JP6753283B2 - Cable laying method and cable laying equipment - Google Patents

Description

The technique disclosed in the present application relates to a cable laying method and a cable laying device for laying a cable connecting a pair of connected portions in a cable laying portion between the pair of connected portions.

By holding a part of the cable connecting between the pair of connected parts with a hand and moving this hand, the cable laying method and the cable laying device for laying the cable in the cable laying part between the pair of connected parts are known. (See Patent Documents 1 and 2).

JP-A-2007-87610 Japanese Unexamined Patent Publication No. 2-256471

When laying a cable in a cable laying portion, if a frictional force is generated between the hand and the cable in order to apply tension to the cable, the cable may be damaged by the friction.

An object of the technique disclosed in the present application is, as one aspect, to prevent damage to the cable when the cable is laid in the cable laying portion.

In order to achieve the above object, according to one aspect of the technology disclosed in the present application, the hand holding a part of the cable connecting the pair of connected portions , the driving unit for moving the hand, and the hand. Using a cable laying device provided with a tension sensor for detecting the tension acting on the cable, a position sensor for detecting the position of the hand, and a control unit for controlling the drive unit, the control unit is the said. controls the driving unit such that a portion of the cable is held in the hand, until the tension acting on the cable detected by the tension sensor reaches a predetermined tension, between the hand the pair of the connecting portions The drive unit is controlled so as to move away from the cable laying portion of the cable, and the coordinates obtained in advance for each fixing portion of the cable to the pair of connected portions are set as a pair of focal points, and the hand An elliptical trajectory is calculated with the coordinates obtained based on the detection result of the position sensor as the representative passing point on the elliptical portion of the held portion of the held cable, and the hand is one of the above along the elliptical trajectory. It moved from the connecting portion side to the side beyond the other of the connected part, together with the cable is laid in the cable laying unit, extra length of the cable on the side beyond the other of the connected part A cable laying method is provided that includes controlling the drive unit so that the unit is generated .

According to the technique disclosed in the present application, it is possible to prevent the cable from being damaged when the cable is laid in the cable laying portion.

It is a perspective view which shows the cable laying apparatus which concerns on one Embodiment of the technique disclosed in this application. It is a figure explaining the mode that the 1st hand shown in FIG. 1 is moved to one connector side to open a pair of claws. It is a figure explaining the state of holding a part of a cable by the holding part of the 1st hand shown in FIG. It is a figure explaining how the first hand is raised until the tension acting on the cable shown in FIG. 1 reaches a specified tension. It is a figure explaining how the first hand shown in FIG. 1 is lowered to reduce the tension acting on a cable. It is a figure which shows typically the 1st elliptical orbit which becomes the movement locus of the 1st hand shown in FIG. FIG. 5 is a diagram schematically showing that the first elliptical orbit, which is the movement locus of the first hand shown in FIG. 1, differs depending on the actual length of the cable. It is a figure which shows typically the mode that the 1st hand shown in FIG. 1 is moved along the 1st elliptical orbit. It is a figure which shows typically how the first hand shown in FIG. 1 is moved to the side beyond the other connector, and schematically shows the second elliptical orbit which is the movement locus of the folding back of the first hand. .. It is a figure which shows typically the mode that the 1st hand shown in FIG. 1 is moved along the 2nd elliptical orbit. It is a flowchart which shows the processing flow of the control part shown in FIG. It is a figure explaining the cable laying method of the 1st comparative example. It is a figure explaining the cable laying method of the 2nd comparative example.

Hereinafter, an embodiment of the technology disclosed in the present application will be described.

The cable laying device 10 of the present embodiment shown in FIG. 1 is suitably used for laying a cable 60 connecting a pair of connectors 50 and 52 in a groove 54 provided between the pair of connectors 50 and 52. The connector. The pair of connectors 50 and 52 is an example of a "pair of connected portions", and the groove portion 54 is an example of a "cable laying portion".

Such a cable laying structure in which a cable 60 is laid between a pair of connectors 50 and 52 is applied to, for example, an internal structure of an electronic device. Hereinafter, the present embodiment will be described with an example in which a cable 60 connecting the pair of connectors 50 and 52 is laid in the groove portion 54 provided between the pair of connectors 50 and 52. Further, in the present embodiment, as an example, a case where the cable 60 is laid horizontally in the groove portion 54 arranged horizontally will be described. The groove 54 is open upward.

As shown in FIG. 1, the cable laying device 10 of the present embodiment includes a first hand 12, a first drive unit 14, a first position sensor 16, a tension sensor 18, and a control unit 20. The first hand 12 is an example of a “hand”, the first drive unit 14 is an example of a “drive unit”, and the first position sensor 16 is an example of a “position sensor”.

The first hand 12 is for hooking and holding a part of the cable 60, and has a pair of claw portions 22 and an opening / closing driving portion 24. An arc-shaped notch 26 is formed in each of the pair of claw portions 22, and a circular hole-shaped holding portion 28 is formed by combining the pair of arc-shaped notches 26. The inner diameter of the holding portion 28 is set to be larger than the outer diameter of the cable 60, and when the holding portion 28 holds the cable 60, the first hand 12 is relative to the cable 60 in the length direction of the cable 60. It becomes movable.

The opening / closing drive unit 24 is an actuator that operates to open / close the pair of claw portions 22. The first drive unit 14 is, for example, a robot having an arm. The first driving unit 14 is connected to the first hand 12 and drives the first hand 12 so as to move it in the three-dimensional direction.

The tension sensor 18 is provided on the first hand 12. As will be described later, the tension sensor 18 detects the tension acting on the cable 60 when the first hand 12 rises while holding the cable 60, and outputs the detection result. The first position sensor 16 detects the position of the first hand 12 and outputs the detection result.

The control unit 20 is realized by a computer having an arithmetic unit, a storage device, and the like. The storage device of the control unit 20 stores a program for laying the cable 60 in the groove 54 as described later. The arithmetic unit of the control unit 20 executes a program stored in the storage device, and controls the first drive unit 14 and the open / close drive unit 24 based on the detection results of the first position sensor 16 and the tension sensor 18.

Further, as shown in FIG. 9, the cable laying device 10 has a second hand 32 and a second drive unit 34 as components for pushing the extra length portion 64 generated in the cable 60 into the groove portion 54 as described later. And a second position sensor 36.

The second hand 32 has a pressing portion 38 for pressing the cable 60. The second drive unit 34 is, for example, a robot having an arm, like the first drive unit 14 described above. The second drive unit 34 is connected to the second hand 32 and drives the second hand 32 so as to move in the three-dimensional direction. The second position sensor 36 detects the position of the second hand 32 and outputs the detection result.

As will be described later, the storage device of the control unit 20 stores a program for pushing the extra length portion 64 generated in the cable 60 into the groove portion 54. The arithmetic unit of the control unit 20 executes a program stored in the storage device and controls the first drive unit 14 and the second drive unit 34 based on the detection results of the first position sensor 16 and the second position sensor 36. To do.

Subsequently, before explaining the cable laying method of the present embodiment, a comparative example with respect to the present embodiment will be described.

As a first comparative example, for example, as shown in FIG. 12, the cable 60 is grasped and held by the hand 100, and while tension is applied to the cable 60, the cable 60 is manually moved from one end side to the other end side. A method of laying a cable to be pushed into 54 can be mentioned. In this first comparative example, the cable 60 does not enter the narrow groove 54 unless the bending habit of the cable 60 is removed, so that tension is applied to the cable 60.

However, in the cable laying method of the first comparative example, the gripping force of the hand 100 is adjusted so that a constant frictional force is generated between the hand 100 and the cable 60, and the manual pulling work is performed. Therefore, the cable 60 may be damaged due to friction during the manual pulling operation.

Further, when the length of the cable 60 varies, it is difficult to make the frictional force between the hand 100 and the cable 60 constant. Further, there is a problem that the cable 60 is slackened on the moving side of the hand 100, and this slackness interferes with peripheral objects to cause catching. Further, at the final stage of the manual pulling work, the extra length portion 64 of the cable 60 is pushed into the narrow space on the end end side of the groove portion 54, and it becomes difficult to push the extra length portion 64 into the groove portion 54.

Therefore, a second comparative example can be considered. As shown in FIG. 13, in the cable laying method of the second comparative example, the fixed portions 56, 58 of the cable 60 to the pair of connectors 50, 52 are set as a pair of focal points, and the elliptical orbit 102 is determined from the length of the cable 60. Is calculated. Then, the hand 104 is moved along the elliptical orbit 102 to lay the cable 60 in the groove portion 54. In the second comparative example, design values are used for the positions of the fixed portions 56 and 58 and the length of the cable 60.

According to this second comparative example, the sum of the distance between one fixed portion 56 and the hand 104 and the distance between the other fixed portion 58 and the hand 104 is constant due to the nature of the ellipse. Therefore, since tension can be applied to the cable 60 independently of the frictional force, damage to the cable 60 can be suppressed. Further, it is possible to prevent the cable 60 from being loosened on the moving side of the hand 104.

However, the actual length of the cable 60 varies. Therefore, in the cable laying method of the second comparative example, even if the elliptical orbit is calculated using the design value of the length of the cable 60, if the actual length of the cable 60 is different from the design value, it is desired. It may not be an elliptical orbit.

That is, if the actual length of the cable 60 is shorter than the design value, the tension acting on the cable 60 becomes large, and the cable 60 may be damaged such as the cable 60 being broken. Further, when the actual length of the cable 60 is longer than the design value, the cable 60 is slackened, and this slack interferes with the peripheral objects or the bending habit of the cable 60 cannot be completely removed. There is a risk that it cannot be pushed into 54.

Therefore, a cable laying method that can solve the problems of the first and second comparative examples described above is desired. The cable laying method of the present embodiment described below is devised to solve the above-mentioned problems of the first and second comparative examples.

Next, the cable laying method of the present embodiment will be described.

The cable laying method of the present embodiment is executed by the cable laying device 10 described above. More specifically, the cable laying method of the present embodiment is executed by the arithmetic unit of the control unit 20 executing the program stored in the storage device of the control unit 20.

The processing flow of the control unit 20 is shown in steps S1 to S11 of the flowchart of FIG. The control unit 20 has a function of processing each step of steps S1 to S11 shown in FIG. The functional unit that processes each step is realized by the arithmetic unit of the control unit 20 executing the program stored in the storage device of the control unit 20.

The coordinates of the fixed portions 56 and 58 of the cable 60 to the pair of connectors 50 and 52 are stored in advance in the storage device of the control unit 20. The length of the cable 60 is unknown due to manufacturing errors.

(Step S1)
As shown in FIG. 2, first, the control unit 20 controls the first drive unit 14 to move the first hand 12 located above the cable 60 to one connector 50 side, and the open / close drive unit 24. Is controlled to open the pair of claw portions 22.

Further, as shown in FIG. 3, the control unit 20 controls the first drive unit 14 to lower the first hand 12 so that a part of the cable 60 passes between the pair of claw portions 22. The cable 60 is located between the pair of notches 26. Then, the control unit 20 controls the opening / closing drive unit 24 to close the pair of claw units 22. As a result, a part of the cable 60 is inserted and held in the holding portion 28 formed by the pair of notches 26. At this time, more specifically, a part of the cable 60 on the connector 50 side shown in FIG. 2 is held by the holding portion 28.

(Step S2)
Subsequently, as shown in FIG. 4, the control unit 20 controls the first drive unit 14 to move the first hand 12 up, that is, in a direction away from the groove 54. When the first hand 12 is raised, a part of the cable 60 is caught in the holding portion 28, and the cable 60 is lifted. Then, the cable 60 is gradually straightened on one connector 50 side and the other connector 52 side with respect to the first hand 12. The portion of the cable 60 held by the holding portion 28 is hereinafter referred to as the held portion 62.

Then, when the cable 60 is straightened on one connector 50 side and the other connector 52 side with respect to the first hand 12, the tension acting on the cable 60 reaches the specified tension. The control unit 20 stops the first drive unit 14 when the tension acting on the cable 60 detected by the tension sensor 18 reaches the specified tension. The specified tension is preset according to the design value of the length of the cable 60, and is stored in the storage device of the control unit 20.

(Step S3)
Further, when the tension acting on the cable 60 detected by the tension sensor 18 reaches the specified tension, the control unit 20 determines the held unit 62 shown in FIG. 5 based on the detection result of the first position sensor 16. The coordinates of the center of the are acquired and stored in the storage device. The coordinates of the center of the held portion 62 are the coordinates on the central axis of the cable 60. The coordinates of the center of the held portion 62 are, for example, the absolute position of the first hand 12 detected by the first position sensor 16 and the holding portion 28 and the held portion 62 obtained in advance with respect to this absolute position. It is obtained based on the relative position of the contact and the radius of the cable 60. The coordinates of the cable 60 described below are all coordinates on the central axis of the cable 60, similarly to the coordinates of the center of the held portion 62.

(Step S4)
Subsequently, as shown in FIG. 5, the control unit 20 controls the first drive unit 14 to slightly lower the first hand 12, that is, move the first hand 12 slightly in the direction approaching the groove portion 54. At this time, the control unit 20 makes the center of the circular hole-shaped holding portion 28 coincide with the center of the held portion 62. Even if the first hand 12 is lowered, the shape holding force acts on the cable 60, so that the center of the held portion 62 is held at a fixed position.

Then, as the first hand 12 is lowered, the tension acting on the cable 60 is lowered as compared with the case of step S2. At this time, preferably, the held portion 62 is separated from the inner peripheral surface of the holding portion 28 so that the tension acting on the cable 60 becomes zero.

(Step S5)
Subsequently, as shown in FIG. 6, the control unit 20 calculates the first elliptical orbit 40, which is the movement locus when the first hand 12 is moved. Specifically, first, the control unit 20 stores the coordinates stored in advance for the fixed portions 56, 58 of the cable 60 to the pair of connectors 50, 52, and the held portion 62 in step S3 described above. The actual length of the cable 60 is calculated from the coordinates. The actual length of the cable 60 can be obtained as follows.

That is, assuming that the length of the cable 60 is known, the length of the cable 60 is L, the major axis of the ellipse is 2a, the minor axis of the ellipse is 2b, and the distance between the pair of fixed portions 56, 58 is M. Then, the relationship between a, b, L, and M becomes the following equations (1) and (2).

Then, by substituting the above equations (1) and (2) into the elliptical equation of the following equation (3), the first elliptical orbit 40 can be obtained.

However, at the stage of step S5, the actual length of the cable 60 is unknown. Therefore, the coordinates of one fixed portion 56 are (x ₁ , y ₁ ), the coordinates of the other fixed portion 58 are (x ₂ , y ₂ ), and the coordinates of the held portion 62 are (x ₃ , y ₃ ). .. From these coordinates, the actual length L'of the cable 60 can be obtained by the following equation (4).

(Step S6)
Subsequently, the control unit 20 recalculates the first elliptical orbit 40 from the length L'of the cable 60 calculated in step S5 described above and the coordinates stored in advance for the pair of fixed units 56 and 58. That is, the length L'of the above equation (4) is substituted into the above equation (1) as the length L, and the distance between the pair of fixed portions 56, 58 obtained from the coordinates of the pair of fixed portions 56, 58. By substituting M into the above equation (2) and substituting the equations (1) and (2) into the elliptical equation of the above equation (3), the first elliptical orbit 40 is obtained.

FIG. 7 shows an example of the first elliptical orbit 40 recalculated in step S6. The first elliptical orbit 40 shown in FIG. 7 is, for example, a case where the actual length of the cable 60 is equivalent to the design value. As a reference, the first elliptical orbit 40A is the case where the actual length of the cable 60 is longer than the design value, and the first elliptical orbit 40B is the case where the actual length of the cable 60 is longer than the design value. This is the case when it is short.

As described above, in steps S5 and S6, the coordinates stored in the storage device of the control unit 20 in advance for the fixed units 56 and 58 are set as a pair of focal points, and the coordinates obtained for the held unit 62 in step S3 described above are set. Is calculated as the first elliptical orbit 40 having a representative passing point on the ellipse. The first elliptical orbit 40 is an example of an "elliptical orbit".

The coordinates stored in the storage device of the control unit 20 in advance for each of the fixed portions 56 and 58 are an example of "coordinates obtained in advance for each fixed portion of the cable to the pair of connected portions". Further, the coordinates obtained in step S3 of the held portion 62 are examples of "coordinates obtained based on the detection result of the first position sensor for the held portion of the cable held by the first hand". is there. The design value of the length of the cable 60 is set in advance longer than the distance between the pair of connectors 50 and 52 so that the first elliptical orbit 40 can be obtained.

(Step S7)
Subsequently, as shown in FIG. 8, the control unit 20 controls the first drive unit 14 to move the first hand 12 along the first elliptical orbit 40 calculated in steps S5 and S6 described above. At this time, more specifically, the control unit 20 moves the first hand 12 along the first elliptical orbit 40 from the side of one connector 50 to the side beyond the other connector 52. The side beyond the other connector 52 is the side opposite to the one connector 50 with respect to the other connector 52.

When the first hand 12 moves to the side beyond the other connector 52, the cable 60 is laid in the groove 54, and the extra length portion 64 of the cable 60 is generated on the side beyond the other connector 52. The portion of the cable 60 laid in the groove portion 54 is hereinafter referred to as the laid portion 66. Further, the portion of the extra length portion 64 held by the first hand 12 is hereinafter referred to as a held portion 68.

(Step S8)
Subsequently, as shown in FIG. 9, the control unit 20 controls the second drive unit 34 to move the second hand 32, and presses a part of the laid portion 66 with the second hand 32. At this time, more specifically, a part of the laid portion 66 on the other connector 52 side is pressed by the pressing portion 38 of the second hand 32. The portion of the laid portion 66 pressed by the second hand 32 is hereinafter referred to as the pressed portion 70.

(Step S9)
Subsequently, as shown in FIG. 9, the control unit 20 calculates the second elliptical orbit 42, which is the movement locus when the first hand 12 is turned back and moved. Specifically, first, the control unit 20 reads out the coordinates of the other fixed portion 58, the coordinates of the pressed portion 70, and the coordinates of the held portion 68 of the extra length portion 64.

The coordinates of the other fixed unit 58 are stored in advance in the storage device of the control unit 20. The coordinates of the pressed portion 70 include, for example, the absolute position of the second hand 32 detected by the second position sensor 36, and the relative position of the tip of the pressing portion 38 obtained in advance with respect to this absolute position. Obtained based on the radius of the cable 60. The coordinates of the held portion 68 of the extra length portion 64 are, for example, the absolute position of the first hand 12 detected by the first position sensor 16, and the holding portion 28 and the held portion 28 obtained in advance with respect to this absolute position. It is obtained based on the relative position of the contact portion with 68 and the radius of the cable 60.

Then, the control unit 20 calculates the length of the extra length portion 64 from the coordinates of the other fixed portion 58 described above, the coordinates of the pressed portion 70, and the coordinates of the held portion 68 of the extra length portion 64. To do. The length of the extra length portion 64 can be obtained by the following procedure.

That is, the coordinates of the other fixing portion _{58 (x 2, y 2)} , the coordinates of the pressing portion _{70 (x 4, y 4)} , when the coordinates of the held portion 68 _{(x 5, y} 5) , the length _{L e} of the elongated portion 64 is determined by the following equation (5).

(Step S10)
Subsequently, the control unit 20, the length L _e of the elongated portion 64 calculated in step S9 described above, the coordinates of the other fixed portion 58, a second elliptical orbit 42 from the coordinate of the pressing portion 70 calculate. That is, the formula (5) as well as substituted into the above formula (1) as the length L of the length L _e, the pressing portion 70 obtained from the coordinates of the coordinates and the other fixed portion 58 of the pressing portion 70 and substituted into the equation (2) the distance M _e between the fixed portion 58 as the distance M. Then, by substituting the equations (1) and (2) into the elliptical equation of the above equation (3), the second elliptical orbit 42 can be obtained.

FIG. 9 shows an example of the second elliptical orbit 42 calculated in step S10. As described above, in steps S9 and S10, the coordinates of the other fixed portion 58 and the coordinates of the pressed portion 70 are set as a pair of focal points, and the coordinates of the held portion 68 in the extra length portion 64 are on the ellipse. The second elliptical orbit 42 as the representative passing point is calculated.

The coordinates of the other fixed portion 58 are an example of "coordinates obtained in advance for the fixed portion of the cable to the other connected portion". Further, the coordinates of the pressed portion 70 are an example of "coordinates obtained based on the detection result of the second position sensor for the pressed portion of the cable pressed by the second hand". Further, the coordinates of the held portion 68 in the extra length portion 64 are an example of "coordinates obtained based on the detection result of the first position sensor for the held portion in the extra length portion of the cable held by the first hand". Is.

(Step S11)
Subsequently, as shown in FIG. 10, the control unit 20 controls the first drive unit 14 to move the first hand 12 to the other along the second elliptical orbit 42 calculated in steps S9 and S10 described above. It is moved from the side beyond the connector 52 to the one connector 50 side. As a result, the extra length portion 64 of the cable 60 is pushed into the groove portion 54 and laid. In the present embodiment, the entire cable 60 is laid in the groove 54 as described above.

Next, the operation and effect of this embodiment will be described.

As described in detail above, according to the present embodiment, the fixed portions 56, 58 of the cable 60 to the pair of connectors 50, 52 are set as a pair of focal points, and the cable 60 held by the first hand 12 is held. The first elliptical orbit 40 with the held portion 62 as the representative passing point on the ellipse is calculated. Then, the first hand 12 is moved along the first elliptical orbit 40 to lay the cable 60 in the groove 54 between the pair of connectors 50 and 52.

Therefore, when moving the first hand 12, the sum of the distance between one fixed portion 56 and the first hand 12 and the distance between the other fixed portion 58 and the first hand 12 is constant due to the nature of the ellipse. become. Therefore, since tension can be applied to the cable 60 independently of the frictional force, damage to the cable 60 can be suppressed.

Further, according to the present embodiment, the first elliptical orbit 40 is calculated with the first hand 12 raised until the tension acting on the cable 60 reaches the specified tension. Therefore, even if the actual length of the cable 60 varies, the first hand 12 can be moved in an appropriate elliptical orbit that absorbs the variation.

As a result, even when the actual length of the cable 60 is shorter than the design value, it is possible to suppress an increase in the tension acting on the cable 60, so that damage to the cable 60 such as breakage of the cable 60 can be suppressed. Further, even when the actual length of the cable 60 is longer than the design value, it is possible to prevent the cable 60 from being loosened. Therefore, problems such as slack interfering with peripheral objects and the bending habit of the cable 60 cannot be completely eliminated can be solved, and the cable 60 can be appropriately pushed into the groove portion 54.

Moreover, according to the present embodiment, the first hand 12 is raised until the tension acting on the cable 60 reaches the specified tension, and then the hand is lowered to reduce the tension acting on the cable 60. As a result, the friction between the holding portion 28 of the first hand 12 and the held portion 62 of the cable 60 held by the holding portion 28 can be reduced, so that damage to the cable 60 is even more effective. Can be suppressed.

Further, according to the present embodiment, as described above, when the first hand 12 is moved, the distance between the one fixed portion 56 and the first hand 12 and the other fixed portion 58 due to the nature of the ellipse are used. The sum of the distances between and the first hand 12 becomes constant. As a result, it is possible to prevent the cable 60 from being loosened on the moving side of the first hand 12.

Further, according to the present embodiment, the second elliptical orbit 42 is also calculated for the extra length portion 64 of the cable 60 generated on the side beyond the other connector 52. In the second elliptical orbit 42, the other fixed portion 58 and the pressed portion 70 are set as a pair of focal points, and the held portion 68 in the extra length portion 64 is calculated as a representative passing point on the ellipse. Then, the first hand 12 is moved from the side beyond the other connector 52 to the one connector 50 side along the second elliptical orbit 42, and the extra length portion 64 of the cable 60 is laid in the groove portion 54. As a result, it is possible to prevent the extra length portion 64 from being loosened, so that the extra length portion 64 can be smoothly pushed into the groove portion 54.

By the way, in the above embodiment, even if the actual length of the cable 60 varies, the first hand 12 is controlled by feedback so that a constant tension is applied to the cable 60 based on the detection result of the tension sensor 18. It is also possible to move it.

However, in this case, since it is necessary to always apply a constant tension to the cable 60, the cable 60 is always pulled and the cable 60 is rubbed by the holding portion 28 of the first hand 12 during the laying work. Therefore, the cable 60 may be damaged. Further, since the feedback control process requires time, there is an inconvenience that the moving speed of the first hand 12 cannot be increased and the working time is long.

In this regard, according to the above embodiment, an appropriate first elliptical orbit 40 according to the variation in the actual length of the cable 60 is calculated in advance, and the first hand 12 is moved along the first elliptical orbit 40. .. Therefore, it is possible to prevent the cable 60 from being constantly pulled and to prevent the cable 60 from being rubbed by the holding portion 28 of the first hand 12, so that damage to the cable 60 can be effectively suppressed. Further, since the moving speed of the first hand 12 can be increased as compared with the case of feedback control as described above, the working time can be shortened.

Next, a modified example of this embodiment will be described.

In the above embodiment, the cable laying device 10 and the laying method are applied when laying the cable 60 connecting the pair of connectors 50 and 52. However, the cable laying device 10 and the laying method of the present embodiment may be applied when laying the cable 60 connecting the connected portions other than the connectors 50 and 52.

Further, in the above embodiment, the cable laying device 10 and the laying method are applied when the cable 60 is laid in the groove portion 54. However, the cable laying device 10 and the laying method of the present embodiment may be applied to the case where the cable 60 is laid in the cable laying portion other than the groove portion 54.

Further, in the above embodiment, the cable laying device 10 and the laying method are applied when the cable 60 is laid horizontally. However, the cable laying device 10 and the laying method of the present embodiment may be applied when the cable 60 is laid in a direction other than horizontal.

Further, in the above embodiment, in steps S2 and S4, the first hand 12 rises and falls with respect to the horizontally arranged groove portion 54, so that the first hand 12 moves away from the groove portion 54 and in the groove portion 54. It is moving in the direction of approaching. However, the first hand 12 may move in any direction that intersects the length direction of the groove portion 54 as long as it moves away from the groove portion 54 and approaches the groove portion 54. Further, the first hand 12 may move in different directions depending on the direction away from the groove 54 and the direction approaching the groove 54.

Further, in the above embodiment, the extra length portion 64 of the cable 60 is preferably pushed into the groove portion 54 by the first hand 12 being folded back and moved. However, the extra length portion 64 of the cable 60 may be subjected to other processing such as being fixed to the peripheral portion without being pushed into the groove portion 54.

Further, in the above embodiment, the holding portion 28 for holding the cable 60 is formed in a circular hole shape, but the first hand 12 can move relative to the cable 60 in the length direction of the cable. For example, any shape such as a hook shape may be used.

In addition, the said plurality of modifications may be carried out in combination as appropriate.

As described above, one embodiment of the technique disclosed in the present application has been described, but the technique disclosed in the present application is not limited to the above, and various modifications may be made without departing from the scope of the invention. Of course, it is possible.

The following additional notes will be further disclosed with respect to one embodiment of the above-mentioned technique disclosed in the present application.

(Appendix 1)
Hold a part of the cable connecting the pair of connected parts with your hand,
The hand is moved away from the cable laying portion between the pair of connected portions until the tension acting on the cable reaches the specified tension.
An elliptical orbit was calculated in which each fixed portion of the cable to the pair of connected portions was set as a pair of focal points, and the held portion of the cable held by the hand was set as a representative passing point on the ellipse.
The hand is moved along the elliptical orbit to lay the cable in the cable laying portion.
Cable laying method including that.
(Appendix 2)
After moving the hand in the direction away from the cable laying portion until the tension acting on the cable reaches the specified tension, the hand is moved in the direction approaching the cable laying portion to reduce the tension acting on the cable. Let,
The cable laying method described in Appendix 1.
(Appendix 3)
The first hand as the hand is moved along the first elliptical orbit as the elliptical orbit from one side of the connected portion to the other side beyond the connected portion, and the cable is laid. In addition to laying it in the portion, an extra length portion of the cable is generated on the other side beyond the connected portion.
A part of the laid portion of the cable laid on the cable laying portion is pressed by the second hand.
The cable fixed to the other connected portion of the cable and the pressed portion of the cable pressed by the second hand have a pair of focal points, and the cable held by the first hand. Calculate the second elliptical orbit with the held part in the extra length part of the ellipse as the representative passing point on the ellipse.
The first hand is moved along the second elliptical orbit from the side beyond the other connected portion to the one connected portion side, and the extra length portion of the cable is laid in the cable laying portion. Including that
The cable laying method according to Appendix 1 or Appendix 2.
(Appendix 4)
The cable connecting the pair of connectors as the pair of connected portions is laid.
The cable laying method according to any one of Supplementary notes 1 to 3.
(Appendix 5)
The cable is laid in the groove as the cable laying portion.
The cable laying method according to any one of Supplementary notes 1 to 4.
(Appendix 6)
A hand that holds a part of the cable that connects the pair of connected parts,
The drive unit that moves the hand and
A position sensor that detects the position of the hand and
A tension sensor provided on the hand and detecting the tension acting on the cable,
A control unit that controls the drive unit and
With
The control unit holds a part of the cable with the hand, and the hand is between the pair of connected portions until the tension acting on the cable detected by the tension sensor reaches a specified tension. A function to control the drive unit so that it moves away from the cable laying unit, and
The coordinates obtained in advance for each fixed portion of the cable to the pair of connected portions are set as a pair of focal points, and the held portion of the cable held by the hand is based on the detection result of the position sensor. A function to calculate an elliptical orbit with the obtained coordinates as the representative passing point on the ellipse,
A function of controlling the drive unit so that the hand moves along the elliptical orbit and the cable is laid on the cable laying unit.
Cable laying device with.
(Appendix 7)
The control unit moves the hand in a direction away from the cable laying portion until the tension acting on the cable detected by the tension sensor reaches a specified tension, and then the hand approaches the cable laying portion. It has a function of controlling the drive unit so as to move to and reduce the tension acting on the cable.
The cable laying device according to Appendix 6.
(Appendix 8)
The first hand as the hand holding a part of the cable and
A second hand that presses a part of the laid portion of the cable laid on the cable laying portion, and
The first drive unit as the drive unit for moving the first hand,
The second drive unit that moves the second hand and
The first position sensor as the position sensor that detects the position of the first hand, and
The second position sensor that detects the position of the second hand and
With more
In the control unit, the first hand moves along the first elliptical orbit as the elliptical orbit from one side of the connected portion to the other side beyond the connected portion, and the cable moves. A function of controlling the drive unit so that an extra length portion of the cable is generated on the side of the cable laying portion beyond the connected portion.
A function of controlling the second drive unit so that a part of the cable laid portion laid on the cable laying portion is pressed by the second hand.
Obtained based on the coordinates obtained in advance for the fixed portion of the cable to the other connected portion and the detection result of the second position sensor for the pressed portion of the cable pressed by the second hand. As a pair of focal points, the coordinates obtained based on the detection result of the first position sensor for the held portion in the extra length portion of the cable held by the first hand are represented on the ellipse. A function to calculate the second elliptical orbit as a passing point,
The first hand moves along the second elliptical orbit from the side beyond the other connected portion to the one connected portion side, and the extra length portion of the cable is laid in the cable laying portion. It has a function of controlling the first drive unit as described above.
The cable laying device according to Appendix 6 or Appendix 7.

10 Cable laying device 12 First hand (an example of a hand)
14 First drive unit (an example of drive unit)
16 First position sensor (an example of position sensor)
18 Tension sensor 20 Control unit 32 Second hand 34 Second drive unit 36 Second position sensor 40 First elliptical orbit (an example of elliptical orbit)
42 Second elliptical orbit 50, 52 Connector (Example of connected part)
54 Groove (an example of cable laying)
56, 58 Fixed part 60 Cable 62 Held part 64 Extra length part 66 Laying part 68 Held part 70 Pressed part

Claims (4)

A hand that holds a part of the cable that connects the pair of connected parts ,
The drive unit that moves the hand and
A tension sensor provided on the hand and detecting the tension acting on the cable,
A position sensor that detects the position of the hand and
A control unit that controls the drive unit and
Using a cable laying device equipped with
The control unit
The drive unit is controlled so that a part of the cable is held by the hand .
Until the tension acting on the cable detected by the tension sensor reaches a predetermined tension, said hand controls the drive unit to move in a direction away from the cable laying portion between the pair of the connecting portions,
The coordinates obtained in advance for each fixed portion of the cable to the pair of connected portions are set as a pair of focal points, and the held portion of the cable held by the hand is based on the detection result of the position sensor. Calculate an elliptical orbit with the obtained coordinates as the representative passing point on the ellipse.
The hand moves along the elliptical orbit from one side of the connected portion to the other side beyond the connected portion, so that the cable is laid in the cable laying portion and the other covered portion. The drive unit is controlled so that an extra length portion of the cable is generated on the side beyond the connection portion .
Cable laying method including that. After the control unit has the hand until the tension acting reaches the predetermined tension to the cable, which is detected by the tension sensor is moved in a direction away from said cable laying unit, a direction in which the hand approaches the cabling unit The drive unit is controlled so that the tension acting on the cable is reduced by moving to .
The cable laying method according to claim 1. The cable laying device is
The first hand as the hand holding a part of the cable and
A second hand that presses a part of the laid portion of the cable laid on the cable laying portion, and
The first drive unit as the drive unit for moving the first hand,
The second drive unit that moves the second hand and
The first position sensor as the position sensor that detects the position of the first hand, and
The second position sensor that detects the position of the second hand and
With more
The control unit
Wherein along a first elliptical path as the elliptical orbit first hand is moved from one of the connected part side to the side beyond the other of the connected part, laying the cable in the cable laying unit At the same time, the drive unit is controlled so that an extra length portion of the cable is generated on the other side beyond the connected portion.
Controls the second driving unit so as to be pressed portion of the laying unit is in the second hand of the cable laid in the cable laying unit,
Obtained based on the coordinates obtained in advance for the fixed portion of the cable to the other connected portion and the detection result of the second position sensor for the pressed portion of the cable pressed by the second hand. As a pair of focal points, the coordinates obtained based on the detection result of the first position sensor for the held portion in the extra length portion of the cable held by the first hand are represented on the ellipse. Calculate the second elliptical orbit as the passing point,
Wherein along a second elliptical path first hand is moved to one of the connected part side from the other of the side beyond the connection portion, extra length portion of the cable is laid in the cable laying unit Including controlling the first drive unit so as to
The cable laying method according to claim 1 or 2. A hand that holds a part of the cable that connects the pair of connected parts,
The drive unit that moves the hand and
A tension sensor provided on the hand and detecting the tension acting on the cable,
A position sensor that detects the position of the hand and
A control unit that controls the drive unit and
With
The control unit holds a part of the cable with the hand, and the hand is between the pair of connected portions until the tension acting on the cable detected by the tension sensor reaches a specified tension. A function to control the drive unit so that it moves away from the cable laying unit, and
The coordinates obtained in advance for each fixed portion of the cable to the pair of connected portions are set as a pair of focal points, and the held portion of the cable held by the hand is based on the detection result of the position sensor. A function to calculate an elliptical orbit with the obtained coordinates as the representative passing point on the ellipse,
The hand moves along the elliptical orbit from one side of the connected portion to the other side beyond the connected portion, so that the cable is laid in the cable laying portion and the other covered portion. A function to control the drive unit so that an extra length portion of the cable is generated on the side beyond the connection portion, and
Cable laying device with.