KR200448958Y1 - Drainage device - Google Patents

Abstract

The present invention relates to a drainage device that is easy to repair in case of failure and can have low manufacturing cost and high reliability.

The drainage device according to the present invention is a water level detection unit for detecting the water level of the water flowing into the underground structure, a drain control unit having a plurality of electronic relay and time relay to adjust the first and second drain pump according to the water level and And a drain operation circuit unit configured to operate the first and second drain pumps according to the operations of the plurality of relays and the time relay included in the drain control unit.

Electronic relay, time relay, drain control

Description

Drainage {DRAINAGE DEVICE}

The present invention relates to a drainage device, and more particularly, to a drainage device that can be easily repaired in case of failure and can have low manufacturing cost and high reliability.

Drainage pumps are installed to drain water from underground structures to the outside to prevent damage to electricity supply facilities and to maintain an environment where workers can work safely.

The drain pump control device is required to install two drain pumps in order to prevent flooding of the electricity supply equipment and to have alternating operation and simultaneous operation, and to have a function of alternating operation and preventing idling operation during long operation to prevent failure of the drain pump. have.

The control device configured to compensate for this is a problem that the transmission and distribution lines are concentrated in the underground structure, so the surge is frequently introduced, the operation environment is very poor due to dust, moisture, etc., so the reliability is low, and it takes a long time to receive maintenance from the manufacturer. Is generated. Since the logic part of such a control device generally uses a low voltage, for example, in the range of 0.1 to 5 V, a problem occurs when a surge voltage is introduced.

In addition, there is a risk of a safety accident such as electric shock or gas suffocation due to water operation until maintenance is completed, and a high possibility of failure of the drain pump due to the operation circumference.

Accordingly, the technical problem of the present invention is to provide a drainage device that can be easily repaired in case of failure and can have a low manufacturing cost and high reliability.

In order to achieve the above technical problem, a water level detection unit for detecting the water level of the water flowing into the underground structure according to the present invention, and a plurality of electronic relay and time relay to adjust the first and second drain pump according to the water level And a drain control circuit unit configured to operate the first and second drain pumps according to the operations of the plurality of relays and the time relay included in the drain control unit.

At this time, the water level detection unit is characterized in that it comprises a water level sensor for detecting in accordance with the water level, and the water level detection unit is adjusted according to the water level detected by the water level sensor.

Here, the water level sensor unit is the lowest level sensor for detecting when the water level of the water flowing into the underground structure is the lowest, the low level sensor for detecting when the water level is low, the medium level sensor for detecting when the water level is medium It comprises a high water level sensor for detecting when the water level is high.

In addition, the water level detection unit is connected to the lowest level sensor and the low level detection relay is operated when the low level sensor is turned on, the low level detection relay is connected to the low level sensor and operated when the low level sensor is turned on, and And a high level detection relay connected to the high level sensor and operated when the high level sensor is turned on, and a high level detection relay operated when the high level sensor is turned on.

At least one of the plurality of electronic relays is characterized by using a self-holding electronic relay that mechanically maintains an operating state until a signal is supplied once.

The drain control unit may alternately operate the first and second drain pumps according to the water level.

And, the drain control unit characterized in that to operate the first and second drain pump at the same time.

On the other hand, the drain control unit is characterized in that any one of the first and second drain pump can be operated by another drain pump after a predetermined time during long time operation.

The drain operation circuit unit may include a first contact relay configured to drive a first drain pump according to the plurality of electronic relays and the time relay operation, and a second drain pump according to the plurality of electronic relays and the time relay operation. It is characterized by including a two-contact relay.

As described above, the drainage device according to the present invention controls the first and second drain pumps using a drain control unit including a plurality of electronic relays and a time relay. Therefore, unlike the conventional control device using a low voltage, the electronic relay uses a high voltage in the range of 10 ~ 50V, for example, is strong against surge voltage and strong against moisture. As such, it is resistant to surge voltage and moisture, thereby improving reliability and reducing manufacturing costs.

In addition, the drain control unit according to the present invention can be immediately repaired or replaced by using an electronic relay can be replaced or repaired immediately to avoid the safety accidents such as electric shock, gas suffocation that can occur during manual operation of the drain pump and additional damage to the facility It can be prevented.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 1 to 8.

1 is a front view and a side view of a drain device according to an embodiment of the present invention, Figure 2 shows a flow chart of a drain device according to an embodiment of the present invention.

The drainage device includes a water level detection unit 130 of a drain pump detecting a water level flowing into an underground structure, a control unit 400 of a drain pump including a plurality of electronic relays and a time relay, and a control unit 400 of the drain pump. It includes a control circuit unit 120 of the drain pump for operating the first and second drain pump in accordance with the operation of the plurality of electronic relay and the time relay included.

The water level detector 130 includes a water level sensor 138 that senses water level according to the water level, and a water level detector 238 that is adjusted according to the detected water level of the water level sensor 138.

The water level sensor unit 138 includes a low water level sensor 136, a low water level sensor 134, a medium water level sensor 132, and a high water level sensor 131 that sense the water level flowing into the underground structure. . In this case, the lowest level sensor 136 detects when the water level of the water flowing into the underground structure is the lowest, and the low level sensor 134 detects when the water level is low. In addition, the middle level sensor 132 detects when the water level flowing into the underground structure is medium, and the high level sensor 131 detects when the water level flowing into the underground structure is the highest.

The water level detection unit 238 operates according to the water level detected by the water level sensor unit 138, and includes a low water level detection relay 236, a low water level detection relay 234, a medium water level detection relay 232, and a high water level detection relay 230. ).

The low level detection relay 236 is connected to the low level sensor 136, and when the low level sensor 136 is turned on, the low level detection relay 236 operates, and the low level detection relay 134 is The low water level sensor relay 234 is connected to the low water level sensor 234 when the low water level sensor 134 is turned on. The mid-level detection relay 132 is connected to the mid-level sensor 232, and the mid-level detection relay 232 is operated when the mid-level sensor 132 is turned on. The high level detection relay 230 is connected to the high level sensor 131, and the high level detection relay 230 is operated when the high level sensor 131 is turned on.

The drain control unit 400 is configured according to the operation of the low water level detection relay 236, the low water level detection relay 234, the medium water level detection relay 232, and the high water level detection relay 230 included in the water level detection unit 238. The first to fourth electronic relays 401, 402, 410, 420 and the time relay 430 as shown in FIG. 4 to alternately operate or simultaneously operate the second drain pump.

First, a case in which the drain control unit 400 alternately operates the first and second drain pumps will be described with reference to FIGS. 5A and 5B. FIG. 5A is a circuit diagram showing the case where the drain control part shown in FIG. 4 operates the first drain pump, and FIG. 5B is a circuit diagram showing the case where the drain control part shown in FIG. 4 operates the second drain pump. to be.

As the quantity of water flowing into the underground structure increases, the mid-level sensor 132 of the water level sensor unit 138 is turned on to operate the mid-level detection relay 232. The mid-level detection relay 232 is operated to turn on the first contact point 430-1 of the time relay 430, and the first contact point 232-1 of the mid-level detection relay 232 connected thereto is turned on. do.

Thereafter, the first contact point 232-1 of the heavy water level detection relay 232 is turned on, and at the same time, electricity is supplied to the first contact point 410-1 of the third electronic relay 410 to receive the first electronic relay 401. To operate. Accordingly, as the first electromagnetic relay 401 operates, the first magnetic contactor 121 connected to the first electromagnetic relay 401 is turned on to operate the first drain pump. Here, the first contact point 430-1 of the time relay 430 is in an inoperative state because the first contact point 430-1 operates after 30 to 60 minutes, which is a set time range, and the third electronic relay 410 provides a signal once. When supplied, a self-holding electronic relay is used that mechanically maintains the operating state until the next signal is supplied.

When the drainage is started by the first drain pump, the mid-level sensor 132 included in the water level detection unit 130 of the drain pump returns and cuts off the power of the mid-level detection relay 232, thereby removing the first drain pump. The first electromagnetic relay 401 is self-holding through the first contact 401-1 of the first electromagnetic relay 401 to continue operation to the low water position, and the second contact 401 of the first electromagnetic relay 401 is maintained. -2) constitutes an operation circuit of the third electronic relay 410.

In addition, when the drainage is started through the first drain pump to reach the low water position, the low water level detection relay 234 returns. When the low water level detection relay 234 returns, electricity is supplied to the first contact point 234-1 of the low water level detection relay 234 and the second contact point 401-2 of the first electromagnetic relay 401 to generate a third electron. The coil "S" of the relay 310 operates. When the third electromagnetic relay 410 operates, the first contact point 410-1 of the third electromagnetic relay 410 is turned off to cut off the electric supply of the first electromagnetic relay 401, thereby connecting the first drain pump to the first drain pump. The magnetic contactor 121 is turned off to stop the operation of the first drain pump, and at the same time, the second contact 410-2 of the third electromagnetic relay 410 is turned on so that the second electromagnetic relay 402 can operate. Keep on.

When the water level rises due to the stop of the first drain pump and the low water level sensor 134 is turned on, the low water level detection relay 234 operates to turn off the first contact point 234-1 of the low water level detection relay 234 to turn off the third electronic relay. The electricity of 410 is cut off, and the third electronic relay 410 keeps operating state mechanically so that the second contact 410-2 of the third electronic relay 410 keeps on.

At this time, when the water level continues to increase and the water level of the underground structure reaches the mid-level position, the mid-level sensor 132 of the water level sensor unit 138 is turned on to operate the mid-level detection relay 232. When the mid-level detection relay 232 operates, the first contact 430-1 of the time relay 430 is turned on, and the second contact 232-2 of the mid-level detection relay 232 connected thereto is turned on. do.

Thereafter, the second contact 232-2 of the heavy water level detection relay 232 is turned on and at the same time, electricity is supplied to the second contact 410-2 of the third electronic relay 410 to receive the second electronic relay 402. To operate. Accordingly, as the second electromagnetic relay 402 operates, the second electromagnetic contactor 122 connected to the second electromagnetic relay 402 is turned on to operate the second drain pump, and thus the second electronic relay 402 may be operated. The second electromagnetic relay 402 is self-holding through the first contact 402-1, and the second contact 402-2 of the second electromagnetic relay 402 constitutes an operation circuit of the third electronic relay 410. do.

At this time, when the drainage is started through the second drain pump to reach the low water position, the low water level detection relay 234 returns. When the low water level detection relay 234 returns, electricity is supplied to the first contact point 234-1 of the low water level detection relay 234 and the second contact point 402-2 of the second electromagnetic relay 402 to generate a third electron. The "R" coil of relay 410 is operated. When the "R" coil of the third electronic relay 410 operates, the mechanical operating state is released, and the third electronic relay 410 is returned.

As such, when the third electromagnetic relay 410 returns, the second contact 410-2 of the third electromagnetic relay 410 is turned off to cut off electricity of the second electromagnetic relay 402 to connect the second drain pump. 2 The electromagnetic contactor 402 is turned off to stop the operation of the second drain pump, and at the same time, the first contact 410-1 of the third electromagnetic relay 410 is turned on to operate the first electromagnetic relay 401. Keep it on.

In this way, a plurality of electronic relays are used, and at least one of the plurality of electronic relays uses a self-holding electromagnetic relay for self-maintenance, and is highly reliable, and economical in operating the first and second drain pumps alternately. In addition, automatic operation may be performed in alternately operating the first and second drain pumps.

Next, an example in which the drain control unit simultaneously operates the first and second drain pumps will be described with reference to FIG. 7. FIG. 7 illustrates a solid line when the drain control unit illustrated in FIG. 4 simultaneously operates the first and second drain pumps.

If any one of the first and second drain pumps is in operation, when the water level continues to increase, the high water level sensor 131 is turned on to operate the high water level detection relay 230. The high level detection relay 230 is operated to turn on the contact 230 ′ of the high level detection relay 230 to operate the fourth electronic relay 420 which simultaneously drives the first and second drain pumps. In addition, when the high level detection relay 230 is operated, the magnetic contact is self-maintained by the third contact point 430-3 of the fourth electromagnetic relay 420, and the first contact point 430-1 of the fourth electronic relay 430 or The second contact 430-2 operates the relay that is not operated among the first and second electromagnetic relays 401 and 402 to simultaneously drive the first and second drain pumps.

When the water level reaches the low water level position, the low water level sensor 134 turns off to cut off electricity to the low water level detection relay 234, and when the low water level detection relay 234 returns, the second contact point 234-2 of the low water level detection relay 234 ) Cuts off the power supplied to the fourth electromagnetic relay 420 to return the fourth electromagnetic relay 420.

On the other hand, with reference to Figure 8 will be described an example in which the drain control unit is operated for a long time by using the first and second drain pump. In other words, any one of the first and second drain pumps is operated by another drain pump after a predetermined time during long time operation.

The third contact 401-3 of the first electromagnetic relay 401 or the third contact 403 of the second electromagnetic relay 402 operates the temporary relay 430 by driving either one of the first and second drain pumps for a long time. If it is kept on until the set time of), the time relay 430 operates and the state of the third electronic relay 410 is changed through the second contact point 430-2 of the time relay 430 to transfer the drain pump. do.

When either of the first and second drain pumps continues to operate without stopping and the water level reaches the lowest position, the low water level sensor 136 is turned off to return the low water level detection relay 236 and the low water level detection relay 236. ), The pump is stopped by cutting off the power supply of the first electromagnetic relay 401 or the second electromagnetic relay 402.

The drain operation circuit unit 120 drives the first and second drain pumps according to the operations of the plurality of relays and the time relay included in the control unit 400 of the drain pump.

In other words, the drainage manipulation circuit part 120 is connected to the fourth contact point 401-4 of the first electromagnetic relay 401 and the first electromagnetic contactor 121, and the fourth contact point of the second electromagnetic relay 402. 402-4 and the second electromagnetic contactor 122. Accordingly, when the first electromagnetic relay 401 is turned on through the drain control unit 400, the first electromagnetic contactor 401 driving the first drain pump drives the first drain pump, and the drain control unit 400 is operated. When the second electromagnetic relay 402 is turned on, the second magnetic contactor 402 which drives the second drain pump drives the second drain pump.

Although the detailed description of the present invention described above has been described with reference to the preferred embodiment of the present invention, those skilled in the art or those skilled in the art have ordinary knowledge in the related art. It will be appreciated that various modifications and changes can be made in the present invention without departing from the spirit and technical scope of the invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the utility model registration claims.

1 is a front view and a side view of a drainage device according to an embodiment of the present invention.

2 is a flowchart illustrating a drainage device according to an embodiment of the present invention.

3 is a circuit diagram illustrating a water level detector according to an embodiment of the present invention.

4 is a circuit diagram illustrating a drain control unit according to an exemplary embodiment of the present invention.

FIG. 5A is a circuit diagram showing the case where the drain control part shown in FIG. 4 operates the first drain pump, and FIG. 5B is a circuit diagram showing the case where the drain control part shown in FIG. 4 operates the second drain pump. to be.

6 is a circuit diagram illustrating a drain operation circuit unit according to an embodiment of the present invention.

FIG. 7 is a circuit diagram illustrating a case where the drain control unit shown in FIG. 4 simultaneously operates the first and second drain pumps.

FIG. 8 is a circuit diagram illustrating a case where the drain control part shown in FIG. 4 operates for a long time by using the first and second drain pumps.

<Description of the symbols for the main parts of the drawings>

120: drainage operation circuit portion 121: first electromagnetic contactor

122: second magnetic contactor 130: water level detection unit

138: level sensor 238: level detector

400: drain control unit 401: first electronic relay

402: second electronic relay 410: third electronic relay

420: fourth electronic relay 430: time relay

Claims (9)

A water level detecting unit detecting a water level flowing into the underground structure; A drain control section having a plurality of electronic relays and time relays for adjusting first and second drain pumps according to the water level; And a drainage manipulation circuit unit configured to operate the first and second drainage pumps according to the operations of the plurality of relays and the time relay included in the control unit of the drainage pump. The water level detection unit, A water level sensor unit for detecting the water level; Including; water level detection unit is adjusted according to the level of water detected by the water level sensor unit, The water level sensor unit, A lowest level sensor for detecting when the level of water flowing into the underground structure is lowest; A low level sensor for detecting when the water level is low; A medium level sensor for detecting when the water level is about medium; And a high water level sensor for detecting when the water level is high. The water level detection unit, A low level detection relay connected to the low level sensor and operated when the low level sensor is turned on; A low level detection relay connected to the low level sensor and operated when the low level sensor is turned on; A middle level detection relay connected to the middle level sensor and operated when the middle level sensor is turned on; And a high level detection relay connected to the high level sensor and operated when the high level sensor is turned on. delete delete delete The method of claim 1, At least one of the plurality of electronic relays uses a self-maintaining electronic relay which mechanically maintains an operating state until the next signal is supplied once the signal is supplied once. The method of claim 1, The drain control unit And the first and second drain pumps are alternately operated according to the water level. The method of claim 1, The drain control unit And the first and second drain pumps can be operated simultaneously. The method of claim 1, The drain control unit Drainage device characterized in that any one of the first and the second drain pump to be operated by another one of the drain pump after a predetermined time during long time operation. The method of claim 1, The drain operation circuit unit A first contact relay for driving a first drain pump in accordance with the plurality of electronic relay and time relay operations; And And a second contact relay for driving a second drain pump according to the plurality of electronic relay and time relay operations.

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