JP5634382B2 - Manufacturing method of wheel nut wrench - Google Patents

Description

  The present invention relates to a wheel nut wrench and a method for manufacturing a wheel nut wrench.

  In an automobile, an L-shaped wheel nut wrench for attaching / detaching a wheel is mounted as an in-vehicle tool. The wheel nut wrench generally uses carbon steel as a material, and forms a nut fitting part to be fitted to the nut in a plurality of processes by hot forging, and machine the plane and cylindrical part of the nut fitting part by machining. Finishing is performed by bending the shaft (handle part) from a predetermined position and further quenching the whole (Patent Document 1).

JP 2001-219380 A

In the hot forging process described above, one end of a heated bar-shaped steel member is first forged to form a dumpling-shaped nut fitting scheduled portion, and this nut fitting scheduled portion is forged to have a nut fitting hole inside. Form a mating part.
At this time, the volume of the nut fitting scheduled portion is set to be larger than the volume of the nut fitting portion after completion. This is for avoiding a problem that the nut fitting portion after completion does not satisfy a necessary volume. For this reason, after the hot forging process, machining that scrapes off the excess of the nut fitting portion is essential.
However, in the conventional manufacturing method, since there are many manufacturing processes, there exists a problem that the cost of a wheel nut wrench becomes high.

Moreover, in order to make the volume of the nut fitting planned portion larger than the volume of the nut fitting portion after completion, it is necessary to make the diameter of the rod-shaped steel member larger than necessary (generally, a diameter of 13 to 14 mm). There is. This is because, in order to form a large volume nut fitting portion from a thin rod-shaped steel member, a plurality of hot forgings are required, which in turn increases the manufacturing cost.
However, since the conventional manufacturing method uses a rod-shaped material that is thicker than necessary, there is a problem that the weight of the wheel nut wrench becomes heavy.

  An object of this invention is to provide the manufacturing method of the wheel nut wrench and wheel nut wrench which can aim at reduction of manufacturing cost and weight reduction.

  The wheel nut wrench according to the present invention is a wheel nut wrench in which a nut fitting portion having a nut fitting hole inside is formed on one end side of a handle portion by hot forging, and the nut fitting portion has an outer periphery The surface or the open end surface of the nut fitting hole is a hot forged surface that omits a cutting process.

  An annular flange portion protruding in the outer diameter direction is integrally formed on the end face of the nut fitting portion.

  The nut fitting portion is characterized in that the diameter of the handle portion side gradually decreases in a conical shape toward the handle portion side with respect to a portion fitted to the wheel nut.

  A method for manufacturing a wheel nut wrench according to the present invention is a method for manufacturing a wheel nut wrench in which a nut fitting portion having a nut fitting hole on the inside is formed at one end of a handle portion. Among them, a first hot working step of hot forming a portion having the same volume as the post-completion volume of the nut fitting portion in the nut fitting planned portion, and the nut fitting fitting by hot forging the nut fitting planned portion And a second hot working step formed on the portion, and the cutting process for the outer peripheral surface of the nut fitting portion or the opening end surface of the nut fitting hole is omitted.

  In the second hot working step, an annular flange portion protruding in an outer diameter direction is integrally formed on an end surface of the nut fitting portion.

  In the second hot working step, the nut fitting portion is formed such that the diameter of the handle portion side is gradually reduced to a conical shape toward the handle portion side with respect to the portion fitted to the wheel nut. Features.

  According to the present invention, it is possible to reliably reduce the cost and weight of the wheel nut wrench.

It is a general view and a bottom view showing a wheel nut wrench according to the first embodiment. It is an expanded sectional view (partially enlarged view of FIG. 1) of a nut fitting part. It is a flowchart figure which shows the manufacturing process of the wheel nut wrench which concerns on 1st embodiment. It is explanatory drawing of a preforming forge (1st hot working process). It is explanatory drawing of shaping | molding forging (2nd hot working process). It is the whole view and bottom view which show the wheel nut wrench which concerns on 2nd embodiment. It is an expanded sectional view of the nut fitting part (partial enlarged view of FIG. 6). It is explanatory drawing of shaping | molding forging (2nd hot working process). It is an expanded sectional view which shows the nut fitting part of the conventional wheel nut wrench. It is explanatory drawing of the conventional shaping | molding forge process.

  Hereinafter, wheel nut wrench 10,20 concerning the embodiment of the present invention and its manufacturing method are explained.

[First embodiment]
FIG. 1 is a view showing a wheel nut wrench 10 according to the first embodiment of the present invention. FIG. 2 is an enlarged cross-sectional view of the nut fitting portion 11 (partially enlarged view of FIG. 1).
The wheel nut wrench 10 is formed of an enlarged-diameter nut fitting portion 11 that is externally fitted to an M21 size wheel nut 50, and a handle portion 13 that extends in a rod shape connected to the nut fitting portion 11. The base side of the handle portion 13 is formed in a bent portion 12 bent at about 100 degrees.
The end surface 11t of the nut fitting portion 11 is provided with a fitting hole 11a that is fitted on the wheel nut 50.

  The wheel nut wrench 10 is formed by hot forging a rod-shaped steel (carbon steel) member 1. The diameter of the rod-shaped steel member 1 is 13 mm or more, preferably 13 mm. It is the material of the thickness similar to the material which forms the wheel nut wrench 100 of a prior art example (refer FIG.9 and FIG.10).

As shown in FIG. 2, the nut fitting portion 11 has an outer shape (outer peripheral surface 11 s) that decreases in diameter toward the proximal end side that is connected to the handle portion 13 from the end surface 11 t. More specifically, in the range of about 18 mm from the end face 11t to the base end side, it is formed in a cylindrical shape having the same diameter, and is formed in a conical shape that gradually decreases in diameter from the vicinity exceeding about 18 mm.
The range of about 18 mm from the end face 11 t to the base end side is a portion that fits into the wheel nut 50, and the range on the handle portion 13 side from the vicinity beyond about 18 mm is a portion that does not contact the wheel nut 50. And the site | part which does not contact the wheel nut 50 is formed in uniform wall thickness (about 3-4 mm).
The fitting hole 11a of the nut fitting portion 11 is formed to be a minimum space necessary for accommodating the wheel nut 50 to be fitted therein. The outer peripheral surface 11s of the nut fitting portion 11 is formed in a cylindrical shape following the fitting hole 11a while ensuring the minimum necessary thickness.

The nut fitting portion 11 has a strength capable of giving a prescribed tightening torque to the wheel nut 50. That is, the nut fitting portion 11 is formed to a thickness (thickness) having sufficient torsional strength.
The nut fitting portion 11 is particularly susceptible to cracking at the end surface 11t. For this reason, the thickness (wall thickness) of the nut fitting part 11 is formed to a sufficient thickness so that no cracks occur in the end face 11t.
On the other hand, it is necessary to avoid incurring weight. Therefore, the thickness of the nut fitting portion 11 is 3 to 4 mm.
The volume V1 (after completion) of the nut fitting portion 11 is about 13 cm ³ . In addition, the volume of the nut fitting scheduled part 105 of the conventional wheel nut wrench 100 is about 16 cm < ³ > (refer FIG. 10).

Both the end surface 11t and the outer peripheral surface 11s of the nut fitting portion 11 are not subjected to cutting (machining). That is, both the end surface 11t and the outer peripheral surface 11s are not cutting surfaces, but the forging surfaces are exposed.
The nut fitting part 11 is hardened by quenching (tempering). The nut fitting portion 11 is cured to an HRC hardness of about 35 to 45.

FIG. 3 is a flowchart showing the manufacturing process of the wheel nut wrench 10 according to the first embodiment.
In the manufacturing process of the wheel nut wrench 10, first, the rod-shaped steel member 1 (carbon steel) is heated to about 1000 to 1100 ° C. (first step S1). Next, one end (tip) of the heated steel member 1 is hot forged to form a dumpling (spherical) nut fitting scheduled portion 15 (see FIG. 4) (second step S2).
And it forges before the nut fitting scheduled part 15 becomes 900 degrees C or less, and forms the nut fitting part 11 (3rd process S3).

Further, the bent portion 12 is formed by bending the base portion of the nut fitting portion 11 of the rod-shaped steel member 1 (handle portion 13) to about 100 degrees (fourth step S4). Thereby, the external shape of the wheel nut wrench 10 is almost completed.
Thereafter, the wheel nut wrench 10 is used for shot blasting (fifth step S5), quenching (sixth step S6), surface cleaning, etc. for the purpose of removing oxide scale (carbonized film) and deburring. The shot blasting (seventh step S7) and plating (eighth step S8) are applied.
The manufacturing of the wheel nut wrench 10 is completed through such a plurality of steps.

  In the manufacturing process of the wheel nut wrench 10, the cutting process performed between the third process S3 (forming forging) and the fourth process S4 (bending process) is omitted as compared with the conventional manufacturing process. That is, the cutting process with respect to the end surface 11t and the outer peripheral surface 11s of the nut fitting part 11 is omitted.

  The manufacturing process of the wheel nut wrench 10 is performed in the second step S2 (preliminary forging) and the third step S3 (forming forging) in order to omit the cutting process by controlling the volume in the same manner as cold forging. Do. That is, in the manufacturing process of the wheel nut wrench 10, after the completion volume of the nut fitting portion 11 is predicted in the second process S2 and the third process S3, only the part necessary for the completed volume (heat During) forging. Specifically, the following steps are performed.

FIG. 4 is an explanatory diagram of preforming forging (first hot working step).
In the second step S2 (first hot working step), a dumpling-shaped nut fitting scheduled portion 15 is formed at the tip of the rod-shaped steel member 1 by preforming forging. That is, preforming forging is performed on the tip of the rod-shaped steel member 1 heated to about 1000 to 1100 ° C. in the first step S1.
At this time, a completed volume V1 of the completed nut fitting portion 11 is calculated from a design drawing or the like. The completed volume V1 is about 13 cm ³ . And the nut fitting scheduled part 15 which has the same volume V1 as the volume V1 after completion of the nut fitting part 11 is formed.

  Specifically, since the diameter (13 mm) of the rod-shaped steel member 1 is known, the necessary length for the volume V1 is obtained. And in the case of hot forging, the rod-shaped steel member 1 is correctly positioned with respect to the 1st metal mold | die 51 holding the rod-shaped steel member 1. FIG. When the distal end of the rod-shaped steel member 1 is inserted and positioned with respect to the first mold 51, it is projected from the distal end into the cavity space of the first mold 51 by a necessary length that is a volume V1. Thereby, only the site | part (volume V1) which should become the nut fitting scheduled part 15 among the rod-shaped steel members 1 is protruded in the cavity space of the 1st metal mold | die 51. FIG.

  Next, the tip of the steel member 1 protruding into the cavity space of the first mold 51 is struck by the second mold 52 to apply pressure. And the position (stroke of the 2nd metal mold | die 52) of the 2nd metal mold | die 52 with respect to the 1st metal mold | die 51 is set correctly. Thereby, it deform | transforms between the 1st metal mold | die 51 and the 2nd metal mold | die 52, and the nut fitting scheduled part 15 of the volume V1 is formed.

Since the diameter of the rod-shaped steel member 1 is 13 mm and the volume is smaller than the volume of the nut fitting scheduled portion 105 (about 16 cm ³ ) in the conventional wheel nut wrench 100, the heat treatment in the first step is short. Furthermore, the nut fitting scheduled portion 15 having the volume V1 can be quickly formed in the second step.

FIG. 5 is an explanatory diagram of forming forging (second hot working step).
In the third step S3 (second hot working step), the nut-shaped nut fitting scheduled portion 15 formed at the tip of the rod-shaped steel member 1 is formed in the nut fitting portion 11 by forming forging.
First, before the nut fitting scheduled portion 15 reaches 900 ° C. or lower, the rod-shaped steel member 1 is gripped by the first female die 55 and the second female die 56, and the nut fitting planned portion 15 is changed to the first female die 55. The second female die 56 is accommodated in the cavity space.
At this time, the nut fitting scheduled portion 15 is accurately positioned with respect to the first female die 55 and the second female die 56. That is, the first female die 55 and the second female die 56 are protruded into the cavity space of the first female die 55 and the second female die 56 from the tip of the rod-shaped steel member 1 (the nut fitting scheduled portion 15) by a necessary length to become the volume V1.

Next, the male mold 57 is inserted toward the cavity space of the first female mold 55 and the second female mold 56, and the nut fitting scheduled portion 15 is struck to apply pressure. The male mold 57 is formed with a flange portion 57f. Further, the flange portion 57 f fits into the cavity space of the first female die 55 and the second female die 56.
Then, the position of the male mold 57 relative to the first female mold 55 and the second female mold 56 (stroke of the male mold 57) is set accurately. Thereby, the nut fitting scheduled portion 15 is deformed following the cavity space formed by the first female die 55, the second female die 56 and the male die 57, and the nut fitting portion 11 having the volume V1 is formed. .
Since the volume V1 of the nut fitting scheduled portion 15 is substantially the same as the volume V1 after the nut fitting portion 11 is completed, the nut fitting portion 11 that is actually formed has almost no surplus wall, and there is no surplus from the cavity space. Meat hardly eats out.

In the conventional manufacturing method, the volume of the nut fitting scheduled portion is formed to be about 15% larger than the volume of the nut fitting portion after completion. The volume of the nut fitting portion is about 16 cm ³ , and the post-completion volume of the nut fitting portion is about 14 cm ³ .
As shown in FIG. 10 (a), when the nut-fitting portion is formed and forged into the nut fitting portion, an excess of about 2 cm ³ protrudes into the nut fitting portion.
For this reason, as shown in FIG.10 (b), the nut fitting part is completed by giving the machining which scrapes off the surplus thickness of about 2 cm < ³ >.

On the other hand, in the third step S3, when the nut fitting portion 11 is formed, there is almost no surplus, so that the cavity space formed by the first female die 55, the second female die 56, and the male die 57 is substantially reduced. It can be a sealed space.
Therefore, it is not necessary to remove surplus by cutting in the post process of the third step S3 for the nut fitting portion 11 that is actually formed.

  In 3rd process S3, it adjusts to such an extent that a little surplus comes out from the nut fitting part 11. FIG. This slight excess appears as a fine burr on the outer surface side of the nut fitting portion 11. And this fine burr | flash is removed with an oxide scale by performing shot blasting at a post process (5th process S5).

In the wheel nut wrench 10 and its manufacture according to the first embodiment, it is not necessary to perform cutting on the nut fitting portion 11 in the subsequent process of the third process S3 (hot forging). Since the surplus wall hardly protrudes from the nut fitting part 11, cutting can be omitted.
Therefore, in the manufacture of the wheel nut wrench 10, operations such as cutting and setup are not required, and the number of manufacturing steps and the manufacturing time can be greatly reduced. Therefore, the manufacturing cost of the wheel nut wrench 10 can be reliably reduced. In addition, since the hot forging is performed under precise volume control like the cold forging without using a special apparatus, the cost of the manufacturing apparatus is hardly increased.

  Further, in the wheel nut wrench 10 and its manufacture, the first step S1, the second step S2, the fifth step S5, and the seventh step S7 are also set to a smaller volume than before, so the time can be shortened.

  Moreover, since the nut fitting part 11 does not become larger than necessary, the weight reduction of the wheel nut wrench 10 is achieved.

  In addition, when forming the nut fitting portion 11 in the third step S3 (molding and forging), there is almost no surplus, so the cavity formed by the first female die 55, the second female die 56, and the male die 57. Even if the space is almost sealed, the first female mold 55, the second female mold 56, and the male mold 57 are not damaged by excessive pressure.

[Second Embodiment]
About the structure same as the wheel nut wrench 10 which concerns on 1st embodiment, a manufacturing process, etc., the same code | symbol is attached | subjected and the description is abbreviate | omitted.
FIG. 6 is a view showing a wheel nut wrench 20 according to the second embodiment of the present invention. FIG. 7 is an enlarged cross-sectional view of the nut fitting portion 21 (partially enlarged view of FIG. 6).
The wheel nut wrench 20 is formed of a diameter-enlarged nut fitting portion 21 that is externally fitted to an M21 size wheel nut 50, and a handle portion 23 that extends in a rod shape connected to the nut fitting portion 21. The base side of the handle portion 23 is formed in a bent portion 22 bent at about 100 degrees.
The end surface 21t of the nut fitting portion 21 is provided with a fitting hole 11a that is fitted on the wheel nut 50.

  The wheel nut wrench 20 is formed by hot forging a rod-shaped steel member 1 (carbon steel). The diameter of the rod-shaped steel member 1 is less than 13 mm, preferably 12 mm. It is a thin material compared with the material which forms the wheel nut wrench 100 of a prior art example (refer FIG.9 and FIG.10).

As shown in FIG. 6, the nut fitting portion 21 has an outer shape (outer peripheral surface 21 s) whose diameter decreases from the end surface 21 t toward the base end side connected to the handle portion 23. More specifically, in the range of about 18 mm from the end surface 21t to the base end side, it is formed in a cylindrical shape having the same diameter, and is formed in a conical shape that gradually decreases in diameter from the vicinity exceeding about 18 mm. The range of about 18 mm from the end face 21 t to the base end side is a portion that fits the wheel nut 50, and the range on the handle portion 23 side from the vicinity exceeding about 18 mm is a portion that does not contact the wheel nut 50. And the site | part which does not contact the wheel nut 50 is formed in uniform wall thickness (about 3-4 mm).
The fitting hole 11a of the nut fitting portion 21 is formed to be a minimum space necessary for accommodating the wheel nut 50 to be fitted therein. The outer peripheral surface 21s of the nut fitting portion 21 is formed in a cylindrical shape following the fitting hole 11a while ensuring a necessary minimum thickness.

The nut fitting portion 21 has a necessary minimum strength capable of giving a prescribed tightening torque to the wheel nut 50. That is, the nut fitting portion 21 is formed to a thickness (thickness) having a minimum necessary torsional strength.
The nut fitting portion 21 is particularly susceptible to cracking at the end surface 21t. For this reason, the thickness (wall thickness) of the nut fitting portion 21 is formed to a sufficient thickness so that no cracks occur in the end surface 21t. Specifically, the wall thickness is 3 to 4 mm.
On the other hand, in a portion other than the end surface 21t of the nut fitting portion 21 (a portion in a range from about 4 mm to about 18 mm from the end surface 21t to the base end side), a thickness of about 2 to 3 mm is sufficient.
For this reason, in the nut fitting part 21, the thickness of the end surface 21t is formed to be thicker than the thickness of the other part to form the annular flange part 21f. That is, the thickness of the ring-shaped flange portion 21f is formed to be about 3 to 4 mm, and the portion fitted to the wheel nut 50 is formed to be about 2 to 3 mm.
The volume V2 (after completion) of the nut fitting portion 21 is about 10 cm ³ . In addition, the volume of the nut fitting scheduled part 105 of the conventional wheel nut wrench 100 is about 16 cm < ³ > (refer FIG. 10).

  Both the end surface 21t and the outer peripheral surface 21s of the nut fitting portion 21 are not cut. That is, both the end surface 21t and the outer peripheral surface 21s are not cutting surfaces and the forging surfaces are exposed.

The manufacturing process of the wheel nut wrench 20 is the same as the process shown in FIG. That is, FIG. 3 is also a flowchart showing the manufacturing process of the wheel nut wrench 20 according to the second embodiment.
Also in the manufacturing process of the wheel nut wrench 20, in the second step S2, one end portion (tip end) of the heated steel member 2 is hot forged to form a dumpling-shaped nut fitting scheduled portion 25 (see FIG. 8). Form.
Then, in the third step S3, the nut fitting portion 21 is formed by forging before the nut fitting planned portion 25 reaches 900 ° C. or less.

The second step S2 (first hot working step), that is, the formation of the nut fitting scheduled portion 25 is performed in the same manner as the nut fitting scheduled portion 15.
First, a completed volume V2 of the completed nut fitting portion 21 is calculated from a design drawing or the like. The completed volume V2 is about 10 cm ³ .

  And the nut fitting scheduled part 25 which has the same volume V2 as the volume V2 after completion of the nut fitting part 21 is formed. In addition, the metal mold | die (not shown) used here differs from the case of the nut fitting scheduled part 15 (small size) is used.

Since the diameter of the rod-shaped steel member 2 is 12 mm, it is inefficient to increase the volume of the nut fitting scheduled portion 25. This is because the rod-shaped steel member 2 is cooled before the nut fitting scheduled portion 25 is completely formed. That is, it becomes necessary to repeat reheating of the rod-shaped steel member 2 (first step S1).
For this reason, it is preferable that the volume V2 of the nut fitting scheduled portion 25 formed at the tip of the rod-shaped steel member 2 is about 10 cm ³ which is the minimum necessary. Therefore, by setting the volume of the nut fitting planned portion 25 to the minimum necessary, before the rod-shaped steel member 2 is cooled (below 900 ° C.), the nut fitting planned portion 25 and the nut fitting portion of the volume V2 are obtained. The formation of 21 can be completed.

FIG. 8 is an explanatory diagram of forming forging (second hot working step).
The third step S <b> 3 (second hot working step), that is, the formation of the nut fitting portion 21 is performed in the same manner as the nut fitting portion 11.
As shown in FIG. 8, the first female mold 65 and the second female mold 66 accurately position the nut fitting scheduled portion 25 to be gripped and accommodated. Then, the male mold 57 is inserted toward the cavity space of the first female mold 65 and the second female mold 66, and the nut fitting scheduled portion 25 is struck to apply pressure. The male mold 57 is formed with a flange portion 57f. Further, the flange portion 57 f is fitted into the cavity space of the first female die 65 and the second female die 66.
On the other hand, in the cavity space of the first female mold 65 and the second female mold 66, stepped portions 65d and 66d extending in the diameter direction are formed. An annular flange portion 21 f of the nut fitting portion 21 is formed by the step portions 65 d and 66 d of the first female die 65 and the second female die 66 and the flange portion 57 f of the male die 57.

Then, the position of the male mold 57 with respect to the first female mold 65 and the second female mold 66 (stroke of the male mold 57) is accurately set. Accordingly, the nut fitting scheduled portion 25 is deformed following the cavity space formed by the first female die 65, the second female die 66, and the male die 57, and the nut fitting of the volume V2 having the annular flange portion 21f is performed. Part 21 is formed.
Since the volume V2 of the nut fitting scheduled portion 25 is substantially the same as the volume V2 after the nut fitting portion 21 is completed, the nut fitting portion 21 that is actually formed has almost no surplus wall, and there is no surplus from the cavity space. Meat hardly eats out.

In the third step S3, when the nut fitting portion 21 is formed, there is almost no surplus, so the cavity space formed by the first female mold 65, the second female mold 66, and the male mold 57 is substantially sealed. Can be.
Therefore, it is not necessary to remove surplus by cutting in the post process of 3rd process S3 with respect to the nut fitting part 21 actually formed. This is because by performing shot blasting in the subsequent process (fifth process S5), fine burrs appearing on the outer surface side of the nut fitting portion 21 can be removed together with the oxide scale.

In the wheel nut wrench 20 and its manufacture according to the second embodiment, it is not necessary to cut the nut fitting portion 21 in the post-process of the third step S3 (hot forging). Since surplus material hardly protrudes from the nut fitting part 21, cutting can be omitted.
Therefore, in the manufacture of the wheel nut wrench 20, operations such as cutting and setup are not required, and the number of manufacturing steps and the manufacturing time can be greatly reduced. Therefore, the manufacturing cost of the wheel nut wrench 20 can be surely reduced. In addition, since the hot forging is performed under precise volume control like the cold forging without using a special apparatus, the cost of the manufacturing apparatus is hardly increased.

  Moreover, in the wheel nut wrench 20 and its manufacture according to the second embodiment, since the material having a smaller diameter is used as compared with the conventional material, the weight of the wheel nut wrench 20 can be reduced. The mechanical strength of the nut fitting portion 21 can be sufficiently secured.

  Further, since the nut fitting portion 21 does not become larger than necessary, the weight of the wheel nut wrench 20 can be reduced.

  Also in the second step S2, the time can be shortened because the volume can be set smaller than the conventional volume. In addition, since a material having a smaller diameter than the conventional one is used, the heating time and the amount of heat for heating in the second step S2 and the third step S3 can be suppressed. Further, the shot blasting in the fifth step S5 and the seventh step S7 can also reduce the time because the surface area is smaller than that in the prior art. Therefore, the manufacturing cost can be further reduced.

  In addition, when forming the nut fitting portion 21 in the third step S3 (molding and forging), there is almost no surplus, so the cavity formed by the first female die 65, the second female die 66, and the male die 57 Even if the space is almost sealed, the first female mold 65, the second female mold 66, and the male mold 57 are not damaged by excessive pressure.

  The various shapes and combinations of the constituent members shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  Any method can be used as the heating method in the second step S2 and the third step S3. The second step S2 is not limited to hot forging, and may be any processing (formation) processing that is performed hot such as by electrical resistance. Moreover, the shape of the nut fitting scheduled parts 15 and 25 is not restricted to dumpling (sphere) shape.

The wheel nut wrench 10, 20 need not be L-shaped. A so-called T-type wheel nut wrench may be used.
Moreover, the handle | steering-wheel part 13 (steel members 1 and 2) does not need to be a cross-sectional round shape, and may be a square, a polygon, or an ellipse.

  Further, the fitting holes 11a and 21a) of the wheel nut wrench 10 and 20 are not limited to the case corresponding to the wheel nut of the M21 size, and may be the case corresponding to the wheel nut of another size.

  The female mold used in the third step S3 forms the cavity space with the two split female molds 55 and 56, but is not limited thereto. The cavity space may be formed by one female mold or three or more female molds.

  DESCRIPTION OF SYMBOLS 1, 2 ... Steel member, 10, 20 ... Wheel nut wrench, 11, 21 ... Nut fitting part, 11a ... Fitting hole (nut fitting hole), 11s, 21s ... Outer peripheral surface, 11t, 21t ... End face (opening) End face), 13, 23 ... handle part, 15, 25 ... nut fitting scheduled part (part), 50 ... wheel nut

Claims (3)

A method for manufacturing a wheel nut wrench in which a nut fitting portion having a nut fitting hole inside is formed at one end of a handle portion,
By deforming following the space formed by the single female mold and the single male mold , a portion having the same volume as the post-completion volume of the nut fitting portion of one end of the rod-shaped steel member is formed. A first hot working process for hot forming in the nut fitting planned part;
The outer surface and nut fitting hole are obtained by hot forging the nut fitting planned portion by deforming following a space formed by a plurality of female molds holding the rod-shaped steel member and a single male mold. A second hot working step to be formed in the nut fitting portion having :
With
The manufacturing method of the wheel nut wrench characterized by omitting the cutting process with respect to the outer peripheral surface of the said nut fitting part, and the opening end surface of the said nut fitting hole. 2. The method of manufacturing a wheel nut wrench according to claim 1 , wherein in the second hot working step, an annular flange portion protruding in an outer diameter direction is integrally formed on an end surface of the nut fitting portion. In the second hot working step, the nut fitting portion is formed such that the diameter of the handle portion side is gradually reduced to a conical shape toward the handle portion side with respect to the portion fitted to the wheel nut. The manufacturing method of the wheel nut wrench of Claim 1 or 2 characterized by the above-mentioned.

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