JP2006126950A - Information processing method and information processor regarding safety of pole - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide technology for confirming the safety of a pole under the sufficient consideration of the safety of the pole compared with the conventional manner. <P>SOLUTION: This information processing method comprises: a process for calculating a combined moment for an installation set to height which is not shorter than the specific height of a specific pole and an installation to be set when instructed, and for storing it in a storage device; a process for acquiring a calm time permissible reference value in the specific height of the specific pole, and for outputting the comparison result of the calm time permissible reference value and the value of the combined moment stored in the storage device or the calm time permissible reference value and the value of the combined moment; and a process for acquiring a strong wind time permissible reference value associated with a load leading to cause any permissible crack in the specific height of the specific pole, and for outputting the comparison result of the strong wind time permissible reference value and the value of a second combined moment stored in the storage device or the strong wind time permissible reference value and the value of the second combined moment. Thus, it is possible to confirm safety in more points of view than the conventional manner. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for confirming safety of a utility pole.

  Conventionally, with regard to the safety of utility poles, the "Ministerial Ordinance for Establishing Technical Standards for Electrical Equipment" (Revised July 2004), Chapter 2 Section 3, "Preventing Risks due to Collapse of Support Materials" Therefore, in accordance with “Interpretation of Technical Standards for Electrical Equipment” and “Distribution Regulations”, the load received by utility poles and wires in strong winds is converted to the moment at the most severe point of the utility pole, The safety of the utility pole is confirmed by comparing the design strength of the utility pole.

  However, with the advancement of a highly information-oriented society, the types and number of wires (including communication lines) connected to utility poles have increased, and the poles have become congested. In some cases, it may not be sufficient to compare the strength alone.

In addition, although there is a disclosure in Japanese Patent Laid-Open No. 10-123926 regarding the design of the utility pole, such a problem is not considered.
JP-A-10-123926 Technical standards for electrical equipment Ministry of Economy, Trade and Industry Nuclear Safety and Safety Agency edited by Bunichi General Publishing ISBN 4-8299-2016-5 Distribution Regulations (Low Voltage and High Voltage) Electrical Technology Regulations Distribution Edition Electricity Distribution Special Committee Japan Electric Association ISBN4-88948-025-0

  As described above, the conventional strength evaluation alone on the ground of a power pole does not necessarily assume all accidents that can actually occur, and there have been cases where sufficient consideration has not been given to the safety of the power pole.

  Accordingly, an object of the present invention is to provide a technique for considering the safety of a utility pole from a new viewpoint.

  The information processing method related to the safety of the utility pole according to the first aspect of the present invention is to be installed at a height higher than a specific height of a specific power pole and when instructed. A composite moment calculating step for calculating a composite moment for the installed object and storing it in a storage device, and obtaining a no-wind allowable reference value at a specific height for a specific power pole, and the no-wind allowable reference value and the storage device And a step of outputting a comparison result with the value of the composite moment stored in the above, or an allowable reference value during no wind and a value of the composite moment. In this way, when the combined moment is calculated not only on the ground but also at an arbitrary height in the normal time without considering the wind pressure, the safety of the utility pole in the normal time can be determined in consideration of many cases. It becomes like this. Note that the no-wind allowable reference value may be stored in advance in a table or the like for each height, or may be calculated according to a predetermined curve or straight line.

  The information processing method related to the safety of the utility pole according to the second aspect of the present invention is to be installed at a height higher than a specific height of a specific power pole and when instructed. Calculating a second combined moment when a predetermined wind pressure is taken into consideration for the installation to be obtained, storing the second combined moment in a storage device, and an allowable reference in a strong wind at a specific height for a specific power pole Obtaining a value, and outputting a comparison result between the allowable reference value during strong wind and the value of the second combined moment stored in the storage device, or the allowable reference value during strong wind and the value of the second combined moment. . As described above, when the wind pressure is taken into consideration, it can be confirmed whether or not the pressure can be suppressed to a predetermined level or less.

  In the first aspect of the present invention, when a predetermined wind pressure is taken into consideration for an installation installed at a height higher than a specific height and an installation to be installed when instructed. A second combined moment calculating step for calculating the second combined moment and storing it in the storage device, and obtaining a strong wind allowable reference value at a specific height for a specific power pole, and storing the strong wind allowable reference value and the storage A step of outputting a comparison result with the value of the second combined moment stored in the apparatus or a reference value for the allowable strong wind and the value of the second combined moment may be further included.

  In addition, the specific height described above may be the height at which the electric wire is laid or the ground. The height may be arbitrary, but may be limited to the above-described one for reducing the processing amount.

  Furthermore, the specific height may be set and changed to the height of the electric line that is hung on the specific power pole in order from the top of the specific power pole. In this way, it is possible to confirm all the changing points of the composite moment.

  Further, referring to the map data storage unit, a step of displaying a map of a specific range including the display of the power pole symbol, and the data of the power pole is displayed in accordance with the selection of the power pole in the map of the specific range And a step of reading from the equipment data storage unit, and a step of receiving input of data about an installation to be installed and storing the input data in a storage device. Then, the data read from the map data storage unit and the facility data storage unit may be used as data for a specific utility pole, and the composite moment may be calculated using the input data stored in the storage device.

  It is also possible to create a program for causing a computer to execute the information processing method according to the present invention. The program is, for example, a storage medium such as a flexible disk, a CD-ROM, a magneto-optical disk, a semiconductor memory, a hard disk, or the like. It is stored in a storage device. In some cases, digital signals are distributed over a network. Note that data being processed is temporarily stored in a storage device such as a computer memory.

  According to the present invention, it becomes possible to consider the safety of a utility pole from a new viewpoint.

  FIG. 1 shows a system outline diagram according to an embodiment of the present invention. For example, in a network 1 such as an in-house LAN (Local Area Network), a user terminal A, a user terminal B,..., Which are a server 3 that performs main processing in the present embodiment, and a personal computer that executes a client application. . . Etc. are connected. The server 3 manages an equipment information DB 32, an equipment diagram DB 33, and a threshold value DB 34. This facility information DB 32 is placed between the two utility poles using the utility pole table (the identification information) as a key and the utility pole table that holds the type, length, strength, etc. of the utility pole and the utility pole code of the two utility poles as the key. And a branch table that holds the basic type of the branch line, the thickness of the steel wire, and the like using the utility pole cord as a key. In addition, the facility diagram DB 33 holds, as coordinate information, X coordinate and Y coordinate values for each utility pole, and map data of various scales representing facilities such as utility poles and electric wires. The threshold value DB 34 holds threshold values or threshold calculation data for various utility poles described below.

  The server 3 includes a utility pole strength calculation unit 31 that performs the main processing in the present embodiment. The utility pole strength calculation unit 31 includes a data setting processing unit 311, a composite moment calculation unit 312, and a determination. A processing unit 313 and an output processing unit 314 are included. The combined moment calculator 312 includes a no-wind combined moment calculator 3121 and a strong wind combined moment calculator 3122.

  Next, processing of the system shown in FIG. 1 will be described with reference to FIGS. First, in response to access from the user terminal A or the like, the server 3 transmits menu display data to the user terminal A, and the client application of the user terminal A receives the menu display data from the server 3 and displays it on the display device ( Step S1). For example, when the server 3 has other functions, menu items for using other functions are displayed in addition to the calculation of the utility pole strength. Here, the user operates the user terminal A to select the utility pole strength calculation. Then, the user terminal A receives a selection input from the user, and transmits data representing the selection of the utility pole strength calculation to the server 3 (step S3).

  When the data setting processing unit 311 of the utility pole strength calculation unit 31 in the server 3 receives data representing the selection of the utility pole strength calculation from the user terminal A, the data setting processing unit 311 reads the map data from the facility diagram DB 33 and transmits it to the user terminal A. The client application of the user terminal A receives the map data from the server 3 and displays it on the display device (step S5). For example, in a first stage, a wide area map is displayed, and the map is gradually narrowed down to a map of the area including the utility pole for which the utility pole strength should be calculated. Or the map containing the telephone pole number input from the user terminal A is displayed. Since such a technique is well known, detailed description thereof will be omitted. Here, it is assumed that the user has reached the map on which the target utility pole is displayed according to the instruction from the user. Then, for example, a map as shown in FIG. 3 is displayed. In FIG. 3, a circle-shaped utility pole representing a utility pole symbol and a span (generic name of a power line) connecting the utility pole and the utility pole (may be a house) are displayed on the map in a selectable state. An example is shown. Also, other data such as roads may be displayed.

  The user selects a power pole and an electric line to be processed on the map displayed on the display device of the user terminal A. That is, as shown in FIGS. 4A to 4D, first, the utility pole 402 to be processed is clicked with the cursor 401 (FIG. 4A) and the span 403 is clicked (FIG. 4B). The span 404 is clicked (FIG. 4C), and finally the span 405 is clicked (FIG. 4D). Thus, by selecting the span in the clockwise direction, the reference electric wire and the angle formed with the electric wire are specified. Note that in the case where all of the electric wires laid on the power pole 402 to be processed are taken into account, the clicks on the spans 403 to 405 as shown in FIGS. 4B to 4D may be omitted. .

  The client application of the user terminal A accepts the selection of the power pole and span by the user, and the power pole code of the selected power pole and the code for specifying the selected span (the electric wire cord or the power poles at both ends of the selected span). (Electric pole code) is transmitted to the server 3 (step S7). When the data setting processing unit 311 of the utility pole strength calculation unit 31 in the server 3 receives the utility pole code and the code for specifying the span from the user terminal A, the following is used from the facility information DB 32 and the facility diagram DB 33 using the code. Data necessary for the above process is read out and stored in a storage device such as a main memory. Then, data used for calculating the utility pole strength is transmitted to the user terminal A. The client application of the user terminal A receives data used for the utility pole strength calculation from the server 3 and displays it on the display device (step S9).

  For example, a screen as shown in FIG. 5 is displayed on the display device. On the screen as shown in FIG. 5, a table 501 for displaying / input / correcting data on wind pressure load type, utility pole length, utility pole strength, utility pole type, soil type, foundation reinforcement presence / absence, and penetration length; Column 502 for individually displaying / input / correcting wind pressure [Pa] applied to the support, electric wire and others, and table 503 for displaying / input / correcting data about the transformer installed in the selected power pole. A column 504 for displaying / input / correcting the presence / absence of a PHS (Personal Handyphone System) antenna, a table 505 for displaying / input / correcting the temperature at the overhead line, the worst-case temperature, and the temperature difference, and GW (Ground Wire) A table 506 for displaying / input / correcting the data on the bracelet, and for displaying / inputting / correcting the data on the attachment point height of the branch line and the opening of the branch line. Table 507, a column for designating whether or not unbalanced tension is considered depending on the support state of the wire for the selected span S1, and the type, line type, thickness, and number of strips of the wire path corresponding to the span S1 , Table 509 for display / input / correction of ground height, sag rate, Mw1 (bending moment due to wind pressure applied to the wireway), Ms1 (bending moment due to unbalanced tension of the wireway) A column for designating whether to consider unbalanced tension for the span S2 and a table 510 for various information, and a column for designating whether to consider unbalanced tension for the selected span S3. And table 511 for various information and FIG. 512 for display / input / correction of span and angle.

  FIG. 512 shows the selected utility pole sign name and utility pole code, the utility pole indicator name and utility pole code connected by the selected first span, the utility pole indicator name connected by the selected second span, and Utility pole code, name of utility pole connected by the selected third span and utility pole code, first to third span length, angle S1-S2, angle S1-S3, wind pressure used for wind pressure calculation Includes direction display fields.

  Some of the numerical values (wind direction, Mw1, Ms1, etc.) among the numerical values to be displayed in the display column provided on the screen of FIG. 5 include data calculated by the utility pole strength calculation described below. May be calculated by the composite moment calculator 312 when performing the utility pole strength calculation, or may be calculated and displayed by the composite moment calculator 312 when performing the display of FIG. May be. Further, for the angle between the selected span and another selected span, the data setting processing unit 311 determines from the coordinate value of the selected utility pole, the coordinate value of the utility pole connected by the selected span, and the like. Calculate and display.

  The user refers to the screen as shown in FIG. 5 and makes a setting input to the user terminal A, for example, making corrections if necessary, or adding data about the newly established electric lines to the table for the corresponding span. The client application of the user terminal A receives a setting input from the user and transmits it to the server 3. The composite moment calculation unit 312 of the utility pole strength calculation unit 31 in the server 3 receives the setting input data received from the user terminal A and stores it in a storage device such as a main memory (step S11).

  Thereafter, processing by the composite moment calculation unit 312 is performed. First, the counter N is initialized to 2 (step S13). Further, the electric lines to be processed are sorted in the order of height, and the sorting result is stored in a storage device such as a main memory (step S14). Since the ground (= height 0) is also the height to be processed, it is set as the last order in the sort result. The windless combined moment calculation unit 3121 calculates the combined moment when there is no wind due to the N-th electric line from the top of the processing target power pole and stores the calculated moment in a storage device such as a main memory (step S15). . In the case of the first process, since N = 2, the combined moment due to the highest electric line or the like is calculated based on the second height from the top. Basically, it is the sum of the product of the difference between the first height and the second height and the tension of the first electric line, but since the method of calculating the composite moment is well known, it will be described in detail here. Absent. Unlike the conventional technology, this embodiment calculates the combined moment assuming no wind in normal times, and calculates the combined moment not only on the ground of the power pole but also on the height of the middle of the power pole. Therefore, it is possible to determine whether or not a problem such as breaking in the middle occurs.

  On the other hand, the determination processing unit 313 refers to the threshold value DB 34 to identify the no-wind allowable load according to the height of the Nth electric line and stores it in a storage device such as a main memory (step S17). As described above, in the present embodiment, unlike the conventional technology, whether or not there is a problem is not determined only on the ground of the utility pole, but whether the problem arises in the utility pole at the height where the electric line is installed. to decide. In order to make such a determination, it is necessary to specify a threshold value corresponding to each height of the utility pole. For example, in the threshold value DB 34, a threshold value for each height is specified in a specific step (for example, 5 cm) for each type of utility pole. It may be registered and read in this step. In addition, data for calculation in this step (such as a coefficient of a formula representing a straight line or a curve) may be held and specified by calculating a threshold corresponding to the height of the Nth electric line or the like. .

  Then, the determination processing unit 313 determines whether there is a problem in the height of the Nth electric line or the like, and stores the determination result in a storage device such as a main memory (step S19). This step is about the moment applied to the utility pole even when there is no wind due to the unbalanced tension generated in the utility pole due to the unbalanced facility of the electric wire, even if the force is applied to the utility pole over a long period of time, It is determined by comparing with a threshold value.

  The outline of this step will be described with reference to FIGS. FIG. 6A is a diagram illustrating an installation example of a power pole and a power line, a wire path group 601 extending left and right at the top of the power pole, and a wire path group 602 extending only in the right direction at the second height. A wire path group 603 extending only in the right direction at the third height and a wire path 604 extending left and right at the fourth height are shown. As for the electric wire path group 601 and the electric wire 604, if the tension is the same on the left and right, it is canceled and the load is not calculated. For the electric line group 602 and the electric line group 603, a load as indicated by an arrow is calculated.

  FIG. 6B is a diagram showing the relationship between height and moment in the case shown in FIG. A solid line 612 represents a curve connecting the acting moments applied to an arbitrary height of the utility pole (in this case, the concrete pillar). On the other hand, a dotted line 611 is a load straight line from which the compression pressure (prestress) applied in the vertical direction of the concrete column is released. The dotted line 611 basically increases as the height decreases. On the other hand, the solid line 612 also increases as the height decreases because the electrical line is installed above the utility pole. Accordingly, in some cases, as shown in FIG. 6B, the solid line 612 may have a larger value than the dotted line 611 on the way. In such a case, a problem does not occur in the portion where the electric wire is attached, but the threshold value is exceeded near the ground. In the present embodiment, since the composite moment is calculated only for the height at which the electric line is attached, the intersection of the dotted line 611 and the solid line 612 as shown in FIG. 6B is intentionally searched. However, it is possible to employ a configuration in which the composite moment is calculated for an arbitrary height. In this case, in the case of FIG. 6B, an intersection can also be extracted.

  Therefore, in step S15, the combined moment in the absence of wind due to the Nth electric line is calculated. In step S17, the value of the dotted line 611 at the height of the Nth electric line is specified. Do. In FIGS. 6A and 6B, for example, when the height of the electric wire 604 is a processing target, the value of the combined moment (value of the solid line 612) and the value of the dotted line 611 at the height of the dotted line 613 Are compared. The comparison result may be expressed as a difference between the two values, or may be expressed as the value of the dotted line 611 / the combined moment.

  Next, the strong wind combined moment calculation unit 3122 calculates a combined moment during a strong wind due to the N-th electric line from the uppermost part of the power pole to be processed, and stores it in a storage device such as a main memory (step S21). ). In step S15, the wind pressure is not considered, but in this step, the combined moment is calculated in consideration of the wind pressure. When the wind pressure is taken into consideration, the combined moment is repeatedly calculated by changing the wind direction by 360 °, and the angle at which the combined moment is maximized and the combined moment at that time are adopted. For example, the direction of the wind is rotated in increments of 5 °, but the combined moment may be calculated for each finer angle or larger angle. Since a specific method for calculating the combined moment in a strong wind is well known, it will not be described in detail here. Note that this embodiment is different from the prior art in that it determines whether a problem such as breakage occurs in the middle by calculating the composite moment not only on the ground of the power pole but also on the height of the middle of the power pole. It can be so.

  On the other hand, the determination processing unit 313 refers to the threshold value DB 34 to determine the crack generation load (N is the maximum value, that is, the design load when reaching the ground level) according to the height of the Nth electric line or the like. For example, it is stored in a storage device such as a main memory (step S23). As described above, in the present embodiment, unlike the conventional technology, whether or not there is a problem is not determined only on the ground of the utility pole, but whether the problem arises in the utility pole at the height where the electric line is installed. Also judge. In order to make such a determination, it is necessary to specify a threshold value corresponding to each height of the utility pole. For example, in the threshold value DB 34, a threshold value for each height is specified in a specific step (for example, 5 cm) for each type of utility pole. It may be registered and read in this step. In addition, data for calculation in this step (such as a coefficient of a formula representing a straight line or a curve) may be held and specified by calculating a threshold corresponding to the height of the Nth electric line or the like. . In the present embodiment, a crack generation load that is a limit load at which a crack can occur on the surface of a reinforced concrete column is compared.

  Then, the determination processing unit 313 determines whether there is a problem in the height of the Nth electric line or the like, and stores the determination result in a storage device such as a main memory (step S25).

  The outline of this step will be described with reference to FIGS. FIG. 7A is a diagram showing an installation example of a power pole and a power line, a wire path group 601 extending left and right at the top of the power pole, and a wire path group 602 extending only in the right direction at the second height. An electric wire group 603 extending only in the right direction at the third height and an electric wire path 604 extending left and right at the fourth height are shown. Since the wire path group 601 and the wire 604 are canceled if the tension is the same on the left and right, hatched arrows are not shown. However, with respect to the wire path group 602 and the wire path group 603, for example, if the height of the wire path 604 is used as a reference, a load as indicated by an arrow with hatching is calculated. On the other hand, it is assumed that the wind 605 is blowing from left to right in FIG. If it does so, the wind-pressure load represented with the normal arrow will be applied to the electric wire path group 601, the electric wire path group 602, the electric wire path group 603, and the electric wire path 604. Accordingly, in this example, the combined load is the sum of the hatched arrow and the normal arrow.

  FIG. 7B is a diagram showing the relationship between height and moment in the case shown in FIG. A solid line 713 represents a curve that connects synthetic moments applied to an arbitrary height of a utility pole (here, a concrete pillar). On the other hand, a dotted line 711 is a straight line representing a crack generation load. In other words, it represents the threshold value for cracking with respect to the composite moment during strong winds. On the other hand, a conventional design load that is a threshold at the ground is represented by a point 712. In Article 32 of the technical standards for electrical equipment, there is no risk of support collapse due to constant load and wind pressure load, so the value is compared with the composite moment on the ground.

  Similar to FIG. 6B, the dotted line 711 basically increases as the height decreases. On the other hand, the solid line 713 also increases as the height decreases because the electrical line is installed at the top of the utility pole. Therefore, as shown in FIG. 7B, the solid line 713 may have a larger value than the dotted line 711 on the way. In such a case, a problem does not occur in the portion where the electric wire is attached, but the threshold value is exceeded near the ground. In the present embodiment, since the combined moment is calculated only for the height at which the electric line is attached, there is no intentional search for an intersection as shown in FIG. The composition moment may be calculated with respect to the height, and in that case, an intersection can also be extracted in the case of FIG. 7B.

  Therefore, in step S21, the combined moment at the time of strong winds up to the Nth electric line or the like is calculated, in step S23, the value of the dotted line 711 at the height of the Nth electric line or the like is specified, and in step S25, both are compared. Do. In FIGS. 7A and 7B, for example, when the height of the electric line 604 is a processing target, the value of the combined moment at the height of the dotted line 714 (the value of the solid line 713) and the value of the dotted line 711 Are compared. The comparison result may be expressed as a difference between the two values, or may be expressed as the value of the dotted line 711 / the combined moment.

  Furthermore, if N reaches a value corresponding to the ground, a design load is specified from the threshold value DB 34 in step S23, and a comparison determination between the design load and the combined moment during strong winds on the ground is also performed in step S25.

  Then, the utility pole strength calculating unit 31 determines whether N has reached the maximum value (number corresponding to the ground) (step S26). If it is determined that N has not yet reached the maximum value, N is incremented by 1 (step S27), and the process returns to step S15. On the other hand, when it is determined that N has reached the maximum value, the output processing unit 314 transmits a processing result stored in a storage device such as a main memory to the user terminal A, for example. The client application of the user terminal A receives the processing result from the server 3 and displays it on the display device (step S29).

  For example, screens as shown in FIGS. 8 to 10 are displayed. FIG. 8 is substantially the same as the upper part of FIG. 5, and FIG. 8 shows a state in which specific numerical values are embedded in each column. Thus, the data set and input is displayed as it is in the upper part of the screen of FIG. In addition, it is in a format that can be modified for use in performing recalculation.

  FIG. 9 shows the processing results of steps S15 to S25 (excluding comparison with the design load). In the example of FIG. 9, there are seven types of electric lines, etc. installed in the span S1, six types of electric lines, etc. are provided in the span S2, and five types are provided in the span S3. Are installed. The height of each electric wire is shown at the left end of the table. In each span column, the type, line type, thickness, number of strips, and sag (sag rate) of each electric line are shown. These data are in accordance with the data displayed / set and input at the bottom of the screen in FIG. Furthermore, the value calculated in step S21 is shown in the column of the combined moment during strong wind for each height. Although not shown in FIG. 9, the value of the combined moment when no wind is present may be indicated. In addition, the determination result is shown in the magnification column. That is, the calculation result of the threshold value / composite moment indicates that if it is less than 1, the composite moment is larger, that is, a problem may occur. Is determined not to occur. In addition, when considering a safety factor, you may determine by less than 2/2 or more. You may use the threshold value which considered the safety factor beforehand. In the example of FIG. 9, the determination result when there is no wind (the processing result of step S19) and the crack determination result when the wind is strong (the processing result of step S25) are shown for each height. However, the numerical value is not shown here because the combined moment is 0 without calculating the height (N = 1) of the highest electric line or the like. Moreover, the determination result about the ground is also shown. Thereby, it can be judged whether the synthetic | combination moment which exceeds a threshold value can arise in the height in which the electrical line etc. are not installed.

  Further, FIG. 10 shows an example of a screen for displaying the calculation result of the ground synthetic moment and the comparison result with the design load at the time of strong wind. That is, the result of examining the strength of the support and the result of examining the strength of the PHS co-mounting are shown. The results of the strength examination of the support include items such as the pole body strength of the utility pole, the safety factor of the utility pole foundation, and the strength examination of the branch line. The pole strength of the utility pole is applied to the bending moment due to the wind pressure applied to the wire, the bending moment due to the unbalanced tension of the wire, the bending moment due to the wind pressure applied to the support, the bending moment due to the wind pressure applied to the transformer, and the overhead wire support hardware. The bending moment due to the wind pressure, the bending moment due to the wind pressure applied to the PHS antenna, the combined moment, the allowable moment of the utility pole, and the determination result are shown. In addition, the safety factor of the utility pole foundation indicates the total load in terms of the top concentration, the safety factor of the support foundation, and the determination result. In the examination of the strength of the branch line, the bending moment due to the unbalanced tension shared by the branch line and the stress applied to the branch line are shown.

  In addition, the strength examination results of PHS co-mounting include items such as the antenna unit limit load (ground conversion), the strength of the overhead ground wire support hardware, and the antenna portion limit load (equivalent to the overhead ground wire support hardware pole installation part). It is. In the antenna part limit load (ground conversion), the calculation result by the judgment formula, the bending moment at the limit load of the PHS antenna, and the comparison result thereof are shown. Also, the strength of the overhead ground wire support hardware includes the bending moment due to the wind pressure applied to the support hardware, the bending moment due to the wind pressure applied to the overhead ground wire, the bending moment due to the unbalanced tension of the overhead ground wire, the bending moment due to the wind pressure applied to the PHS, The composite moment, the allowable moment of the overhead ground wire support hardware, and the determination result are shown. For the limit load of the antenna section (converted to the overhead pole support metal pole mounting section), the load bearing moment of the overhead ground wire support hardware, the calculation result by the judgment formula, the bending moment at the limit load of the PHS antenna (overhead ground pole support pole utility pole) (Converted to the attachment portion) and the determination result are shown.

  Although omitted in the above description, in steps S15 to S25, calculations as shown in the screen of FIG. 10 are also performed and stored in a storage device such as a main memory. However, these numerical values are calculated as the same conditions as in the case of the column.

  Returning to the description of FIG. 2, after step S29, it is determined whether an instruction to end the process is given (step S31). If the process end is instructed, the utility pole strength calculation process ends. On the other hand, if the process is not finished, the process returns to step S5. In addition, you may make it return to step S9.

  If such a process is performed, according to facility requirements, such as many electrical lines, it will be possible to promptly confirm the safety of the utility pole assuming more cases.

  Although one embodiment of the present invention has been described above, the present invention is not limited to this. For example, the functional blocks of the server 3 shown in FIG. 1 do not necessarily correspond to program modules. Also, the processing flow of FIG. 2 is not limited to the processing flow of FIG. 2 as long as the processing results are the same, and there are steps that can be switched in order or executed in parallel.

  Further, in the example described above, an example is shown in which processing is executed serially for one utility pole, but processing may be performed by designating a plurality of utility poles at a time. In addition, the user is requested to input a setting in step S11. For example, for a newly installed electric line, etc., it is assumed that the default electric line is provided at a predetermined default position, and the determination process is performed once. Only when it is determined that there is, a detailed numerical value may be set and determined again.

  Moreover, the structure which makes a user determine by displaying the value of a threshold value and a synthetic | combination moment on a user terminal as it is, without performing determination may be sufficient. Furthermore, although a client-server system has been described above, a stand-alone system configuration may be used. Further, the above functions may be realized by a plurality of computers. Further, the client application may be a dedicated program or a Web browser.

  The server 3, user terminal A, user terminal B, and the like described above are computer devices, and as shown in FIG. 11, in the computer device, a memory 2501 (storage unit), a CPU 2503 (processing unit), A bus 2519 connects a hard disk drive (HDD) 2505, a display control unit 2507 connected to the display device 2509, a drive device 2513 for the removable disk 2511, an input device 2515, and a communication control unit 2517 for connecting to a network. Has been. Application programs including an operating system (OS) and a Web browser are stored in the HDD 2505, and are read from the HDD 2505 to the memory 2501 when executed by the CPU 2503. If necessary, the CPU 2503 controls the display control unit 2507, the communication control unit 2517, and the drive device 2513 to perform necessary operations. Further, data in the middle of processing is stored in the memory 2501 and stored in the HDD 2505 if necessary. Such a computer realizes various functions as described above by organically cooperating hardware such as the CPU 2503 and the memory 2501 described above with the OS and necessary application programs.

  In addition, the electric wire in this application includes a communication line in addition to a power line.

It is a system block diagram in one embodiment of the present invention. It is a figure which shows the processing flow which concerns on one embodiment of this invention. It is a figure which shows an example of the map displayed. (A) thru | or (d) is a figure which shows the mode of selection of a utility pole and an electric wire path (or span). It is a figure which shows the example of a screen for a setting input. (A) is a figure which shows the example of the utility pole at the time of no wind, (b) is a figure showing the relationship between height and a moment. (A) is a figure which shows the example of the utility pole at the time of a strong wind, (b) is a figure showing the relationship between height and a moment. It is a figure which shows the 1st example of a screen for showing a setting input etc. FIG. It is a figure which shows the 2nd example of a screen for showing a process result. It is a figure which shows the 3rd example screen for showing a process result. It is a functional block diagram of a computer.

Explanation of symbols

1 Network 3 Server 31 Utility Pole Strength Calculation Unit 32 Equipment Information DB 33 Equipment Diagram DB
34 Threshold DB
311 Data Setting Processing Unit 312 Synthetic Moment Calculation Unit 313 Determination Processing Unit 314 Output Processing Unit 3121 No Wind Synthetic Moment Calculation Unit 3122 Strong Wind Synthetic Moment Calculation Unit

Claims (9)

An information processing method related to the safety of a utility pole,
A composite moment calculation step of calculating a composite moment for an installation installed at a height higher than a specific height of a specific power pole and an installation to be installed when instructed, and storing it in a storage device When,
Obtaining a no-wind allowable reference value at the specific height for the specific utility pole, and comparing the no-wind allowable reference value with the value of the combined moment stored in the storage device or the no-wind allowable reference Outputting a value and a value of the composite moment;
An information processing method executed on a computer. An information processing method related to the safety of a utility pole,
Calculate the second combined moment when the specified wind pressure is taken into consideration for the installation installed at a height higher than the specific height of the specific power pole and the installation to be installed when instructed. A second synthesized moment calculating step for storing in the storage device;
Obtaining a strong wind allowable reference value at the specific height of the specific power pole, and comparing the strong wind allowable reference value with the second combined moment value stored in the storage device or the Outputting an allowable reference value during strong wind and a value of the second combined moment;
Information processing method including computer and causing computer to execute. A second synthetic moment is calculated and stored for the installation object installed at a height higher than the specific height and the installation object to be installed when instructed, in consideration of a predetermined wind pressure. A second synthetic moment calculation step stored in the apparatus;
Obtaining a strong wind allowable reference value at the specific height of the specific power pole, and comparing the strong wind allowable reference value with the second combined moment value stored in the storage device or the Outputting an allowable reference value during strong wind and a value of the second combined moment;
The information processing method according to claim 1, further comprising:   The information processing method according to any one of claims 1 to 3, wherein the specific height is a height at which an electric wire is laid or a ground.   The information processing method according to claim 4, wherein the specific height is set and changed to the height of an electric line that is hung on the specific power pole in order from the top of the specific power pole. Referring to the map data storage unit, displaying a map of a specific range including the display of the telephone pole symbol;
In response to selection of a power pole in the map of the specific range, reading the power pole data from the map data storage unit and the facility data storage unit;
Receiving input of data about an installation to be installed, and storing the input data in a storage device;
Further including
The data read from the map data storage unit and the facility data storage unit is used as the data for the specific power pole, and the composite moment is calculated using the input data stored in the storage device. Item 6. The information processing method according to any one of Items 1 to 5.   A program for causing a computer to execute the information processing method according to any one of claims 1 to 6. An information processing apparatus that performs information processing on the safety of a utility pole,
A composite moment calculating means for calculating a composite moment for an installation installed at a height higher than a specific height of a specific power pole and an installation to be installed when instructed, and storing it in a storage device When,
Obtaining a no-wind allowable reference value at the specific height for the specific utility pole, and comparing the no-wind allowable reference value with the value of the combined moment stored in the storage device or the no-wind allowable reference Means for outputting a value and a value of the composite moment;
An information processing apparatus. An information processing apparatus that performs information processing on the safety of a utility pole,
Calculate the second combined moment when the specified wind pressure is taken into consideration for the installation installed at a height higher than the specific height of the specific power pole and the installation to be installed when instructed. Second synthetic moment calculating means for storing in the storage device;
Obtaining a strong wind allowable reference value at the specific height of the specific power pole, and comparing the strong wind allowable reference value with the second combined moment value stored in the storage device or the Means for outputting an allowable reference value during strong wind and a value of the second combined moment;
An information processing apparatus.

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