KR102066417B1 - Water level sensing structure and wataer level sensing method using the same - Google Patents

Abstract

A level sensing structure and a level sensing method using the same are disclosed.
Water level detection structure according to an embodiment of the present invention is connected to the water supply source and the main tank 200 is supplied with water from the water supply and stored; One or more sub tanks 300 and 400 connected to the main tank 200 and supplied with and stored with water from the main tank 200; And a pressure level sensor 500 connected to one of the main tank 200 and one or more sub tanks 300 and 400 for detecting a water level. It is configured to include, the first sub tank 300 is located below the main tank 200 is connected, the pressure-type water level sensor 500 is connected to the first sub tank 300, the main A second sub tank 400 is further connected to the tank 200, and a second sub tank from the main tank 200 is connected to the connection pipe L connecting the main tank 200 and the second sub tank 400. Water is moved to the tank 400, but a check valve (CV) is provided to block the movement of water from the second sub tank 400 to the main tank 200, and the main tank 200 and the first sub tank ( 300 is divided into the main tank 200 and the first sub tank 300 is provided with a separating wall (W) having a plurality of holes (H) in one tank, the first sub tank ( The lower end of the 300 is located at the same height as the lower end of the second sub tank 400 and from the lower end of the first sub tank 300 to the upper end of the main tank 200. Height may be equal to the height of the second sub-tank 400.

Description

Level sensing structure and level sensing method using the same {WATER LEVEL SENSING STRUCTURE AND WATAER LEVEL SENSING METHOD USING THE SAME}

The present invention relates to a water level sensing structure configured to detect a water level and a water level sensing method using the same. More specifically, the water level sensing structure and the water level sensing method configured to sense the water level stored in a plurality of tanks with one pressure level sensor. It is about.

The level sensing structure is configured to detect the level of the water where water is stored, such as a water tank, that is, the height of the water.

Conventionally, in order to measure the water level where water, such as a water tank, is stored, several water level sensors were needed. That is, the water level sensor was installed at the height of the water level to be measured where the water such as the water tank is stored, respectively, and measured the water level where the water such as the water tank is stored. For example, in order to measure the low level, the medium level, and the high level where water, such as a water tank, is stored, a water level sensor is installed at each of the low level, the medium level, and the high level where water, such as a water tank, is stored. In this case, three level sensors are required.

In addition, in the case of the conventional water level sensor, since the water level is configured to detect the water contact, there is a problem that the degree of change in the water level is difficult to measure. In addition, since the water level can be measured only when the water is in contact, there is a problem that the water level sensor is slightly lower or slightly higher than the level where the water level sensor is located. That is, there is a problem that it is difficult to precisely measure the water level.

On the other hand, a water treatment device such as a water purifier may be provided where the water, such as a plurality of water tanks are stored. For example, a water treatment device such as a water purifier may be provided with a water purification tank, a cold water tank, a hot water tank, an ionized water tank, and a carbonated water tank. Therefore, there is a problem in that a relatively large number of water level sensors are required to detect the level of each of these tanks. As described above, in the case where the purified water tank, the cold water tank, the hot water tank, the ionized water tank, and the carbonated water tank are provided in the water purifier, in order to measure the low water level, the medium water level, and the high water level for each tank, three water level sensors in each tank 15 water level sensors will be required.

Since the water level sensor is relatively expensive, there is a problem that a relatively high cost is required to detect the water level. In addition, since a plurality of water level sensors must be provided in each tank, there is a problem that it takes a relatively long time to construct a water level sensing structure.

The present invention is made by recognizing at least any one of the above-mentioned demands or problems.

One aspect of the present invention is to detect the water level of the water stored in the plurality of tanks with one pressure level sensor.

Another aspect of the object of the present invention is to measure the amount of water level change per unit time.

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Another aspect of the object of the present invention is to configure the water level sensing structure at a relatively low cost and time.

The water level sensing structure related to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on one pressure level sensor configured to sense the level of water stored in a plurality of tanks.

Water level detection structure according to an embodiment of the present invention is connected to the water supply source and the main tank is supplied with water from the water supply and stored; One or more sub tanks connected to the main tank and stored with water supplied from the main tank; And a pressure level sensor connected to one of the main tank and one or more sub tanks to sense the water level. It is configured to include, the first sub tank is located under the main tank is connected, the pressure level sensor is connected to the first sub tank, the main tank is further connected to the second sub tank, the main tank and the The connecting pipe connecting the two sub tanks is provided with a check valve to block the movement of water from the main tank to the second sub tank, but from the second sub tank to the main tank, and the main tank and the first sub tank are A separation tank having a plurality of holes is formed in one tank and is divided into a main tank and a first sub tank. The lower end of the first sub tank is located at the same height as the lower end of the second sub tank and the first sub tank. The height from the bottom of the main tank to the top of the main tank is the same as the height of the second sub tank, and the second sub tank has a temperature sensor and a heating unit configured to heat the stored water supplied from the main tank. When the water level of the main tank is lower than the height of the connecting pipe, water is supplied to the main tank from the water supply source, and the water level of the main tank and the first and second sub tanks is detected by a pressure level sensor. The sensor may measure the change in water level per unit time through the first sub tank to which the pressure level sensor is connected to detect which tank is discharged from the main tank and the first and second sub tanks.

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In addition, the first sub tank may be provided with a cooling unit configured to cool the stored water supplied from the main tank.

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When the initial water is supplied to the main tank and the first and second sub tanks, the water stored in the second sub tank by the heating unit and the temperature sensor must be filled with water in both the main tank and the first and second sub tanks. It is possible to maintain a predetermined desired temperature.

In addition, when discharging water from the main tank, the first sub tank or the second sub tank, water may be supplied to the main tank when the water level of the main tank is lower than the height of the connecting pipe.

The temperature of the water stored in the second sub tank may be maintained by the heating unit and the temperature sensor only when the water level of the second sub tank is higher than the height of the temperature sensor.

In addition, during continuous discharge of water from the second sub tank, if the water level of the main tank is lower than the imaginary line higher than the height of the connecting pipe by a predetermined height, water is supplied to the main tank, and the second sub tank is supplied by the heating unit and the temperature sensor. The temperature of the water stored in the can be maintained to maintain a predetermined desired temperature.

The pressure level sensor may be connected to the first sub tank by a sensor connection unit.

The sensor connection unit may further include a connection trap connected to the first sub tank; A measuring rod connected to the connecting trap; And a connecting tube connected to the measuring rod and the pressure level sensor; It may include.

In addition, the measuring rod and the connection tube and the pressure level sensor and the connection tube may be connected by a connection adapter.

In addition, the pressure level sensor may be provided on a circuit board.

The water supply source may include a filtration unit including one or more purified water filters and filtering the introduced water.

In the water level sensing method according to an embodiment of the present invention, in the water level sensing method for detecting the water level of the main tank and the one or more sub-tanks supplied and stored from the main tank is supplied with water from the water supply source, the main tank Below the first sub tank is connected, the pressure level sensor is connected to the first sub tank, the second sub tank is further connected to the main tank, the connector connecting the main tank and the second sub tank is Water flows from the main tank to the second sub tank, but from the second sub tank to the main tank is provided with a check valve to block the movement of water, and the main tank and the first sub tank have a plurality of holes formed in one tank. The separation wall is provided to be divided into the main tank and the first sub tank, the lower end of the first sub tank is located at the same height as the lower end of the second sub tank of the first sub tank The height from the stage to the upper end of the main tank is the same as the height of the second sub tank, and the second sub tank is provided with a temperature sensor and a heating unit configured to heat the stored water supplied from the main tank, and the water level of the main tank is When it is lower than the height of the connecting pipe, water is supplied to the main tank from the water supply source, and the pressure level sensor detects the water level of the main tank and the first and second sub tanks, and the pressure level sensor is connected to the pressure level sensor. The water level change per unit time is measured through the first sub tank to detect which tank is discharged from the main tank and the first and second sub tanks.

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And, if the water level change per unit time measured by the pressure level sensor when water is discharged from the first sub-tank as a reference value, if the water level change per unit time measured by the pressure-type water level sensor at the same extraction amount is less than the reference value It is detected that water is discharged from one of the main tank and the second sub tank, and when larger than the reference value, water may be detected from two or more of the main tank, the first sub tank, and the second sub tank.

In addition, when the measured water level change per unit time is between a first value smaller than a reference value and a second value smaller than the first value, the water is discharged from the main tank, and if smaller than the second value, the second sub tank is detected. It can be detected that water is discharged from.

In addition, each of the connection pipes connected to the main tank, the first sub tank, and the second sub tank is provided with an electronic valve, or each of the outlets connected to each of the connection pipes includes an electronic valve. You can check whether it is detected correctly.

According to the embodiment of the present invention as described above, it is possible to detect the water level of the water stored in the plurality of tanks with one pressure level sensor.

In addition, according to an embodiment of the present invention, it is possible to measure the amount of water level change per unit time.

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In addition, according to the embodiment of the present invention, it is possible to configure the water level sensing structure at a relatively low cost and time.

1 is a view showing an embodiment of a water level sensing structure according to the present invention.
2 to 11 are views showing the operation of one embodiment of the water level sensing structure according to the present invention.

In order to help the understanding of the features of the present invention as described above, it will be described in more detail with respect to the water level detection structure associated with the embodiment of the present invention.

Hereinafter, the described embodiments will be described based on the embodiments best suited for understanding the technical features of the present invention, and the technical features of the present invention are not limited by the described embodiments. It is intended to illustrate that the invention can be implemented as described embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention. And, hereinafter, in order to help the understanding of the embodiments described, in the reference numerals described in the accompanying drawings, among the components that will have the same function in each embodiment is represented by the same or an extension line number.

Embodiments related to the present invention are basically based on one pressure level sensor configured to sense the level of water stored in a plurality of tanks.

As shown in FIG. 1, the water level sensing structure 100 according to the present invention may include a main tank 200, one or more sub tanks 300 and 400, and a pressure level sensor 500.

The main tank 200 may be connected to a water supply source (not shown). Also, as shown in FIGS. 2 to 4, water may be supplied and stored from a water supply source. To this end, the main tank 200 may be connected to the connector (L) as shown in the embodiment shown in FIG. In addition, the connection pipe (L) may be provided with an on-off valve (V) as shown in the illustrated embodiment. Therefore, when opening and closing the valve (V) of the connecting pipe (L) connected to the water supply source as shown in Figure 2 and Figure 3, the water of the water supply source can be supplied to the main tank 200 and stored.

The water supply source connected to the main tank 200 may be a filtration unit (not shown) for filtering the introduced water. The filtration unit, which is a water supply source connected to the main tank 200, may include one or more purified water filters (not shown) for filtration of water. The purified water filter included in the filtration unit may be, for example, a precipitation filter, a precarbon filter, a membrane filter, or a post carbon filter. However, the purified water filter included in the filtration unit is not limited to this, and any purified water filter may be used as long as the purified water filter filters water.

As such, if the water supply source connected to the main tank 200 is a filtration unit including one or more water purification filters, the main tank 200 may be supplied with and stored with water filtered by the filtration unit.

As in the embodiment shown in Figure 1, the main tank 200 may be connected to the outlet (C1) by a connecting pipe (L). Accordingly, as shown in FIG. 6, the water stored in the main tank 200 is filtered by the filtering unit in the illustrated embodiment, and the water stored in the main tank 200 connects the connection pipe L and the outlet C1. It can be discharged to the outside and supplied to the user.

One or more sub tanks 300 and 400 may be connected to the main tank 200 as shown in FIG. 1. Accordingly, as illustrated in FIGS. 2 and 3, water may be supplied to and stored in the one or more sub tanks 300 and 400 from the main tank 200.

As shown in FIG. 1, the first sub tank 300 may be connected and positioned below the main tank 200. To this end, a separation wall W having a plurality of holes H through which water passes may be formed between the main tank 200 and the first sub tank 300 as shown in the illustrated embodiment. By this configuration, as shown in FIG. 2, the water supplied to the main tank 200 may be supplied to the first sub tank 300 through the plurality of holes H of the separation wall W.

The first sub tank 300 may be provided with a cooling unit 310 as shown in the embodiment shown in FIG. The water supplied from the main tank 200 by the cooling unit 310 and stored in the first sub tank 300 may be cooled. To this end, the cooling unit 310 may be an evaporator through which a low temperature refrigerant flows as shown in the illustrated embodiment.

However, the cooling unit 310 is not limited thereto, and if the water supplied from the main tank 200 is capable of cooling the water stored in the first sub tank 300, for example, when power is applied, heat is transferred from one side to the other side. Any well-known thing, such as a thermoelectric module containing a thermoelectric element which can cool water, is possible.

As shown in FIG. 1, the first sub tank 300 may be connected to the outlet C1 by a connecting pipe L. Accordingly, as shown in FIG. 5, the water stored in the first sub tank 300, and in the illustrated embodiment, the water stored in the first sub tank 300 and cooled by the cooling unit 310 is connected to the connection pipe ( L) and discharged to the outside through the outlet (C1) can be supplied to the user.

The second sub tank 400 may be further connected to the main tank 200 as shown in FIG. 1. As shown in the illustrated embodiment, the main tank 200 and the second sub tank 400 may be connected by a connection pipe (L). In addition, a check valve CV allowing water to move only from the main tank 200 to the second sub tank 400 in the connecting pipe L connecting the main tank 200 and the second sub tank 400. It may be provided.

As the check valve CV is provided, water moves from the main tank 200 to the second sub tank 400 as shown in FIG. 3, but as shown in FIGS. 5 and 6. Water from the tank 400 to the main tank 200 may block the movement of water.

As illustrated in FIG. 1, the second sub tank 400 may include a heating unit 410. The water supplied from the main tank 200 by the heating unit 410 and stored in the second sub tank 400 may be heated. To this end, the heating unit 410 may be, for example, a sheath heater. However, the heating unit 410 is not limited thereto, and may be any known material as long as it is capable of heating the water stored in the second sub tank 400 supplied from the main tank 200.

The second sub tank 400 may be connected to the outlet C2 by the connecting pipe (L) as in the embodiment shown in FIG. Accordingly, as shown in FIG. 7, the water stored in the second sub tank 400, and in the illustrated embodiment, the water heated by the heating unit 410 is externally connected through the connection pipe L and the outlet C2. Can be supplied to the user.

The second sub tank 400 may be provided with a temperature sensor (T) as shown in the embodiment shown in FIG. The temperature of the water stored in the second sub tank 400 and heated by the heating unit 410 may be measured by the temperature sensor T.
On the other hand, as shown in Figures 1 to 11, the lower end of the first sub tank 300 is located at the same height as the lower end of the second sub tank 400 is located at the lower end of the first sub tank 300 (main tank ( The height of the water level up to the upper end of the 200 may be configured to be the same as the height of the water level of the second sub tank 400.

As illustrated in FIG. 1, the pressure level sensor 500 may be connected to one of the main tank 200 and one or more sub tanks 300 and 400. As described below, the pressure level sensor 500 may detect the level of the main tank 200 and the one or more sub tanks 300 and 400.

The pressure level sensor 500 is configured to detect a level of the tank by detecting a change in pressure depending on the level of water stored in the tank. Therefore, when the water level of the tank is detected by the pressure-type water level sensor 500, the water level of the tank can be continuously detected, whereby the degree of change of the water level can be detected.

Therefore, it is possible to detect the water level of the tank without using a plurality of water level sensors as in the prior art. Further, as will be described later, the tank to which the pressure level sensor 500 is connected, in the illustrated embodiment, is not only the water level of the first sub tank 300, but also other tanks indirectly or directly connected thereto, for example, in the illustrated embodiment. The water level of the tank 200 and the second sub tank 400 may also be detected.

Accordingly, the water level sensing structure can be configured at a relatively low cost and time.

The configuration of the pressure-type water level sensor 500 is not particularly limited, and any type of well-known may be used as long as it is configured to detect a level of the tank by detecting a change in pressure depending on the level.

The pressure level sensor 500 may be provided on a circuit board (PCB) as shown in FIG. 1. As such, when the pressure level sensor 500 is provided on the circuit board, the pressure level sensor 500 is provided on the circuit board together with the pressure level sensor 500 to provide another configuration of the level sensing structure 100 according to the present invention. For example, it may be easily connected to an electric circuit (not shown) for operating the valve V or the cooling unit 310, the heating unit 410, or the outlets C1 and C2. As a result, the valve V, the cooling unit 310, the heating unit 410, or the discharge ports C1 and C2 may be easily operated according to the water level measured by the pressure level sensor 500.

As shown in FIG. 1, the pressure level sensor 500 may be connected to one of the main tank 200 and one or more sub tanks 300 and 400 by the sensor connection unit 600. To this end, the sensor connection unit 600 may include a connection trap 610, a measuring rod 620, and a connection tube 630, as shown in the illustrated embodiment.

The connection trap 610 may be connected to one of the main tank 200 and one or more sub tanks 300 and 400 as shown in FIG. 1. As shown in the illustrated embodiment, the connection trap 610 may be connected to the first sub tank 300. However, the present invention is not limited thereto and may be connected to the main tank 200 or the second sub tank 400.

As shown in FIG. 1, the connection trap 610 may be connected to a lower end of the first sub tank 300. To this end, a hole (not shown) in which a portion of the connection trap 610 may be inserted is formed at a lower end of the first sub tank 300, and a portion of the connection trap 610 is formed in the first sub tank 300. It may have a shape that can be inserted into a hole formed in the lower end of the, and a sealing member (not shown) such as an O-ring is provided in a portion of the connection trap 610, a part of the connection trap 610 is the first sub tank 300 It can be sealed when inserted into the hole formed at the bottom of the). Accordingly, water stored in the first sub tank 300 may flow into the connection trap 610.

The measuring rod 620 may be connected to the connection trap 610 as shown in FIG. 1. The measuring rod 620 may be formed integrally with the connection trap 610. For example, the connection trap 610 and the measuring rod 620 is made of a synthetic resin, it can be made integrally by injection molding of the synthetic resin. As such, when the connection trap 610 and the measuring rod 620 are integrally formed, the pressure level sensor 500 may be easily connected to the main tank 200 and one of the one or more sub tanks 300 and 400. Can be. In addition, it may not be easily damaged by external force.

As shown in FIG. 1, the connection tube 630 may be connected to the measuring rod 620 and the pressure level sensor 500. The connecting tube 630 may be, for example, a silicon tube. Therefore, because of the flexibility, the measuring rod 620 and the pressure level sensor 500 can be easily connected by the connecting tube 630. However, the material of the connection tube 630 is not limited to this, and any material known as long as it is a flexible material.

The measuring rod 620 and the connection tube 630 and the pressure level sensor 500 and the connection tube 630 may be connected by the connection adapters 625 and 635 as shown in FIG. 1. Accordingly, the measuring rod 620 and the pressure-type water level sensor 500 can be easily connected by the connecting tube 630.

The connecting adapters 625 and 635 may be provided with connection grooves that can be connected by being sealedly connected to the connection protrusions provided in the measuring rod 620 or the pressure level sensor 500 as shown in the embodiment shown in FIG. 1. . And, as shown in the illustrated adapter adapter 625, 635 may be formed with a connecting projection that can be connected to the connection tube 630 is inserted into the seal.

However, the configuration of the adapter 625, 635 for connection is not limited to the embodiment shown in Figure 1, the measuring rod 620 and the connection tube 630 and the pressure level sensor 500 and the connection tube 630 easily. Any configuration can be used as long as it can be connected.

The pressure of one of the main tank 200 and the one or more sub tanks 300 and 400 is transmitted to the pressure level sensor 500 provided on the circuit board by the sensor connection unit 600 having such a configuration. The water level may be detected by the sensor 500.

2 to 11, a method of detecting the water level by the water level sensing structure 100 according to the present invention will be described.

As shown in FIG. 2, when the on / off valve V provided in the connection pipe L connected to the water supply source and the main tank 200 is opened, water from the water supply source is connected to the main tank 200 through the connection pipe L. FIG. ) Can be supplied. Then, the water supplied to the main tank 200 is supplied to the first sub tank 300 through the hole (H) of the separation wall (W) as shown. Since the pressure level sensor 500 is connected to the first sub tank 300 by the sensor connection unit 600 as described above, the pressure level sensor 500 first of the first sub tank 300 The water level can be detected.

When the water level sensed by the pressure level sensor 500 becomes equal to the height of the first sub tank 300, it can be seen that all of the water is filled in the first sub tank 300. In addition, when the water is filled in the first sub tank 300, the water is also filled in the main tank 200, as shown in FIG. Since the height of the first sub tank 300 is a fixed value, subtracting the height of the first sub tank 300 from the level of the main tank 200 detected by the pressure-type water level sensor 500, the main tank 200 The water level of the bay is known.

When the water level of the main tank 200 is increased to reach the connecting pipe L connecting the main tank 200 and the second sub tank 400 as shown in FIG. 3, the main tank 200 as shown in FIG. The supplied water may also be supplied to the second sub tank 400. As such, when the water supplied to the main tank 200 is also supplied to the second sub tank 400, the water level change amount per unit time detected by the pressure-type water level sensor 500 (hereinafter, in the detailed description and claims) 'Level change' means the amount of water level change per unit time detected by the pressure-type water level sensor 500) than the water level change amount per unit time before the water in the main tank 200 is supplied to the second sub tank 400. The value can be reduced. That is, when water is supplied from the water supply source to the main tank 200, the water supply source before the water level of the main tank 200 reaches the connection pipe L connecting the main tank 200 and the second sub tank 400. While water is supplied only to the main tank 200, when the water level of the main tank 200 is greater than or equal to the height of the connection pipe L, the water from the water supply source is connected to the connection pipe L and the check valve as well as the main tank 200. Since it is also supplied to the second sub tank 400 through the CV, the amount of water level change per unit time is reduced than before. Accordingly, when the amount of water level change per unit time detected by the pressure level sensor 500 is reduced, it can be seen that water is also supplied to the second sub tank 400.
On the other hand, the connecting pipe (L) connecting the main tank 200 and the second sub tank 400 is provided with a check valve (CV) acting as a flow resistance, the connecting pipe is provided with a check valve (CV) (L) itself also has a flow resistance, the water is moved due to the pressure difference between the main tank 200 and the second sub tank 400, the water level of the main tank 200 is greater than the height of the connection pipe (L). In this case, the amount of water per unit time supplied from the water supply source to the main tank 200 is slightly larger than the amount of water per unit time supplied from the main tank 200 to the second sub tank 400. Therefore, when the water level of the main tank 200 is supplied to the main tank 200 from the water supply source in a state in which the water level of the main tank 200 is greater than or equal to the height of the connecting pipe L, as shown in FIG. At a position slightly higher than (L), the pressure balance is made between the main tank 200 and the second sub tank 400 so that the water level of the main tank 200 is equal to the water level of the second sub tank 400. (Delay time exists until pressure balance is achieved).

Subsequently, as shown in FIG. 4, when water is filled in the second sub tank 400, the first sub tank 300, and the main tank 200 (that is, the pressure corresponding to the full water level of the main tank is detected). After that), the supply of water to the main tank 200 is stopped.

In addition, when the water is discharged to the outside through the connecting pipe (L) and the outlet (C1) connected to it from the first sub tank 300, as shown in Figure 5, the amount of water discharged to the main tank 200 Since the water is moved from the first sub tank 300 to the water level of the main tank 200 is lowered. And, as shown in Figure 6 when the water is discharged to the outside through the connection pipe (L) and the outlet (C1) connected to it from the main tank 200, the water level of the main tank 200 is lowered. Meanwhile, in the case of FIGS. 5 and 6, the water level of the second sub tank 400 is higher than that of the main tank 200, but the check valve CV provided in the connection pipe L is removed from the main tank 200. Since the water is moved only in the direction of the second sub tank 400, the water of the second sub tank 400 does not move to the main tank 200.

5 and 6, the water level of the main tank 200 is lowered in all cases, but the water level change per unit time detected by the pressure-type water level sensor 500 in the case shown in FIG. 5 and shown in FIG. In this case, the amount of water level change per unit time detected by the pressure-type water level sensor 500 is different.

That is, when water is discharged from the first sub tank 300 as shown in FIG. 5, the pressure received by the connection pipe L connected to the outlet C1 is discharged from the main tank 200 as shown in FIG. 6. If the connecting pipe (L) connected to the outlet (C1) in the case is slightly greater than the pressure received.

Therefore, as shown in FIG. 5, the water level change per unit time when water is discharged from the first sub tank 300 is a unit when water is discharged from the main tank 200 as shown in FIG. 6. It is slightly larger than the hourly level change. In addition, since the pressure level sensor 500 can detect the amount of water level change per unit time as described above, by detecting the amount of water level change per unit time by the pressure type water level sensor 500, If the water level is lowered, it may be determined whether this is due to the discharge of water from the first sub tank 300 or the discharge of water from the main tank 200.

In addition, as shown in FIG. 7, when water is discharged to the outside through the connection pipe L and the discharge port C2 connected thereto from the second sub tank 400, the water level of the second sub tank 400 is lowered. do. Then, as water is discharged from the second sub tank 400 and the water level is lowered, the second sub tank (from the main tank 200 until the water level of the main tank 200 and the second sub tank 400 is the same). 400) the water is moved. That is, the check valve CV causes the water to move only in the direction of the second sub tank 400 from the main tank 200. When the water level of the main tank 200 is higher than the water level of the second sub tank 400, the pressure is increased. Since water moves from the main tank 200 to the second sub tank 400 by the car, the water level of the main tank 200 is lowered. As such, when water is discharged from the second sub tank 400 in a state in which the water level of the main tank 200 is greater than or equal to that of the second sub tank 400, the water level of the main tank 200 and the second sub tank 400. When the water is discharged from the second sub-tank 400, the speed at which the water level of the main tank 200 is lowered is the water discharged from the main tank 200 or the first sub-tank (300) In this case, the water level of the main tank 200 becomes slower than the speed of lowering.

Therefore, as shown in FIG. 7, the water level change per unit time detected by the pressure-type water level sensor 500 when water is discharged from the second sub tank 400 is shown in FIG. 5 (in the first sub tank). Water discharge) and the water level change per unit time detected by the pressure-type water level sensor 500 in the case shown in FIG. 6 (water discharge from the main tank). That is, as shown in FIG. 7, the water level change amount per unit time when water is discharged from the second sub tank 400 is the water level per unit time when water is discharged from the main tank 200 as shown in FIG. 6. It becomes smaller than the change amount. Therefore, when the water level of the main tank 200 is lowered and the water level change per unit time detected by the pressure-type water level sensor 500 is smaller than that of FIG. 6, it can be seen that water is discharged from the second sub tank 400. have.

In the case of FIG. 7, the water level of the main tank 200 and the water level of the second sub tank 400 are equal to each other. Therefore, the water level of the second sub tank 400 can be known thereby. In addition, multiplying the area of the main tank 200 by the water level lowered in the main tank 200 may determine the amount of water moved from the main tank 200 to the second sub tank 400.

In summary, it is possible to determine in which tank the water is discharged based on the amount of water level change per unit time measured by the pressure-type water level sensor 500 when the water is discharged from the first sub tank 300.

First, if the water level change per unit time measured by the pressure-type water level sensor 500 at the same extraction amount is less than the reference value, it is detected that water is discharged from one of the main tank 200 and the second sub tank 400. Can be.

In addition, when the reference value is larger than the reference value, it may be detected that water is discharged from two or more of the main tank 200, the first sub tank 300, and the second sub tank 400.

If the measured water level change per unit time is between a first value smaller than a reference value and a second value smaller than the first value, the main tank 200 detects that water is discharged. It can be detected that the water is discharged from the 2 sub tank (400).

As such, since it is possible to know which tank the water is discharged from, it is possible to check in which tank the water level fluctuation occurs through the pressure-type water level sensor 500.

On the other hand, when the heating unit 410 is provided in the second sub tank 400, as shown in the embodiment shown in Figure 1 is configured to heat the water stored in the second sub tank 400 supplied from the main tank (200) For example, a temperature sensor T may be provided in the second sub tank 400. The temperature sensor T may be provided at a position of the second sub tank 400 below the connection pipe L connecting the main tank 200 and the second sub tank 400 as shown in the illustrated embodiment. . However, the position of the temperature sensor T in the second sub tank 400 is not particularly limited and may be any position as long as it can sense the temperature of the water stored in the second sub tank 400.

In this configuration, as shown in Figures 2 to 4 when the initial water supply to the main tank 200 and one or more sub-tanks 300, 400 of the hot water detection structure 100 according to the present invention as shown in Figure 4 Likewise, the main unit 200 and the at least one sub tank 300 and 400 both have water to fill the second sub tank 400 by the heating unit 410 and the temperature sensor T provided in the second sub tank 400. The temperature of the water stored in the can be maintained to maintain a predetermined desired temperature.

In addition, when discharging water from the main tank 200 or the first sub tank 300 as shown in FIG. 8 or when discharging water from the second sub tank 400 as shown in FIG. As described above, when the water level of the main tank 200 is lower than the height of the connection pipe L connecting the main tank 200 and the second sub tank 400, water may be supplied to the main tank 200.

8 and 10, the heating unit 410 and the temperature provided in the second sub tank 400 only when the water level of the second sub tank 400 is higher than the height of the temperature sensor T. The temperature of the water stored in the second sub tank 400 may be maintained by the sensor T to maintain a predetermined desired temperature.

In FIG. 8, since the water level of the second sub tank 400 is higher than the height of the temperature sensor T, the heating unit 410 and the temperature sensor T provided in the second sub tank 400 are provided. By doing so, the temperature of the water stored in the second sub tank 400 may be maintained at a predetermined desired temperature.

However, in FIG. 9, since the water level of the second sub tank 400 is lower than the height of the temperature sensor T, as shown in FIG. 10, the second sub tank 400 from the main tank 200 is shown. Only when the water level of the second sub tank 400 is higher than the height of the temperature sensor T due to the water supply to the furnace, the heating unit 410 and the temperature sensor T provided in the second sub tank 400 are provided. The temperature of the water stored in the second sub tank 400 may be maintained at a predetermined desired temperature.

In addition, when the continuous discharge of water from the second sub tank 400, as shown in FIG. 11, the water level of the main tank 200 connects the main tank 200 and the second sub tank 400 ( When the height is lower than the virtual line (not shown), which is higher than the height of L), water may be supplied to the main tank 200.

Such an imaginary line may be a line representing the level of the main tank 200 which may allow the level of the second sub tank 400 to be higher than the height of the temperature sensor T as shown in FIG. 11. However, the virtual line is not particularly limited, and any line may be used as long as the line is a predetermined height higher than the height of the connection pipe L connecting the main tank 200 and the second sub tank 400.

In the case of continuous discharge of the water from the second sub tank 400, the temperature of the water stored in the second sub tank 400 by the heating unit 410 and the temperature sensor (T) to maintain a predetermined desired temperature. Can be. As a result, even when water is continuously discharged from the second sub tank 400, water of a predetermined desired temperature can be discharged and supplied to the user.

Meanwhile, as shown in FIG. 1, the connection pipes L respectively connected to the main tank 200 and the first sub tank 300 are connected to the same outlet C1 and connected to the second sub tank 400. The connector L may be connected to another outlet C1, but the connector L connected to the main tank 200, the first sub tank 300, and the second sub tank 400, respectively, may be connected to the other outlet. May be connected. The outlet may also include an electronic valve.

In addition, other electronic valves may be provided in the connection pipes L connected to the main tank 200, the first sub tank 300, and the second sub tank 400, respectively.

In addition, it is possible to know whether water is discharged from the main tank 200, water is discharged from the first sub tank 300, or water is discharged from the second sub tank 400 by receiving a signal from the electronic valve.

As a result, it is possible to confirm whether the level detected by the level sensing structure 100 and the level sensing method according to the present invention is correctly detected.

As described above, by using the water level detection structure and the water level detection method according to the present invention, one pressure level sensor can detect the water level stored in the plurality of tanks, and can measure the amount of water level change per unit time. It is possible to construct the water level sensing structure at low cost and time.

The level sensing structure and the level sensing method described above are not limited to the configuration of the above-described embodiment, but the embodiments may be selectively combined with each or all of the embodiments so that various modifications can be made. It may be configured.

100: water level detection structure 200: main tank
300: first subtang 310: cooling unit
400: second sub tank 410: heating unit
500: Pressure level sensor 600: Sensor connection unit
610: connecting trap 620: measuring rod
625,635: adapter for connection 630: connection tube
L: Connector CV: Check valve
T: Temperature sensor V: On-off valve
PCB: Circuit Board C1, C2: Outlet
W: Partition wall H: Hole

Claims (22)

A main tank 200 connected to the water supply source and storing water supplied from the water supply source;
One or more sub tanks 300 and 400 connected to the main tank 200 and supplied with and stored with water from the main tank 200; And
A pressure level sensor 500 connected to one of the main tank 200 and one or more sub tanks 300 and 400 for detecting a water level; It is configured to include,
A first sub tank 300 is connected and positioned below the main tank 200, and the pressure level sensor 500 is connected to the first sub tank 300.
A second sub tank 400 is further connected to the main tank 200,
Water is moved from the main tank 200 to the second sub tank 400 in the connecting pipe L connecting the main tank 200 and the second sub tank 400, but the second sub tank 400 is connected to the second sub tank 400. From the main tank 200 is provided with a check valve (CV) to block the movement of water,
The main tank 200 and the first sub tank 300 are provided with a separation wall W having a plurality of holes H formed in one tank to the main tank 200 and the first sub tank 300. Comprising a compartment, the lower end of the first sub tank 300 is located at the same height as the lower end of the second sub tank 400 of the main tank 200 at the lower end of the first sub tank (300) Height to the top is the same as the height of the second sub tank 400,
The second sub tank 400 is provided with a temperature sensor (T) and a heating unit 410 configured to heat the water stored and supplied from the main tank 200,
When the water level of the main tank 200 is lower than the height of the connecting pipe (L) supplies water to the main tank 200 from the water supply source,
Detecting the water level of the main tank 200 and the first and second sub tanks 300 and 400 by the pressure-type water level sensor 500,
The pressure level sensor 500 measures the amount of water level change per unit time through the first sub tank 300 to which the pressure level sensor 500 is connected to the main tank 200 and the first and second sub tanks. 300,400) of water level sensing structure for detecting which water is discharged from the tank. delete delete delete The water level sensing structure according to claim 1, wherein the first sub tank (300) is provided with a cooling unit (310) configured to cool water stored and supplied from the main tank (200). delete delete According to claim 1, When the initial water supply to the main tank 200 and the first and second sub tanks 300 and 400, the water in both the main tank 200 and the first and second sub tanks (300, 400) The water level sensing structure, characterized in that for the temperature of the water stored in the second sub tank 400 to maintain a predetermined desired temperature by the heating unit (410) and the temperature sensor (T). According to claim 1, When the water discharged from the main tank 200, the first sub tank 300 or the second sub tank 400, the water level of the main tank 200 is the connection pipe (L) When the water level is lower than the water level sensing structure, characterized in that for supplying water to the main tank (200). 10. The method of claim 9, wherein the second sub tank 400 by the heating unit 410 and the temperature sensor T only when the water level of the second sub tank 400 is higher than the height of the temperature sensor T. The water level sensing structure, characterized in that to maintain the temperature of the water stored in the predetermined desired temperature. According to claim 1, When the continuous discharge of water from the second sub-tank 400, if the water level of the main tank 200 is lower than the virtual line of a predetermined height higher than the height of the connecting pipe (L) the main tank ( Water)
The water level sensing structure, characterized in that the temperature of the water stored in the second sub tank 400 by the heating unit 410 and the temperature sensor (T) maintain a predetermined desired temperature. The level sensor structure according to claim 1, wherein the pressure level sensor (500) is connected to the first sub tank (300) by a sensor connection unit (600). The method of claim 12, wherein the sensor connection unit 600
A connection trap 610 connected to the first sub tank 300;
A measuring rod 620 connected to the connection trap 610; And
A connecting tube 630 connected to the measuring rod 620 and the pressure level sensor 500;
Water level detection structure comprising a. The water level sensor according to claim 13, wherein the measuring rod 620, the connection tube 630, and the pressure level sensor 500 and the connection tube 630 are connected by a connection adapter 625, 635. rescue. The water level sensing structure according to claim 1, wherein the pressure level sensor (500) is provided on a circuit board (PCB). The water level sensing structure according to claim 1, wherein the water supply source includes at least one purified water filter and is a filtration unit for filtering the introduced water. In the water level sensing method for detecting the water level of the main tank 200 is supplied and stored in the water supply source and at least one sub tank 300,400 is supplied and stored from the main tank 200,
A first sub tank 300 is connected and positioned below the main tank 200, and a pressure level sensor 500 is connected to the first sub tank 300.
A second sub tank 400 is further connected to the main tank 200,
Water is moved from the main tank 200 to the second sub tank 400 in the connecting pipe L connecting the main tank 200 and the second sub tank 400, but the second sub tank 400 is connected to the second sub tank 400. From the main tank 200 is provided with a check valve (CV) to block the movement of water,
The main tank 200 and the first sub tank 300 are provided with a separation wall W having a plurality of holes H formed in one tank to the main tank 200 and the first sub tank 300. Comprising a compartment, the lower end of the first sub tank 300 is located at the same height as the lower end of the second sub tank 400 of the main tank 200 at the lower end of the first sub tank (300) Height to the top is the same as the height of the second sub tank 400,
The second sub tank 400 is provided with a temperature sensor (T) and a heating unit 410 configured to heat the water stored and supplied from the main tank 200,
When the water level of the main tank 200 is lower than the height of the connecting pipe (L) supplies water to the main tank 200 from the water supply source,
Detecting the water level of the main tank 200 and the first and second sub tanks 300 and 400 by the pressure-type water level sensor 500,
The pressure level sensor 500 measures the amount of water level change per unit time through the first sub tank 300 to which the pressure level sensor 500 is connected to the main tank 200 and the first and second sub tanks. 300, 400) of the water level detection method characterized in that it detects which water is discharged from the tank. delete delete The water level change amount per unit time measured by the pressure level sensor 500 when water is discharged from the first sub tank 300 is used as a reference value.
If the amount of water level change per unit time measured by the pressure-type water level sensor 500 is less than the reference value at the same extraction amount, it is detected that water is discharged from one of the main tank 200 and the second sub tank 400. ,
When the water level is greater than the reference value, the water level sensing method characterized in that it detects that water is discharged from at least two of the main tank (200), the first sub tank (300) and the second sub tank (400). The method of claim 20, wherein when the measured water level change per unit time is between a first value smaller than the reference value and a second value smaller than the first value, the water is discharged from the main tank 200. The water level detection method for detecting that the water is discharged from the second sub tank 400 when less than the second value. The connection pipe (L) connected to the main tank (200), the first sub tank (300) and the second sub tank (400), respectively, is provided with an electronic valve or each of the connection pipes (L). Each outlet (C1) connected to the water level detection method including an electronic valve to determine whether the water level sensed by the pressure level sensor 500 is correctly detected.

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