection unit 320 can be turned on.

FIG. 9 shows an example of how to use the submersible pump according to the embodiment of the present invention. FIG. 9 is a schematic view of a drainage facility (foul odor prevention type drainage facility) in which a submersible pump 1200 according to an embodiment of the present invention is arranged. In this facility, the sewage tank 1010 is used as a drainage facility for the basement portion F of a building 1100 such as a building. As shown in FIG. 9, the sewage tank 1010 is provided in the pit Pi, which is a drainage tank installed under the basement portion F of the building (for example, a building) 1100. An opening (manhole) 1102 is formed in the pit Pi, and a lid 1103 is attached to the opening 1102. In the example shown in FIG. 9, a plurality of sewage tanks 1010 are arranged in the pit Pi, but one sewage tank 1010 may be arranged in the pit Pi. In the example of FIG. 9, a plurality of sewage tanks 1010 are connected to each other by a communication pipe 1300, one of which is connected to an inflow pipe 1101 for receiving sewage from the basement portion F, and the like. One of the water tanks 1010 is connected to a discharge pipe composed of a vertical pipe 1104, and a submersible pump 1200 is installed in the sewage tank 1010. The sewage is pumped into the sewage basin 191 and 193 by the submersible pump 1200 and drained to the public sewer pipe 180 via the sewage basin 191, 193. The submersible pump 1200 includes a plurality of float switches. The sewage tank 1010 may have a depth of about 4 m. Since the plurality of float switches are provided with light emitting parts having different emission colors, the position of the float switch can be confirmed even from the upper part of the sewage tank 1010 having a large depth, and the operation of the float switch can be confirmed. It can be done easily.

In the above embodiment, with respect to the float switch corresponding to the starting water level and the float switch corresponding to the abnormal water level, the light emitting unit is in a lit state, a blinking state, and a blinking state based on the on / off signal of the detection unit and the start / stop state of the motor. It is switched between the off state. However, according to another embodiment of the present invention, the blinking state can be omitted. That is, for all float switches, the light emitting unit may be switched between a lighting state and an extinguishing state. In this case, the processing unit can turn on the light emitting unit when an on signal from the detection unit is input and turn off the light emitting unit when an off signal is input, without referring to the history information of the motor.

Further, according to another embodiment of the present invention, switching of the display state of the light emitting unit (that is, switching between the lit state and the extinguished state, or switching between the lit state, the blinking state, and the extinguished state) is performed. It may be stopped if necessary. When the switching of the display state of the light emitting unit is stopped, the light emitting unit is maintained in the extinguished state. For this purpose, for example, the control unit may be configured such that the light emitting unit can be switched between the operation mode and the stop mode. Switching between the operation mode and the stop mode may be automatically performed by the control unit, or may be manually performed via a control panel or the like.
Further, according to another embodiment of the present invention, a circuit configuration in which the light emitting unit is connected in series to the detection unit is provided in the float unit so that the lighting / extinguishing of the light emitting unit is directly linked to the on / off of the detection unit. Can be incorporated. In this case, the light emitting unit does not have to be controlled by the control unit. Further, when the lighting / extinguishing of the light emitting unit is directly linked to the on / off of the detection unit, the light emitting unit may be switched between the lighting state and the extinguishing state without blinking. Further, the switching of the display state of the light emitting unit may be stopped as needed, and the switching unit for switching may be provided in the float unit (for example, the substrate unit).

Although the embodiments of the present invention have been described above, the above-described embodiments of the invention are for facilitating the understanding of the present invention and do not limit the present invention. The present invention can be modified and improved without departing from the spirit thereof, and it goes without saying that the present invention includes an equivalent thereof. In addition, any combination or omission of the claims and the components described in the specification is possible within the range in which at least a part of the above-mentioned problems can be solved, or in the range in which at least a part of the effect is exhibited. Is.

The present invention includes the following aspects.
1. 1. A submersible pump with multiple float switches located in the tank at different heights.
Multiple float switches, at least
The first float switch that can detect the stop water level that stops the operation of the submersible pump,
Including a second float switch capable of detecting a starting water level higher than the stopping water level, which starts the operation of the submersible pump.
Each of the multiple float switches includes a light emitting part,
A submersible pump in which the light emitting parts of multiple float switches have different light emitting colors from each other.
2. Above 1. The submersible pump described in
A submersible pump in which the light emitting part of a plurality of float switches can be switched between a lit state and an extinguished state, or a lit state, a blinking state, and an extinguished state, respectively, depending on the water level in the tank.
3. 3. Above 2. The submersible pump described in
Equipped with a control unit that controls the motor that drives the submersible pump
The light emitting unit is a submersible pump that can be switched between a lighting state and an extinguishing state, or a lighting state, a blinking state, and an extinguishing state by a signal from a control unit.
4. Above 3. The submersible pump described in
When the water level in the tank falls below the starting water level, the control unit blinks the light emitting part of the second float switch while the motor is operating, and then emits light from the second float switch when the motor stops. A submersible pump that is configured to turn off the lights.
5. Above 4. The submersible pump described in
Includes a third float switch that can detect abnormal water levels above the starting water level
When the water level in the tank falls below the abnormal water level, the control unit blinks the light emitting part of the third float switch while the motor is operating, and then emits light from the third float switch when the motor stops. A submersible pump that is configured to turn off the lights.
6. Above 3. ~ 5. The submersible pump described in any of
The light emitting unit is configured to be switchable between an operation mode and a stop mode by a control unit, and the light emitting unit is switched between a lighting state and an extinguishing state, or a lighting state, a blinking state, and an extinguishing state in the operation mode. A submersible pump that is possible and remains off in stop mode.
7. Above 2. The submersible pump described in
A submersible pump in which each of the light emitting parts of a plurality of float switches can be switched between a lit state and an extinguished state in conjunction with the on / off of the reed switch built in the float switch.
8. 7. Above. The submersible pump described in
A switching unit for switching the light emitting unit between the operation mode and the stop mode is provided in the float switch, and the light emitting unit can be switched between the lit state and the extinguished state in the operation mode, and the stop mode. A submersible pump that is kept off at.
9. Above 2. ~ 8. The submersible pump described in any of
The light emitting part of the first float switch is a submersible pump configured to turn off when the water level in the tank exceeds the stop water level and turn on when the water level in the tank falls below the stop water level.
10. Above 1. ~ 9. The submersible pump described in any of
The float switch is a submersible pump having a float portion having a substantially conical base end portion and a substantially hemispherical tip portion, and a light emitting portion provided inside the tip portion of the float portion.
11. 10. The submersible pump described in
A submersible pump in which the tip of the float is made of a transparent or translucent material.
12. Above 1. ~ 11. The submersible pump described in any of
The light emitting part is a submersible pump equipped with an LED.
13. It is a pump device equipped with multiple submersible pumps.
At least one of the multiple submersible pumps is described in 1. ~ 12. The submersible pump described in any of
A pumping device in which all of the light emitting parts of the float switch of at least one submersible pump have different emission colors from each other.

The present invention can be widely applied to a submersible pump having a plurality of float switches.

A, B, C, D Section F Basement part L1 First stop water level L2 First start water level L3 Abnormal water level L4 Second stop water level L5 Second start water level Pi Pit 10 Submersible pump 100 Motor unit 102 Impeller 104 Pump part 106 Main shaft 108 Upper casing 108a Discharge port 110 Lower casing 110a Suction port 112 Tapping screw 116 Motor cover 117 Cable support 118 Float switch 120 Power cable 122 Cable 180 Public sewer pipe 191 and 193 Sewage pump 200 Pump device 201 1st Submersible pump 202 Second submersible pump 210 First float switch 220 Second float switch 230 Third float switch 240 Fourth float switch 250 Fifth float switch 302 Upper case 304 Lower case 306 Floating member 308 Detection unit 310 Magnet 312 Internal case 314 Cable 316 Board 318 Light emitting unit 320 Detection unit 400, 500 Control unit 402, 502 Motor 404, 504 Processing unit 406, 506 Recording unit 1200 Submersible pump 1010 Sewage tank 1100 Building 1101 Inflow pipe 1102 Opening 1103 Lid 1104 Vertical pipe 1300 Communication pipe

Claims (13)

A submersible pump with multiple float switches located in the tank at different heights.
The plurality of float switches are at least
A first float switch capable of detecting the stop water level at which the operation of the submersible pump is stopped, and
A second float switch capable of detecting a starting water level higher than the stopped water level, which starts the operation of the submersible pump, is included.
Each of the plurality of float switches includes a light emitting unit and includes a light emitting unit.
A submersible pump in which the light emitting portions of the plurality of float switches have different light emitting colors from each other. The submersible pump according to claim 1, wherein the light emitting units of the plurality of float switches are in a lit state and an extinguished state, or in a lit state, a blinking state, and an extinguished state, respectively, depending on the water level in the tank. Submersible pump that can be switched between. The submersible pump according to claim 2.
A control unit for controlling a motor for driving the submersible pump is provided.
The submersible pump is capable of switching between a lit state and an extinguished state, or a lit state, a blinking state and an extinguished state by a signal from the control unit. The submersible pump according to claim 3.
When the water level in the tank falls below the starting water level, the control unit blinks the light emitting unit of the second float switch while the motor is operating, and then when the motor stops, the control unit blinks the light emitting unit. A submersible pump configured to turn off the light emitting part of the second float switch. The submersible pump according to claim 4.
A third float switch capable of detecting an abnormal water level higher than the starting water level is included.
When the water level in the tank falls below the abnormal water level, the control unit blinks the light emitting unit of the third float switch while the motor is operating, and then when the motor stops, the control unit blinks the light emitting unit. A submersible pump configured to turn off the light emitting part of the third float switch. The submersible pump according to any one of claims 3 to 5.
The light emitting unit is configured to be switchable between an operation mode and a stop mode by the control unit, and the light emitting unit is in a lit state and an extinguished state, or in a lit state, a blinking state, and an extinguished state in the operation mode. A submersible pump that can be switched between and remains off in said stop mode. The submersible pump according to claim 2.
A submersible pump in which each of the light emitting units of the plurality of float switches can be switched between a lighting state and an extinguishing state in conjunction with the on / off of a reed switch built in the float switch. The submersible pump according to claim 7.
A switching unit for switching the light emitting unit between the operation mode and the stop mode is provided in the float switch, and the light emitting unit can be switched between a lighting state and an extinguishing state in the operation mode. A submersible pump that is present and is maintained in the extinguished state in the stop mode. The submersible pump according to any one of claims 2 to 8.
The light emitting unit of the first float switch is a submersible pump configured to turn off when the water level in the tank exceeds the stop water level and turn on when the water level in the tank falls below the stop water level. The submersible pump according to any one of claims 1 to 9.
The float switch is a submersible pump having a float portion having a substantially conical base end portion and a substantially hemispherical tip portion, and the light emitting portion is provided inside the tip portion of the float portion. The submersible pump according to claim 10.
A submersible pump in which the tip of the float portion is made of a transparent or translucent material. The submersible pump according to any one of claims 1 to 11.
The light emitting unit is a submersible pump including an LED. It is a pump device equipped with multiple submersible pumps.
The submersible pump according to any one of claims 1 to 12, wherein at least one of the plurality of submersible pumps is a submersible pump.
A pumping device in which all of the light emitting parts of the float switch of the at least one submersible pump have different emission colors from each other.

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