RU2762174C2 - Tool for tightening torque control and combination of tool for tightening torque control and fastener - Google Patents

Abstract

FIELD: tools.

SUBSTANCE: invention relates to tools, in particular to a tool for tightening torque control designed to tighten a fastener, such as a nut or a bolt, with the required torque, and to a combination of such a tool for tightening torque control and a fastener. Tool for tightening torque control (2) includes section (4) containing the fastener and section (6) of the tightening torque application made as a single whole of synthetic resin. Section (4) containing the fastener is made with accommodating hole (8) having an open free end, and the inner peripheral surface of this accommodating hole (8) is given a shape, in which recessed section (16) is made in the middle part of each of side surfaces (15) of the regular polygonal inner peripheral surface of the fastener corresponding to the torque-applying regular polygonal outer peripheral surface of the fastener, and between bottom surface (16a) of recessed section (16) and surface (16b) of the input of the recessed section located on the input side, when viewed in the direction of rotation when tightening, an obtuse angle is formed. On section (15b), which is located on side surface (15) in front of recessed section (16), when viewed in the direction of rotation when tightening, there is a retaining protrusion consisting, for example, of edge (21) extending in the axial direction into accommodating hole (8).

EFFECT: reliable provision for preventing the occurrence of cracking.

22 cl, 12 dwg

Description

TECHNICAL FIELD OF THE INVENTION

This invention relates to a torque-controlling tool for tightening a fastener, such as a nut or bolt, to a desired torque, and to a combination of such a torque-controlling tool and the fastener.

LEVEL OF TECHNOLOGY

As is well known, when installing, for example, a soundproof wall on an expressway, when installing a tunnel ceiling wall or similar structure, or when installing various components in various buildings, numerous fasteners are used, which include bolts and nuts. In such a fastening, it is important that the nut (usually a lock nut) is tightened to the bolt with a relatively high required torque of the order of 17-24 Nm, for example, in the case of a hex nut with a nominal diameter of M10. Each of Patent Documents 1 and 2 below discloses a torque controlling tool used when a nut is pulled against a bolt or a bolt against a nut with a required torque. Such a tightening torque controlling tool includes a fastener receiving portion and a tightening torque applying portion, which are integrally connected to each other by a connecting portion to be broken with a required torque. The head of the nut or bolt is accommodated in the fastener-containing portion and torque is applied to the tightening torque portion to pull the nut to the bolt or the bolt to the nut. When the tightening torque applied to the tightening torque application site, as well as applied to the nut or bolt by the fastener receiving portion, exceeds a certain threshold, breakage of the connecting portion occurs, causing the tightening torque application portion to separate from the fastener housing portion. As a result, the nut is attracted to the bolt or the bolt is pulled to the nut with the required torque.

PREVIOUS TECHNOLOGY DOCUMENTS

Patent documents

Patent Document 1: JP-A-2001-140832

Patent Document 2: JP-A-2015-224781

SUMMARY OF THE INVENTION

Tasks solved by the invention

However, the torque controlling tools disclosed in Patent Documents 1 and 2 discussed above pose such a problem for solving that if a relatively high tightening torque in particular is required, then the whole tool must be formed from difficult-to-machine metal. , such as ferrous metal, and therefore the manufacturing cost is high. If the tool is formed from a suitable synthetic resin in order to reduce the manufacturing cost, the connecting portion that connects the fastener receiving portion and the tightening torque application portion to each other is broken at the moment when the tightening torque applied to the tightening torque application portion is low.

In order to solve the aforementioned problem arising from the torque controlling tools disclosed in Patent Documents 1 and 2, the inventors of the present invention have previously proposed in Japanese patent application specification No. 2016-139152 a torque controlling tool with a unique configuration that is completely different from conventional configurations. This torque control tool includes a fastener receiving portion and a tightening torque application portion integrally formed from a synthetic resin. The fastener-receiving portion is formed with an enclosing hole having an open free end, and the enclosing hole is shaped in which a recessed section is formed in the middle of each of the side surfaces of a regular polygonal inner peripheral surface corresponding to a torque-applying regular polygonal outer peripheral surface of the fastener ... Both side surfaces of the recessed section, namely the inlet surface on the inlet side and the outlet surface on the outlet side, when viewed in the direction of rotation when tightened, extend perpendicular to the side surface. When the tightening torque applied to the tightening torque application site and transmitted to the fastener by the fastener-receiving portion exceeds a certain threshold, the inner peripheral surface of the enclosing hole is deformed, causing the fastener-receiving portion to rotate relative to the fastener. Therefore, the tightening torque of the fastener is controlled.

The aforementioned torque control tool proposed by the present inventors, even formed from a suitable synthetic resin such as polycarbonate or acrylonitrile butadiene styrene, can help to give a sufficiently high tightening torque value at which the inner peripheral surface of the housing hole begins to deform, and therefore can help reducing the cost of manufacturing from a suitable synthetic resin due to the deformation of the latter.

However, the experience of the present inventors has led them to discover that the aforementioned torque control tool proposed by the present inventors is not yet completely satisfactory and entails the following problem: when the inner peripheral surface of the hole containing the fastener receiving portion is deformed, thereby the tightening torque control tool is rotated relative to the fastener, each corner of the fastener with great force collides with the entrance surface of each recessed section formed in the inner peripheral surface of the housing hole. This can lead to cracking from the boundary between the bottom surface and the recessed section entrance surface to the outer peripheral surface of the fastener-containing portion, causing the detached pieces to scatter as dust. This event is particularly noticeable when tightening is carried out with an electric tool such as an electric torque screwdriver.

Moreover, the experience of the present inventors has allowed them to find that the above-mentioned torque control tool proposed by the present inventors has the following objectives: the torque control tool made of synthetic resin can be molded with sufficient accuracy by injection molding or compression molding , and its technological tolerance can be made small enough. On the other hand, as is well known among those skilled in the art, the technological tolerance of conventional commercially available fasteners, i. E. conventional nuts or bolts is relatively large. Therefore, in particular, when a nut or bolt head is pressed into a housing hole formed in a fastener housing portion of a torque controlling tool to create a combination of a torque controlling tool and a fastener, and this combination is put on the market, the following problems arise. (1) If the head of the nut or bolt is excessively large for the housing hole, a large force is required when the head of the nut or bolt is pressed into the housing hole and a high stress is applied to the holding portion of the fastener. As a result, when the nut or bolt is actually pulled against the bolt or nut, the fastener receiving portion of the torque controlling tool tends to break. (2) On the other hand, if the head of the nut or bolt is too small for the receiving hole, then the head of the nut or bolt fits into the receiving hole with little force. However, due to vibration or similar phenomena during transportation, the possibility of a nut or bolt falling out of the housing hole must not be neglected.

This invention was made in light of the above facts. Its main technical objective is to further improve the above-mentioned torque control tool proposed by the present inventors, thereby providing a new and improved torque control tool, in which crack prevention is ensured even if each corner of the outer peripheral surface of the fastener collides with great force. with the entrance surface of each recessed section formed in the inner peripheral surface of the enclosing hole when the inner peripheral surface of the enclosing hole of the fastener receiving portion is deformed so that the torque controlling tool rotates relative to the fastener. Another main technical problem of the invention is to provide a new and improved combination of such torque controlling tool and fastener.

An additional technical object of the present invention is to further improve the aforementioned tightening torque control tool proposed by the present inventors, thereby providing a new and improved tightening torque control tool that prevents - as much as possible - a situation where the force required when accommodating the fastener in the fastener receiving opening of the fastener receiving portion is unnecessarily enlarged or unnecessarily reduced due to the relatively large manufacturing tolerance of the fastener. Yet another further technical object of the present invention is to provide a new and improved combination of such a torque controlling tool and fastener.

As a result of in-depth research and experimentation, the inventors of the present invention have found that the above-described main technical problems can be solved by assuming a shape that forms an obtuse angle between the bottom surface and the entrance surface (the side surface on the entrance side when viewed in the direction of rotation when tightening) of each of the recessed sections formed in the receiving hole of the fastener receiving portion.

That is, according to the first aspect of the present invention, as a torque control tool that solves the main technical problems, there is provided a torque control tool including a fastener housing portion and a tightening torque application portion integrally formed made of synthetic resin, and the fastener-containing portion is made with a receiving hole having an open free end, and the inner peripheral surface of this containing hole is shaped in which a recessed section is formed in the middle part of each of the side surfaces of a regular polygonal inner peripheral surface corresponding to applying a torque the moment of the regular polygonal outer peripheral surface of the fastener, and between the bottom surface of the recessed section and the inlet surface of the recessed section on the inlet side when viewed in the direction of rotation when tightened, an obtuse angle is formed, and when the tightening torque applied to the tightening torque application portion and transmitted to the fastener by the fastener-receiving portion exceeds a certain threshold value, the inner peripheral surface of the enclosing hole is deformed so that the fastener-receiving portion rotates relative to the fastener so that the fastener tightening torque is controlled.

The entry surface of the recessed section preferably extends outwardly from the side surface, tilting in the direction of rotation when tightened. The bottom surface and the entrance surface of the recessed section are preferably smoothly connected to each other by means of an arcuate boundary surface. The torque-applying regular polygonal outer peripheral surface is preferably a regular hexagon. The exit surface of each of the recessed sections on the exit side as viewed in the direction of rotation when tightened desirably extends perpendicular to the lateral surface. The outer peripheral surface of the tightening torque application portion is advantageously a regular polygon corresponding to the torque applying regular polygonal outer peripheral surface of the fastener. A retaining protrusion is provided for convenience in a portion that is on the lateral surface of the regular polygonal inner circumferential surface in front of the recessed section as viewed in the direction of tightening rotation. The retaining protrusion is preferably a rib extending in the axial direction of the receiving opening. In a preferred embodiment, the height of the projection - rib - is from 0.1 to 0.5 mm and the circumferential width of the rib is from 0.1 to 0.5 mm. The cross-sectional shape of the protruding end portion of the rib is preferably semicircular.

In accordance with a second aspect of the present invention, as a combination of a torque controlling tool that solves a general technical problem and a fastener, there is provided a combination of the aforementioned torque control tool of the first aspect of the invention and a fastener that fits at least partly in the housing bore of the torque control tool. The regular polygonal inner peripheral surface bounded by the side surfaces of the receiving hole of the torque control tool is preferably less than the torque-applying regular polygonal outer peripheral surface of the fastener, and the fastener is pressed into the containing hole. The fastener can be a hex nut.

As a result of in-depth research and experimentation, the inventors of the present invention have also found that the above-described additional technical problems can be solved by positioning the retaining protrusion on a portion that is located in front of the lateral surface of the regular polygonal inner peripheral surface corresponding to the recessed section when viewed in the direction of rotation when tightening.

That is, according to the third aspect of the present invention, as a torque control tool that solves the main technical problems, there is provided a torque control tool including a fastener receiving portion and a tightening torque application portion integrally formed synthetic resin,

wherein the fastener-containing section is formed with a containing hole having an open free end, and the inner peripheral surface of this containing hole is shaped in which a recessed section is formed in the middle part of each of the side surfaces of a regular polygonal inner peripheral surface corresponding to a torque-applying regular polygonal outer the peripheral surface of the fastener,

a retaining protrusion is disposed in a portion that on the lateral surface of the regular polygonal inner peripheral surface is in front of the recessed section, as viewed in the direction of tightening rotation, and

when the tightening torque applied to the tightening torque application portion and transmitted to the fastener by the fastener-containing portion exceeds a certain threshold, the inner peripheral surface of the enclosing hole is deformed, causing the fastener-receiving portion to rotate relative to the fastener, so that control occurs tightening torque of the fastener.

The retaining protrusion is preferably a rib extending in the axial direction of the receiving opening. In a preferred embodiment, the height of the projection - rib - is from 0.1 to 0.5 mm and the circumferential width of the rib is from 0.1 to 0.5 mm. The cross-sectional shape of the protruding end portion of the rib is preferably semicircular. Desirably, the torque-applying regular polygonal outer peripheral surface is a regular hexagon, and a retaining protrusion is located on each of the six side surfaces in front of the recessed section. The outer peripheral surface of the tightening torque application portion is preferably a regular polygon corresponding to the torque applying regular polygonal outer peripheral surface of the fastener.

In accordance with a fourth aspect of the present invention, as a combination of a torque controlling tool that solves a general technical problem and a fastener, there is provided a combination of the aforementioned torque controlling tool of the third aspect of the invention and a fastener that fits at least partly in the housing bore of the torque control tool. The fastener is preferably pressed into the receiving hole. The fastener can be a hex nut.

Effects of the invention

With regard to the torque controlling tool and the combination of the torque controlling tool and the fastener provided in accordance with the first and second aspects of the present invention, the torque controlling tool is formed from a synthetic resin. Therefore, although they can be made relatively inexpensive to manufacture, they can therefore be imparted with a relatively large tightening torque. Therefore, an obtuse angle is formed between the bottom surface and the entry surface in each of the recessed sections formed in the housing opening located in the fastener housing portion of the tightening tool torque. Thus, cracking is prevented - as much as possible - even if each corner of the outer peripheral surface of the fastener with great force collides with the entrance surface of each recessed section formed in the inner peripheral surface of the enclosing hole when the inner peripheral surface of the enclosing hole of the fastener receiving portion is deformed. so that the torque-controlling tool rotates relative to the fastener.

With regard to the torque controlling tool and the combination of the torque controlling tool and the fastener provided in accordance with the third and fourth aspects of the present invention, the torque controlling tool is formed from a synthetic resin. Therefore, although they can be made relatively inexpensive to manufacture, they can be imparted with a relatively large tightening torque. Therefore, when the fastener is pressed into the housing opening of the fastener receiving portion, the relatively large manufacturing tolerance of the fastener is also compensated for by elastic deformation and / or plastic deformation of the retaining protrusion on the side surface located in front of the recessed section when viewed in the direction of rotation when tightened. As a consequence, there is a chance - as far as possible - to avoid unnecessarily increasing or decreasing the force required to press in the fastener.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a preferred embodiment of a torque control tool configured in accordance with the present invention as viewed from above.

FIG. 2 is a perspective view of the torque control tool of FIG. 1 when viewed from below.

FIG. 3 is a front view, partly in section, of a torque control for the tool of FIG. one.

FIG. 4 is a plan view of the torque control tool of FIG. one.

FIG. 5 is a bottom view of the torque control tool of FIG. one.

FIG. 6 is a front view, partly in section, of a combination of the torque-controlling tool of FIG. 1, and a nut, which is a typical fastener.

FIG. 7 is a cross-sectional view of the combination shown in FIG. 6.

FIG. 8 is a cross-sectional view of the combination shown in FIG. 6 illustrating a state in which the tightening torque of the nut exceeds a certain threshold value, whereby the torque controlling tool rotates with respect to the nut.

FIG. 9 is a perspective view similar to FIG. 2 illustrating another embodiment of a torque control tool configured in accordance with the present invention.

FIG. 10 is a bottom view of the torque control tool of FIG. 9.

FIG. 11 is a section similar to FIG. 7, the combination of the torque control tool shown in FIG. 9, and a nut, which is a typical fastener.

FIG. 12 is a cross-section similar to FIG. 7 and 11, illustrating yet another embodiment of a torque controlling tool configured in accordance with the present invention.

CARRYING OUT THE INVENTION

The invention will now be described in more detail with reference to the accompanying drawings, illustrating preferred embodiments of a torque controlling tool configured in accordance with the invention and combinations of such embodiments and a nut that is a typical fastener.

Referring to FIG. 1-3, it is noted that the torque control tool, denoted as a whole by 2, is formed integrally by injection molding or compression molding from a suitable synthetic resin, preferably a relatively high strength synthetic resin such as polycarbonate or acrylonitrile butadiene styrene (ABS ). The torque control tool 2 includes a fastener receiving portion 4 constituting almost the entire lower half of the control tool 2 and a torque application portion 6 constituting almost the entire upper half of said tool.

Referring also to FIG. 4 and 5 along with FIG. 1-3, it is noted that the fastener-receiving portion 4 has a generally tubular shape and is formed with a receiving opening 8 having an open free end, that is, open at the lower end. The annular bottom surface 10 of the fastener receiving portion 4 is flat and the annular top surface 12 of the fastener receiving portion 4 is similarly flat and extends parallel to the annular bottom surface 10. The outer peripheral surface 14 of the fastener receiving portion 4 is cylindrical.

It is important that the inner peripheral surface of the receiving hole 8 is shaped such that a recessed section 16 is formed in the middle portion of each lateral surface 15 of an imaginary regular polygonal inner peripheral surface corresponding to a torque-applying regular polygonal outer peripheral surface of the fastener 16. In the illustrated embodiment the fastener is a hex nut, as will be described later. Thus, the torque-applying regular polygonal outer peripheral surface of the fastener is a regular hexagon and an imaginary regular polygonal inner peripheral surface (the inner peripheral surface shown by the dash-dot line in FIG. 5) is also a regular hexagon. Each of the recessed sections 16 has a bottom surface 16a and two side surfaces, namely an inlet surface 16b on the inlet side and an outlet surface 16c on the outlet side as viewed in the tightening rotation direction (clockwise direction on Fig. 4; counterclockwise direction in Fig. 5). It is important that the angle α formed between the bottom surface 16a and the entrance surface 16b is an obtuse angle, preferably in the order of 100-160 degrees. In the illustrated embodiment, the bottom surface 16a is formed into an arc forming part of a circle concentric with the outer peripheral surface 14, and the entrance surface 16b extends outwardly relative to the side surface 15, tilting in the direction of rotation when tightened. The bottom surface 16a and the entrance surface 16b are preferably smoothly connected to each other via an arcuate boundary surface 16d. On the other hand, the exit surface 16c extends perpendicular to the side surface 15. The circumferential length L1 of the side surface 15a after the recessed section 16 in the direction of tightening rotation is advantageously greater than the circumferential length L2 of the side surface 15b before the recessed section 16 (in this case, the threshold torque the tightening torque is determined by the deformation of the lateral surface located after the recessed section 16, as will be quite clear from the explanations given later). As will be understood with reference to FIG. 3, the lower end portion of the inner peripheral surface of the receiving hole 8 opening at the annular bottom surface 10 of the fastener receiving portion 4 is chamfered. In the illustrated embodiment, the fastener receiving portion 4 is also provided with a communication opening 18 continuous with the upper end of the receiving opening 8. As will be readily apparent with reference to FIG. 5, the cross-sectional shape of the communication hole 18 is circular, the diameter of the hole 18 is slightly smaller than the diameter of a circle inscribed in an imaginary regular hexagon in the containing hole 8, and at the boundary between the containing hole 8 and the communication hole 18, a downward-facing annular surface 20 of the shoulder is bounded. facing down.

Referring next to FIG. 1-4, the torque application portion 6 extending upwardly from the annular top surface 12 of the fastener receiving portion 4 is also generally tubular and has a through hole 22 extending in the vertical direction. As will be abundantly clear from FIG. 3, the through hole 22 communicates with the receiving hole 8 through the communication hole 18. The cross-sectional shape of the through hole 22 is circular, the diameter of the through hole is even smaller than the diameter of the communication hole 18, and a toroidal shoulder surface 24 facing downward is defined at the boundary between the through hole 22 and the communication hole 18. The outer peripheral surface 26 and the top surface 28 of the torque application portion 6 preferably have shapes and sizes corresponding to the shapes and sizes of the outer peripheral surface and the top surface of the fastener to be received in the fastener-receiving portion 4. In the illustrated embodiment, the outer peripheral surface 26 the tightening torque application portion 6 is in the shape of a regular hexagon corresponding to the outer peripheral surface of the hex nut (accordingly, the outer diameter of the tightening torque application portion 6 is smaller than the outer diameter of the fastener-receiving portion 4), and the main portion of the upper surface 28 is flat, and the outer peripheral portion of each corner of the top surface 28 is chamfered. The diameter of the through hole 22 of the section 6 for applying the tightening torque is slightly larger than the outer diameter of the shank of the bolt to which the hex nut is attached. As will be further mentioned later, when the hex nut enclosed in the fastener receiving portion 4 is to be secured to the bolt, the shank of the bolt is inserted through the fastener receiving portion 4 communication hole 18 and the through hole 22 of the fastening torque application portion 6 when fastening occurs.

The above described tightening torque control tool 2 can be marketed independently, but is advantageously marketed in combination with a fastener as shown in FIG. 6 and 7 (to simplify the drawing, FIG. 7 does not show the chamfer at the lower end of the inner peripheral surface of the receiving hole 8). In the embodiment shown in FIG. 6 and 7, hex nut 30 is illustrated as a typical fastener. The outer peripheral surface 32 of the hex nut 30 is a regular hexagon that is slightly larger than the imaginary regular hexagon discussed in connection with the containing hole 8 formed in the fastener containing portion 4 (in other words, the imaginary regular hexagon of the containing hole 8 the fastener of the portion 4 in the torque-controlling tool 2 is made smaller than the imaginary regular hexagon of the outer circumferential surface 32 of the hex nut 30). The main part of the hex nut 30, namely, a part except for its lower end part, is pressed into the receiving hole 8 of the fastener receiving portion 4, and the upper surface of the cylindrical protrusion 36 formed from the inside of the portion 34 of the outer peripheral edge of the upper surface of the hex nut 30 is inserted into contact with the aforementioned toroidal surface 24 of the shoulder (if the hex nut 30 accommodated in the housing hole 8 of the fastener-receiving portion 4 is shaped without a cylindrical protrusion 36, then the portion 34 of the outer peripheral edge of the upper surface itself is brought into contact with the aforementioned annular surface 20 of the shoulder hex nut 30).

The following will explain how to use the torque-controlling tool 2 described above. If the hex nut 30 is already integrated with the torque control tool 2, then the hex nut 30 is fitted onto the shank 38 (FIG. 6) of the bolt to be fastened. If the hex nut 30 is not combined with the torque controlling tool 2, then the hex nut 30 temporarily fastened to the bolt is accommodated in the accommodating hole 8 formed in the fastener containing portion 4 of the torque controlling tool 2 (in this case, it is desirable to set the containing hole 8 of an imaginary regular hexagon having essentially the same dimensions as the outer peripheral surface of the regular hexagonal shape of the hex nut 30, so that it is quite easy to fit the hex nut 30 into the accommodating hole 8). Then, a suitable tightening tool (not shown) is brought into contact with the outer peripheral surface of the tightening torque application portion 6 and rotated in the tightening rotation direction (clockwise direction in FIG. 4; counterclockwise direction in FIG. 5). Torque applied to the tightening torque application portion 6 from the tightening tool side is transmitted to the hex nut 30 by the fastener receiving portion 4, whereby the hex nut 30 is tightened against the bolt shank 38. If the hex nut 30 is moved relative to the bolt shank 38 a relatively large distance in the axial direction, the bolt shank 38 is advanced into the communication hole 18 formed in the fastener receiving portion 4 and the through hole 22 formed in the tightening torque application portion 6, and is inserted through the communication opening 18 and the through opening 22, as shown in dash-dotted lines in FIG. 6.

When the tightening torque imparted to the hex nut 30 exceeds a predetermined threshold value to the inner peripheral surface of the receiving hole 8 formed in the fastener receiving portion 4, especially at the location after the recessed section 16 when viewed in the tightening rotation direction (more specifically - in the place between the boundary region of the surface 15 on the inlet side and the recessed section 16 of the surface 15 on the inlet side, when viewed in the direction of rotation when tightening), apply a preliminary mechanical stress in the direction opposite to the direction of rotation when tightening, and as a result, deform, as shown in fig. 8 (like Fig. 7, for simplification of the drawing, Fig. 8 does not show the chamfer at the lower end of the inner peripheral surface of the receiving hole 8). As a result, the torque control tool 2 is rotated relative to the hex nut 30. Therefore, the hex nut 30 is attached to the bolt with the required tightening torque. When the torque control tool 2 begins to rotate about the hex nut 30, the corner of the outer peripheral surface of the hex nut 30 may with great force collide with the entrance surface 16b of the recessed section 16 of the receiving hole 8 formed in the fastener receiving portion 4. However, since an obtuse angle is formed between the bottom surface 16a and the entry surface 16b of the recessed section 16 in the torque control tool 2 configured according to the present invention, a force applied on the entry surface 16b of the recessed section 16 by the angle of the outer peripheral surface of the hex nut 30, reduced or eliminated as appropriate. Therefore, there is a chance - as far as possible - to prevent cracking in the fastener-containing region 4, resulting in damage to the fastener-receiving region 4. After the torque-controlling tool 2 begins to rotate relative to the hex nut 30, the torque-controlling tool 2 can be it is easy enough to release from the hex nut 30, drawn to the shank 38 of the bolt with the required tightening torque.

FIG. 9 and 10 depict another preferred embodiment of a torque control tool configured in accordance with the present invention. In the torque control tool 2 shown in FIG. 9, 10 and 11, a retaining protrusion is disposed in portion 15b, which on the side surface 15 defining the inner peripheral surface of the receiving hole 8 is in front of the recessed section 16 as viewed in the tightening rotation direction (counterclockwise direction in FIG. 10) ... In the illustrated embodiment, a rib 21 is formed as the retaining protrusion, extending in the axial direction of the containing hole 8 (in a direction perpendicular to the surface of the sheet according to FIG. 10), preferably in a direction substantially parallel to the center line of the containing hole 8. In the illustrated an embodiment, a retaining protrusion, i.e., a rib 21, is formed on each of the portions 15b of the six side surfaces 15. Each of the ribs 21 extends from the upper end of the receiving opening 8 to some location near its lower end, substantially parallel to the center line of the containing opening 8, as will become abundantly clear when referring to FIG. 9 and 10. In particular, when the fastener has a nominal diameter of M8, M10 or M12, the height H of the rib 21 will be on the order of 0.1-0.5 mm and the circumferential width W of each of the ribs 21 will be on the order of 0.1 to 0.5 mm. The cross-sectional shape of the protruding end portion of the rib 21 is advantageously semicircular, as shown in FIG. 10. In the illustrated embodiment, ribs 21 are formed on all portions 15b of the six side surfaces 15. However, if desired, ribs 21 can be formed, for example, either only on portions 15b of the three side surfaces 15 located in every second position, or only in the regions 15b of the two side surfaces 15 located in diametrically opposite positions.

The rib 21 constituting the retaining protrusion can be formed not only in the portion 15b, which on the side surface 15 is in front of the recessed section 16 as viewed in the direction of rotation when tightened, but also in the portion 15a, which on the side surface 15 is after the recessed section 16 when viewed in the direction of rotation when tightening. However, if the rib 21 is also formed on the portion 15a, which is located on the side surface 15 after the recessed section 16, when viewed in the direction of rotation when tightening, then the rib is completely deformed before the side surface 15 deforms. This is because when the torsional the tightening torque reaches a threshold value, the portion 15a which is located on the side surface 15 after the recessed section 16 when viewed in the direction of rotation when tightening, deforms mainly as previously mentioned. Due to this deformation of the rib, the torque-controlling tool 2 tends to be released from the fastener before the tightening torque reaches the threshold value. Therefore, it is desirable not to position the rib 21 on the portion 15a that is on the side surface 15 after the recessed section 16 as viewed in the direction of rotation when tightened.

Configurations other than the configuration of the rib 21 in the embodiment shown in FIG. 9 and 10 are substantially the same as the configurations in the embodiment explained with reference to FIGS. 1 to 8, and the same constituent elements as the constituent elements in the last embodiment are assigned the same reference numbers as the constituent elements in the last embodiment.

Continuing further to FIG. 11 along with FIG. 9 and 10, it is noted that the above-described torque control tool 2 can be independently marketed. However, it is advantageously marketed in combination with a fastener as shown in FIG. 11 (in order to simplify the drawing, Fig. 11 does not show the image of the chamfer at the lower end of the inner peripheral surface of the containing hole 8; moreover, although the rib 21 is slightly deformed elastically or plastically by pressing the fastener, namely the hex nut 30, into the containing hole 8, in Fig. 11 such a deformation is not shown, and the rib 21 is shown superimposed on the hex nut 30 without deformation). As mentioned earlier, the outer peripheral surface 32 of the hex nut 30 as a typical example of a fastener is a regular hexagon, and if the technological tolerance of the hex nut 30 is small enough, then this regular hexagon is slightly larger than the regular hexagon, which was discussed in connection with the containing a hole 8 formed in the fastener receiving portion 4 (in other words, the imaginary regular hexagon of the fastener receiving hole 8 of the fastener receiving portion 4 in the torque control tool 2 is made smaller than the imaginary regular hexagon of the outer peripheral surface 32 of the hex nut 30). The main portion of the hex nut 30, namely a portion except for its lower end portion, is pressed into the housing hole 8 of the fastener housing portion 4, and the upper surface of the cylindrical protrusion 36 formed on the inside from the edge portion 34 of the outer peripheral edge of the upper surface of the hex nut 30 is inserted into contact with the aforementioned toroidal shoulder surface 24 (see FIG. 6). The hex nut 30 is held in the accommodating hole 8 because the side surface of the hex nut 30 is brought into contact with the pressing of the rib 21 in alignment with the portion 15a downstream of the recessed section 16 as viewed in the tightening direction of rotation (counterclockwise direction in FIG. eleven).

As mentioned above, the manufacturing tolerance of the torque controlling tool 2 obtained by injection molding or compression molding from a suitable synthetic resin is relatively small, and therefore the manufacturing error of the inner peripheral surface of the receiving hole 8 is relatively small. On the other hand, the manufacturing tolerance of the hex nut 30 is relatively large, and therefore the manufacturing tolerance of the outer peripheral surface of the hex nut 30 is relatively large. However, in the torque control tool 2 shown in FIG. 9, 10 and 11, the technological error of the outer peripheral surface of the hex nut 30, which is relatively large compared to the technological error of the inner peripheral surface of the containing hole 8, is compensated by elastic or plastic deformation of the ribs 21 formed in the necessary parts of the inner peripheral surface of the containing hole 8. As a consequence, an unnecessary increase or decrease in the force required to press the hex nut 30 into the accommodating hole 8 is prevented as much as possible.

In the embodiment shown in FIG. 9, 10 and 11, the retaining protrusion consists of a single rib 21 extending in the axial direction of the receiving opening 8. However, if desired, the retaining protrusion can be made consisting of: a plurality of ribs extending axially at intervals provided in the axial or circumferential direction of the containing hole 8; a single rib extending in the circumferential direction of the housing opening 8; or a plurality of ribs extending in the circumferential direction at intervals provided in the axial or circumferential direction of the receiving opening 8; or a plurality of appropriately arranged projections (preferably having a circular cross-section). FIG. 12 shows another embodiment of the retaining protrusion. In such an embodiment, on the side surface 15 (see FIG. 10) over the entire surface of the portion 15b in front of the recessed section 16, as viewed from the above-mentioned tightening rotation direction (counterclockwise direction in FIG. 12), a tubercle 40 is formed. and a groove 42 is formed on the rear side of the tubercle 40, extending along the tubercle 40. In such an embodiment, the hex nut 30 is held in the accommodating hole 8 because the side surface of the hex nut 30 is brought into contact with the tubercle 40 along with the portion 15a, which on the lateral surface 15 is after recessed section 16 when viewed in the tightening rotation direction (counterclockwise direction in FIG. 12).

The relatively large technological error of the outer peripheral surface of the hex nut 30 in comparison with the inner peripheral surface of the containing hole 8 is compensated by elastic deformation of the tubercle 40. As a result, an excessive increase or decrease in the force required to press the hex nut 30 into the containing hole 8 is prevented as much as possible degree.

EXPLANATION of symbols or positions

2: Torque control tool

4: Fastener-containing area

6: Tightening torque application area

8: Host hole

15: Side surface

15a: Section of the exit of the lateral surface

15b: Side entry section

16: Recessed section

16a: Bottom surface of the recessed section

16b: Surface of the entrance of the recessed section

16 s: Recessed section exit surface

18: Message hole

21: Rib (retaining lug)

22: Through hole

30: Hexagon nut

38: Shank of the bolt

Claims (27)

1. A torque control tool including a fastener receiving portion and a tightening torque application portion integrally made of synthetic resin, moreover, the fastener-containing section is formed with a containing hole having an open free end, and the inner peripheral surface of this containing hole is shaped in which a recessed section is made in the middle part of each of the side surfaces of a regular polygonal inner peripheral surface of the fastener corresponding to a regular the polygonal outer peripheral surface of the fastener, and an obtuse angle is formed between the bottom surface of the recessed section and the inlet surface of the recessed section on the inlet side as viewed in the direction of rotation when tightened, and when the tightening torque applied to the tightening torque application portion and transmitted to the fastener by the fastener-containing portion exceeds a certain threshold, the inner peripheral surface of the enclosing hole is deformed, causing the fastener-receiving portion to rotate relative to the fastener, so that control occurs tightening torque of the fastener. 2. The tightening torque control tool of claim 1, wherein the inlet surface of the recessed section extends outward from the side surface, tilting in the direction of rotation when tightening. 3. The torque control tool of claim 1 or 2, wherein the bottom surface and the inlet surface of the recessed section are smoothly connected to each other by an arcuate boundary surface. 4. The torque control tool according to any one of paragraphs. 1-3, in which the torque-applying regular polygonal outer peripheral surface is a regular hexagon. 5. The torque control tool according to any one of paragraphs. 1-4, in which the exit surface of each of the recessed sections on the exit side, as viewed in the direction of tightening rotation, extends perpendicular to the lateral surface. 6. The torque control tool according to any one of paragraphs. 1-5, in which the outer peripheral surface of the tightening torque application portion is a regular polygon and corresponds to the torque applying regular polygonal outer peripheral surface of the fastener. 7. Controlling the tightening torque tool according to any one of paragraphs. 1-6, in which a retaining protrusion is disposed in a portion that is on the lateral surface of the regular polygonal inner peripheral surface in front of the recessed section as viewed in the direction of tightening rotation. 8. The torque control tool of claim 7, wherein the retaining protrusion is a rib extending in the axial direction of the receiving bore. 9. The torque control tool of claim 8, wherein the height of the projection — the rib — is 0.1 to 0.5 mm and the circumferential width of the rib is 0.1 to 0.5 mm. 10. The torque control tool of claim 8 or 9, wherein the cross-sectional shape of the protruding end portion of the rib is semicircular. 11. The combination of torque control tool tightening according to any one of paragraphs. 1-10 and a fastener that fits at least partially in the receiving hole of the torque control tool. 12. The combination of claim 11, wherein the regular polygonal inner peripheral surface bounded by the side surfaces of the housing hole of the torque control tool is less than the torque-applying regular polygonal outer peripheral surface of the fastener, and the fastener is pressed into the containing hole. 13. The combination of claim 11 or 12, wherein the fastener is a hex nut. 14. A torque control tool including a fastener receiving portion and a tightening torque application portion integrally formed from a synthetic resin, wherein the fastener-containing portion is formed with an enclosing hole having an open free end, and the inner peripheral surface of this enclosing hole is shaped in which a recessed section is formed in the middle part of each of the side surfaces of a regular polygonal inner peripheral surface corresponding to a torque-applying regular polygonal outer the peripheral surface of the fastener, a retaining protrusion is disposed on the portion that on the lateral surface of the regular polygonal inner peripheral surface is in front of the recessed section as viewed in the direction of tightening rotation, and when the tightening torque applied to the tightening torque application portion and transmitted to the fastener by the fastener-containing portion exceeds a certain threshold, the inner peripheral surface of the enclosing hole is deformed, causing the fastener-receiving portion to rotate relative to the fastener, so that control occurs tightening torque of the fastener. 15. The torque control tool of claim 14, wherein the retaining protrusion is a rib extending in the axial direction of the receiving hole. 16. The torque control tool of claim 15, wherein the height of the projection — the rib — is 0.1 to 0.5 mm and the circumferential width of the rib is 0.1 to 0.5 mm. 17. The torque control tool of claim 15 or 16, wherein the cross-sectional shape of the protruding end portion of the rib is semicircular. 18. Controlling the tightening torque tool according to any one of paragraphs. 14-17, in which the torque-applying regular polygonal outer peripheral surface is a regular hexagon, and on each of the six side surfaces - in the area located in front of the recessed section - a retaining protrusion is located. 19. Controlling the tightening torque tool according to any one of paragraphs. 14-18, in which the outer peripheral surface of the tightening torque application portion is a regular polygon and corresponds to the torque applying regular polygonal outer peripheral surface of the fastener. 20. The combination of the aforementioned torque control tool tightening according to any one of paragraphs. 14-19 and a fastener that fits at least partially in the receiving hole of the torque control tool. 21. The combination of claim 20, wherein the fastener is pressed into the containing hole. 22. The combination of claim 20 or 21, wherein the fastener is a hex nut.

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