FLOODING DETECTION CIRCUIT AND FLOODING DETECTION APPARATUS USING SAME

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of priority of Korean Patent Application No. 2011-0095082 filed on September 21, 2011, and Korean Patent Application No. 10-2012-0015596 filed on February 16, 2012, all of which are incorporated by reference in their entirety herein.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a flooding detection circuit and a flooding detection apparatus using same and, more particularly, to a flooding detection circuit capable of checking a flooding position and a flooding detection apparatus using same.

Discussion of the Related Art

Electrical and electronic equipments, machines, etc. may have their functions deteriorated or lost if they submerge. Accordingly, submerged electrical and electronic equipments, submerged machines, etc. require instant repair or replacement.

Particularly, if only some of the parts of equipment including a plurality of parts submerge, it is important to check the degree of flooding and the flooding position of the equipment in order to check whether to replace or repair the equipment.

Furthermore, in large-sized equipments, factories, etc. in addition to electrical and electronic equipments or machines, it is important to check the degree of flooding and the flooding position in order to maintain the equipment or facilities.

Korean Patent No. 536524 entitled 'A FLOODING SENSOR AND THE SYSTEM FOR WARNING OF FLOODING THEREOF' discloses a flooding detection apparatus for checking whether flooding has occurred or checking the level of flooding by using differential pressure sensors for detecting a pressure difference.

SUMMARY OF THE INVENTION

The present invention provides a flooding detection circuit and a flooding detection apparatus using a plurality of resistors which is electrified by flooding.

In order to achieve the above, a flooding detection circuit according to an aspect of the present invention includes a power source unit; a reference resistor connected between the power source unit and a voltage measurement node; a flooding unit configured to include a plurality of flooding measurement resistors connected in parallel to the voltage measurement node, wherein flooding contact terminals are formed at respective ends of the flooding measurement resistors; and a voltage measurement unit connected to the voltage measurement node and configured to measure voltage divided by the reference resistor and the flooding unit when the flooding contact terminals submerge.

Composite resistance values of one or more of the plurality of flooding measurement resistors may be different from each other.

The plurality of flooding measurement resistors may have different resistance values.

The plurality of flooding measurement resistors may have resistance value of different prime numbers.

The flooding contact terminals may be electrical wires extended from the respective flooding measurement resistors.

The voltage measurement unit may be an Analog to Digital Converter (ADC).

A flooding detection apparatus according to another aspect of the present invention includes a power source unit; a reference resistor configured to have one terminal connected to the power source unit and have the other terminal connected to a voltage measurement node; a flooding unit configured to include a plurality of flooding measurement resistors connected in parallel to the voltage measurement node and placed in respective flooding measurement positions; a voltage measurement unit connected to the voltage measurement node and configured to measure divided voltage values divided by the reference resistor and the flooding unit; and a processing unit connected to the voltage measurement unit and configured to determine whether flooding has occurred and flooding measurement positions based on the divided voltage values.

Flooding contact terminals are included at respective ends of the plurality of flooding measurement resistors, and the plurality of flooding measurement resistors are electrified when the flooding contact terminals submerge.

Composite resistance values by combinations of the plurality of flooding measurement resistors may be different from each other.

The processing unit may include a data storage unit for storing the divided voltage values according to the respective composite resistance values.

The data storage unit may further store the flooding measurement positions which correspond to the respective divided voltage values and where the respective flooding measurement resistors are placed.

The processing unit determines whether flooding has occurred and the flooding measurement positions by comparing the divided voltage values, measured by the voltage measurement unit, with the respective divided voltage values stored in the data storage unit.

The processing unit may include a data storage unit for storing the composite resistance values.

The data storage unit may further store the flooding measurement positions which correspond to the respective composite resistance values and where the respective flooding measurement resistors are placed, in association with the composite resistance values.

The processing unit further may include a reverse composite resistance value calculation unit for calculating reverse composite resistance values of the flooding unit based on the divided voltage values, a supply voltage of the power source unit, and a resistance value of the reference resistor.

The processing unit determines whether flooding has occurred and the flooding measurement positions by comparing the reverse composite resistance values of the reverse composite resistance value calculation unit with the respective composite resistance values stored in the data storage unit.

The flooding detection apparatus may further include a display unit for displaying whether flooding has occurred and the flooding measurement positions by the processing unit.

BRIEF DESCRIPTION OF THE DRAWINGS

• FIG. 1 is a block diagram of a flooding detection circuit according to an embodiment of the present invention.
• FIG. 2 is a block diagram of a flooding detection apparatus according to an embodiment of the present invention.
• FIG. 3 is a diagram illustrating an example in which the flooding detection apparatus according to the embodiment of the present invention is applied to a vehicle.
• FIG. 4 is a diagram illustrating an example in which the flooding detection apparatus according to the embodiment of the present invention is applied to a factory.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, some embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the disclosed embodiments, but may be implemented in various ways. The present embodiments are provided to complete the disclosure of the present invention and to allow those having ordinary skill in the art to understand the scope of the present invention. The shapes, etc., of elements in the drawings may be enlarged in order to highlight a clearer description. The same reference numbers are used throughout the drawings to refer to the same parts.

FIG. 1 is a block diagram of a flooding detection circuit according to an embodiment of the present invention.

As shown in FIG. 1, the flooding detection circuit 100 according to the embodiment of the present invention includes a power source unit 10, a reference resistor 20, a flooding unit 30, and a voltage measurement unit 40.

The power source unit 10 is an electrical source for supplying voltage to the flooding detection circuit 100.

The driving source of an apparatus or equipment on which the flooding detection circuit 100 is mounted may be used as the power source unit 10. Alternatively, the power source unit 10 may be a power source additionally included in the flooding detection circuit 100.

The power source unit 10 may be connected to one terminal of the reference resistor 20. Furthermore, the other terminal of the reference resistor 20 may be connected to the flooding unit 30.

The flooding unit 30 includes a plurality of first to N^th flooding measurement resistors 31 to 34 connected in parallel.

Each of the first to N^th flooding measurement resistors 31 to 34 may be formed of a resistor having a different impedance.

Furthermore, composite resistance values according to all the combinations of one or more of the first to N^th flooding measurement resistors 31 to 34 may be different.

For example, in order for the composite resistance values to be different, the impedance of each of the first to N^th flooding measurement resistors 31 to 34 may have a different prime number. For example, resistance values of N different prime numbers may be selected in such a manner that the first flooding measurement resistor 31 has 3 KΩ, the second flooding measurement resistor 32 has 5 KΩ, the third flooding measurement resistor 33 has 7 KΩ, a fourth flooding measurement resistor (not shown) has 11 KΩ, etc.

Meanwhile, flooding contact terminals 31a to 34a may be provided at the respective ends of the first to N^th flooding measurement resistors 31 to 34.

The flooding contact terminals 31 a to 34a are parts coming in contact with water when flooding occurs. When the flooding contact terminals 31 a to 34a submerge, the first to N^th flooding measurement resistors 31 to 34, the reference resistor 20, and the power source unit 10 form a closed circuit.

The flooding contact terminals 31 a to 34a may be made of conductive material and may be electrical wires extended from the first to N^th flooding measurement resistors 31 to 34.

Accordingly, of some of the flooding contact terminals 31a to 34a submerge, flooding measurement resistors connected to the submerged flooding contact terminals are electrified, but flooding measurement resistors connected to flooding contact terminals not submerged are not electrified.

Meanwhile, the voltage measurement unit 40 is connected to a point 50 (hereinafter referred to as a voltage measurement node) at which the reference resistor 20 and the flooding unit 30 are connected together. Thus, voltage at the voltage measurement node 50 can be measured.

If flooding does not occur, voltage supplied by the power source unit 10 is supplied to only the reference resistor 20 because current does not flow through the flooding unit 30.

If some or all of the flooding contact terminals 31a to 34a submerge, however, current passing through the reference resistor 20 flows into flooding measurement resistors connected to the submerged flooding contact terminals, and voltage supplied by the power source unit 10 is divided into the reference resistor 20 and the relevant flooding measurement resistors.

Accordingly, whether flooding has occurred can be checked on the basis of voltage at the voltage measurement node 50 which is measured by the voltage measurement unit 40.

Furthermore, the impedances of the first to N^th flooding measurement resistors 31 to 34 are selected so that the composite resistance values according to the combinations of the first to N^th flooding measurement resistors 31 to 34 are different as described above. Thus, the voltage measurement node 50 has a different voltage value depending on a flooding position. Accordingly, even a submerged flooding position can be determined by checking only the voltage of the voltage measurement node 50 which is measured by the voltage measurement unit 40.

For example, assuming that the power source unit 10 supplies DC voltage of 5 V, the reference resistor 20 has 5 KΩ, the first flooding measurement resistor 31 has 3 KΩ, the second flooding measurement resistor 32 has 5 KΩ, and the third flooding measurement resistor 33 has 7KΩ,

1. 1) if only the flooding contact terminal 31a connected to the first flooding measurement resistor 31 submerges, voltage measured by the voltage measurement unit 40 is 5*{3/(3+5)}=1.875 V,
2. 2) if only the flooding contact terminal 32a connected to the second flooding measurement resistor 32 submerges, voltage measured by the voltage measurement unit 40 is 5*{5/(5+5)}=2.5 V,
3. 3) if only the flooding contact terminal 33a connected to the third flooding measurement resistor 33 submerges, voltage measured by the voltage measurement unit 40 is 5* {7/(7+5)}=2.917 V,
4. 4) if only the flooding contact terminal 31 a connected to the first flooding measurement resistor 31 and the flooding contact terminal 32a connected to the second flooding measurement resistor 32 submerge, voltage measured by the voltage measurement unit 40 is 5*{1.875/(1.875+5)}≒1.364 V,
5. 5) if only the flooding contact terminal 31 a connected to the first flooding measurement resistor 31 and the flooding contact terminal 33a connected to the third flooding measurement resistor 33 submerge, voltage measured by the voltage measurement unit 40 is 5*{2.1/(2.1+5)}≒1.479 V,
6. 6) if only the flooding contact terminal 32a connected to the second flooding measurement resistor 32 and the flooding contact terminal 33a connected to the third flooding measurement resistor 33 submerge, voltage measured by the voltage measurement unit 40 is 5*{2.917/(2.917+5)}≒1.842 V, and
7. 7) if only the flooding contact terminal 31 a connected to the first flooding measurement resistor 31, the flooding contact terminal 32a connected to the second flooding measurement resistor 32, and the flooding contact terminal 33a connected to the third flooding measurement resistor 33 submerge, voltage measured by the voltage measurement unit 40 is 5* {1.479/(1.479+5)}≒1.141 V.

As in the above example, voltage measured by the voltage measurement unit 40 is different depending on a flooding position. Accordingly, a flooding position can be checked on the basis of the measured voltage. In other words, if voltage measured by the voltage measurement unit 40 is 2.5 V, it can be seen that only a position where the second flooding measurement resistor 32 is placed has submerge. If voltage measured by the voltage measurement unit 40 is 1.141 V, it can be seen that only positions where the first flooding measurement resistor 31, the second flooding measurement resistor 32, and the third flooding measurement resistor 33 have submerged.

An Analog to Digital Converter (ADC) for converting the voltage value (i.e., an analog value) of the voltage measurement node 50 into a digital value may be used as the voltage measurement unit 40.

The flooding detection circuit 100 according to the embodiment of the present invention includes the first to N^th flooding measurement resistors 31 to 34 equipped with the respective flooding contact terminals 31 a to 34a instead of the conventional differential pressure sensors or floating sensors in order to check flooding. Accordingly, whether flooding has occurred and a flooding position can be checked, and a circuit can be configured at a low price.

Furthermore, if additional flooding measurement resistors are connected in parallel to the first to N^th flooding measurement resistors 31 to 34, the number of places where the occurrence of flooding is measured can be increased. Here, the circuits can be easily extended and installed.

A flooding detection apparatus according to an embodiment of the present invention is described below.

FIG. 2 is a block diagram of the flooding detection apparatus including the flooding detection circuit 100 according to the embodiment of the present invention.

As shown in FIG. 2, the flooding detection apparatus 1000 according to the embodiment of the present invention includes the flooding detection circuit 100, a processing unit 200, and a display unit 300.

The flooding detection circuit 100 has been described above and a description thereof is omitted.

The processing unit 200 may include a data storage unit 210 and a data processing unit 220.

The data storage unit 210 may store the divided voltage values of the voltage measurement node 50 according to the composite resistance values by the combinations of the first to N^th flooding measurement resistors 31 to 34.

The divided voltage values may be previously calculated on the basis of the composite resistance values, the resistance value of the reference resistor 20, and the supply voltage value of the power source unit 10 and then stored in the data storage unit 210.

The data storage unit 210 may store pieces of position information about the first to N^th flooding measurement resistors 31 to 34 corresponding to the respective divided voltage values in association with the respective divided voltage values. For example, a divided voltage value when the flooding contact terminal 31a of the first flooding measurement resistor 31 submerges may be recorded in association with the first flooding measurement resistor 31, a divided voltage value when the flooding contact terminal 32a of the second flooding measurement resistor 32 submerges may be recorded in association with the second flooding measurement resistor 32, and a divided voltage value when the flooding contact terminals 31a and 32a of the first and the second flooding measurement resistors 31 and 32 submerge may be recorded in association with the first flooding measurement resistor 31 and the second flooding measurement resistor 32. In case of other combinations of the first to N^th flooding measurement resistors 31 to 34, a divided voltage value may be recorded likewise.

The data processing unit 220 receives the divided voltage values measured by the voltage measurement unit 40 and compares the divided voltage values with the respective divided voltage values stored in the data storage unit 210.

The data processing unit 220 may extract a divided voltage value equal to the divided voltage measured by the voltage measurement unit 40 or falling within a specific tolerance, from among the divided voltage values, and check information about the first to N^th flooding measurement resistors 31 to 34 associated with the relevant divided voltage value.

In an alternative embodiment, the composite resistance values by the combinations of the first to N^th flooding measurement resistors 31 to 34 instead of the divided voltage values may be stored in the data storage unit 210. Furthermore, the pieces of position information about the first to N^th flooding measurement resistors 31 to 34, corresponding to the respective composite resistance values, may be stored in association with the respective composite resistance values.

The data processing unit 220 may receive the divided voltage values measured by the voltage measurement unit 40 and calculate the composite resistance values of the flooding unit 30 on the basis of the supply voltage value of the power source unit 10 and the resistance value of the reference resistor 20.

In this case, the supply voltage value of the power source unit 10 may be previously stored, or the voltage value of the output terminal of the power source unit 10 may be detected in real time and used. It is preferred that previously stored data be used as the resistance value of the reference resistor 20 in order to improve the data processing speed and to simplify the apparatus.

The data processing unit 220 may compare the calculated composite resistance values with the respective composite resistance values stored in the data storage unit 210, extract a composite resistance value equal to the stored composite resistance value or falling within a specific tolerance, from among the calculated composite resistance values, and check information about the first to N^th flooding measurement resistors 31 to 34 associated with the relevant composite resistance value.

This construction may be used to detect the voltage value of the output terminal of the power source unit 10 in real time and to use the detected voltage value in an operation. Accordingly, the construction may be applied to a variety of equipments using different voltages when the power source of equipment including the circuit is used as the power source unit 10.

The processing unit 200 constructed as above can check whether flooding has occurred and check flooding positions at which the first to N^th flooding measurement resistors 31 to 34 are placed on the basis of information about the first to N^th flooding measurement resistors 31 to 34.

The display unit 300 may be connected to the processing unit 200 and configured to visually inform a user of whether flooding has occurred and of a flooding position.

A display device may be used as the display unit 300. Positions where the first to N^th flooding measurement resistors 31 to 34 are placed may be displayed on a screen of the display device and, at the same time, a position where a submerged flooding measurement resistor is placed may be displayed on a screen of the display device.

In an alternative embodiment, a plurality of flickering lamps may be used as the display unit 300. Only lamps displaying positions where submerged flooding measurement resistors are placed, from among the plurality of flickering lamps, may be flickered.

The display unit 300 may display a flooding position and simultaneously generate an alarm to a user when flooding is detected.

Examples in which the flooding detection apparatus according to the embodiment of the present invention is applied are described below. FIG. 3 is a diagram illustrating an example in which the flooding detection apparatus according to the embodiment of the present invention is applied to a vehicle.

As shown in FIG. 3, the first to N^th flooding measurement resistors 31 to 34 may be installed in the respective elements of a vehicle 1. The first to N^th flooding measurement resistors 31 to 34 are connected in parallel. Furthermore, the flooding contact terminals 31a to 34a may be included in the respective ends of the first to N^th flooding measurement resistors 31 to 34.

The flooding unit 30, including the first to N^th flooding measurement resistors 31 to 34 and the flooding contact terminals 31a to 34a, is connected to the reference resistor 20. The voltage measurement node 50 is formed at the position where the flooding unit 30 and the reference resistor 20 are connected together.

The voltage measurement unit 40 is connected to the voltage measurement node 50. An Analog to Digital Converter (ADC) may be used as the voltage measurement unit 40.

The reference resistor 20 is connected to the power source unit 10. The power source unit 10 may be a vehicle battery embedded in the vehicle 1 or may be an electric charging source separately provided.

The processing unit 200 may be connected to the voltage measurement unit 40 and configured to check whether the elements of the vehicle 1 in which the first to N^th flooding measurement resistors 31 to 34 are installed have submerged. The construction of the processing unit 200 has been described above, and a description thereof is omitted.

The processing unit 200 may be included in an Electronic Control Unit (ECU) 400 embedded in the vehicle 1.

Information about the elements of the vehicle 1 whose flooding has been checked by the processing unit 200 is stored in the ECU 400. When a diagnosis device (not shown) for checking the vehicle is connected to the ECU 400, relevant flooding information is displayed in the diagnosis device so that the subject of repair according to the flooding can be checked.

Whether a vehicle has submerged and a submerged part of the vehicle can be easily checked through the above construction.

The flooding detection apparatus according to the embodiment of the present invention may also be applied to a variety of large-sized machines and electronic equipments in addition to the vehicle.

FIG. 4 is a diagram illustrating an example in which the flooding detection apparatus according to the embodiment of the present invention is applied to a factory.

As shown in FIG. 4, the flooding measurement resistors 31 to 35 may be installed in the respective sections A to E of the factory 2. The flooding measurement resistors 31 to 35 are connected in parallel. Furthermore, the flooding contact terminals 31a to 35a may be provided at the respective ends of the flooding measurement resistors 31 to 35.

The flooding unit 30, including the flooding measurement resistors 31 to 35 and the flooding contact terminals 31a to 35a, is connected to the reference resistor 20. The voltage measurement node 50 is formed at a portion at which the flooding unit 30 and the reference resistor 20 are connected together.

The voltage measurement unit 40 is connected to the voltage measurement node 50. An Analog to Digital Converter (ADC) may be used as the voltage measurement unit 40.

The reference resistor 20 is connected to the power source unit 10.

The processing unit 200 may be connected to the voltage measurement unit 40 and configured to check whether flooding has occurred in each of the sections A to E of the factory 2 in which the flooding measurement resistors 31 to 34 are installed. The construction of the processing unit 200 has been described, and a description thereof is omitted.

The display unit 300 connected to the processing unit 200 may be provided in a control room F in which the entire factory 2 is managed controlled and configured to display flooding occurring in each of the sections A to E of the factory 2 in which the flooding measurement resistors 31 to 34 are installed. As described above, the display device or the plurality of flickering lamps may be used as the display unit 300.

Whether flooding has occurred in a factory and a flooding section can be easily checked through the construction. Furthermore, the present invention may also be applied buildings, large-sized equipments, etc. using a similar construction.

The flooding detection circuit and the flooding detection apparatus according to the present invention can check whether flooding has occurred and a flooding position.

Furthermore, a circuit can be configured at a low price, the circuit can be easily installed, and the number of places whose flooding is measured can be easily increased.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical spirit of the present invention. The scope of the present invention is restricted by only the claims, and a person having ordinary skill in the art to which the present invention pertains may improve and modify the technical spirit of the present invention in various forms. Accordingly, the modifications and modifications will fall within the scope of the present invention as long as they are evident to those skilled in the art.