JP5961549B2 - Cable construction management support system and method - Google Patents

Description

  The present invention relates to all cable laying work, and more particularly, to a cable construction management support system suitable for construction design in a large plant where the amount of cable is enormous.

  In cable installation work, it is necessary to determine the final cable installation time from the cable installation priority and the cable installation route of each cable. Both the cable laying priority and the cable laying route are designed by the designer. However, the final cable laying time decision is made by the construction site supervisor who knows the progress of the construction. This means that the success or failure of the cable laying work depends on the skill of the director. In addition, it is a waste of time to determine the cable installation timing twice with the designer and the construction supervisor.

  In cable laying work, the progress of the work generally draws an S-curve. In Patent Document 1, if the cable laying length in every unit period is constant, the piled line (progress of construction) is a straight line, and considering that work efficiency is reduced at the start and end of construction, It is reported that the progress of the construction is preferably a gentle S-curve with a substantially constant slope near the center.

  In cable laying work, it is necessary to determine the cable to be wound around the cable drum in consideration of the cable laying time. Patent Document 2 pays attention to the fact that 10% of the cables to be manufactured are discarded due to inadequate construction, so that the cable wound around the cable drum is not left as much as possible by manipulating the order of cutting and the order of construction. A method for effective carving is reported.

JP 2004-112853 A JP 2002-191106 A

In the conventional technique described in Patent Document 1, it has been reported that the progress of the construction is preferably a gentle S - curve having a substantially constant slope near the center, but the optimum S - curve is obtained. , Planning the progress of the construction in advance, has not reached a quantitative view.

Since the progress of various works is not limited to the cable laying work, and the S - curve progresses, the technique solved by the present invention is not limited to the cable laying work.

  Further, the conventional technique described in Patent Document 2 does not consider the following matters.

It is not mentioned that each cable has a laying time, and no consideration is given to determining the cable laying time from two points of laying priority and laying route. Further, no consideration is given to determining the cable laying time based on an optimum progress plan.
The present invention has been made to solve the above-described problems, and an object thereof is to obtain a cable construction management support system capable of executing an optimum progress plan.

  In order to achieve the above object, the cable construction management support system of the present invention includes a design database storing a cable number, a cable physical quantity, a cable wire type, a cable length, cable route information, and a cable laying time, and the number of cores. A cable line type database storing the conductor size, a drum database storing the maximum winding length, a management database storing the installation limit error, the construction period, the installation period, and the number of work days per unit construction period, and a. The total cable length, d is the number of working days per unit construction period, w is the construction period, and the estimated value of the total laying cable length on the xth day from the start of work, determined by these values, is one of the growth curves of Gompertz Y (x) represented by a curve (Gompertz curve), a cable reflecting the cable installation time and the cable line type. From the data processing having a display device including a cable length and a parameter storage area, and from the installation priority in which the cable installation times are arranged in ascending order, the cable has the same installation route information as the cable having the higher installation priority. A function of making the laying time of a cable having a low laying priority the same as the laying priority of a cable having the same laying route information.

  The total laying cable length at each laying time that can be calculated from the above values is compared with the estimated value y (x) of the total laying cable length, and the following processing is performed according to each comparison result.

  When the estimated value y (x) ≦ the total laying cable length at each laying time, that is, when the cable length that can be laid during the scheduled laying period is estimated to be shorter than the actually planned cable length Therefore, it is estimated that the cable installation time of the cable length that was actually planned will be later than the initially planned cable installation time. Therefore, among the cables with the lower installation priority, the cable installation priority with the higher cable installation priority will be used. By returning the rank to the original laying priority, the estimated value y (x) = the total laying cable length at each laying time.

   When estimated value y (x)> total laying cable length at each laying time, that is, when it is estimated that the cable length that can be laid during the planned laying period is longer than the actually planned cable length Therefore, it is estimated that the cable laying time that was actually planned will be earlier than the originally planned laying time. By shortening the construction period and bringing the construction progress forward, the total laying cable at each laying time will be Let length = estimated value y (x).

  According to the present invention, it is possible to obtain a cable construction management support system capable of executing an optimum progress plan by estimating the total laying cable length on the x-th day in advance of the work.

The configuration and processing outline of the cable construction management support system is shown. It is a block diagram which shows the concept in the case of using a cable construction management assistance system. It is a block diagram which shows the concept in the case of using a cable construction management assistance system. It is a block diagram which shows the concept of the drum determination method which considered the cable laying time in the case of using the conventional cable construction management support system. It is a block diagram which shows the concept of the drum determination method which considered the cable laying time in the case of using the cable construction management assistance system of this invention. It is a flowchart which determines a cable installation time from the installation priority and the installation route information in the case of using a cable installation management support system. It is a flowchart which determines a cable installation time from the installation priority and the installation route information in the case of using a cable installation management support system. It is a flowchart which determines an optimal laying progress plan from the total laying cable length of each laying time, and Formula 1 when using a cable construction management support system. It is a flowchart which determines an optimal laying progress plan from the total laying cable length of each laying time, and Formula 1 when using a cable construction management support system. It is a flowchart which considers an installation period in addition to line | wire type information to each cable drum by winding a cable around a cable drum for every installation period in the case of using a cable construction management support system. It is a flowchart which considers an installation period in addition to line | wire type information to each cable drum by winding a cable around a cable drum for every installation period in the case of using a cable construction management support system.

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

  FIG. 1 is a configuration and processing overview of a cable construction management support system according to the present invention. The cable construction management support system of the present invention is realized using a computer having a CPU, a memory, a storage device, and a display device. As shown in FIG. 1, the cable construction management support system 101 includes a design database 102, a cable line type database 103, a drum database 104, a management database 105, and a data processing 106 having a display device.

In the data processing 106, a is the total cable length, d is the number of work days per unit construction period, w is the construction period, and the estimated value of the total laying cable length on the x-th day from the start of work, which is determined by these values, grows. The cable laying time is determined based on y (x) represented by a Gompertz curve, which is one of the curves. The estimated value y (x) of the total laying cable length is expressed by Equation 1. The Gompertz curve passes through the origin of the coordinates, and has the freedom to set the curve change at the beginning and end separately.
[Formula 1] y (x) = C (d · w ^{f (x)} ) / 2 (Formula 1)
Where f (x) = exp (−kx), k = (1 / w) ln {ln (p) / ln (1-p)}, p = dw / (2a), “ln” is the natural logarithm ln = Log _e . 2p = wd / a is the number of work days required for laying a unit-length cable. If 0 <w <1 (assuming that w in Equation 1 is corrected in advance so as to satisfy this condition), y (x) is y (−∞) = 0, y (0). = (D · w) / 2, y (+ ∞) = d / 2 curve, inflection point (x = (w / k) ln {ln (1 / w)}) It is a curve that is asymmetric in the center. C is a proportional constant for converting the working days into the cable length.

  The cable construction management support system is a system capable of the following four output functions 107. In order to realize the contents described in the output function 107 of FIG. ~ 5. Perform the process.

  FIG. 1 shows an example of the design database 102. The number 108 of the cable to be laid, the physical quantity 109 such as conductor resistance, the line type information 110, the length 111, the route 112, and the laying time information 113 can be known at a glance.

  FIG. 1 shows an example of the cable line type database 103 and the drum database 104. In the cable line type database 103, the number of cores 114 of the cable to be installed and the conductor size 115 can be known at a glance, and the drum database 104 and the line type information 110 in the design database are linked. Also, in the drum database 104, it is understood that the cable drum maximum winding length 116 is different for each cable line type.

  FIG. 1 shows an example of the management database 105. The laying limit error 117, the construction period 118, the laying period 119, and the number of work days 120 per unit construction period can be input.

  The data processing device 106 having a display device includes two parameters A121 and B122, Formula 1 (123), and a cable length 124 reflecting the laying time and the line type. A parameter for determining the final laying time is input to A, and the cloth design drawing time allocated at the initial planning stage is input to B.

  Here, the four output functions 107 in setting the cable laying time by the cable construction management support system will be described.

  1. Cable laying time is set in ascending order, and the cable laying time of the cable with the same laying route information is set to the laying time of the cable with lower laying priority with the same laying route information as the cable with higher laying priority. Same function as

  2. A function that preferentially increases the laying priority of cables having a high degree of matching of the laying routes when there is no cable having the same laying route information.

  3. Comparing the total laying cable length of each laying time that can be calculated by the above values with the estimated value y (x) of the total laying cable length of Equation 1, the estimated value y (x) ≦ the total laying cable of each laying time If it is estimated that the cable length that can be installed in the planned installation period is shorter than the actually planned cable length, the actual installation time of the cable length is Since it is estimated that it will be later than the originally planned laying time, the estimated value y can be obtained by returning the cable laying priority with the higher cable laying priority to the original laying priority among the cables with the lower laying priority. (X) = Function to make the total laying cable length at each laying time.

  4). When estimated value y (x)> total laying cable length at each laying time, that is, when it is estimated that the cable length that can be laid during the planned laying period is longer than the actually planned cable length Therefore, it is estimated that the cable laying time that was actually planned will be earlier than the originally planned laying time. By shortening the construction period and bringing the construction progress forward, the total laying cable at each laying time will be Function that length = estimated value y (x).

  5. Of the total installed cable length at each installation time corresponding to Equation 1, the cable length is totaled for each cable line type database 103, and the cable is wound around the cable drum for each installation period. A function that considers the installation period in addition to information.

  FIGS. 2A and 2B show conceptual diagrams when comparing with Equation 1 after determining the optimum cable laying time.

  In the conventional design method 201, a plan is laid out in which all cables are laid during the entire construction period. On the other hand, in the cable construction management support system, the setting section 202 and the setting period 202 are set first. Next, an operation 203 is performed in which the cable installation period of the cable having the same installation route information as that of the cable having the early installation period is advanced among the cables having the later installation period. In step 203, A-B is set to the laying period B in step 202, but the laying period has the same route as the cable of A, and therefore the laying period is advanced to A. Then, the laying physical quantity is compared 204 with Equation 1, and a hill-off 205 is performed for the quantity deviating from Equation 1. In step 205, an example is shown in which a part of the cable A-C is returned to the laying period determined in step 202 because the amount of cable laying objects in the laying period A exceeds Expression 1. Finally, the period optimization 206 is performed, that is, the period is reset so that the period in which the laying of the physical quantity is completed is the same as the estimated value of Formula 1, and the cable is laid based on that. Step 206 shows an example in which the laying period of B is shortened because the amount of cable laying objects in the laying period B is less than Equation 1.

  In FIG. 3, the conceptual diagram of the drum determination method which considered the said cable laying time determined by this invention is shown. In FIG. 3, three types of cable lines are considered.

  In the conventional design method 301 shown in FIG. 3A, a plan is laid out in which all cables are laid during the entire construction period. FIG. 3 shows an example when a 1,000 m cable can be wound around each drum. In the example of step 301, since the cable length of the line type I is 2,500 m in the entire construction period, three drums, two drums around which the cable 1,000 m is wound and one drum around 500 m are completed. The same applies to line types II and III, and a total of 11 drums are required. On the other hand, in step 302 in FIG. 3B in which the cable line type is applied to step 206 in FIG. 2B, the drum around which the cable is wound varies depending on the construction period even in the same line type. The maximum winding length of the cable of the drum is 1,000 m as in step 301, but the winding length varies depending on each drum because it is wound around the drum in consideration of the length of each cable. In step 302, it can be seen that the cable 2,500m of the line type I is wound around one drum (900m) in the laying period A and two drums (800m) in the laying periods B and C.

  Next, a processing procedure for carrying out the present invention in the cable construction management support system 101 will be described with reference to FIGS. The cable construction management support system is provided with the above four functions and implements functions not provided in Patent Documents 1 and 2, and will be described with reference to FIGS.

  4A and 4B are arranged in ascending order, the cable installation time of the low installation priority cable having the same installation route information as the cable having the high installation priority is changed to the same installation route. The flow to make the same as the laying priority of the cable having information will be described.

  First, numbers 1 to N are assigned to all cables (step 401). At this time, the order of assigning numbers to the cables is not limited. Each cable has route information. In addition, two parameters A and B are prepared for each cable. A parameter for determining the final laying time is input to A, and the cloth design drawing time allocated in the initial planning stage is input to B.

  After the planned time of 1 to M (M is the total number of planned times) is input to B (step 402), the cable counter k is used (step 403) to determine whether B is 1 in the order of cable numbers 1 to N. Judgment is made (whether the construction period is the first) (step 404). At this time, if B = 1, A = 1 is input (the final facility time is also the work period 1) (step 405). If B ≠ 1, nothing is input to A, Repeat until k = N (steps 406 and 408).

  Next, a laying time counter j is prepared (step 407). At this time, the cable counter k is set to k = 1 (step 409). If “Y” in step 406, k = N, and therefore, in step 409, the initial value “1” is set again in the cable counter k. For the cable in which A is blank (step 410), it is determined whether or not the B of the cable follows the same route as the cable of j (step 411). When B = j, A = j is input (step 412), and this is repeated until k = N (steps 413 and 415).

  Finally, the laying time of all cables is determined using the counter j until B = M (steps 414 and 417).

  Next, using FIG. 5A and FIG. 5B, the total laying cable length at each laying time is compared with Equation 1, and when the estimated value y (x) ≦ the total laying cable length at each laying time, A flow in which the estimated value y (x) = the total installed cable length at each installation time is set by returning the installation priority of the cable having a higher cable installation priority to the original installation priority among the low cables (step 514, 516, 521, 522) and the estimated value y (x)> the total laying cable length at each laying time, the estimated value y (x) = each laying time by shortening the construction period and bringing the construction progress forward The flow (steps 515 and 517) for setting the total installed cable length will be described.

  In FIG. 5A, the sum of all cable lengths in the design database (total quantity a), the installation limit error α in the management database, and the number of work days d per unit construction period are defined (step 501). Using the data processing and display device, the construction period w is defined (step 502), and equation 1 is defined (step 503). A counter i indicating the cable laying time obtained in FIG. 4 is defined (step 504). Following the above definition, the cable quantity Q with a cable laying time of 1 is determined. The initial condition for Q is Q = 0 (step 505). The counter k indicating the cable number is set to 1 (step 506), and it is determined whether the cable A of the cable number k is 1 (step 507). When A of cable k is 1, each cable length is added to Q (step 508). When A of cable k is not 1, the above operation is repeated using counter k until k = N (step 509). 511).

Subsequently, the amount of cable that can be laid at the cable laying time 1 is calculated from Equation 1. First, the counter j is set to a state in which the value of the parameter B is M (maximum) among the cables assigned with the cable laying time of 1 (step 510). The first week of cable laying time 2 _{x 1,} the last week of the cable laying time 0 and _{x 0} (step 512). In FIG. 5, 512 (S) is the laying period, and ΣS (L) is the total laying period at that time. Said substituting x ₁ and x _0, respectively having 1, calculates the laying possible cable length y in the cable laying time 1 (step 513). The cable quantity Q obtained in step 508 is compared with y obtained in step 513 (step 514). When both are compared and Q is less than y (Q <y), the installation limit error α is added to Q. Thereafter, the value obtained by adding the laying limit error α to the Q is compared with the y (step 515). If Q + α exceeds the y, the laying amount of the cable laying time 1 is determined by Q. . Thereafter, the i counter is incremented by 1, and the plans up to the laying time M are examined in order (steps 518 and 520). On the contrary, when the value obtained by adding the laying limit error α to the Q is less than the y, the laying period is shortened (step 517). The laying period is shortened, and Q and y are compared again.

On the other hand, if the Q is larger than the y (Q> y), it is confirmed whether or not there is a cable having the parameter B in the cable group at the cable laying time 1 (step 516). When there is no cable with the parameter B being M, the counter j is decremented by one (step 521). When there is a cable having the parameter B of M, the laying time of the cable having the minimum length in the cable group is changed to B (step 522).
By the above, the laying progress plan that coincides with Equation 1 is implemented.

  Finally, using FIGS. 6A and 6B, among the total laying cable lengths at the respective laying times corresponding to Equation 1, the cable lengths are tabulated for each cable line type database 103, and the cables are connected to the cable drums every laying period. A flow for setting the laying period in addition to the line type information to each cable drum will be described.

  First, the quantity q for each cable line type is calculated for each laying time. The counter LC indicating the drum number and the counter i indicating the cable laying time are set to 1 (steps 601 and 602). In this embodiment, it is assumed that the stock of the cable drum will not run out of stock until the cable laying is completed, so there is no maximum value of the counter LC.

  Subsequently, the quantity q for each cable line type is set to 0 (step 603), and the counter k indicating the cable number is also set to 1 (step 604). When the cable laying time of the cable with the cable number k is 1, the r counter indicating the type of line is set to 1, and if the cable line type C (k) is 1, Q (k) (the cable number is k ) Is added to q (steps 605, 606, 607, 608). When the line type is not 1, the counter r is incremented by 1, and the q for each line type when the cable laying time is 1 is calculated (step 609). The above operation is performed for all cable numbers k (steps 610 and 612).

  The q is compared with the maximum winding length of the cable drum, and drum winding is performed. The counter j indicating the q number is set to 1 (step 611). The q is compared with MAX indicating the maximum drum winding length of the line type (step 613). When q is smaller than MAX, the drum number of the cable having the cable laying time of 1 and the line type of j is determined (step 614). On the other hand, when q is greater than MAX, drum winding is performed using a counter s indicating a cable number. The cable with the line type j is searched in order from the cable of cable number 1, and added to Q (steps 615, 616, 617, 618). Each time addition is performed, the maximum drum winding length MAX of the line type j is compared (step 619). When the Q exceeds MAX, the previous Q is wound on one drum, and the next and subsequent cables are operated to be wound on the next drum (steps 620, 621, 622, and 623). These operations are performed on all cables (steps 624 and 626). After the above operation of the cable laying time 1 is completed, drum winding is performed for all the cable laying times using the counter i (step 631).

  By the above, it becomes possible to set the laying period in addition to the line type information for each cable drum.

101: Cable construction management support system, 102: Design database, 103: Cable line type database, 104: Drum database, 105: Management database, 106: Arithmetic unit and display unit, 107: Output function, 108: Cable number (input unit) ), 109: cable physical quantity, 110: cable line type number, 111: cable length (input unit), 112: cable route information (input unit), 113: cable laying time information (input unit), 114: number of cores, 115 : Conductor size, 116: maximum winding length of cable drum, 117: installation limit error, 118: construction period, 119: installation period, 120: working days per unit construction period, 121: parameter A, 124: installation time and line Cable length reflecting the seed, 126: conventional design method, 202: period setting, 03: Set the laying period upon adding the route information, 205: Mountain break, 206: optimization of the engine, 301: drum-breaking, 302: cable drum determined considering communication cable installation construction period

Claims (6)

Cable construction management support system
A design database that stores the cable number, cable physical quantity, cable line type, cable length, cable route information, and cable installation time,
A cable line type database that stores the number of cores and conductor size;
A drum database storing the maximum winding length,
A management database that stores the installation limit error, construction period, cable laying period, and number of work days per unit construction period;
A processing device having a display device,
The processor is
Estimated total cable length on the xth day from the start of work, determined by the total cable length, the number of work days per unit work period, and the work period, and y (x) as a growth curve, and the cable laying The laying having the same laying route information as the cable having the higher laying priority from the laying priority in which the cable length reflecting the timing and the cable line type, the parameter storage area, and the laying priority of the cable laying order are arranged in ascending order. Means for setting the laying time of the low priority cable to be the same as the laying priority of the cable having the same laying route information,
When setting the cable laying time,
Comparing the total laying cable length at each laying time that can be calculated by the above values with the estimated value y (x) of the total laying cable length,
When the estimated value y (x) ≦ the total laying cable length at each laying time, among the cables with the low laying priority, the cable laying priority with the higher cable laying priority is returned to the original laying priority. And the estimated value y (x) = the total laying cable length at each laying time,
When the estimated value y (x)> the total laying cable length at each laying time, the total laying cable length at each laying time = the estimated value y (x) is obtained by shortening the construction period and moving the construction forward. ,
Cable construction management support system characterized by that. The processor is
Of the total installed cable length at each installation time that matches the estimated value y (x), the cable length is counted for each cable line type database, and the cable is wound around the cable drum for each installation period. 2. The cable construction management support system according to claim 1, further comprising means for determining a laying period in addition to the line type information on the drum. A design database that stores the cable number, cable physical quantity, cable line type, cable length, cable route information, and cable installation time,
A cable line type database that stores the number of cores and conductor size;
A drum database storing the maximum winding length,
A management database that stores the installation limit error, construction period, cable laying period, and number of work days per unit construction period;
A cable construction management support method in a processing apparatus having a display device,
The processor is
Estimated total cable length on the xth day from the start of work, determined by the total cable length, the number of work days per unit work period, and the work period, and y (x) as a growth curve, and the cable laying Store the cable length and parameters reflecting the time and the cable line type in the storage area,
From the laying priority in which the cable laying times are arranged in ascending order, the cable laying time of the low laying priority cable having the same laying route information as the cable having the high laying priority is set to the cable having the same laying route information. Set the same as the laying priority,
When setting the cable laying time,
Comparing the total laying cable length at each laying time that can be calculated by the above values with the estimated value y (x) of the total laying cable length,
When the estimated value y (x) ≦ the total laying cable length at each laying time, among the cables with the low laying priority, the cable laying priority with the higher cable laying priority is returned to the original laying priority. And the estimated value y (x) = the total laying cable length at each laying time,
When the estimated value y (x)> the total laying cable length at each laying time, the total laying cable length at each laying time = the estimated value y (x) is obtained by shortening the construction period and moving the construction forward. ,
A cable construction management support method characterized by that. The processor is
Of the total installed cable length at each installation time that matches the estimated value y (x), the cable length is counted for each cable line type database, and the cable is wound around the cable drum for each installation period. 4. The cable construction management support method according to claim 3, wherein the laying period is determined in addition to the line type information on the drum.   The cable construction management support system according to claim 1, wherein the growth curve is a Gompertz curve.   The cable construction management support method according to claim 3, wherein the growth curve is a Gompertz curve.

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