JP7496857B2 - How to adjust the amount of elongation of bolt components - Google Patents

Description

This disclosure relates to a method for adjusting the amount of elongation of a bolt member to which a multi-jackbolt tensioner is attached.

Patent Document 1 discloses a multi-jackbolt tensioner that includes a tensioner body having a central hole with a threaded portion that screws into the fastener head, and multiple holes spaced around the central hole, each with a threaded portion, multiple jackbolts that screw into the threaded portions formed in the multiple holes, and a washer that is disposed between the tensioner body and the fastener head and through which the fastener head passes.

The multi-jackbolt tensioner distributes the axial force involved in tightening the fastener head to multiple jackbolts attached to the tensioner body, making it possible to tighten the fastener head with a common tightening tool such as a torque wrench.

JP 2010-054046 A

Multi-jackbolt tensioners are widely used for torque management, where the fastener head is tightened with a specified torque, but there are cases where elongation management is desired, where the fastener head is tightened so that it has a desired elongation. With the above torque management, there is no strong correlation between torque and elongation, and there are no effective management indicators for adjusting the elongation, so elongation adjustment work may be performed depending on the experience, skill, and intuition of the worker. For this reason, in order to ensure the desired elongation, workers often repeat the elongation adjustment work multiple times, which has led to the problem of poor workability when adjusting the elongation when tightening with a multi-jackbolt tensioner.

In view of the above circumstances, at least one embodiment of the present disclosure aims to provide a method for adjusting the elongation of a bolt member that can improve the ease of adjusting the elongation of a bolt member to which a multi-jackbolt tensioner is attached.

A method for adjusting an elongation amount of a bolt member according to at least one embodiment of the present disclosure includes:
A method for adjusting an elongation amount of a bolt member to which a multi-jackbolt tensioner is attached, comprising the steps of:
The multi-jackbolt tensioner comprises:
a tensioner body having a first hole formed with a first threaded portion that screws into a bolt member protruding from a fastened object, and a plurality of second holes provided at intervals around the first hole, each of the second holes formed with a second threaded portion;
A plurality of jack bolts respectively screwed into the plurality of second threaded portions;
an annular plate member disposed between the tensioner body and the object to be fastened and through which the bolt member is inserted,
The method for adjusting the elongation amount of the bolt member includes the steps of:
a mounting step of mounting the multi-jackbolt tensioner to the bolt member;
a first tightening step of tightening each of the plurality of jack bolts with a predetermined torque after the mounting step;
a first elongation amount acquisition step of acquiring an elongation amount of the bolt member after the first fastening step;
a shortage amount acquisition step of acquiring a shortage amount of the elongation amount of the bolt member acquired in the first elongation amount acquisition step with respect to a target elongation amount;
a rotation angle acquisition step of acquiring a rotation angle of the jackbolt corresponding to the deficiency from the pitch of the jackbolt and the deficiency;
and a second tightening step of tightening each of the plurality of jackbolts by the rotation angle of the jackbolt acquired in the rotation angle acquisition step.

At least one embodiment of the present disclosure provides a method for adjusting the elongation of a bolt member that can improve the ease of adjusting the elongation of a bolt member to which a multi-jackbolt tensioner is attached.

FIG. 1 is a schematic perspective view of a multi-jackbolt tensioner used in a method for adjusting the elongation amount of a bolt member according to one embodiment. FIG. 2 is a schematic cross-sectional view showing the multi-jackbolt tensioner shown in FIG. 1 attached to a bolt member. FIG. 4 is a flow chart illustrating an example of a method for adjusting an elongation amount of a bolt member according to an embodiment. FIG. 3 is a schematic cross-sectional view of the jackbolt and its surroundings of the multi-jackbolt tensioner shown in FIG. 11 is an explanatory diagram for explaining an example of a rotation angle acquisition step of a method for adjusting an elongation amount of a bolt member according to an embodiment. FIG. 10A to 10C are explanatory diagrams for explaining an example of a first tightening step and a second tightening step of a method for adjusting an elongation amount of a bolt member according to one embodiment. FIG. 11 is an explanatory diagram for explaining a method for measuring the amount of elongation of a bolt member according to a comparative example. 10A to 10C are explanatory diagrams for explaining an example of a method for adjusting the elongation amount of a bolt member according to an embodiment.

Below, several embodiments of the present disclosure will be described with reference to the attached drawings. However, the dimensions, materials, shapes, relative arrangements, etc. of the components described as the embodiments or shown in the drawings are not intended to limit the scope of the present disclosure and are merely illustrative examples.

(Multi-jackbolt tensioner)
A method 1 for adjusting the elongation amount of a bolt member 2 according to some embodiments of the present disclosure is a method for adjusting the elongation amount E of a bolt member 2 to which a multi-jack-bolt tensioner 3 is attached. Fig. 1 is a schematic perspective view of a multi-jack-bolt tensioner 3 used in the method 1 for adjusting the elongation amount of a bolt member 2 according to one embodiment. Fig. 2 is a schematic cross-sectional view showing a state in which the multi-jack-bolt tensioner 3 shown in Fig. 1 is attached to the bolt member 2. As shown in Figs. 1 and 2, the multi-jack-bolt tensioner 3 includes a tensioner body 4, a plurality of jack bolts 5, and an annular plate member 6.

As shown in FIG. 2, the tensioner body 4 has a first hole 41 in which a first threaded portion 42 is formed to screw into the bolt member 2 protruding from the fastened object 10, and a plurality of second holes 43 provided at intervals around the first hole 41. Each of the plurality of second holes 43 has a second threaded portion 44 formed therein to screw into the jack bolt 5. The first hole 41 and each of the plurality of second holes 43 extend along the axis LA of the tensioner body 4.

Each of the multiple jack bolts 5 is adapted to be screwed into one of the multiple second threaded portions 44. The annular plate member 6 is disposed between the tensioner body 4 and the fastened object 10, and the bolt member 2 is adapted to be inserted therethrough.

Hereinafter, the direction in which the axis LA of the tensioner body 4 extends (the vertical direction in Figs. 1 and 2) is defined as the axial direction of the tensioner body 4 (multi-jackbolt tensioner 3), the direction perpendicular to the axis LA is defined as the radial direction of the tensioner body 4 (multi-jackbolt tensioner 3), and the circumferential direction around the axis LA is defined as the circumferential direction of the tensioner body 4 (multi-jackbolt tensioner 3). In addition, in the above axial direction, the side where the tensioner body 4 is located relative to the annular plate member 6 (upper side in Figs. 1 and 2) is defined as the first side, and in the above axial direction, the side where the annular plate member 6 is located relative to the tensioner body 4 (lower side in Figs. 1 and 2) is defined as the second side.

(Fastened object, bolt component)
2, the fastened object 10 includes a first fastened member 11 and a second fastened member 12 that is disposed on a second side in the axial direction from the first fastened member 11 and abuts against the first fastened member 11. The first fastened member 11 has a first side end face 111 and a second side end face 112 that is located opposite the first side end face 111 in the axial direction and abuts against a first side end face 121 of the second fastened member 12. A through hole 113 is formed in the first fastened member 11, extending from the first side end face 111 to the second side end face 112.

As shown in FIG. 2, the bolt member 2 has a shaft portion 21 that passes through the through hole 113 of the first fastened member 11, and a second end portion 22 that protrudes beyond the second end face 112 of the first fastened member 11 to the second side and engages with the second fastened member 12.

In the embodiment shown in FIG. 2, a hole 122 extending toward the second side is formed in the end face 121 on the first side of the second fastened member 12. A threaded portion 123 is formed on at least a portion of the inner circumferential surface of the hole 122 in the axial direction. A threaded portion 23 that screws into the threaded portion 123 of the second fastened member 12 is formed on at least a portion of the outer circumferential surface of the end portion 22 on the second side in the axial direction. The bolt member 2 is fixed to the second fastened member 12 by screwing the threaded portion 23 into the threaded portion 123 of the second fastened member 12.

2, the bolt member 2 further has a first-side end portion 24 that protrudes toward the first side beyond the first-side end face 111 of the first fastened member 11 (fastened object 10). The first-side end portion 24 has a threaded portion 25 formed on at least a portion of the outer circumferential surface in the axial direction, which threads into the first threaded portion 42 of the tensioner body 4. The shaft portion 21, the second-side end portion 22, and the first-side end portion 24 each extend along the axis LB of the bolt member 2. The second-side end portion 22 and the first-side end portion 24 each are integrally formed with the shaft portion 21. It is preferable that the second-side end portion 22 and the first-side end portion 24 each be formed coaxially with the shaft portion 21.

(Annular plate member)
As shown in Fig. 2, the annular plate member 6 is formed in the shape of an annular plate having a central hole 61 through which the end portion 24 on the first side is inserted. The annular plate member 6 may be, for example, a flat washer. The annular plate member 6 has a first end face 62 which is an end face on one side in the plate thickness direction, and a second end face 63 which is an end face on the other side in the plate thickness direction. When the annular plate member 6 is attached to the bolt member 2, at least a part (outer peripheral edge) of the second end face 63 is adapted to abut against the first end face 111 of the first fastened member 11.

(Tensioner body)
As shown in Figures 1 and 2, the tensioner body 4 has an end face 45 on the first axial side and an end face 46 on the second axial side. The first hole 41 is formed in the end face 46 on the second side and extends toward the first side. The first threaded portion 42 that screws into the threaded portion 25 of the bolt member 2 is formed on at least a portion of the inner circumferential surface of the first hole 41 in the axial direction. Note that the first hole 41 may be a through hole that extends from the end face 46 on the second side to the end face 45 on the first side, as shown in Figures 1 and 2.

The first hole 41 is formed in the radial center of the tensioner body 4, at a position through which the axis LA of the tensioner body 4 passes. The first hole 41 may be the center hole of the tensioner body 4. In other words, the axis of the first hole 41 may be coaxial with the axis LA. The tensioner body 4 is attached to the bolt member 2 by screwing the first threaded portion 42 into the threaded portion 25 of the bolt member 2. When the tensioner body 4 is attached to the bolt member 2, the second side end face 46 faces the first side end face 62 of the annular plate member 6.

Each of the second holes 43 is a through hole extending from the end face 45 on the first side to the end face 46 on the second side. Each of the second holes 43 has the above-mentioned second screw portion 44 formed on at least a part of the inner circumferential surface of the second hole 43 in the axial direction, which screw into the screw portion 54 of the jack bolt 5. Each of the second holes 43 has a smaller hole diameter than the first hole 41 and is formed at positions spaced apart from each other along the circumferential direction around the axis LA of the tensioner body 4. The second holes 43 may have the same distance between the axis LC of the second hole 43 and the axis of the first hole 41 (e.g., axis LA).

(Jack Bolt)
Each of the multiple jack bolts 5 has a head 51 and a shaft portion 53 having one end in the longitudinal direction connected to a bottom surface 52 of the head 51. The above-mentioned threaded portion 54 is formed on at least a portion of the outer circumferential surface in the longitudinal direction of the shaft portion 53. Each of the multiple jack bolts 5 is attached to the bolt member 2 via the tensioner body 4 by screwing the threaded portion 54 into the second threaded portion 44. When each of the multiple jack bolts 5 is attached to the bolt member 2, the head 51 is located on the first side relative to the first end face 45 of the tensioner body 4. When each of the multiple jack bolts 5 is attached to the bolt member 2, the end face (tip face) 55 on the other end side opposite to the one end side connected to the head 51 of the shaft portion 53 abuts against the first end face 62 of the annular plate member 6.

The multi-jackbolt tensioner 3 distributes the axial force involved in fastening the bolt member 2 to multiple jack bolts 5 attached to the tensioner body 4, making it possible to fasten the bolt member 2 using a general tightening tool such as a torque wrench.

(Method of adjusting the amount of elongation of the bolt member)
3 is a flow diagram showing an example of a method 1 for adjusting the elongation amount of a bolt member 2 according to one embodiment. As shown in FIG. 3, the method 1 for adjusting the elongation amount of a bolt member 2 according to some embodiments includes at least an attachment step S1, a first tightening step S2, and a first elongation amount acquisition step S3.

In the installation step S1, the multi-jackbolt tensioner 3 (tensioner body 4, multiple jack bolts 5, and annular plate member 6) is installed on the bolt member 2. In the installation step S1, the tip surface 55 of the shaft portion 53 of each of the multiple jack bolts 5 installed on the bolt member 2 via the tensioner body 4 abuts against the end surface 62 on the first side of the annular plate member 6.

The first tightening step S2 is performed after the installation step S1. In the first tightening step S2, each of the multiple jack bolts 5 is tightened with a predetermined torque (target torque). That is, in the first tightening step S2, the multiple jack bolts 5 are tightened by torque management. By tightening each of the multiple jack bolts 5 to the tensioner body 4 with a predetermined torque, the amount of elongation of the bolt member 2 increases compared to before the first tightening step S2 was performed.

In the first tightening step S2, a torque wrench may be attached to the head 51 of the jack bolt 5, and the head 51 may be rotated in a direction in which the jack bolt 5 is tightened relative to the tensioner body 4, thereby tightening each of the multiple jack bolts 5 with a predetermined torque. The predetermined torque (target torque) in the first tightening step S2 is set in advance before the first tightening step S2. This target torque may be set based on at least one of the past performance values of the method for adjusting the elongation amount of the bolt member 2 or the results of a numerical analysis of the elongation amount of the bolt member 2.

At least a part of the first elongation amount acquisition step S3 is performed after the first tightening step S2. In the first elongation amount acquisition step S3, the elongation amount E (the increase in the axial length of the bolt member 2 due to tightening) of the bolt member 2 after the first tightening step S2 relative to the bolt member 2 before the first tightening step S2 is acquired.

Figure 4 is a schematic cross-sectional view of the vicinity of the jackbolt 5 of the multi-jackbolt tensioner 3 shown in Figure 2. As shown in Figure 4, either the surface (first side end surface 111) of the fastened object 10 facing the annular plate member 6 or the surface (first side end surface 62) of the annular plate member 6 facing the tensioner body 4 is defined as the reference plane RP, and the length from the reference plane RP to an arbitrary position of the tensioner body 4 is defined as the reference length RL. As shown in Figure 3, the above-mentioned first elongation amount acquisition step S3 may include a first measurement step S31 for measuring the reference length (first reference length) RL before the first tightening step S2, and a second measurement step S32 for measuring the reference length (second reference length) RL after the first tightening step S2. In this case, the difference between the second reference length and the first reference length may be the elongation amount E of the bolt member 2 after the first tightening step S2.

As shown in FIG. 3, the elongation amount E of the bolt member 2 acquired in the first elongation amount acquisition step S3 is compared with the target elongation amount TE (comparison step S33). If the elongation amount E of the bolt member 2 acquired in the first elongation amount acquisition step S3 is equal to or greater than the target elongation amount TE ("NO" in S33), the multiple jack bolts 5 have been properly tightened by elongation amount management, and retightening of the bolt member 2 (steps S4 to S6 described below) is not necessary. The target elongation amount TE is set in advance before the comparison step S33. This target elongation amount TE may be set based on at least one of the past performance values of the adjustment method of the elongation amount of the bolt member 2 or the results of a numerical analysis of the elongation amount of the bolt member 2.

On the other hand, if the elongation amount E of the bolt member 2 acquired in the first elongation amount acquisition step S3 is less than the target elongation amount TE ("YES" in S33), further tightening of the bolt member 2 (steps S4 to S6 described below) is required to make the elongation amount E of the bolt member 2 equal to or greater than the target elongation amount TE.

As shown in FIG. 3, the method 1 for adjusting the elongation amount of the bolt member 2 according to some embodiments further includes a shortage amount acquisition step S4, a rotation angle acquisition step S5, and a second tightening step S6.

The shortfall acquisition step S4 is performed after the first elongation acquisition step S3 and the comparison step S33. In the shortfall acquisition step S4, the shortfall ΔE (see FIG. 5) of the elongation E of the bolt member 2 acquired in the first elongation acquisition step S3 relative to the target elongation TE is acquired. The shortfall ΔE is the difference between the elongation E of the bolt member 2 and the target elongation TE, and may be calculated by a calculator or the like from the elongation E of the bolt member 2 and the target elongation TE.

The rotation angle acquisition step S5 is performed after the deficiency acquisition step S4. In the rotation angle acquisition step S5, the rotation angle TRA of the jack bolt 5 corresponding to the deficiency ΔE is acquired from the pitch P (see FIG. 4) of the threaded portion 54 of the jack bolt 5 and the deficiency ΔE acquired in the deficiency acquisition step S4. The rotation angle TRA is the target tightening angle of the jack bolt 5 to set the elongation amount E of the bolt member 2 to the target elongation amount TE.

In the rotation angle acquisition step S5, the rotation angle TRA may be calculated from the deficiency ΔE acquired in the deficiency acquisition step S4 based on association information that associates the pitch P, the deficiency ΔE, and the rotation angle TRA, which is prepared beforehand before the rotation angle acquisition step S5. The association information indicates the correspondence between the pitch P, the deficiency ΔE, and the rotation angle TRA, and may be any information that can acquire the rotation angle TRA corresponding to the pitch P and the deficiency ΔE as output information from the input information of the pitch P and the deficiency ΔE. The association information may be a formula, a diagram or table, or a data map.

5 is an explanatory diagram for explaining an example of the rotation angle acquisition step S5 of the method 1 for adjusting the elongation of the bolt member 2 according to one embodiment. In FIG. 5, a graph is shown with the elongation amount E of the bolt member 2 on the horizontal axis and the rotation angle TRA on the vertical axis. A1 in FIG. 5 is an approximate straight line showing the relationship between the elongation amount E of the bolt member 2 and the rotation angle TRA. The inclination of the approximate straight line A1 may be determined by the ratio of the lead of the threaded portion 54, which can be calculated from the shape and pitch P of the threaded portion 54 of the jack bolt 5, to the rotation angle TRA. For example, when the rotation angle TRA is set to 360°, the jack bolt 5 moves in the axial direction by the lead (for example, the pitch P), and the elongation amount E of the bolt member 2 increases by the lead amount, and the rotation angle TRA corresponding to the shortage amount ΔE may be obtained from the approximate straight line A1.

The second tightening step S6 is performed after the rotation angle acquisition step S5. In the second tightening step S6, each of the multiple jack bolts 5 is tightened by the rotation angle TRA (predetermined rotation angle) acquired in the rotation angle acquisition step S5. That is, in the second tightening step S6, the multiple jack bolts 5 are tightened by angle management. By tightening each of the multiple jack bolts 5 by the rotation angle TRA relative to the tensioner body 4, the elongation amount E of the bolt member 2 increases compared to before the second tightening step S6 was performed.

6 is an explanatory diagram for explaining an example of a first tightening step S2 and a second tightening step S6 of the method 1 for adjusting the elongation amount of the bolt member 2 according to one embodiment. In the first tightening step S2, for example, each of the multiple jack bolts 5 is tightened one by one using a torque wrench (not shown). In the second tightening step S6, an angle wrench 13 (see FIG. 6) may be attached to the head 51 of the jack bolt 5, and the head 51 may be rotated in a direction in which the jack bolt 5 is tightened relative to the tensioner body 4, thereby tightening each of the multiple jack bolts 5 one by one by a rotation angle TRA.

According to the above method, when the multiple jack bolts 5 are tightened by torque management in the first tightening step S2, the amount of elongation E of the bolt member 2 due to mechanical tension may be insufficient compared to the target amount of elongation TE. In this case, the amount of elongation E of the bolt member 2 due to mechanical tension can be adjusted to the target amount of elongation TE by further tightening the multiple jack bolts 5 by angle management in the second tightening step S6.

According to the above method, the rotation angle TRA corresponding to the deficiency ΔE obtained from the pitch P of the jack bolt 5 and the deficiency ΔE is used as a control index for adjusting the elongation E of the bolt member 2, making it possible to adjust the elongation E of the bolt member 2 without relying on the experience, skill, or intuition of the worker. The presence of the above control index allows even a worker who does not have the experience or skill to adjust the elongation E of the bolt member 2 to quickly adjust the elongation E of the bolt member 2. In addition, the presence of the above control index reduces the repetition of the adjustment work of the elongation E of the bolt member 2 and the work of re-tightening the bolt member 2 compared to the conventional adjustment work of the elongation that depends on the experience, skill, and intuition of the worker, thereby improving the workability of the adjustment work of the elongation E of the bolt member 2.

(Second stretch amount adjustment step)
3, the above-described method 1 for adjusting the elongation of the bolt member 2 may further include a second elongation acquisition step S7. In the second elongation acquisition step S7, the elongation amount E of the bolt member 2 after the second tightening step S6 is acquired.

The second elongation amount acquisition step S7 is performed after the second tightening step S6. In the second elongation amount acquisition step S7, the elongation amount E (the increase in the axial length of the bolt member 2 due to tightening) of the bolt member 2 after the second tightening step S6 relative to the bolt member 2 before the first tightening step S2 is acquired.

As shown in FIG. 3, the second elongation amount acquisition step S7 described above may include a third measurement step S71 in which the reference length (third reference length) RL after the second tightening step S6 is measured. In this case, the difference between the third reference length and the first reference length may be the elongation amount E of the bolt member 2 after the second tightening step S6. The elongation amount E of the bolt member 2 acquired in the second elongation amount acquisition step S7 is compared with the target elongation amount TE, and it is confirmed whether the elongation amount E of the bolt member 2 acquired in the second elongation amount acquisition step S7 is equal to or greater than the target elongation amount TE.

According to the above method, in the second elongation acquisition step S7, it is possible to check whether the elongation E of the bolt member 2 due to mechanical tension is equal to the target elongation TE. By checking the elongation E of the bolt member 2 in the second elongation acquisition step S7, appropriate elongation management of the bolt member 2 is performed. Note that if the elongation E of the bolt member 2 acquired in the second elongation acquisition step S7 does not meet the target elongation TE, the above-mentioned steps S4 to S7 may be performed again.

(Measurement points and measurement method for elongation amount of bolt member according to comparative example)
FIG. 7 is an explanatory diagram for explaining a method for measuring the amount of elongation E of the bolt member 2 according to the comparative example. In the method for measuring the amount of elongation E of the bolt member 2 according to the comparative example, a dedicated measuring device (an elongation measuring dial gauge 14, an elongation measuring rod 15, and an elongation measuring sleeve 16) is used to measure the amount of elongation E of the bolt member 2 as shown in FIG. 7. The bolt member 2 is formed with a through hole 26 penetrating along the axis LB of the bolt member 2. One end (first side end) of the elongation measuring rod 15 in the longitudinal direction is connected to the gauge of the elongation measuring dial gauge 14, and the other end (second side end) of the longitudinal direction is inserted into the through hole 26. The elongation measuring dial gauge 14 is supported by the elongation measuring sleeve 16 and is disposed on the first side of the bolt member 2. In the illustrated embodiment, the elongation measuring sleeve 16 is erected on the end face of the first side of the bolt member 2.

The movement of the extension measuring rod 15 along the axis LB is read by the extension measuring dial gauge 14 and displayed on the extension measuring dial gauge 14. The extension measuring dial gauge 14 allows the reference length of the extension measuring rod 15 to be obtained. The change in this reference length before and after tightening the bolt member 2 may be taken as the extension amount E of the bolt member 2. For example, the end face on the first side of the bolt member 2 may be taken as the reference position, and the length of the extension measuring rod 15 from this reference position to the bottom surface of the hole portion 122 may be taken as the reference length of the extension measuring rod 15.

(Measuring points and methods for bolt elongation)
In some embodiments, as shown in FIG. 3, the above-mentioned first elongation amount acquisition step S3 includes the above-mentioned first measurement step S31 of measuring a first reference length, and the above-mentioned second measurement step S32 of measuring a second reference length.

According to the above method, the amount of elongation E of the bolt member 2 can be obtained from the reference length RL (change in the length) of the bolt member 2 before and after the first tightening step S2 measured in the first measurement step S31 and the second measurement step S32. A dedicated measuring device (dial gauge 14 for measuring elongation, rod 15 for measuring elongation, and sleeve 16 for measuring elongation) is not required to measure the reference length RL of the bolt member 2, and a general measuring device such as a gap gauge (thickness gauge), a depth gauge, or a non-contact dimension measuring device using a laser can be used. In addition, the measurement of the reference length RL of the bolt member 2 can be performed easily and quickly by an operator compared to measuring the amount of elongation using a dedicated measuring device. This allows the operator to easily and quickly perform the first elongation amount acquisition step S3. In addition, according to the above method, it is not necessary to form a through hole 26 in the bolt member 2.

In some embodiments, in the first measurement step S31 and the second measurement step S32 described above, as shown in FIG. 4, the surface (first side end surface) 62 of the annular plate member 6 facing the tensioner body 4 is set as the reference surface RP, and the length L1 from the reference surface RP in the axial direction to the end surface (second side end surface) 46 of the tensioner body 4 closer to the reference surface RP is set as the reference length RL.

According to the above method, the reference length RL, i.e., the length L1 between the surface 62 of the annular plate member 6 facing the tensioner body 4 and the end surface 46 of the tensioner body 4 on the annular plate member 6 side, can be easily and quickly measured by an operator using a general measuring instrument such as a feeler gauge. Note that in the above-mentioned third measurement step S71, measurement may also be performed using the above-mentioned length L1 as the reference length RL.

In some embodiments, in the first measurement step S31 and the second measurement step S32 described above, as shown in FIG. 4, the surface (first side end surface) 111 facing the annular plate member 6 of the fastened object 10 is set as the reference surface RP, and the length L2 from the reference surface RP in the axial direction to the end surface (first side end surface) 45 of the tensioner body 4 away from the reference surface RP is set as the reference length RL.

According to the above method, the reference length RL, i.e., the length L2 between the surface 111 facing the annular plate member 6 of the fastened object 10 and the end surface 45 of the tensioner body 4 away from the annular plate member 6, can be easily and quickly measured by an operator using a general measuring instrument such as a depth gauge. Note that in the above-mentioned third measurement step S71, measurement may also be performed using the above-mentioned length L2 as the reference length RL.

(Uniform distribution of elongation in the circumferential direction of the bolt member)
8 is an explanatory diagram for explaining an example of a method 1 for adjusting the elongation amount E of the bolt member 2 according to an embodiment. In some of the above-described embodiments, the elongation amount E of the bolt member 2 due to mechanical tension at an arbitrary position in the circumferential direction of the bolt member 2, the deficiency ΔE, and the rotation angle TRA corresponding to the deficiency ΔE are obtained, and each of the multiple jack bolts 5 attached to the tensioner body 4 is retightened by this rotation angle TRA, but it is also possible to obtain the rotation angles TRA corresponding to the elongation amount E of the bolt member 2 due to mechanical tension at multiple positions (first position P1, second position P2) in the circumferential direction of the bolt member 2.

In some embodiments, the first elongation amount acquisition step S3 includes a first position elongation amount acquisition step of acquiring the elongation amount E of the bolt member 2 at a first position P1 (see FIG. 8) in the circumferential direction of the bolt member 2, and a second position elongation amount acquisition step of acquiring the elongation amount E of the bolt member 2 at a second position P2 (see FIG. 8) different from the first position P1 in the circumferential direction of the bolt member 2. The angle difference between the first position P1 and the second position P2 centered on the axis LA of the tensioner body 4 is defined as θ. The angle difference θ is the smaller of the two angles that the first position P1 and the second position P2 make with respect to the axis LA of the tensioner body 4. It is preferable that this angle difference θ is larger. In some embodiments, the angle difference θ satisfies the condition 90°≦θ≦180°.

The above-mentioned deficiency acquisition step S4 includes a first deficiency acquisition step of acquiring a first deficiency, which is a deficiency ΔE of the elongation amount E of the bolt member 2 acquired in the first position elongation acquisition step with respect to the target elongation amount TE, and a second deficiency acquisition step of acquiring a second deficiency, which is a deficiency ΔE of the elongation amount E of the bolt member 2 acquired in the second position elongation acquisition step with respect to the target elongation amount TE. The above-mentioned rotation angle acquisition step S5 includes a first rotation angle acquisition step of acquiring a first rotation angle TRA of the jack bolt 5 corresponding to the first deficiency ΔE from the first deficiency ΔE and the pitch P of the jack bolt 5, and a second rotation angle acquisition step of acquiring a second rotation angle TRA of the jack bolt 5 corresponding to the second deficiency ΔE from the second deficiency ΔE and the pitch P of the jack bolt 5.

The second tightening step S6 includes a first jack bolt tightening step of tightening the first jack bolt 5A (see FIG. 8) of the multiple jack bolts 5 that is closer to the first position P1 than the second position P2 by the first rotation angle TRA, and a second jack bolt tightening step of tightening the second jack bolt 5B (see FIG. 8) of the multiple jack bolts 5 that is closer to the second position P2 than the first position P1 by the second rotation angle TRA. Here, "closer to the first position P1 than the second position P2" means that in the circumferential direction of the bolt member 2, the circumferential angle difference of the first jack bolt 5A with respect to the first position P1 is smaller than the circumferential angle difference of the first jack bolt 5A with respect to the second position P2. Similarly, "closer to the second position P2 than the first position P1" means that in the circumferential direction of the bolt member 2, the circumferential angle difference of the second jack bolt 5B with respect to the second position P2 is smaller than the circumferential angle difference of the second jack bolt 5B with respect to the first position P1.

According to the above method, the elongation amount E of the bolt member 2 due to mechanical tension at multiple positions (first position P1, second position P2) in the circumferential direction of the bolt member 2, the deficiency amount ΔE, and the rotation angle TRA corresponding to the deficiency amount ΔE are obtained, and by tightening the jack bolts 5A and 5B by angle management in the first jack bolt tightening step and the second jack bolt tightening step, the elongation amount E of the bolt member 2 can be adjusted to the target elongation amount TE over a wide range in the circumferential direction of the bolt member 2, and the distribution of the elongation amount E in the circumferential direction of the bolt member 2 can be sufficiently uniformed.

In this specification, expressions expressing relative or absolute configuration, such as "in a certain direction,""along a certain direction,""parallel,""orthogonal,""center,""concentric," or "coaxial," do not only strictly express such a configuration, but also express a state in which there is a relative displacement with a tolerance or an angle or distance to the extent that the same function is obtained.
For example, expressions indicating that things are in an equal state, such as "identical,""equal," and "homogeneous," not only indicate a state of strict equality, but also indicate a state in which there is a tolerance or a difference to the extent that the same function is obtained.
Furthermore, in this specification, expressions describing shapes such as a rectangular shape or a cylindrical shape do not only refer to shapes such as a rectangular shape or a cylindrical shape in the strict geometric sense, but also refer to shapes that include uneven portions, chamfered portions, etc., to the extent that the same effect can be obtained.
In addition, in this specification, the expressions "comprise,""include," or "have" a certain element are not exclusive expressions that exclude the presence of other elements.

The present disclosure is not limited to the above-described embodiments, but also includes variations of the above-described embodiments and appropriate combinations of these embodiments.

The contents described in the above-mentioned embodiments can be understood, for example, as follows:

1) A method (1) for adjusting an elongation amount of a bolt member (2) according to at least one embodiment of the present disclosure,
A method for adjusting an elongation amount of a bolt member (2) to which a multi-jackbolt tensioner (3) is attached, comprising the steps of:
The multi-jackbolt tensioner (3) comprises:
a tensioner body (4) having a first hole (41) formed with a first threaded portion (42) that screws into a bolt member (2) protruding from a fastened object (10), and a plurality of second holes (43) provided at intervals around the first hole (41), each of the second holes (43) having a second threaded portion (44);
A plurality of jack bolts (5) screwed into the plurality of second screw portions (44), respectively;
an annular plate member (6) disposed between the tensioner body (4) and the object (10) and through which the bolt member (2) is inserted;
The method (1) for adjusting the elongation amount of the bolt member (2) comprises:
a mounting step (S1) of mounting the multi-jackbolt tensioner (3) to the bolt member (2);
a first tightening step (S2) of tightening each of the plurality of jack bolts (5) with a predetermined torque after the mounting step (S1);
a first elongation amount acquisition step (S3) of acquiring an elongation amount (E) of the bolt member (2) after the first fastening step (S2);
a shortage amount acquisition step (S4) of acquiring a shortage amount (ΔE) of the elongation amount (E) of the bolt member (2) acquired in the first elongation amount acquisition step (S3) with respect to a target elongation amount (TE);
a rotation angle acquisition step (S5) of acquiring a rotation angle (TRA) of the jack bolt (5) corresponding to the deficiency (ΔE) from the pitch (P) of the jack bolt (5) and the deficiency (ΔE);
and a second tightening step (S6) of tightening each of the plurality of jack bolts (5) by the rotation angle (TRA) of the jack bolt (5) acquired in the rotation angle acquisition step (S5).

According to the method 1), in the tightening of the jack bolt (5) by torque management in the first tightening step (S2), the amount of elongation (E) of the bolt member (2) due to mechanical tension may be insufficient for the target amount of elongation (TE). In this case, the amount of elongation (E) of the bolt member (2) due to mechanical tension can be adjusted to the target amount of elongation (TE) by tightening the jack bolt (5) by angle management in the second tightening step (S6). According to the method 1), the rotation angle (TRA) corresponding to the shortage amount (ΔE) obtained from the pitch (P) and shortage amount (ΔE) of the jack bolt (5) is used as a management index for adjusting the amount of elongation (E) of the bolt member (2), thereby making it possible to adjust the amount of elongation (E) of the bolt member (2) without relying on the experience, skill, or sense of the worker. The presence of the above-mentioned control index allows even workers who have no experience or skill in adjusting the elongation amount (E) of the bolt member (2) to quickly adjust the elongation amount (E) of the bolt member (2). In addition, the presence of the above-mentioned control index reduces the repetition of the adjustment work of the elongation amount (E) of the bolt member (2) and the work of re-tightening the bolt member (2) compared to conventional elongation adjustment work that depends on the experience, skill, and intuition of the worker, thereby improving the workability of the adjustment work of the elongation amount of the bolt member (2).

2) In some embodiments, there is provided a method (1) for adjusting the elongation amount of the bolt member (2) described in 1), comprising the steps of:
When either the surface (111) of the fastened object (10) facing the annular plate member (6) or the surface (62) of the annular plate member (6) facing the tensioner body (4) is defined as a reference surface (RP), and the length from the reference surface (RP) to an arbitrary position on the tensioner body (4) is defined as a reference length (RL),
The first elongation amount acquisition step (S3) includes:
a first measuring step (S31) of measuring the reference length (RL) before the first fastening step (S2);
and a second measuring step (S32) of measuring the reference length (RL) after the first fastening step (S2).

According to the method 2) above, the amount of elongation (E) of the bolt member (2) can be obtained from the reference length (RL) of the bolt member (2) before and after the first tightening step (S2) measured in the first measurement step (S31) and the second measurement step (S32). A dedicated measuring instrument is not required to measure the reference length (RL) of the bolt member (2), and general measuring instruments such as a gap gauge (thickness gauge), a depth gauge, or a non-contact dimensional measuring device using a laser can be used. Furthermore, the measurement of the reference length (RL) of the bolt member (2) can be performed more easily and quickly by an operator compared to measuring the amount of elongation using a dedicated measuring instrument. This allows the operator to easily and quickly perform the first elongation acquisition step (S3).

3) In some embodiments, there is provided a method (1) for adjusting an elongation amount of the bolt member (2) described in 2) above, comprising the steps of:
In the first measurement step (S31) and the second measurement step (S32), the surface (62) of the annular plate member (6) facing the tensioner body (4) is defined as the reference surface (RP), and the length (L1) from the reference surface (RP) to the end face (46) of the tensioner body (4) closer to the reference surface (RP) is defined as the reference length (RL).

According to the method 3) above, the reference length (RL), i.e., the length (L1) between the surface (62) of the annular plate member (6) facing the tensioner body (4) and the end surface (46) of the tensioner body (4) on the annular plate member (6) side, can be easily and quickly measured by an operator using a general measuring instrument such as a feeler gauge.

4) In some embodiments, there is provided a method (1) for adjusting the elongation amount of the bolt member (2) described in 2) above, comprising:
In the first measurement step (S31) and the second measurement step (S32), the surface (111) of the fastened object (10) facing the annular plate member (6) is defined as the reference surface (RP), and the length (L1) from the reference surface (RP) to the end face (45) of the tensioner body (4) away from the reference surface (RP) is defined as the reference length (RL).

According to the method 4) above, the reference length (RL), i.e., the length (L1) between the surface (111) of the fastened object (10) facing the annular plate member (6) and the end surface (45) of the tensioner body (4) facing away from the annular plate member (6), can be easily and quickly measured by an operator using a general measuring instrument such as a depth gauge.

5) In some embodiments, the method (1) for adjusting the elongation amount of the bolt member (2) according to any one of 1) to 4) above,
The method further includes a second elongation amount acquisition step (S7) of acquiring an elongation amount (E) of the bolt member (2) after the second tightening step (S6).

According to the method 5) above, in the second elongation amount acquisition step (S7), it is possible to check whether the elongation amount (E) of the bolt member (2) due to mechanical tension is the target elongation amount (TE). By checking the elongation amount (E) of the bolt member (2) in the second elongation amount acquisition step (S7), appropriate elongation amount management of the bolt member (2) is performed.

6) In some embodiments, the method (1) for adjusting the elongation amount of the bolt member (2) according to any one of 2) to 4) above,
The first elongation amount acquisition step (S3) includes:
a first position elongation amount acquisition step of acquiring an elongation amount (E) of the bolt member (2) at a first position (P1) in a circumferential direction of the bolt member (2);
a second position elongation amount acquisition step of acquiring an elongation amount (E) of the bolt member (2) at a second position (P2) different from the first position (P1) in the circumferential direction of the bolt member (2),
The shortage amount acquisition step (S4)
a first deficiency acquisition step of acquiring a first deficiency, which is a deficiency (ΔE) of the elongation (E) of the bolt member (2) acquired in the first position elongation acquisition step with respect to a target elongation (TE);
a second deficiency acquisition step of acquiring a second deficiency, which is a deficiency (ΔE) of the elongation (E) of the bolt member (2) acquired in the second position elongation acquisition step with respect to a target elongation (TE),
The rotation angle acquisition step (S5)
a first rotation angle acquisition step of acquiring a first rotation angle (TRA) of the jackbolt (5) corresponding to the first deficiency (ΔE) from the first deficiency (ΔE) and a pitch (P) of the jackbolt (5);
and a second rotation angle acquisition step of acquiring a second rotation angle (TRA) of the jackbolt (5) corresponding to the second deficiency (ΔE) from the second deficiency (ΔE) and a pitch (P) of the jackbolt (5),
The second tightening step (S6)
a first jackbolt tightening step of tightening a first jackbolt (5A) of the plurality of jackbolts (5), the first jackbolt (5A) being closer to the first position (P1) than the second position (P2), by the first rotation angle (TRA);
and a second jackbolt tightening step of tightening a second jackbolt (5B) of the plurality of jackbolts (5) that is closer to the second position (P2) than the first position (P1) by the second rotation angle (TRA).

According to the method 6) above, the elongation (E), the deficiency (ΔE), and the rotation angle (TRA) corresponding to the deficiency (ΔE) of the bolt member (2) due to mechanical tension at multiple positions (first position P1, second position P2) in the circumferential direction of the bolt member (2) are obtained, and by tightening the jack bolts (5A, 5B) by angle management in the first jack bolt tightening step and the second jack bolt tightening step, the elongation (E) of the bolt member (2) can be adjusted to the target elongation (TE) over a wide range in the circumferential direction of the bolt member (2), and the distribution of the elongation (E) in the circumferential direction of the bolt member (2) can be sufficiently uniformed.

1 Method for adjusting the amount of elongation of a bolt member 2 Bolt member 3 Multi-jackbolt tensioner 4 Tensioner body 5, 5A, 5B Jack bolt 6 Annular plate member 10 Fastened object 11 First fastened member 12 Second fastened member 13 Angle wrench 14 Dial gauge for measuring elongation 15 Rod for measuring elongation 16 Sleeve for measuring elongation 41 First hole 42 First threaded portion 43 Second hole 44 Second threaded portion A1 Approximate straight line E, TE Elongation amount LA, LB, LC Axis P Pitch P1 First position P2 Second position RL Reference length RP Reference surface S1 Installation step S2 First tightening step S3 First elongation amount acquisition step S4 Shortage amount acquisition step S5 Rotation angle acquisition step S6 Second tightening step S7 Second elongation amount acquisition step S31 First measurement step S32 Second measurement step S33 Comparison step S71 Third measurement step TRA Rotation angle

Claims (5)

A method for adjusting an elongation amount of a bolt member to which a multi-jackbolt tensioner is attached, comprising the steps of:
The multi-jackbolt tensioner comprises:
a tensioner body having a first hole formed with a first threaded portion that screws into a bolt member protruding from a fastened object, and a plurality of second holes provided at intervals around the first hole, each of the second holes formed with a second threaded portion;
A plurality of jack bolts respectively screwed into the plurality of second threaded portions;
an annular plate member disposed between the tensioner body and the object to be fastened and through which the bolt member is inserted,
The method for adjusting the elongation amount of the bolt member includes the steps of:
a mounting step of mounting the multi-jackbolt tensioner to the bolt member;
a first tightening step of tightening each of the plurality of jack bolts with a predetermined torque after the mounting step;
a first elongation amount acquisition step of acquiring an elongation amount of the bolt member after the first tightening step using a measuring instrument for measuring a length;
a shortage amount acquisition step of calculating a shortage amount which is a difference between the elongation amount of the bolt member acquired in the first elongation amount acquisition step and a target elongation amount;
a rotation angle acquisition step of acquiring a rotation angle of the jack bolt corresponding to the deficiency from the pitch of the jack bolt and the deficiency calculated in the deficiency acquisition step, based on association information in which the pitch of the jack bolt, the deficiency, and the rotation angle of the jack bolt are associated with each other;
a second tightening step of tightening each of the plurality of jackbolts by the rotation angle of the jackbolt acquired in the rotation angle acquisition step ,
When either the surface of the fastened object facing the annular plate member or the surface of the annular plate member facing the tensioner body is defined as a reference surface, and the length from the reference surface to an arbitrary position on the tensioner body is defined as a reference length,
The first elongation amount acquisition step includes:
a first measuring step of measuring the reference length before the first fastening step using the measuring device;
a second measuring step of measuring the reference length after the first fastening step by using the measuring device;
Including,
an elongation amount of the bolt member is obtained from a change in the reference length before and after the first fastening step measured in the first measuring step and the second measuring step.
A method for adjusting the amount of elongation of a bolt component. In the first measuring step and the second measuring step, a surface of the annular plate member facing the tensioner body is set as the reference surface, and a length from the reference surface to an end face of the tensioner body closer to the reference surface is set as the reference length.
The method for adjusting the elongation of a bolt member according to claim 1 . In the first measuring step and the second measuring step, a surface of the object to be fastened facing the annular plate member is set as the reference surface, and a length from the reference surface to an end face of the tensioner body away from the reference surface is set as the reference length.
The method for adjusting the elongation of a bolt member according to claim 1 . The method further includes the step of: acquiring an elongation amount of the bolt member after the second tightening step by using the measuring device.
The method for adjusting an elongation amount of a bolt member according to any one of claims 1 to 3 . The first elongation amount acquisition step includes:
a first position elongation amount acquisition step of acquiring an elongation amount of the bolt member at a first position in a circumferential direction of the bolt member using the measuring device;
a second position elongation amount acquisition step of acquiring an elongation amount of the bolt member at a second position different from the first position in the circumferential direction of the bolt member by using the measuring device,
The shortage amount obtaining step includes:
a first deficiency amount acquisition step of calculating a first deficiency amount which is a difference between the elongation amount of the bolt member acquired in the first position elongation amount acquisition step and a target elongation amount;
a second deficiency amount acquisition step of calculating a second deficiency amount which is a difference between the elongation amount of the bolt member acquired in the second position elongation amount acquisition step and a target elongation amount,
The rotation angle acquisition step includes:
a first rotation angle acquisition step of acquiring a first rotation angle of the jackbolt corresponding to the first deficiency from the first deficiency and a pitch of the jackbolt;
and a second rotation angle acquisition step of acquiring a second rotation angle of the jackbolt corresponding to the second deficiency from the second deficiency and a pitch of the jackbolt,
The second fastening step includes:
a first jackbolt tightening step of tightening a first jackbolt, of the plurality of jackbolts, that is closer to the first position than to the second position, by the first rotation angle;
a second jackbolt tightening step of tightening a second jackbolt, among the plurality of jackbolts, that is closer to the second position than the first position, by the second rotation angle.
The method for adjusting an elongation amount of a bolt member according to any one of claims 1 to 3 .

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