KR20190133317A - current source based device for monitoring temperature detecting cable - Google Patents

Abstract

The present invention provides a thermal sensitive monitoring technique based on a current source, capable of flowing a constant current to the thermal sensitive wire irrespective of the length of the thermal line installed in a field. As configured to flow a constant current through a current source in a closed thermal sensitive wire, a constant current source can be adopted without a separate auxiliary unit regardless of the length of the thermal sensitive wire installed in the field. When a short circuit occurs in a position adjacent to a current source without the separate auxiliary unit, an apparatus for monitoring the thermal sensitive wire can be smoothly operated. According to the present invention, regardless of the length of the thermal sensitive wire installed in the field, a predetermined current source may flow a constant constant-current on the thermal sensitive line without a separate auxiliary unit.

Description

Current source based device for monitoring temperature detecting cable

The present invention is a current source-based thermal line monitoring technology that can always flow a constant current to the thermal line irrespective of the length of the thermal line installed in the field.

More specifically, the present invention is configured to flow a constant current through the current source in the closed thermal line, it is possible to adopt a constant current source without a separate auxiliary unit irrespective of the length of the thermal line installed in the field and a separate auxiliary unit The present invention relates to a technology in which a thermal radiation monitoring device operates smoothly even when a short circuit occurs in a position adjacent to a current source without the use of the same.

In general, the thermal wire is arranged to closely contact with the power cable along the longitudinal direction of the power cable. As a result, when heat is generated in the power cable, the twisted portion of the thermal wire is configured to short-circuit, thereby confirming that heat is generated in the power cable.

1 is an exemplary view showing a cross section of a general thermal line. 1 is a cross-sectional view of the thermal line 10, so the strand A 11 and strand B 12 are not twisted with each other.

However, the thermal wire 10 is arranged in the conductor shell 13, strand A (11) and strand B (12) twisted with each other.

The strand A (11) and the strand B (12) are configured such that each of the conductive cores (11a, 12a) can be energized, and each of the conductive cores (11a, 12a) is provided with a respective core shell (11b, 12b). It is configured to be wrapped.

Each of the lead cores 11a and 12a is configured to be closed to each other so that electricity flows. In addition, the core shells 11b and 12b have a property of melting by heat at a predetermined temperature.

As a result, when heat is applied to the thermal wire 10, the respective core cores 11a and 12a are shorted as the core shells 11b and 12b melt.

The external monitoring device may know that heat is applied to the thermal line 10 through a short circuit of the thermal line 10.

On the other hand, in order to flow electricity to the thermal line 10 is generally connected to a voltage source for generating DC to the thermal line 10. Details of this will be described with reference to FIG. 2 below.

2 is an exemplary view schematically illustrating a general voltage source based thermal line monitoring device. Referring to [FIG. 2], strand A (11) and strand B (12) are twisted into two strands as shown in FIG.

In addition, the voltage source-based thermal line monitoring device 20 to allow electricity to flow through the thermal line 10 composed of two strands, as shown in FIG. 2, and a voltage source 22 connected to both ends of the thermal line 10. By providing the relay switch 21, the two strands of the thermal wire 10 are energized in a closed manner.

As a result, when electricity flows through the thermal line 10 by the voltage source 22, the relay switch 21 reacts. At this time, the reaction detection microcomputer 23 is connected to the relay switch 21 to detect the reaction of the relay switch 21, it is possible to check whether the thermal line 10 is short-circuited.

In addition, when it is determined that the thermal sensing line 10 is short-circuited, the reaction detecting microcomputer 23 may sense the short-circuited position of the thermal sensing line 10 by sensing a current flowing from the voltage source 22 to the thermal sensing line 10.

Here, since the constant voltage of the voltage source 22 is fixed and the resistance per unit length of the heat sensitive line 10 is determined, when the current flowing in the heat sensitive line 10 adjacent to the current voltage source 22 is sensed, Ohm's law (V) is determined. = IR), the value of the corresponding resistance indicates the short-circuit position of the thermal line 10.

However, when a short circuit occurs in the thermal line 10 very close to the voltage source based thermal line monitoring device 20, the thermal line 10 corresponding to the short circuit position of the voltage source 22 and the thermal line 10 may be The extremely short length makes the resistance close to zero.

As a result, a very large current flows suddenly in the thermal line 10 corresponding between the voltage source 22 and the short-circuit position, resulting in a problem that the voltage source-based thermal line monitoring device 20 fails.

In order to solve this problem, the voltage source-based thermal line monitoring device 20 is moved around the voltage source 22 as described above by placing the current limiting resistor 24 adjacent to the voltage source 22 as shown in FIG. It is possible to prevent a lot of current flowing suddenly due to the hot wire 10 short.

In order to allow the constant current to flow in the thermal line 10, when the voltage source based thermal line monitoring device 20 is manufactured, the voltage source 22 also applies a constant voltage corresponding to the constant current in consideration of the resistance of the thermal line 10. It must be constructed.

As a result, the thermal line resistance 10R 'also varies according to the thermal wires 10 arranged in various lengths corresponding to the various lengths of the power cable, so that the thermal wires 10 having various lengths through the specific voltage source 22 are different. In order to allow a constant current to flow through the corresponding thermal line 20, the resistance value is checked, and correspondingly, the current limiting resistor 24 also includes various patterns having different resistance values. 20) There is a problem to be applied differently.

The present invention has been proposed in view of the above, and an object of the present invention is to monitor a current source-based thermal line that allows a predetermined current source to flow a constant constant current to the thermal line at all times regardless of the length of the thermal line installed in the field. In providing a device.

In order to achieve the above object, the present invention is a device for monitoring the heat-sensitive wires arranged side by side so that the two wires are energized along the length of the power cable, based on the current source, connected to each end of the two strands from the outside A short circuit reaction part operating in response to a power supply and operating in response to a short circuit when two strands are shorted to each other; A current source connected in series with the short-circuit reacting unit at each end of the two strands to operate the short-circuit reacting unit by supplying a constant current to the heat-sensitive line regardless of the length of the heat-sensitive line; When the two strands are mutually shorted and the constant current supplied from the current source to the short-circuit reacting unit is cut off, a reaction sensing micom for detecting a reaction of the shorting reacting unit in response to the blocking of the constant current.

Here, the short-circuit reaction unit is a relay switch indicating a short-circuit state in response to the power delivered to the thermal wire, and when the two strands are mutually shorted, the relay switch is switched to the open state corresponding to the short circuit of the two strands; The reaction sensing microcomputer may be configured to detect an open state of the relay switch in response to the interruption of the constant current when the constant current supplied from the current source to the relay switch is interrupted by two short circuits.

In addition, the reaction detection microcomputer may be configured to detect the current voltage of the current source and determine the short-circuit position of the two strands when it detects that the relay switch is open.

On the other hand, the short-circuit reacting unit, a sensing resistor that represents the potential difference at both ends in response to the power delivered to the thermal line, and when the two strands mutually short-circuit corresponding to the short circuit of the two strands showing a potential difference at both ends thereof; When the constant current supplied from the current source to the sensing resistor is cut off by the mutual short-circuit of the two strands, the reaction sensing microcomputer may be configured to sense the potential difference at both ends of the sensing resistor in response to the blocking of the constant current.

In addition, the reaction detecting microcomputer may be configured to detect the current voltage of the current source and determine the short-circuit position of the two strands when detecting the potential difference at both ends of the sensing resistor.

In addition, the reaction detection microcomputer may be configured to determine that at least one of the two strands is open when the current voltage of the current source is detected to be zero.

The present invention is configured such that the current source flows a constant current to the thermal line while the current source is connected to the closed thermal line, thereby maintaining the durability of the thermal line monitoring device even when a thermal line is shorted at a position adjacent to the current source. It can show advantages.

In addition, the present invention exhibits an advantage that a predetermined current source can flow a constant constant current to the thermal line always without a separate auxiliary unit irrespective of the length of the thermal line installed in the field.

In addition, the present invention also exhibits the advantage of detecting the short-circuit position of the thermal line by sensing the current voltage appearing in the current source.

1 is an exemplary view showing a cross section of a general thermal line,
2 is an exemplary view schematically showing a thermal line monitoring device based on a general voltage source;
3 is an exemplary view schematically showing a current source based thermal ray monitoring apparatus according to a first embodiment of the present invention;
4 is an exemplary view schematically showing a current source based thermal ray monitoring apparatus according to a second embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

3 is an exemplary view schematically illustrating a current source based thermal ray monitoring apparatus according to a first embodiment of the present invention.

Referring to FIG. 3, a first embodiment of the present invention is arranged side by side so that two conductors consisting of strand A 11 and strand B 12 are energized along a length direction of a power cable (not shown). The apparatus 100 for monitoring the thermal line 10 based on the current source 120 includes a relay switch 111 as a short circuit reaction unit, a current source 120, and a reaction sensing micom 130.

First, the relay switch 111 as a short-circuit reaction part is a strand A (11) and strand B (12) is arranged in a closed manner as the current source 120 is connected to both ends of the two strands of the thermal wire (10) To form a thermal strand 10 of two strands.

At this time, the two lines of the thermal wire 10 by the current supplied from the current source 120 represents a state of being energized closed.

In addition, the relay switch 111 as a short-circuit reacting unit operates in response to a power source transmitted from the current source 120 to the thermal line 10 and when the two strands of the thermal line 10 are mutually shorted at any position, It works in response.

For example, the relay switch 111 represents a short-circuit state in response to a power transmitted to the thermal line 10 through the current source 120, and the relay switch 111 has two strands of the thermal line 10 at a certain position. When short-circuited with each other, it may be configured to switch to the open state in response to the short-circuit of the two thermal wires 10.

At this time, the current source 120 is connected in series with the relay switch 111, which is a short-circuit reaction section, at each end of the two thermal wires 10 to supply a constant current to the thermal wire 10 regardless of the length of the thermal wire 10. Accordingly, the relay switch 111 which is a short circuit reaction part is operated.

Here, since the current supplied from the current source 120 is transmitted to the thermal line 10, even when the thermal line 10 adjacent to the current source 120 is short-circuited, the current source 120 converts the constant current to the thermal line 10. Since the current source 120 operates in a direction of lowering the voltage internally, the current source 120 can maintain its durability without failure.

The reaction detecting microcomputer 130 is a short-circuit reacting unit in response to the blocking of the constant current when the two thermal wires 10 are short-circuited to each other and the constant current supplied from the current source 120 to the relay switch 111 is a short circuit reaction unit. It is configured to detect the open state of the relay switch 111.

In addition, the reaction detecting microcomputer 130 is configured to detect the current voltage of the current source 120 to determine the short-circuit position of the two strands of the thermal wires 10 when detecting that the relay switch 111 is in an open state.

For example, when the reaction detecting microcomputer 130 obtains the current voltage of the current source 120, the resistance value may be calculated based on the current voltage and the constant current value of the current source 120 according to Ohm's law (V = IR).

The length of the thermal wire 10 can be calculated from the resistance value of the thermal wire 10 corresponding to the previously calculated resistance value for the thermal wire 10 having a predetermined resistance value per unit length from the calculated resistance value. have.

As a result, the position is short-circuited when the calculated thermal line 10 is measured from the current source 120.

On the other hand, the voltage of the current source 120 in FIG. 3 is a value obtained by multiplying the constant current of the current source 120 by the sum of the thermal resistance 10R 'and the switch resistance 111a.

In addition, the reaction detection microcomputer 130 is configured to determine that any one or more strands of the two heat sensitive lines 10 are open when the current voltage of the current source 120 is zero.

That is, if the thermal line 10 between the current source 120 and the relay switch 111 is broken, the current from the current source 120 will not be transmitted to the thermal line 10. As a result, the current voltage of the current source 120 represents zero.

4 is an exemplary view schematically showing a current source based thermal ray monitoring apparatus according to a second embodiment of the present invention.

According to the second embodiment of the present invention, a heat source 10 is disposed side by side so that two conductors consisting of Strand A 11 and Strand B 12 are energized along a length direction of a power cable (not shown). 120, the monitoring device 100 is configured to include a sensing resistor 112, a current source 120, and a reaction sensing microcomputer 130 as a short circuit reaction unit.

First, the sensing resistor 112 as a short-circuit reaction part has a strand A (11) and a strand B (12) arranged in a closed type as the current source (120) is connected to both ends of the two strands of the thermal wire (10). To form a thermal strand 10 of two strands.

At this time, the two lines of the thermal wire 10 by the current supplied from the current source 120 represents a state of being energized closed.

In addition, the sensing resistor 112 as a short-circuit reacting unit operates in response to the power transmitted from the current source 120 to the thermal line 10, and when the two strands of thermal line 10 are mutually shorted at any position, It works in response.

For example, when a constant current is transmitted from the current source 120 to the sensing resistor 112 through the thermal line 10, the voltage at both ends of the sensing resistor 112 indicates a constant value, and the two thermal lines 10 are short-circuited to each other. In this case, since no current flows through the sensing resistor 112, the voltage at both ends of the sensing resistor 112 represents “0”.

In this case, the reaction sensing microcomputer 130 is configured to determine that the thermal line 10 operates without abnormality when the voltage across the sensing resistor 112 indicates a constant value, and the voltage across the sensing resistor 112 is "0". It is configured to determine that an abnormality occurs in the thermal line 10 when indicating.

On the other hand, since the current source 120 is connected in series with the sensing resistor 112 to supply a constant current to the thermal line 10 irrespective of the length of the thermal line 10, the sensing resistor 112, which is a short-circuit reaction part, may be operated. have.

Here, since the current supplied from the current source 120 is transmitted to the heat sensitive line 10, even when the heat sensitive line 10 adjacent to the current source 120 is short-circuited, the current source 120 converts the constant current to the heat sensitive line 10. Since the current source 120 operates in a direction of lowering the voltage internally, the current source 120 can maintain its durability without failure.

The reaction detecting microcomputer 130 of the sensing resistor 112 responds to the blocking of the constant current when the constant current supplied from the current source 120 to the sensing resistor 112 is cut off by the mutual short circuit of the two strands 10. It is configured to detect potential difference at both ends.

In addition, the reaction sensing microcomputer 130 is configured to detect the current voltage of the current source 120 to determine the short-circuit position of the two strands of the thermal wires 10 when detecting the potential difference at both ends of the sensing resistor 112.

For example, when the reaction detecting microcomputer 130 obtains the current voltage of the current source 120, the resistance value may be calculated based on the current voltage and the constant current value of the current source 120 according to Ohm's law (V = IR).

The length of the thermal wire 10 can be calculated from the resistance value of the thermal wire 10 corresponding to the previously calculated resistance value for the thermal wire 10 having a predetermined resistance value per unit length from the calculated resistance value. have.

As a result, the position is short-circuited when the calculated thermal line 10 is measured from the current source 120.

On the other hand, the voltage of the current source 120 in FIG. 4 is a value obtained by multiplying the constant current of the current source 120 by the sum of the thermal resistance 10R 'and the resistor resistance 112a.

In addition, the reaction detecting microcomputer 130 is configured to determine that any one or more strands of the two strands are open when the current voltage of the current source 120 is detected to be zero.

That is, if the thermal line 10 between the current source 120 and the sensing resistor 112 is broken, the current from the current source 120 will not be transmitted to the thermal line 10. As a result, the current voltage of the current source 120 represents zero.

10: heat ray
10R, 10R ': Thermal Wire Resistance
11: strand A
11a: wire core
11b: core shell
12: strand B
12a: Lead core
12b: core shell
13: wire sheath
20: heat source monitoring device based on voltage source
21: relay switch
21R: Switch Resistor
22: voltage source
23: reaction detection microcomputer
24: current limiting resistor
100: current source based thermal line monitoring device according to the present invention
111: relay switch
111a: switch resistance
112: sensing resistor
112a: resistor resistance
120: current source
130: reaction detection microcomputer

Claims (6)

As a device for monitoring the heat-sensitive wire (10) arranged side by side so that two conductors are energized along the length of the power cable,
A short-circuit reaction part connected to each end of the two strands to operate in response to a power transmitted from the outside to the thermal line, and when the two strands are mutually shorted;
A current source 120 connected to each of the two strands in series with the short-circuit reacting unit to operate the short-circuit reacting unit by supplying a constant current to the heat-sensitive line regardless of the length of the heat-sensitive line;
A reaction sensing micom 130 for detecting a reaction of the shorting reaction part in response to the blocking of the constant current when the two strands are mutually shorted and the constant current supplied from the current source to the shorting reaction part is cut off;
The current source based thermal line monitoring device is configured to include.
The method according to claim 1,
The short circuit reaction unit,
A relay switch 111 indicating a shorted state in response to a power transmitted to the thermal wire, and switching to an open state in response to a short circuit of the two strands when the two strands are mutually shorted;
It is configured to include,
The reaction detecting microcomputer 130 detects an open state of the relay switch in response to the interruption of the constant current when the constant current supplied from the current source to the relay switch is interrupted by the short circuit of the two strands. Thermal source monitoring device based on the current source.
The method according to claim 2,
The reaction detecting micom 130 is a current source based thermal line monitoring device, characterized in that configured to determine the short-circuit position of the two strands by detecting the current voltage of the current source when detecting that the relay switch is open.
The method according to claim 1,
The short circuit reaction unit,
A sensing resistor 112 indicating a potential difference at both ends thereof in response to a power delivered to the thermal line, and a potential difference at both ends thereof in response to the short circuit of the two strands when the two strands are mutually shorted;
It is configured to include,
When the constant current supplied from the current source to the sensing resistor is cut off by the mutual short-circuit of the two strands, the reaction detecting micom 130 detects that there is no potential difference at both ends of the sensing resistor in response to the blocking of the constant current. Thermal source monitoring device based on current source.
The method according to claim 4,
The reaction detecting microcomputer 130 is a current source-based thermal line monitoring device, characterized in that configured to determine the short-circuit position of the two strands by detecting the current voltage of the current source when detecting the potential difference at both ends of the sensing resistor.
The method according to claim 3 or 5,
The reaction sensing micom 130 is a current source based thermal line monitoring device, characterized in that configured to determine that any one or more of the two strands of the open, when the current voltage of the current source is zero.

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