KR102551072B1 - Precision measuring device for checking relay contact damage - Google Patents

Abstract

The present invention is a precision measuring device for checking relay contact damage implemented in a computing device including one or more processors and one or more memories storing instructions executable by the processors, in a configuration for applying current to a relay module, wherein the a current applicator configured to change the direction of the current into a forward or reverse direction by adjusting the intensity of the current or converting the polarity of the current; As current is applied to the coil terminal of the relay module from the outside, magnetic force is generated in the coil connected to the coil terminal, and the first switch of the relay module contacts the second switch to form a relay contact. a voltage measuring unit configured to measure a first voltage for the relay contact point when an auxiliary current is applied to the relay contact point in a forward direction; In a state in which the measurement of the first voltage is completed, when the current applying unit applies a current to the relay contact in the reverse direction and the measurement of the second voltage for the relay contact is completed by the voltage measuring unit, the first voltage and a damage determining unit that calculates a resistance value of the relay contact based on the second voltage and compares the calculated resistance value with a specified reference resistance value to determine whether or not the resistance of the first switch is damaged; and when damage to the resistance of the relay contact is confirmed by the damage determining unit, damage information based on the confirmed damage is generated and the damage information is output through a display, so that the damage to the resistance of the relay contact is notified. It is characterized in that it comprises a; damage notice unit to. In addition, various embodiments understood through this document are possible.

Description

Precision measuring device for checking relay contact damage {PRECISION MEASURING DEVICE FOR CHECKING RELAY CONTACT DAMAGE}

The present invention relates to a precision measuring device for checking relay contact damage, and more specifically, as a current is applied from the outside to a coil terminal of a relay module, magnetic force is generated in a coil connected to the coil terminal so that the first switch of the relay module operates. 2 In a state in which a relay contact is formed by being in contact with the switch, when the current applying unit applies current to the relay contact in the forward direction, the voltage measuring unit measures the first voltage for the relay contact, and in a state in which the measurement of the first voltage is completed When a current is applied in the reverse direction to the relay contact point, when the voltage measurement unit completes the measurement of the second voltage for the relay contact point, the damage determination unit calculates the resistance value of the relay contact point through the first voltage and the second voltage to calculate the first switch resistance value. The present invention relates to a technique for notifying damage of a relay contact by determining whether or not there is damage to and outputting damage information based on the confirmed damage by a damage notification unit through a display.

In relation to the foregoing, the present invention, a precision measuring device for checking relay contact damage, discloses a technique for accurately measuring the resistance value of a relay contact by excluding the seeback effect. The Seebeck effect is a phenomenon in which electromotive force is generated by the temperature difference between different metal junctions (eg, contacts). More specifically, when the temperature between a contact and another contact is different, a gradient action occurs and additional current flows, resulting in a high temperature area It is a phenomenon in which electromotive force is generated as electrons located at are diffused to a low-temperature region through a conduction region. Existing measuring devices cannot accurately measure the resistance of relay contacts because they measure the sum of the error voltage corresponding to the electromotive force and the normal voltage measured at the relay contacts when checking the voltage of the relay module.

Accordingly, the present invention, a precision measuring device for checking relay contact damage, excludes the error voltage caused by the Seebeck effect from the measured voltage, and calculates the normal voltage to disclose a technique for calculating an accurate resistance value at the relay contact point. .

A relay is a module for controlling the operation of electrical and electronic products with only a switch, and is a relay device that typically opens and closes a sunroof with a switch or folds and unfolds side mirrors, and controls various electronic devices. However, as the number of times the relay is used and the current supplied to the relay is excessive, the change in shape and aging of the relay contact point rapidly increases, which causes fire accidents to occur frequently. Accordingly, the industry is developing various technologies for notifying the risk of fire by checking whether the relay contact is damaged.

As an example, Korean Patent Publication No. 10-2020-0025762 (Relay Fault Diagnosis Method) has a technique for diagnosing a relay fault by using a current flowing in the main relay circuit or a current flowing in the precharge relay circuit when the relay is operated. has been initiated.

However, in the prior art described above, only a technology for diagnosing a failure of a relay based on the value of current flowing in a circuit when the relay is operated is disclosed, and as current is applied to the coil terminal of the relay module from the outside, the coil In a state in which magnetic force is generated in the coil connected to the terminal and the first switch of the relay module contacts the second switch to form a relay contact point, when the current applying unit applies current to the relay contact point in the forward direction, the voltage measurement unit is connected to the relay contact point. When the first voltage is measured, and the current is applied to the relay contact in the reverse direction in a state in which the measurement of the first voltage is completed, and the voltage measurement unit completes the measurement of the second voltage for the relay contact, the damage determination unit first voltage And technology that calculates the resistance value of the relay contact through the second voltage to determine whether there is damage to the first switch, and notifies the risk of fire by outputting damage information based on the confirmed damage to the damage notification unit through a display. Since it is not disclosed, the need for a technology capable of solving this problem is emerging.

That is, the precise measuring device for checking relay contact damage according to the present invention discloses a technique for accurately measuring the resistance value of a relay contact by excluding the seeback effect, and when the temperature between a contact and another contact is different, the slope action As this occurs, an additional current flow occurs, and as electrons located in the high-temperature region pass through the conduction region and diffuse to the low-temperature region, the error voltage due to the Seebeck effect that generates the electromotive force is excluded to calculate the normal voltage, thereby calculating the normal voltage. A technique for calculating an accurate resistance value is disclosed.

Therefore, according to the present invention, as current is applied to the coil terminal of the relay module from the outside through a precision measuring device for checking relay contact damage, magnetic force is generated in the coil connected to the coil terminal, so that the first switch of the relay module is connected to the second switch. In a state in which a relay contact is formed by being contacted, when the current applying unit applies current to the relay contact in the forward direction, the voltage measuring unit measures the first voltage for the relay contact, and in a state in which the measurement of the first voltage is completed, the relay contact When the current is applied in the reverse direction, when the voltage measurement unit completes the measurement of the second voltage for the relay contact, the damage determination unit calculates the resistance value of the relay contact through the first voltage and the second voltage to damage the first switch. By determining whether or not the damage is present, and outputting damage information based on the confirmed damage through the display, the damage notification unit notifies the risk of fire, excluding the error voltage corresponding to the electromotive force due to the Seebeck effect. Accurate measurement can reduce the risk of fire.

In the precision measuring device for checking relay contact damage implemented in a computing device including one or more processors and one or more memories storing commands executable by the processors according to an embodiment of the present invention, a current is applied to a relay module. In the configuration, the current applying unit for adjusting the intensity of the current or converting the polarity of the current to change the direction of the current in the forward or reverse direction; As current is applied to the coil terminal of the relay module from the outside, magnetic force is generated in the coil connected to the coil terminal, and the first switch of the relay module contacts the second switch to form a relay contact. a voltage measuring unit configured to measure a first voltage for the relay contact point when an auxiliary current is applied to the relay contact point in a forward direction; In a state in which the measurement of the first voltage is completed, when the current applying unit applies a current to the relay contact in the reverse direction and the measurement of the second voltage for the relay contact is completed by the voltage measuring unit, the first voltage and a damage determining unit that calculates a resistance value of the relay contact based on the second voltage and compares the calculated resistance value with a specified reference resistance value to determine whether or not the resistance of the first switch is damaged; and when damage to the resistance of the relay contact is confirmed by the damage determining unit, damage information based on the confirmed damage is generated and the damage information is output through a display, so that the damage to the resistance of the relay contact is notified. It is characterized in that it comprises a; damage notice unit to.

The current applying unit is configured to adjust the intensity of the current and change the direction of the current based on a user input input through the display, and when applying the current in the forward direction and the reverse direction, a current having the same intensity It is desirable to apply

The voltage measuring unit, before measuring the first voltage, the first switch of the relay module is in contact with the second switch to form a relay contact, in a state in which no current is applied to the relay contact, the first switch A third voltage that is a voltage based on the electromotive force generated between the relay contact and the coil terminal at a point in time, a fourth voltage that is a voltage based on an electromotive force generated between the relay contact point and the coil terminal at a second point in time, and It is possible to measure a fifth voltage, which is a voltage based on electromotive force generated between the relay contact and the coil terminal.

The damage determination unit, when the measurement of the third voltage, the fourth voltage, and the fifth voltage by the voltage measurement unit is completed, the third voltage, the fourth voltage, and the fifth voltage, respectively, are designated reference voltages. an electromotive force numerical check unit that checks whether it is included in the range; When it is confirmed that at least one of the third voltage, the fourth voltage, and the fifth voltage is a voltage exceeding the specified reference voltage range by performing the function of the electromotive force value checker, some of the checked voltages are transferred to the relay. an error voltage determination unit that determines that the error voltage generates an error in measuring the resistance value of the contact point; and when the measurement of the third voltage, the fourth voltage, and the fifth voltage is completed by the voltage measurer, the fourth voltage and the fifth voltage are compared with each other based on the third voltage. It is possible to include; a comparison voltage checking unit that checks whether the value exceeds a specified reference voltage value.

The damage determination unit determines that the error voltage is confirmed by performing the function of the error voltage determination unit or that the comparison value exceeds the designated reference voltage value by the comparison voltage determination unit, the relay contact through the display. It is possible to stop measuring the voltage for , and request that the temperature of the relay contact be lowered.

The damage determination unit, when the measurement of the first voltage and the second voltage is completed, subtracts a second error voltage corresponding to the electromotive force of the second voltage from the first error voltage corresponding to the electromotive force of the first voltage a resistance value calculator configured to calculate a resistance value of the relay contact through a normal voltage of the first voltage and a normal voltage of the second voltage; and when the function of the resistance calculation unit is completed, the calculated resistance value is compared with a designated reference resistance value, and when the calculated resistance value exceeds the designated reference resistance value, the shape of the first switch is modified. It is possible to include; a damage determination unit that determines that the damage has occurred.

When the damage to the resistance of the relay contact is determined, the damage notifying unit generates damage information including the calculated resistance value against the specified reference resistance value, and outputs the generated damage information through a display to a manager. It is possible to notify the risk of fire occurrence by the relay contact.

The precise measuring device for checking relay contact damage according to the present invention accurately calculates the resistance value of the relay contact by excluding the error voltage due to the seeback effect generated in the relay module, thereby quickly determining whether the relay contact is damaged or not. can

Accordingly, it is possible to reduce the time and labor required to check the relay contact damage and to prepare for a fire in advance.

1 is a diagram for explaining a precision measuring device for checking relay contact damage according to an embodiment of the present invention.
2 is a diagram for explaining a voltage measuring unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.
3 is a block diagram for explaining a damage determining unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.
4 is another block diagram illustrating a damage determination unit of a precision measuring device for checking damage to a relay contact point according to an embodiment of the present invention.
5 is a view for explaining a damage notification unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.
6 is a diagram for explaining an example of an internal configuration of a computing device according to an embodiment of the present invention.

In the following, various embodiments and/or aspects are disclosed with reference now to the drawings. In the following description, for purposes of explanation, numerous specific details are set forth in order to facilitate a general understanding of one or more aspects. However, it will also be appreciated by those skilled in the art that such aspect(s) may be practiced without these specific details. The following description and accompanying drawings describe in detail certain illustrative aspects of one or more aspects. However, these aspects are exemplary and some of the various methods in principle of the various aspects may be used, and the described descriptions are intended to include all such aspects and their equivalents.

References to “embodiment,” “example,” “aspect,” “example,” etc., used in this specification should not be construed as indicating that any aspect or design described is preferable to or advantageous over other aspects or designs. .

Also, the terms "comprises" and/or "comprising" mean that the feature and/or element is present, but excludes the presence or addition of one or more other features, elements and/or groups thereof. It should be understood that it does not.

In addition, terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. The terms and/or include any combination of a plurality of related recited items or any of a plurality of related recited items.

In addition, in the embodiments of the present invention, unless otherwise defined, all terms used herein, including technical or scientific terms, are those commonly understood by those of ordinary skill in the art to which the present invention belongs. have the same meaning. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the embodiments of the present invention, an ideal or excessively formal meaning not be interpreted as

1 is a diagram for explaining a precision measuring device for checking relay contact damage according to an embodiment of the present invention.

Referring to FIG. 1, a precision measuring device (hereinafter referred to as a precision measuring device) for checking relay contact damage includes a current applying unit 101, a voltage measuring unit 103, a damage determining unit 105, and a damage notification unit ( 107) may be included.

According to one embodiment, the current applying unit 101 is a component that applies current to the relay module 110, and changes the direction of the current in a forward or reverse direction by adjusting the intensity of the current or converting the polarity of the current. can be For example, the current applying unit 101 may be a constant current source.

In more detail, the current applying unit 101 is configured to adjust the intensity of the current and change the direction of the current based on a user input input through the display of the precision measuring device 100, forward and reverse directions. When a current is applied to, it may be configured to apply a current of the same intensity.

According to an exemplary embodiment, the voltage measuring unit 103 generates magnetic force in a coil connected to the coil terminal 117 as current is applied to the coil terminal 117 of the relay module 110 from the outside, and the relay module 110 generates magnetic force. In a state where the first switch 111 of the module 110 contacts the second switch 113 to form the relay contact 115, the current applying unit 101 applies current to the relay contact 115 in the forward direction. When applying, the first voltage for the relay contact 115 may be measured.

According to an embodiment, the current applied to the relay contact 115 may be a current applied from the outside, and the current applied to the coil terminal 117 may be a current applied from the current applying unit 101 .

In relation to the above, in the relay module 110, as the coil starts to be heated due to the current applied from the current applying unit 101, the relay contact point 115 is also connected by thermal energy generated from the coil. can be heated At this time, a seeback effect may occur in the relay module 110 .

In relation to the above, the Seebeck effect is a phenomenon in which an electromotive force is generated by a temperature difference between two different metal junctions. When checking the voltage of the relay module 110, the voltage corresponding to the electromotive force is combined with the error voltage Since it is measured, there may be difficulties in accurately measuring the voltage for the relay module 110.

In more detail, the Seebeck effect is a phenomenon in which an electromotive force is generated due to a temperature difference between two different metals (eg, a first metal and a second metal) having a junction, and the first metal and the second metal have different temperatures. This is a phenomenon in which an additional current flow (electromotive force) occurs due to a gradient action, and electromotive force is generated as electrons located in the high temperature region of two different metals with junctions pass through the conduction region and diffuse to the low temperature region. It is a phenomenon that

In relation to the above, the reason why the temperature difference occurs in the relay module is, firstly, as the current is applied to the coil terminal due to the relay operation, the coil is heated by the current and the metal junction (eg, contact) of two different metals This is because the first contact is also heated, and second, when a current is applied to the contact, a temperature difference may occur while generating thermal energy due to resistance of the contact.

Accordingly, when measuring the voltage at the relay contact point, the error voltage due to the electromotive force is added to the normal voltage measured at the relay contact point as the electromotive force generated by the Seebeck effect flows to the relay contact point in the relay module. In measuring resistance values, exact values cannot be calculated. Accordingly, it is difficult to accurately determine whether or not the first switch and the second switch constituting the relay contacts are damaged and the extent of the damage, and a risk of fire may exist.

Accordingly, the present invention calculates an accurate value for the resistance of the relay contact 115 by measuring an accurate voltage at the relay contact by excluding the error voltage generated due to the Seebeck effect, and thereby A technique for performing a damage check on the first switch and the second switch constituting the relay contact 115 may be disclosed.

In relation to the above, the voltage measurer 103 may measure a first voltage of the relay contact point 115 to which current is applied from the current supply unit 101 . That is, the first voltage may be a value obtained by adding the first normal voltage corresponding to the current applied to the relay contact 115 in the forward direction and the first error voltage, which is an error voltage generated by the Seebeck effect.

According to one embodiment, the damage determination unit 105 is in a state in which the measurement of the first voltage is completed, the current applying unit 101 applies a current to the relay contact 115 in the reverse direction, so that the voltage measuring unit 103 When the measurement of the second voltage for the relay contact 1150 is completed by ), the resistance value of the relay contact 115 is calculated based on the first voltage and the second voltage, and the calculated resistance value and the specified reference resistance value It is possible to determine whether or not the resistance of the first switch 111 is damaged by comparing .

In relation to the above, the second voltage may be a voltage obtained by adding the second normal voltage corresponding to the current applied in the reverse direction to the relay contact 115 and the second error voltage, which is an error voltage generated by the Seebeck effect. there is.

For example, the first voltage may be a voltage of a value to be summed with V1 (first normal voltage) + Ve1 (first error voltage), and the second voltage may be -V2 (second normal voltage) + Ve2 ( second error voltage).

However, in relation to the above, the value of the error voltage generated due to the Seebeck effect is different depending on the measurement time and number of measurements for the relay contact 115, so the numerical value of each voltage may be different, but the present invention Since the voltage for the relay contact 115 is measured at short time intervals, it is set assuming that the value of the first error voltage and the value of the second error voltage generated due to the Seebeck effect are the same.

According to an embodiment, the damage determining unit 105 may calculate a resistance value of the relay contact based on the first voltage and the second voltage. In relation to the above, since the first voltage is V1+Ve1 and the second voltage is -V2+Ve2, subtracting the second voltage from the first voltage (V1+Ve1)-(-V2+Ve2)=V1+V2 can be calculated. At this time, since the constant current (I) of the same value is supplied from the outside, the value of V1 and the value of V2 may be the same. That is, V1 + V2 = 2V.

Accordingly, the damage determination unit 105 may divide 2I by 2V to calculate the resistance value of the relay point 115 . In relation to the above, since the 2V is 2IR, it is possible to calculate the resistance value of the relay contact 115 as 2IR/2I=R.

According to an embodiment, when the calculation of the resistance value of the relay contact point 115 is completed, the damage determining unit 105 may compare the calculated resistance value of the relay contact point 115 with a specified reference resistance value. The designated reference resistance value is a reference value based on the normal resistance value of the relay contact 115, and may be input by a manager who manages the precision measuring device 100.

Accordingly, when the resistance value of the relay contact point 115 exceeds a specified range based on the specified reference resistance value, the damage determination unit 105 causes damage to the relay contact point 115 and the resistance value When it is determined that is high, it can be determined that the relay contact point 115 is damaged.

According to an embodiment, when damage to the resistance of the relay contact 115 is confirmed by the damage determining unit 105, the damage notifying unit 107 generates damage information based on the confirmed damage to accurately measure the damage. By outputting damage information through the display of the device 100, the risk of fire may be notified to the manager.

According to one embodiment, the damage information is information including a resistance value of the relay contact 115 and a specified reference resistance value, and notifies the manager whether the relay resistance value exceeds the specified reference resistance value to notify the manager of the fire. It may be information that notifies you of danger.

2 is a diagram for explaining a voltage measuring unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.

Referring to FIG. 2 , a precision measuring device (hereinafter referred to as a precision measuring device) for checking relay contact damage may include a voltage measuring unit 201 (eg, the voltage measuring unit 103 of FIG. 1 ).

According to an embodiment, before measuring the first voltage, the voltage measuring unit 201 may use a first switch (eg, the first switch of FIG. 1 ) of a relay module (eg, the relay module 110 of FIG. 1 ). The switch 111 is brought into contact with the second switch (eg, the second switch 113 of FIG. 1 ) to form a relay contact (eg, the relay contact 115 of FIG. 1 ), but a current applying unit (eg, In a state in which current is not applied to the relay contact by the current applying unit 101 of FIG. 1 , the third voltage, which is a voltage based on the electromotive force generated between the relay contact and the coil terminal at the first time, and the third voltage at the second time, A fourth voltage, which is a voltage based on the electromotive force generated between the relay contact and the coil terminal, and a fifth voltage, which is a voltage based on the electromotive force generated between the relay contact and the coil terminal at the third point in time, may be measured.

For example, before measuring the first voltage, the voltage measuring unit 201 contacts the first switch of the relay module to the second switch to form the relay contact point 203 at the first point in time. In this case, the third voltage V(t), which is a voltage based on the electromotive force generated between the relay contact point 201 and the coil terminal at the first time point, may be measured.

In addition, before measuring the first voltage, the voltage measuring unit 201 is in contact with the second switch of the relay module to form a relay contact point 205 at a second point in time, A fourth voltage V(t2), which is a voltage based on electromotive force generated between the relay contact point 205 and the coil terminal at the second time point, may be measured.

In addition, before measuring the first voltage, the voltage measuring unit 201 contacts the second switch of the relay module to form a relay contact point 207 at a third point in time, A fifth voltage V(t3), which is a voltage based on electromotive force generated between the relay contact point 207 and the coil terminal at the third point in time, may be measured.

In relation to the above, the voltage measuring unit 201 measures the third voltage (V(t)), the fourth voltage (V(t2)) and the fifth voltage (V(t3)) at each time point. The reason is to determine whether the error voltage among the normal voltage and error voltage included in the voltage measured at each time point has an excessively adverse effect on the normal voltage.

That is, the voltage measurement unit 201 measures the voltage at each point in time to check whether the error voltage due to the seeback effect of the precision measuring device has an excessively adverse effect on calculating the normal voltage. can

3 is a block diagram for explaining a damage determining unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.

Referring to FIG. 3 , a precision measurement device (hereinafter, referred to as a precision measurement device) for checking damage to a relay contact may include a damage determining unit 300 (eg, the damage determining unit 105 of FIG. 1 ).

According to one embodiment, the damage determining unit 300 applies a current to the relay contact in the reverse direction by a current applying unit (eg, the current applying unit 101 of FIG. 1 ) in a state in which the measurement of the first voltage is completed. When the measurement of the second voltage for the relay contact is completed by the voltage measuring unit (eg, the voltage measuring unit 103 of FIG. 1), the resistance value of the relay contact is based on the first voltage and the second voltage. It is possible to determine whether the resistance of the first switch is damaged by comparing the calculated resistance value with a specified reference resistance value.

According to one embodiment, the damage determination unit 300 may perform other functions in addition to the above-described functions. Another function performed by the damage determining unit 300 may be a function performed in connection with the function of the voltage measuring unit disclosed in FIG. 2 (eg, the voltage measuring unit 201 of FIG. 2 ).

In relation to the above, the damage determining unit 300 is a detailed configuration for performing the above-mentioned other functions, and includes an electromotive force value checking unit 301, an error voltage determining unit 303, and a comparative voltage checking unit 305. can do.

According to an embodiment, the electromotive force value checking unit 301, when the measurement of the third voltage 301a, the fourth voltage 301b, and the fifth voltage 301c is completed by the voltage measurement unit, the third voltage, the third voltage It may be checked whether each of the 4 voltages and the 5 th voltage is included in a designated reference voltage range.

In relation to the above, the specified reference voltage range is a configuration that is set based on the voltage for the relay contact point measured at each point in time, and is set based on the normal voltage of the voltage for the relay contact point measured at each point in time. It can be a range of voltages. That is, the designated reference voltage range may be configured to check the presence or absence of error voltages excluding normal voltages among the voltages measured at relay contacts generated at each point in time and the value of the error voltages.

According to an embodiment, the error voltage determining unit 303 is designated by at least one of the third voltage 301a, the fourth voltage 301b, and the fifth voltage 301c by the electromotive force value checking unit 301. If it is confirmed that the voltage exceeds the reference voltage range, it may be determined that some of the checked voltages are error voltages that generate errors in measuring the resistance value of the relay contact.

For example, when the third voltage is 10V and the designated reference voltage range for the relay contact at the first time is 6V to 8V, the error voltage determination unit 303 determines that a part of the third voltage, 2V, is determined to be 2V. It can be determined that it is an error voltage that creates an error in measuring the resistance value of the relay contact.

According to an embodiment, the comparison voltage checking unit 305 may, when the measurement of the third voltage 301a, the fourth voltage 301b, and the fifth voltage 301c is completed by the voltage measuring unit, the third voltage By comparing each of the fourth voltage 301b and the fifth voltage 301c based on the voltage 301a, it is possible to determine whether the comparison value exceeds a designated reference voltage value.

For example, the comparison voltage checker 305 measures the third voltage 301a as 10V, the fourth voltage 301b as 13V, and the fifth voltage 301c by the voltage measurer. It can be seen that this was measured at 18V. Thereafter, the comparison voltage checking unit 305 may mutually compare each of the fourth voltage 301b and the fifth voltage 301c based on the third voltage 301a.

In relation to the above, the comparison voltage checking unit 305 measures that the fourth voltage 301b is 3V higher than the third voltage 301a, and the fifth voltage 301c is equal to or greater than the third voltage 301a. It can be seen that more than 7V is measured.

Accordingly, the comparison voltage checking unit 305 may check whether the comparison value exceeds a designated reference voltage value. When the designated reference voltage value is 5V, the comparison voltage checking unit 305 verifies that a comparison value obtained by comparing the third voltage 301a and the fourth voltage 301b is included within the designated reference voltage value. can In addition, the comparison voltage checking unit 305 determines whether a comparison value obtained by comparing the third voltage 301a and the fifth voltage 301c exceeds the specified reference voltage value when the designated reference voltage value is 5V. can confirm that

In relation to the foregoing, the comparison voltage checking unit 305 may determine the fifth voltage 301c when a comparison value obtained by comparing the third voltage 301a and the fifth voltage 301c exceeds the designated reference voltage value. ) of the normal voltage and the error voltage, it can be determined that the value of the error voltage is the error voltage that creates an error in measuring the resistance value of the relay contact.

According to an embodiment, the damage determination unit 300 determines whether the error voltage is confirmed by performing the function of the error voltage determination unit 303 or the comparison value exceeds a designated reference voltage value by the comparison voltage verification unit 305. If it is confirmed, it is possible to request to stop measuring the voltage of the relay contact through the display of the precision measuring device and to lower the temperature of the relay contact.

At this time, the damage determining unit 300 causes the damage notifying unit (eg, the damage notifying unit 107 of FIG. 1) to generate damage information based on the request, and outputs the damage information through the display can do.

4 is another block diagram illustrating a damage determination unit of a precision measuring device for checking damage to a relay contact point according to an embodiment of the present invention.

Referring to FIG. 4 , a precision measuring device (hereinafter referred to as a precision measuring device) for checking damage to a relay contact point may include a damage determining unit 400 (eg, the damage determining unit 105 of FIG. 1 ).

According to one embodiment, the damage determining unit 400 applies a current to the relay contact in the reverse direction by a current applying unit (eg, the current applying unit 101 of FIG. 1 ) in a state in which the measurement of the first voltage is completed. When the measurement of the second voltage for the relay contact is completed by the voltage measuring unit (eg, the voltage measuring unit 103 of FIG. 1), based on the first voltage 401a and the second voltage 401b A resistance value of the relay contact may be calculated, and whether the resistance of the first switch is damaged may be determined by comparing the calculated resistance value with a specified reference resistance value.

According to an embodiment, the damage determining unit 400 may include a resistance value calculating unit 401 and a damage determining unit 403 as detailed components for performing the above-described functions.

According to an embodiment, when the measurement of the first voltage 401a and the second voltage 401b is completed, the resistance value calculating unit 401 generates a first error voltage (corresponding to the electromotive force of the first voltage 401a). The second error voltage 401d corresponding to the electromotive force of the second voltage 401b is subtracted from 401c), and the relay operates through the normal voltage of the first voltage 401a and the normal voltage of the second voltage 401b. The resistance value of the contact can be calculated.

According to an embodiment, the first voltage 401a may be the sum of the first normal voltage, which is a normal voltage, and the first error voltage 401c, and the second voltage 401b is a normal voltage. 2 It may be a configuration in which the settlement voltage and the second error voltage 401d are summed. In this case, the first error voltage 401c and the second error voltage 401d may be voltages corresponding to the electromotive force generated due to the Seebeck effect, and may be generated by thermal energy generated as current is applied to the relay contact. It may be a configuration including the generated voltage.

For example, the resistance value calculator 401 confirms that the normal voltage of the first voltage 401a is 10V and the first error voltage 401c is +5V, and that the normal voltage of the second voltage 401b is normal. It can be seen that the voltage is -10V and the second error voltage 401d is +5V. The values of the normal voltage and the error voltage perform functions of an error voltage determining unit (eg, error voltage determining unit 303 in FIG. 3 ) and a comparison voltage verifying unit (eg, comparing voltage verifying unit 305 in FIG. 3 ). can be confirmed by

Accordingly, the resistance value calculating unit 401 can confirm that the first voltage 401a is 10V+5V and the second voltage 401b is -10V+5V. The resistance value calculator 401 subtracts the second voltage 401b from the first voltage 401a, subtracts the second error voltage 401d from the first error voltage 401c, and subtracts the first voltage 401a. A voltage value of 20V may be obtained by subtracting the normal voltage of 10V of ) and the normal voltage of -10V of the second voltage 401b.

At this time, since voltage is resistance x current, a value obtained by subtracting the normal voltage 10V of the first voltage 401a and the normal voltage -10V of the second voltage 401b may be 2RI. In relation to the above, since I (eg, 2A) is a fixed value supplied from the outside, the resistance numerical calculation unit 401 calculates an R value, that is, through a calculation formula of 2RI/2I, without needing to calculate a separate value. , the resistance value of the relay contact can yield 1 mΩ. (At this time, the basic unit of R is 100)

According to an embodiment, when the function of the resistance calculation unit 401 is completed, the damage determining unit 403 compares the calculated resistance value with a designated reference resistance value, so that the calculated resistance value is the designated reference resistance value. If the value exceeds the value, it may be determined that the first switch is damaged due to deformation in the shape of the first switch.

In relation to the above, the designated reference resistance value is a reference value based on the normal resistance value of the relay contact, and may be input by a manager who manages the precision measurement device.

For example, the damage determination unit 403 may confirm that the function of the resistance value calculation unit 401 is completed and the specified reference resistance value is 80Ω in a state in which the resistance value of the relay contact is calculated as 1mΩ. . Accordingly, the damage determining unit 403 identifies that the resistance of the relay contact exceeds the designated reference resistance value by 20Ω, and since deformation occurs in the shape of the first switch and the resistance value is measured high, the first switch It can be determined that there is damage to the switch.

According to another embodiment, the damage determination unit 403 calculates the resistance value of the relay contact by performing the function of the resistance value calculation unit 401, and the current application unit (eg, the current application of FIG. 1) When the strength of the current applied to the relay module by the unit 101 is changed, the thermoelectric effect based on the changed strength of the current may be measured by measuring the voltage at the relay contact point.

In more detail, the damage determining unit 403 determines, when the strength of the current applied to the relay module is changed in a state in which the resistance value of the relay contact is calculated, the voltage at the relay contact according to the change in the strength of the current. may be measured through a voltage measuring unit (eg, the voltage measuring unit 103 of FIG. 1 ). At this time, the damage determining unit 403 may calculate the normal voltage to be measured at the relay contact through the resistance value of the identified relay contact and the current applied to the relay module. Thereafter, the damage determination unit 403 may measure an error voltage due to a thermoelectric effect by subtracting the calculated normal voltage from the voltage measured at the relay contact point.

Accordingly, the damage determination unit 403 can check the error voltage at the relay contact point according to the current intensity, and measure the thermoelectric effect according to the current intensity.

5 is a view for explaining a damage notification unit of a precision measuring device for checking relay contact damage according to an embodiment of the present invention.

Referring to FIG. 5, a precision measuring device 500 (hereinafter referred to as a precision measuring device) for checking relay contact damage is damage determination unit 501 (eg, damage determination unit 105 of FIG. 1) and damage notification section 503 (eg, damage notification section 107 of FIG. 1 ).

According to an embodiment, the damage determining unit 501 checks the error voltage by performing the function of the error voltage determining unit (eg, the error voltage determining unit 303 of FIG. 3) or the comparison voltage determining unit (eg, the error voltage determining unit 303 of FIG. If it is confirmed by the comparative voltage checking unit 305 of the ) that the comparison value exceeds the specified reference voltage value, it is possible to stop measuring the voltage of the relay contact through the display and request to lower the temperature of the relay contact.

In relation to the above, the damage determining unit 501 may cause the damage notifying unit 503 to generate first damage information corresponding to the request and output the first damage information through a display. The first damage information may be information requesting cooling of the relay contact when a voltage value measured at the relay contact exceeds a safety value.

According to an embodiment, the damage notifying unit 503 determines the damage to the resistance of the relay contact by performing the function of the damage determining unit (eg, the damage determining unit 403 of FIG. 4 ), the specified reference resistance value. Damage information (eg, second damage information) including the calculated resistance value may be generated, and the generated damage information may be output through a display to notify a manager of damage to the resistance of the relay contact.

6 is a diagram for explaining an example of an internal configuration of a computing device according to an embodiment of the present invention.

6 illustrates an example of an internal configuration of a computing device according to an embodiment of the present invention, and in the following description, descriptions of unnecessary embodiments overlapping with those of FIGS. 1 to 5 will be omitted. do it with

As shown in FIG. 6 , a computing device 10000 includes at least one processor 11100, a memory 11200, a peripheral interface 11300, an input/output subsystem ( It may include at least an I/O subsystem (11400), a power circuit (11500), and a communication circuit (11600). In this case, the computing device 10000 may correspond to a user terminal connected to the tactile interface device (A) or the aforementioned computing device (B).

The memory 11200 may include, for example, high-speed random access memory, magnetic disk, SRAM, DRAM, ROM, flash memory, or non-volatile memory. there is. The memory 11200 may include a software module, a command set, or other various data necessary for the operation of the computing device 10000.

In this case, access to the memory 11200 from other components, such as the processor 11100 or the peripheral device interface 11300, may be controlled by the processor 11100.

Peripheral interface 11300 may couple input and/or output peripherals of computing device 10000 to processor 11100 and memory 11200 . The processor 11100 may execute various functions for the computing device 10000 and process data by executing software modules or command sets stored in the memory 11200 .

Input/output subsystem 11400 can couple various input/output peripherals to peripheral interface 11300. For example, the input/output subsystem 11400 may include a controller for coupling a peripheral device such as a monitor, keyboard, mouse, printer, or touch screen or sensor to the peripheral interface 11300 as needed. According to another aspect, input/output peripherals may be coupled to the peripheral interface 11300 without going through the input/output subsystem 11400.

The power circuit 11500 may supply power to all or some of the terminal's components. For example, power circuit 11500 may include a power management system, one or more power sources such as a battery or alternating current (AC), a charging system, a power failure detection circuit, a power converter or inverter, a power status indicator or power It may contain any other components for creation, management and distribution.

The communication circuit 11600 may enable communication with another computing device using at least one external port.

Alternatively, as described above, the communication circuit 11600 may include an RF circuit and transmit/receive an RF signal, also known as an electromagnetic signal, to enable communication with another computing device.

The embodiment of FIG. 6 is only an example of the computing device 10000, and the computing device 11000 may omit some components shown in FIG. 6, further include additional components not shown in FIG. 6, or 2 It may have a configuration or arrangement combining two or more components. For example, a computing device for a communication terminal in a mobile environment may further include a touch screen or a sensor in addition to the components shown in FIG. , Bluetooth, NFC, Zigbee, etc.) may include a circuit for RF communication. Components that may be included in the computing device 10000 may be implemented as hardware including one or more signal processing or application-specific integrated circuits, software, or a combination of both hardware and software.

Methods according to embodiments of the present invention may be implemented in the form of program instructions that can be executed through various computing devices and recorded in computer readable media. In particular, the program according to the present embodiment may be configured as a PC-based program or a mobile terminal-only application. An application to which the present invention is applied may be installed in a user terminal through a file provided by a file distribution system. For example, the file distribution system may include a file transmission unit (not shown) that transmits the file according to a request of a user terminal.

The device described above may be implemented as a hardware component, a software component, and/or a combination of hardware components and software components. For example, devices and components described in the embodiments may include, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable gate array (FPGA), It may be implemented using one or more general purpose or special purpose computers, such as a programmable logic unit (PLU), microprocessor, or any other device capable of executing and responding to instructions. A processing device may run an operating system (OS) and one or more software applications running on the operating system. A processing device may also access, store, manipulate, process, and generate data in response to execution of software. For convenience of understanding, there are cases in which one processing device is used, but those skilled in the art will understand that the processing device includes a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that it can include. For example, a processing device may include a plurality of processors or a processor and a controller. Other processing configurations are also possible, such as parallel processors.

Software may include a computer program, code, instructions, or a combination of one or more of the foregoing, which configures a processing device to operate as desired or processes independently or collectively. You can command the device. Software and/or data may be any tangible machine, component, physical device, virtual equipment, computer storage medium or device, intended to be interpreted by or to provide instructions or data to a processing device. may be permanently or temporarily embodied in Software may be distributed on networked computing devices and stored or executed in a distributed manner. Software and data may be stored on one or more computer readable media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the medium may be specially designed and configured for the embodiment, or may be known and usable to those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. - includes hardware devices specially configured to store and execute program instructions, such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include high-level language codes that can be executed by a computer using an interpreter, as well as machine language codes such as those produced by a compiler. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

As described above, although the embodiments have been described with limited examples and drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques may be performed in an order different from the method described, and/or components of the described system, structure, device, circuit, etc. may be combined or combined in a different form than the method described, or other components may be used. Or even if it is replaced or substituted by equivalents, appropriate results can be achieved. Therefore, other implementations, other embodiments, and equivalents of the claims are within the scope of the following claims.

Claims (7)

In the precision measuring device for relay contact damage check implemented in a computing device including one or more processors and one or more memories for storing instructions executable by the processor,
A configuration for applying a current to the relay module, a current applying unit that adjusts the intensity of the current or converts the polarity of the current to change the direction of the current in a forward or reverse direction;
As current is applied to the coil terminal of the relay module from the outside, magnetic force is generated in the coil connected to the coil terminal, and the first switch of the relay module contacts the second switch to form a relay contact. a voltage measuring unit configured to measure a first voltage for the relay contact point when an auxiliary current is applied to the relay contact point in a forward direction;
In a state in which the measurement of the first voltage is completed, when the current applying unit applies a current to the relay contact in the reverse direction and the measurement of the second voltage for the relay contact is completed by the voltage measuring unit, the first voltage and a damage determining unit that calculates a resistance value of the relay contact based on the second voltage and compares the calculated resistance value with a specified reference resistance value to determine whether or not the resistance of the first switch is damaged; and
When damage to the resistance of the relay contact is confirmed by the damage determination unit, damage information based on the confirmed damage is generated and the damage information is output through a display to notify the damage to the resistance of the relay contact Including; damage notice;
The current applying unit,
A configuration for adjusting the intensity of the current and changing the direction of the current based on a user input input through the display, and applying a current of the same intensity when applying the current in the forward direction and the reverse direction,
The voltage measuring unit,
Before measuring the first voltage, the first switch of the relay module is contacted with the second switch to form a relay contact, but in a state in which no current is applied to the relay contact, the relay at a first time point. A third voltage, which is a voltage based on the electromotive force generated between the contact and the coil terminal, a fourth voltage, which is a voltage based on the electromotive force generated between the relay contact and the coil terminal at a second time point, and the relay contact point at a third time point; Measuring a fifth voltage, which is a voltage based on the electromotive force generated between the coil terminals,
The damage judgment unit,
When the measurement of the third voltage, the fourth voltage, and the fifth voltage is completed by the voltage measuring unit, the relay contact at which each of the third voltage, the fourth voltage, and the fifth voltage is measured at each point in time. As a stable voltage range that is set based on the normal voltage for, among the voltages measured at the relay contact point generated at each point in time, the presence or absence of error voltage excluding the normal voltage and the value of the error voltage can be checked in the specified reference voltage range. an electromotive force value confirmation unit to check whether it is included;
When it is confirmed that at least one of the third voltage, the fourth voltage, and the fifth voltage is a voltage exceeding the specified reference voltage range by performing the function of the electromotive force value checker, some of the checked voltages are transferred to the relay. an error voltage determination unit that determines that the error voltage generates an error in measuring the resistance value of the contact point; and
When the measurement of the third voltage, the fourth voltage, and the fifth voltage is completed by the voltage measurer, the fourth voltage and the fifth voltage are compared with each other based on the third voltage, and a comparison value is obtained. A comparison voltage checking unit for checking whether the specified reference voltage value is exceeded; Including,
The damage judgment unit,
When the error voltage is confirmed by performing the function of the error voltage determination unit or it is confirmed that the comparison value exceeds the specified reference voltage value by the comparison voltage verification unit, the voltage for the relay contact is measured through the display. Stop and request that the temperature of the relay contact be lowered,
The damage judgment unit,
When the measurement of the first voltage and the second voltage is completed, a second error voltage corresponding to the electromotive force of the second voltage is subtracted from the first error voltage corresponding to the electromotive force of the first voltage, and a resistance value calculator configured to calculate a resistance value of the relay contact through a normal voltage and a normal voltage of the second voltage; and
When the function of the resistance calculation unit is completed, the calculated resistance value is compared with a designated reference resistance value, and when the calculated resistance value exceeds the designated reference resistance value, the shape of the first switch is deformed. Including; a damage determining unit that determines that it has occurred and is damaged;
The damage notification unit,
If damage to the resistance of the relay contact is determined, damage information including the calculated resistance value against the specified reference resistance value is generated, and the generated damage information is output through a display to prevent damage to the relay contact to the manager. A precision measuring device for checking relay contact damage, characterized in that the known. delete delete delete delete delete delete

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