KR101817326B1 - Sewage relay pump system - Google Patents

Abstract

The present invention relates to a sewage relay pump system. In a first control mode, when a water level of a relay pump station becomes higher than a reference value of a high water level, the relay pump is operated to control the water level to be lower than a reference value of a low water level. In a second control mode, even when the water level of the relay pump station is lower than the reference value of the high water level, but is greater than the reference value of the low water level, the relay pump is operated to control the water level to be lower than the reference value of the low water level. A time zone for operating in the first control mode and a time zone for operating in the second control mode can be set.

Description

[0001] SEWAGE RELAY PUMP SYSTEM [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a sewerage relay pump system, and more particularly, to a sewerage pump system in which a different control mode can be set for each time zone.

Generally, the sewage is designed and constructed to flow to a natural gradient through a sewer pipe or a conduit, so that when the length of the sewer pipe becomes long, the depth of the sewer pipe is deepened.

 If it can not flow from the end of the sewer pipe to the treatment plant in a natural way, it installs a relay pump station and pumps water to the sewage treatment plant. There is a relay pumping station where the sewage is collected and pumped.

Patent Document 1 is an example of the invention relating to a sewage treatment apparatus installed in a sewage transfer pump station.

The fluctuation of the inflow sewage amount per day varies depending on the size of the treatment area. However, since the inflow sewage amount increases from the start of daily life activity in the morning and the operation of the work site and the drainage increase at home, It reaches the maximum in 10 circles. There is a high possibility that the water level of the relay pump station is close to the high water level at this time, and the time at which the high water level (high level), which is the starting water level of the relay pump over time, becomes the maximum load time zone from 14:00 to 17:00.

However, in the conventional sewage relay pump system, there is no difference in the control of the relay pump according to the time zone, so there is a possibility to reduce the reserve power amount and to increase the electric charge burden by using the power at the time of high power demand.

Therefore, it is necessary to reduce the power consumption when the power demand is high by changing the control method according to the time zone in the sewage relay pump system (the system including the relay pump installed in the sewage relay pump station and the device for controlling the same) The pump system did not make a difference in the control method according to the time zone, and the power use can not be reduced when the power demand is large.

Patent Document 1: KR 10-1221100 (Registered Date: 2013.01.04.)

The purpose of the present invention is to reduce the electric power consumption when electric power demand is large by decreasing the control method according to the time zone in the sewage-returning pump system.

The sewage transfer pump system according to the present invention comprises: a high-water level switch, a low-water level switch and a relay pump provided with at least one relay pump; A relay pump control device for controlling the relay pump; Wherein the relay pump control device is capable of controlling the relay pump by selecting one of a first control mode and a second control mode, the relay pump control device communicating with the central operating device remotely The water level switch can measure whether the water level has reached a predetermined high water level reference value and the low water level switch can measure whether the water level has reached a preset low water level reference value and in the first control mode, When the water level of the relay pump station is higher than the high water level reference value, the water level is controlled to be lower than the low water level reference value by operating the relay pump. In the second control mode, if the water level of the relay pump station is lower than the high water level reference value The relay pump is operated to control the water level to be lower than the low water level reference value , Claim characterized in that to set the time zone and the time zone operating in the second control mode, which operates in the first control mode.

The relay pump station further comprises two relay pumps and further comprises an ultra high water level switch, wherein the ultra high water level switch can measure whether the preset high water level reference value has been reached, and before the water level reaches the ultra high water level reference value, And only one relay pump operates alternately, and then, when the water level reaches the ultra high water level reference value, two water pumps operate at the same time.

A QR code display unit on which a QR code is displayed is formed on the surface of the relay pump control device. An NFC tag is provided inside the QR code display unit. The QR code or the NFC tag is recognized The control mode of the relay pump control device can be changed to the smartphone. If the manager's smartphone is a smart phone having the NFC tag function, when the smart phone is accessed to the NFC tag, When the manager's smartphone is a smart phone without the NFC tag function, when the QR code is photographed by the camera of the smartphone, the communication connection of the smartphone and the relay pump control device is automatically performed .

The sewage transfer pump system according to the present invention can reduce the electric power consumption when electric power demand is large by reducing the control method according to the time zone and reduce the electric charge.

1 is a conceptual diagram of a sewage-relay pump system according to the present invention;
2 shows an example of the control mode setting screen of the smartphone
3 is a conceptual diagram of a QR code-NFC tag according to the present invention

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

FIG. 1 is a conceptual diagram of a sewage transfer pump system according to the present invention. FIG.

The sewage transfer pump system according to the present invention includes a relay pump station (100), a relay pump control unit (200), and a central operation unit (300).

A low water level switch 111, a high water level switch 112, an ultra high water level switch 112, a relay pump A 121 and a relay pump B 122 are installed in the relay pump station 100.

The relay pump control device 200 reads the measurement values of the low water level switch 111, the high water level switch 112 and the ultra high water level switch 112, A 121, and relay pump B 122, respectively.

The relay pump control device 200 can communicate with the remote central operating unit 300 via wired or wireless communication. Thus, one central operating device can be designed to manage a plurality of relay pump control devices 200.

The water level switch is a switch that changes to an on state or an off state when the water level in the relay pump is above a certain level. The water level switch is sold as a commercial product, so detailed explanation is omitted.

The low water level switch 111 is a switch whose state changes when it reaches a preset low water level reference value.

The high water level switch 112 is a switch whose state changes when reaching a preset high water level reference value.

The super high water level switch 113 is a switch whose state changes when reaching a predetermined high water level reference value.

In the normal control mode, when the water level of the relay pump is higher than the high water level reference value, the relay pump is operated to control the water level to be lower than the low water level reference value.

At this time, one of the relay pump A 121 and the relay pump B 122 operates. One of the two relay pumps may be used mainly and the other one may be reserved. However, it is desirable to operate the two relay pumps alternately in order to check whether the relay pump left as a reserve is not broken.

If the water level does not decrease after the operation of the relay pump, it can be judged that the relay pump has failed. In order to check the failure of the relay pump, a sensor for checking whether the relay pump is operating may be separately installed. If one relay pump is found to be faulty, the failed pump is controlled so that only one non-failed relay pump is used until it is repaired or replaced.

In an emergency such as a flood, even if one of the relay pumps operates, the water level may go up without going down. Operation of one relay pump If the water level continuously increases after the operation of the pump, and the water level reaches the super high water level reference value, the two relay pumps operate simultaneously.

In the case of operating only in the normal control mode as described above, there is no difference in the control of the relay pump according to the time zone, so there is a possibility of reducing the reserve power amount and increasing the electric charge burden by using the power at the time of high power demand.

Therefore, when the night time zone or the electric power demand is equal to or less than a preset reference value, it is preferable to operate in the peak power control mode.

 In the peak power control mode, if the water level of the relay pump is lower than the high water level reference value, the relay pump is operated to control the water level to be lower than the low water level reference value. (For example, 30 minutes, 60 minutes, etc.) when it is higher than the low water level reference value may be referred to as a start interval and may be selected by the administrator.

At this time, one of the relay pump A 121 and the relay pump B 122 operates. One of the two relay pumps may be used mainly and the other one may be reserved. However, it is desirable to operate the two relay pumps alternately in order to check whether the relay pump left as a reserve is not broken.

 Even in peak power control mode, when the water level reaches the high water level reference value, two relay pumps operate simultaneously.

The normal control mode is referred to as a first control mode, and the peak power control mode may be referred to as a second control mode.

When the nighttime time zone or the power demand is less than a preset reference value, the apparatus is operated in the second control mode (peak power control mode) and in the other time period in the first control mode (normal control mode) You can reduce usage and reduce your electricity bill.

If two pumps are operated alternately, there is an advantage that they can operate normally even when one pump fails.

If the water level reaches the ultra-high water level standard and two units are operated at the same time, there is a high possibility that the sewage can be treated not to overflow even when the inflow amount of sewage is excessively large, such as flood.

The setting of the control mode may be changed by using an operation device (for example, an operation button or the like) provided in the relay pump control device 200 or by a central operation device 300 . However, it is also possible to implement a control mode setting change using a manager's smartphone without separately installing an operation device (for example, an operation button, etc.) provided in the relay pump control device 200. [ To do this, your smartphone must have an application program installed that allows your smartphone to work like that.

2 is an example of a control mode setting screen of the smartphone.

Fig. 2 (A) is an example of an initial screen, Fig. 2 (B) is an example of a communication method setting screen, Fig. 2 (C) is an example of a control mode selection screen, This is an example of the maximum power (peak power) setting screen.

When an administrator of the relay pump control device drives an app (application program) of his / her smart phone, an initial screen as shown in FIG. 2A can be displayed. When an administrator presses a communication setting button on the initial screen as shown in FIG. 2 (A), a screen as shown in FIG. 2 (B) is displayed so that an administrator can select a communication method of the smartphone and the relay pump control device . When an administrator presses a mode selection button on the initial screen as shown in FIG. 2 (A), a screen as shown in FIG. 2 (C) is displayed so that the administrator can select one of the normal control mode and the peak power control mode . After the administrator selects the peak power control mode, a screen as shown in (D) of FIG. 2 is displayed so that the administrator can select the start time, end time, and start interval of the peak power control mode.

However, it is time-consuming and inconvenient for an administrator to change the control mode setting after manually connecting the communication connection between the smartphone and the relay pump control device after executing the app of his smartphone.

Therefore, when the NFC tag is installed on the surface of the relay pump control device, and the smartphone accesses the NFC tag, the smartphone automatically recognizes the NFC tag, It is preferable to implement such that the mode selection screen is displayed automatically.

Among the current smart phones, a smartphone having an NFC communication function can be implemented as described above, but a smartphone having no NFC communication function can not be implemented as described above. A smartphone without an NFC communication function recognizes a QR code using a camera attached to the smartphone, and when recognizing a specific QR code, the smartphone automatically activates the app, and FIG. 2C shows a control mode selection screen Can be implemented to automatically float.

In the case of QR code recognition, it is more inconvenient than recognition of NFC because the QR code should be photographed by the camera after changing the state of the smartphone to the QR code recognizable state. However, it is more convenient than manually changing the control mode setting after manually connecting the communication connection between the smartphone and the relay pump control device.

Since it is easy for an ordinary technician to make a communication connection between the smartphone and the relay pump control device automatically after recognizing the NFC recognition or QR code, a detailed description will be omitted.

Although the NFC tag and the QR code can be displayed at different positions, they can be displayed at the same position and called the QR code-NFC tag.

3 is a conceptual diagram of a QR code-NFC tag according to the present invention.

On the surface of the relay pump control device body 210 is formed a QR code display part 212 on which a QR code is displayed and an NFC tag 211 is provided on the inside of the QR code display part.

Therefore, when the manager has a smartphone having the NFC function, the control mode selection screen can be displayed while communicating with the QR code-NFC tag automatically. If the administrator has a smartphone that does not have the NFC function, the control mode selection screen can be displayed by automatically communicating with the smartphone only by capturing the QR code.

In order to operate as described above, an application (application program) that allows the smartphone to operate is required to be installed in the smartphone.

The QR code-NFC tag saves space and reduces the inconvenience of separately displaying the position of the NFC tag.

Also, in the present invention, if the possibility of flooding is expected due to weather forecast or the like, it may be designed so that it is automatically set to operate in the second control mode (peak power control mode), even if it is not in the night time zone.

In addition, the QR code-NFC tag is not used only in setting the control mode, but can also be used for recording and viewing the inspection record, the component usage period, and the like after periodic inspection. In order to use such a function, after the QR code or the NFC tag is recognized, a control recording mode setting button, a check recording button, a component use light button, and the like are displayed on the screen of the smartphone. .

100: Relay pumping station
111: Low water level switch
112: High water level switch
113: Super high water level switch
121: Pump A
122: Pump B
200: Relay pump control device
210: Relay pump control body
211: NFC tag
212: QR code display section
300: Central operating unit

Claims (3)

A high-water level switch, a low-water level switch and one or more relay pumps;
A relay pump control device for controlling the relay pump;
Central operating unit;
Lt; / RTI >
Wherein the relay pump control device is capable of controlling the relay pump by selecting one of a first control mode and a second control mode and the relay pump control device is capable of remotely communicating with the central operating device,
The high water level switch can measure whether the water level has reached a predetermined high water level reference value,
The low water level switch can measure whether the water level has reached a preset low water level reference value,
In the first control mode, when the water level of the relay pump station becomes higher than the high water level reference value, the relay pump is operated to control the water level to be lower than the low water level reference value,
If the water level of the relay pump station is lower than the high water level reference value in the second control mode, the relay pump is operated to control the water level to be lower than the low water level reference value,
It is possible to set the time zone in which the first control mode operates and the time zone in which the second control mode operates,
The relay pump station includes two relay pumps and further comprises an ultra high water level switch,
The super high water level switch can measure whether or not the preset high water level reference value has been reached,
Before the water level reaches the ultra-high water level reference value, two relay pumps operate alternately one by one. After the water level reaches the ultra-high water level reference value,
On the surface of the relay pump control device is formed a QR code display part on which a QR code is displayed. An NFC tag is provided on the inside of the QR code display part,
The control mode of the relay pump control device can be changed to the smartphone by recognizing the QR code or the NFC tag with the manager's smartphone,
If the manager's smartphone is a smart phone having NFC tag function, if the smart phone is accessed to the NFC tag, the communication connection between the smartphone and the relay pump controller is automatically established,
Wherein when the manager's smartphone is a smartphone without the NFC tag function, the communication connection between the smartphone and the relay pump control device is automatically established when the QR code is photographed by the camera of the smartphone. delete delete

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