Patent Application
20220252223
The present invention relates to a residual quantity measuring device for a high pressure container storing liquefied gas and a management system for a high pressure container, and more particularly, to a residual quantity measuring device for a high pressure container storing liquefied gas and a management system for a high pressure container, in which, to monitor normal operations of a temperature sensor part and an LED display part, in a heat dissipation process of supplying electricity to the heating wire to monitor normal operations of the temperature sensor part and the LED display part and interrupting the electricity again, the temperature sensor part and the LED display part may be monitored more accurately in the same heat dissipation condition by eliminating a heat dissipation temperature deviation generated between a heating wire starting portion that is adjacent to the power supply part and a heating wire ending portion, and states of the high pressure containers storing the liquefied gas may be monitored in a central control center.
In general, fire extinguishers for firefighting are classified into powder extinguishers, gas extinguishers, and foamite extinguishers according to kinds of used fire extinguishing chemicals, and a gas extinguisher widely used for large-scale fires, such as oil fires or electric fires, is mainly used as an extinguisher for equipment that uses liquefied gas as fire extinguishing chemicals and is used while on one gas container is not used independently but a plurality of gas containers are connected to each other (see
However, because it is impossible to identify an amount of high-pressure liquefied gas stored in a gas container of the gas extinguisher by naked eyes, a method of measuring a weight of the gas container by using a scale is mainly used as a measurement method currently, but it is difficult to manually carry the gas container of a weight of about 180 kg and measure the weight because the gas container furnished in a ship or a building for firefighting is mainly equipped in a machine room and the like and thus transportation equipment cannot be used, and because the firefighting system has to be stopped to measure the weights of several hundreds of individual containers connected to the system, it violates the Fire Service Act to temporarily stop the system for measurement and the gas container cannot achieve the function of the firefighting equipment at all when a fire occurs during the measurement.
To solve the conventional problem, Korean Patent Application Publication No. 10-2013-0141845 (published on Dec. 17, 2013) suggested a residual quantity measuring device for a high pressure container storing liquefied gas and a management system for a high pressure container employing the same.
In the residual quantity measuring device for a high pressure container storing liquefied gas, as illustrated in
In the LED display part 24, a plurality of LED elements 24a are disposed between upper and lower sides of the body 21 of the measuring device at an equal interval to visually show a liquid surface of the liquefied gas through turning-on/off of the LED elements 24a, and the temperature sensor part 25 includes a plurality of heat sensors 25a corresponding to the locations and the number of the plurality of LED elements 24a on a rear surface of the body 21 that is the plate.
The above-configured conventional residual quantity measuring device for a high pressure container storing liquefied gas allows the residual quantity of the liquefied gas in the interior of the gas container 10 to be identified by naked eyes by comparing and analyzing detection signals delivered from the heat sensors 25 with a microprocessor and turning on and displaying the LED elements 24a corresponding to a border of a gas portion and a liquid portion, a temperature of which abruptly decreases as a result.
Meanwhile, the body 21 that is the plate further includes a heating wire 26 that is adjacent to the temperature sensor part 25, and the heating wire 26 is used to test whether the temperature sensor part 25 and the LED display part 24 are normally operated while firefighting equipment is checked. Furthermore, the body 21 that is the plate includes a check switch for supplying and interrupting electricity to and from the heating wire 26.
When the heating wire 26 emits heat by the electricity supplied by pushing a switch during the check, the heat sensor 25a detects the heat and sends a detection signal to the microprocessor, and the microprocessor turns on all of the LED elements 24a. Then, heat dissipation temperatures of the gas portion and the liquid portion become different while the heating wire 26 is cooled when the electricity to the heating wire 26 is interrupted, and the microprocessor in turn identifies a normal operation by comparing and analyzing detection signals delivered from the heat sensors and turning on the LED elements 24a corresponding to the border of the gas portion and the liquid portion.
However, in the conventional heating wire, a temperature deviation occurs between a starting portion and an ending portion of the heating wire that is adjacent to a power supply part, to which electricity is supplied. That is, as the heating wire is closer to the power supply part, the temperature of the heating wire is higher, and as the heating wire is more distant from the power supply part, the temperature of the heating wire is lower. When the heating wire is cooled as the supply of the electricity is interrupted, the temperature deviation makes it impossible to accurately check the temperature sensor part and the LED display part by determining a difference of the temperatures of the gas portion and the liquid portion under the same heat dissipation condition, and thus the reliability of the check deteriorates.
Furthermore, hundreds of gas containers that are kept and managed are connected to the system according to a size of a ship or a building, but a manager has to directly identify and check the gas containers because it is impossible to monitor the gas containers in a disaster prevention center, and thus inconvenience and inefficiency of the management and the operation are caused.
Accordingly, the present invention has been made in an effort to solve the above-mentioned problems, and provides a residual quantity measuring device for a high pressure container storing liquefied gas and a management system for a high pressure container, in which, to monitor normal operations of a temperature sensor part and an LED display part, in a heat dissipation process of supplying electricity to the heating wire to monitor normal operations of the temperature sensor part and the LED display part and interrupting the electricity again, the temperature sensor part and the LED display part may be monitored more accurately in the same heat dissipation condition by eliminating a heat dissipation temperature deviation generated between a heating wire starting portion that is adjacent to the power supply part and a heating wire ending portion, and states of the high pressure containers storing the liquefied gas may be monitored in a central control center.
An embodiment of the present invention provides a residual quantity measuring device for a high pressure container storing liquefied gas, in which a body that is a plate is attached to an outer wall surface of a gas container, an LED display part, in which a plurality of LED elements are disposed at an equal interval, is provided on a front surface of the body that is the plate, a temperature sensor part having a plurality of heat sensors) in correspondence of the LED elements is provided on a rear surface of the body that is the plate, the body that is the plate has a power supply part and a heating wire, permanent magnets are provided at upper and lower portions of a rear surface of the body that is the plate, and a check switch that supplies and interrupts electricity is provided in the heating wire, wherein the heating wire further includes a pattern vertically connected to a heating wire starting portion and a heating wire ending portion between the heating wire starting portion and the heating wire ending portion at an interval, and that reduces a temperature deviation generated between the heating wire starting portion and the heating wire ending portion in a heat dissipation process of the heating wire by outputting an average value of resistance temperatures according to applied quantities of electricity.
Furthermore, the pattern is formed such that downward vertical lines that form line forms toward a vertically lower side and upward vertical lines, a length of which is the same as that of the downward vertical lines and form line forms toward a vertically upper side are repeatedly formed horizontally at the same interval, and the upward vertical lines and the downward vertical lines are connected by lower connection lines and upper connection lines having a “U” shape, which are alternately and repeatedly formed.
An embodiment of the present invention provides a management system for a high pressure container storing liquefied gas, ion which high-pressure gas containers are connected to each other and are preserved, and are intensely managed by a central control center (a disaster prevention center), wherein the management system is formed by connecting, by wire or wirelessly, the central control center (the disaster prevention center) and residual quantity measuring devices attached to outer walls of the gas containers, wherein, in each of the residual quantity measuring devices, a body that is a plate is attached to an outer wall surface of a gas container, an LED display part, in which a plurality of LED elements are disposed at an equal interval, is provided on a front surface of the body that is the plate, a temperature sensor part having a plurality of heat sensors in correspondence of the LED elements is provided on a rear surface of the body that is the plate, the body that is the plate has a power supply part and a heating wire, permanent magnets are provided at upper and lower portions of a rear surface of the body that is the plate, and a check switch that supplies and interrupts electricity is provided in the heating wire, and wherein the heating wire further includes a pattern vertically connected to a heating wire starting portion and a heating wire ending portion between the heating wire starting portion and the heating wire ending portion at an interval, and that outputs an average value of resistance temperatures according to applied quantities of electricity.
In this way, the present invention provides A residual quantity measuring device for a high pressure container storing liquefied gas, in which a body that is a plate is attached to an outer wall surface of a gas container, an LED display part, in which a plurality of LED elements are disposed at an equal interval, is provided on a front surface of the body that is the plate, a temperature sensor part having a plurality of heat sensors in correspondence of the LED elements is provided on a rear surface of the body that is the plate, the body that is the plate has a power supply part and a heating wire, permanent magnets are provided at upper and lower portions of a rear surface of the body that is the plate, and a check switch that supplies and interrupts electricity is provided in the heating wire, wherein the heating wire further includes a pattern vertically connected to a heating wire starting portion and a heating wire ending portion between the heating wire starting portion and the heating wire ending portion at an interval, and configured to reduce a temperature deviation generated between the heating wire starting portion and the heating wire ending portion in a heat dissipation process of the heating wire by outputting an average value of resistance temperatures according to applied quantities of electricity, whereby in a heat dissipation process of supplying electricity to the heating wire to monitor normal operations of the temperature sensor part and the LED display part and interrupting the electricity again, the temperature sensor part and the LED display part may be monitored more accurately in the same heat dissipation condition by eliminating a heat dissipation temperature deviation generated between the heating wire starting portion that is adjacent to the power supply part and the heating wire ending portion, and an easiness and an efficiency of management and operation as well as a performance and a reliability of a device may be further enhanced because a charging state and a total amount of the gas kept and managed in the keeping unit may be monitored via the residual quantity measuring device attached to the gas container in the central control center (the disaster prevention center) through a communication module.
The above and other aspects, features, and advantages of embodiments of the present will become apparent from the following description of the following embodiments given in conjunction with the accompanying drawings.
However, the present invention is not limited by the embodiments disclosed herein but will be realized in various different forms, and the embodiments are provided only to make the disclosure of the present invention complete and fully inform the scope of the present invention to an ordinary person in the art, to which the present invention pertains, and the present invention will be defined by the scope of the claims. Throughout the specification, the same reference numerals denote the same elements.
In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.
Furthermore, the following terms are those defined in consideration of functions in the embodiments of the present invention, and may become different according to an intention or customs of the operator. Therefore, the definition should be made based on the contents over the specification.
Hereinafter, configurations of a residual quantity measuring device for a high pressure container storing liquefied gas and a management system for a high pressure container employing the same according to the present invention will be described in detail according to embodiments with reference to the accompanying drawings.
In a residual quantity measuring device for a high pressure container storing liquefied gas, as illustrated in
In the residual quantity measuring device for a high pressure container storing liquefied gas, according to the present invention, as illustrated in
The pattern 30a is formed such that downward vertical lines 31 that form line forms toward a vertically lower side and upward vertical lines 33, a length of which is the same as that of the downward vertical lines 31 and form line forms toward a vertically upper side are repeatedly formed horizontally at the same interval, and the upward vertical lines 33 and the downward vertical lines 31 are connected by lower connection lines 32 and upper connection lines 34 having a “U” shape, which are alternately and repeatedly formed.
The pattern 30a achieves temperature compensation for a high temperature and a low temperature that are adjacent and temperature compensation for a low temperature and a high temperature while the applied electricity repeatedly travels from the downward vertical lines 31 to the upward vertical lines 33 through the lower connection lines 32 and in turn travels from the upward vertical lines 33 to the downward vertical lines 31 through the upper connection lines 34.
Accordingly, the heating wire 30 dissipates heat when electric power is applied to the heating wire 30 by pushing the check switch and then the electric power supplied to the heating wire 30 is interrupted, and, then, the pattern 30a vertically connected to a heating wire starting portion and a heating wire ending portion between the heating wire starting portion and the heating wire ending portion at an interval may reduce a temperature deviation generated between the heating wire starting portion and the heating wire ending portion in a heat dissipation process of the heating wire 30 by outputting an average value of resistance temperatures according to applied quantities of electricity, and this means that the temperature sensor part 25 and the LED display part 24 may be monitored more accurately in the same heat dissipation condition of the heating wire 30.
Meanwhile, the body 21 that is the plate includes a start signal input terminal 27 and a start signal output terminal 28 connected to the gas container 10, and further includes a state signal output terminal 29 that transmits a charging state of the gas container 10 to a central control center (a disaster prevention center). The state information of the gas containers is transmitted while sequentially interworking with each other in a time division manner, whereby the state information of the gas containers connected to each other and kept in a preservation unit in unit of several hundred gas containers according to a size of a ship or a building may be prevented from being transmitted to the disaster prevention center at once and it is possible to monitor the states of the gas containers in the central control center (the disaster prevention center).
Furthermore, it is convenient because a power input part 22 that supplies necessary electric power to the body 21 that is the plate may use electric power of a battery as well as an external power source, and an amount of the liquefied gas stored in the gas container 10 may be measured while the battery is carried when the battery is used. The residual quantity measuring device 20 is connected to the central control center (the disaster prevention center) by wire or wirelessly, whereby the management system of the present invention intensively manages the central control center (the disaster prevention center).
Furthermore, the central control center (the disaster prevention center) is managed to receive an amount of the liquefied gas from a current measuring unit 20 attached to the gas container 10 and recognize an amount of the whole stored liquefied gas in the gas container kept and managed in a keeping unit, and is connected to an internet and managed and controlled to be monitored from an outside as well.
In this way, the present invention provides a residual quantity measuring device for a high pressure container storing liquefied gas, in which a body that is a plate is attached to an outer wall surface of a gas container, an LED display part, in which a plurality of LED elements are disposed at an equal interval, is provided on a front surface of the body that is the plate, a temperature sensor part having a plurality of heat sensors in correspondence of the LED elements is provided on a rear surface of the body that is the plate, the body that is the plate has a power supply part and a heating wire, permanent magnets are provided at upper and lower portions of a rear surface of the body that is the plate, and a check switch that supplies and interrupts electricity is provided in the heating wire, wherein the heating wire further includes a pattern vertically connected to a heating wire starting portion and a heating wire ending portion between the heating wire starting portion and the heating wire ending portion at an interval, and configured to reduce a temperature deviation generated between the heating wire starting portion and the heating wire ending portion in a heat dissipation process of the heating wire by outputting an average value of resistance temperatures according to applied quantities of electricity, whereby in a heat dissipation process of supplying electricity to the heating wire to monitor normal operations of the temperature sensor part and the LED display part and interrupting the electricity again, the temperature sensor part and the LED display part may be monitored more accurately in the same heat dissipation condition by eliminating a heat dissipation temperature deviation generated between the heating wire starting portion that is adjacent to the power supply part and the heating wire ending portion, and an easiness and an efficiency of management and operation as well as a performance and a reliability of a device may be further enhanced because a charging state and a total amount of the gas kept and managed in the keeping unit may be monitored via the residual quantity measuring device attached to the gas container in the central control center (the disaster prevention center) through a communication module.
Although the residual quantity measuring device for a high pressure container storing liquefied gas and the management system for a high pressure container employing the same according to the present invention have been described until now, those are simply most preferred embodiments of the present invention and do not limit the present invention, and the scope of the present invention is determined and limited by the attached claims. Furthermore, an ordinary person in the art, to which the present invention pertains, may variously modify and imitate the contents of the specification of the present invention, but the modifications and imitations will also fall within the scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2019-0136185 | Oct 2019 | KR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/KR2020/004494 | 4/2/2020 | WO |
