JP6129397B1 - rifle - Google Patents

Abstract

The present invention provides a rifle having a mechanism (rifle) provided with a mechanism for suppressing the occurrence of a detonator breakthrough (opening a hole in a detonator). When a trigger 21 is pulled, a hammer 26 is disengaged from the reverse rod 22 and moves forward in the bottom 25, and a shooting pin 26 strikes the detonator 104 of a bullet 100 contained in a chamber 11 from behind. In the rifle having a structure in which the gunpowder 102 in the cartridge case 101 is exploded and the bullet 103 is fired forward, the abutment portion α1 is provided on the firing needle 26 itself or the firing needle integrated member provided integrally with the firing needle 26. In addition, a contact portion α2 for contacting the contact portion α1 is provided on the firing pin peripheral member (floating bottom 25) that is a separate body from the firing pin 26, and immediately after the firing needle 26 strikes the detonator 104, the contact portion α1. And the contact portion α2 are in contact with each other, so that the firing pin 26 immediately after hitting the detonator 104 is prevented from moving backward from the hitting start position. [Selection] Figure 4

Description

  The present invention relates to a rifle.

  When a general rifle pulls a trigger (trigger), the hammer (hammer) is released from the reverse shear (shear) and moves forward in the floating bottom (bolt), and the bullet (cartridge) stored in the chamber (chamber) ) The detonator (primer) is fired from behind by a firing pin (fire ring pin) to explode gunpowder (powder) in the cartridge case (cartridge case) and to fire a bullet (britt) forward. Yes. In a rifle having such a structure, when a gunpowder explodes, a phenomenon called “detonator breakthrough” in which high-pressure gas generated in the cartridge is ejected backward from the detonator can occur. When a detonator breaks out, not only the rifle engine (receiver) may be damaged, but also the rifle user's eyes may be damaged. For this reason, detonator breakthrough countermeasures are important for rifles.

  The detonator breakthrough is thought to occur mainly because the explosive power of the explosive is too strong and a hole is opened in the detonator (more precisely, a hole is opened at the bottom of the part called “cup” in the detonator). ing. For this reason, a detonator breakthrough often occurs as a bullet side problem rather than a main body (rifle) side problem, and a detonator breakthrough countermeasure is often applied to the bullet side. For example, Patent Document 1 describes that a detonator breakthrough is prevented by devising a component of an explosive applied to a detonator (see paragraph 0002 and the like of the same document). On the other hand, the countermeasures for detonating the detonator on the rifle side are limited to the extent that the user adjusts each part constituting the engine unit through trial and error.

  By the way, Patent Document 2 describes not only a rifle but a machine gun with a large caliber, and it is described that a countermeasure against a detonator breakthrough is taken on the main body (machine gun) side. As shown in FIG. 1 of the same document, the machine gun of Patent Document 2 is configured so that the flange 22 provided on the firing pin 4 is brought into contact with the edge 30a of the firing needle holding hole 30 that holds the firing needle 4, thereby The holding hole 30 is in a sealed state to prevent the gas generated by the detonator breakthrough from moving backward.

JP 2010-024065 A JP 2001-124493 A

  However, as with the technique described in Patent Document 1, most of the detonator breakthrough measures to be applied to the bullet side suppress the explosive force of the explosive, and therefore sacrifice the performance of the bullet, such as shortening the flight distance of the bullet. It is easy to be connected to.

  Further, the technology described in Patent Document 2 merely prevents the gas blown out behind the detonator from detonating the detonator and reaches the guide hole of the hammer. ) Is not deterred. For this reason, even in the cannon of Patent Document 2, there is a possibility that deformation or the like may occur in a portion on the front side of the gun gun 4 that is sealed with the collar portion 30a of the firing pin 4. The deformation of this part is considered not to be a big problem in a cannon that does not require much accuracy, but can be a big problem in a rifle that requires high accuracy.

  The present invention has been made to solve the above problems, and provides a rifle equipped with a mechanism on the main body (rifle) side for suppressing the occurrence of a detonator breakthrough (opening a hole in a detonator). is there.

The above issues
When the trigger is pulled, the hammer strikes away from the reverse trap and moves forward in the bottom of the bottom, and the shooting needle blows from behind the detonator of the bullet housed in the chamber, exploding the gunpowder in the cartridge and moving the bullet forward. A rifle having a firing structure,
The firing pin integral member provided integrally with the firing pin itself or firing pin, abutment alpha ₁ is provided,
The firing pin peripheral members formed of separate from the firing pin, abutment alpha ₂ for abutting the abutment alpha ₁ is provided,
Characterized in that the firing pin by a contact portion alpha ₁ and the contact portion alpha ₂ abut each other immediately after striking the detonator, and prevented from moving rearward from the firing pin striking start position immediately after striking the detonator It is solved by providing a rifle.

  Here, the “striking start position” refers to a position where the front end of the firing needle that moves forward toward the detonator starts to come into contact with the rear surface of the detonator (usually the rear surface of the portion called “cup”) (the firing needle is in relation to the detonator). The first contact position). As will be described later, the detonator breakthrough is considered to occur when the detonator can not withstand the explosive force of gunpowder and greatly deforms, and as with the rifle of the present invention, the striker immediately after hitting the detonator By retracting only to the start position, it is possible to suppress the occurrence of detonator breakthrough (opening a hole in the detonator). Moreover, in this invention, the mechanism which prevents generation | occurrence | production of a detonator breakthrough can be provided in the main body (rifle) side. For this reason, in the rifle of the present invention, it is possible to use bullets filled with explosives having a higher explosive power than conventional rifles.

The cause of the detonator breakthrough and the reason why the present invention can prevent the detonator breakthrough will be described in more detail as follows.
[Cause of detonation breakthrough]
The striker when hitting the detonator continues to advance until reaching the limit position ahead after reaching the hitting start position, and forms a recess (striking mark) on the rear face (bottom face of the cup) of the detonator. At this time, the shock applied to the detonator ignites the explosive (prime) in the detonator, the explosive (propellant) in the shell explodes, and a bullet is fired. The hitting needle that has reached the front limit position reverses the moving direction and moves backward due to the reaction, the biasing force of the spring biasing the hitting needle backward, and the like. At this time, the rear part of the detonator (the bottom part of the cup) tends to swell rearward due to the explosive pressure of the explosive. In particular, the portion where the above-mentioned hitting mark is formed on the rear surface portion of the detonator is thinner than its surroundings, so that deformation such as swelling is likely to occur. When the rear surface portion of the detonator (particularly where the hitting mark is formed) cannot withstand the above deformation, a hole is opened in the detonator, and a blast blows out from the hole. This is presumed to be the cause of detonation breakthrough.
[Reason why the present invention can suppress the detonation of the detonator]
In the rifle of the present invention, as described above, the striker immediately after hitting the detonator is prevented from moving backward from the hitting start position. For this reason, as described in the section “Cause of detonator breakthrough” above, even if the rear surface portion of the detonator bulges back due to the explosive pressure of the explosive, the above-mentioned strike mark is formed on the rear surface portion. When it returns to the position it was when it was not, it is supported by the front end of the firing pin, and after that it cannot be deformed backward. In other words, the rear surface portion of the detonator is in a state where it can withstand the pressure of explosive explosives, and a hole is difficult to open in the rear surface portion. This is presumed to be the reason why the detonator breakthrough can be prevented in the present invention.

In rifles of the present invention, the specific locations to provide an abutment alpha ₁ and the contact portion alpha _2, if is not particularly limited, provided as follows preferred.

Primarily,
With the firing pin as a separate body from the hammer, when the front end of the hammer hits the rear end of the hammer, the hammer moves forward in the playground,
The contact part α ₁ is provided on the firing pin,
An abutment alpha _2, is an aspect to provide a firing pin housing portion is a portion that houses the firing pin in the bolt.
Hereinafter, the rifle of this aspect may be referred to as the “rifle of the first embodiment”.

Secondly,
The firing pin is provided integrally with the hammer, so that the hammer and the hammer strike together to move forward in the playground.
Reverse
A hammer hitting position that keeps the hammer hitting on its front end side,
The rear end side is displaced upward, the front end side is displaced downward, and the hammer hitting release position at which the hammer can no longer be hooked on the front end side,
After swinging between
The abutting part α ₁ is provided on the hammering iron,
An abutment alpha _2, is an aspect to provide the rear end of the sear.
Hereinafter, the rifle of this aspect may be referred to as the “rifle of the second embodiment”.

  The rifle according to the first embodiment has an advantage that it is possible to secure a long run-up distance of the firing pin that strikes the detonator, and the rifle according to the second embodiment has an advantage that the number of movable parts can be reduced.

  As described above, according to the present invention, it is possible to provide a rifle provided with a mechanism on the main body (rifle) side for suppressing the occurrence of a detonator breakthrough (opening of a hole in a detonator).

It is the side view which showed the whole rifle. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 1st embodiment, Comprising: It is the figure which showed the state before a trigger is pulled. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 1st embodiment, Comprising: It is the figure which showed the state which the firing pin started hitting the detonator. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 1st embodiment, Comprising: It is the figure which showed the state which the striker which struck the detonator retreated to the impact start position. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 2nd embodiment, Comprising: It is the figure which showed the state before a trigger is pulled. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 2nd embodiment, Comprising: It is the figure which showed the state which the firing pin started hitting the detonator. It is sectional drawing which showed the internal structure of the engine part periphery in the rifle of a 2nd embodiment, Comprising: It is the figure which showed the state which the striker which struck the detonator retreated to the impact start position.

  The preferred embodiment of the rifle of the present invention will be described more specifically with reference to the drawings.

  FIG. 1 is a side view showing the entire rifle. As shown in FIG. 1, the rifle of this embodiment includes a barrel (barrel) 10, an engine part (receiver) 20, a guard (trigger guard) 30, a gun handle (grip) 40, and a stock (stock). 50. The engine unit 20 is provided with a trigger (trigger 21). In the rifle according to the present embodiment, the stock 50 is provided to extend to the vicinity of the middle part of the barrel 10 (near a portion called a forehand in a general rifle). In addition, it is supported by the base stock 50 as well. For this reason, it has a structure in which the stability of the barrel 10 at the time of bullet firing is improved and the accuracy of hitting is easily increased.

  The rifle of the present invention is provided with a mechanism for preventing the phenomenon called “detonator breakthrough” described above (hereinafter sometimes referred to as “detonator breakthrough prevention mechanism”). In the following, two embodiments having different specific structures in the detonator break-off prevention mechanism (the embodiment according to the above-mentioned “rifle of the first embodiment” and the embodiment according to the above-mentioned “rifle of the second embodiment”) ) To illustrate the rifle of the present invention. However, the technical scope of the rifle of the present invention is not limited to these embodiments, and can be changed as appropriate without departing from the spirit of the present invention.

1. Rifle of the first embodiment First, the rifle of the first embodiment will be described. 2 to 4 are sectional views showing the internal structure around the engine unit 20 in the rifle according to the first embodiment. FIG. 2 shows a state before the trigger 21 is pulled, and FIG. 3 shows the trigger. FIG. 4 shows a state in which 21 is pulled and the firing pin 26 starts to strike the detonator 104, and FIG. 4 shows a state in which the firing needle 26 that has hit the detonator 104 has moved back to the strike start position.

  In the rifle of the first embodiment, as shown in FIG. 2, the engine unit 20 includes a trigger (trigger) 21 for pulling with a finger, a reverse shear (shear) 22 that operates when the trigger 21 is pulled, Strike iron (hammer) 23 hooked by the scissors 22, a coil spring (strike force urging means) 24 that urges the striking iron 23 forward, and a bottom (bolt) that accommodates the strike iron 23 in a movable state in the front-rear direction. 25 and a shooting pin (firing pin) 26 disposed in front of the hammering iron 23 in the play bottom 25. At the rear end of the barrel 10, a chamber 11 for storing a bullet (cartridge) 100 is provided. The bullet 100 is fitted into the cartridge case 101, the explosive powder 102 packed in the cartridge case 101, the bullet 103 held at the tip of the cartridge case 101, and the rear end portion of the cartridge case 101. Detonator (primer) 104. In the rifle of the first embodiment, the trigger 21 and the reverse rod 22 are integrated, while the hammering iron 23 and the firing pin 26 are separate.

  In the rifle of the first embodiment, when the trigger 21 is pulled from the state shown in FIG. 2, as shown in FIG. 3, the hammer 23 is removed from the reverse rod 22 and advances in the bottom 25, and the front end of the hammer 23 Thus, the rear end portion of the striker 26 is hit. When the striker 26 is hit by the hammer 23, it moves forward and hits (presses) the rear surface of the detonator 104 (the rear surface of the cup 104a) at its front end. Thereby, the cup 104a (FIG. 2) of the detonator 104 is deformed so as to be recessed forward, and the explosive 104b (FIG. 2) applied to the front side of the cup 104a is transformed into the cup 104a and the ignition gold (anvil) 104c (FIG. 2). 2), the gunpowder 102 in the cartridge case 101 explodes. By this explosion, the pressure in the cartridge case 101 increases and the bullet 103 is fired.

At this time, the firing pin 26 immediately after striking the detonator 104 is a striking start position (a position where the front end of the firing pin 26 starts to contact the rear surface of the detonator 104. In the rifle of the first embodiment, the firing needle 26 is located in FIG. If it moves rearward than the position, it may break through the detonator. In this regard, in the rifle first embodiment, as shown in FIG. 4, the firing pin 26, provided with an abutment alpha _1, the contact portion alpha ₂ provided on bolt 25 (the firing pin peripheral member), firing pin 26 by but it and the contact portion alpha ₁ and the contact portion alpha ₂ immediately after striking the detonator 104 abut each other and prevented from moving rearward from the firing pin 26 immediately after striking the detonator 104 is batting start position .

Specifically, the front shaft portion 26a for hitting the detonator 104 with the hammer 26, the rear shaft portion 26b provided behind the front shaft portion 26a, the front shaft portion 26a and the rear shaft portion 26b, from the connecting portion is constituted by a flange portion 26c that protrudes outward, along with the rear surface of the flange portion 26c is made to be abutment alpha _1, in the internal space (hammer 23 is longitudinal bolt 25 in the vicinity of the front end portion in the movement space) (near portion housing the firing pin 26), the flange portion 25a that protrudes inward is provided, the front surface of the flange portion 25a are set to be a contact portion alpha _2, firing pin 26 is Even if it tries to retreat from the position shown in FIG. 4, the contact portion α ₁ (the rear surface of the flange portion 26c) and the contact portion α ₂ (the front surface of the flange portion 25a) come into contact with each other so that the firing pin 26 does not move backward. Yes.

The length of the front shaft portion 26a of the firing pin 26 is the front limit position (in the rifle of the first embodiment, as shown in FIG. 3, the front end surface of the flange portion 26c (contact portion β ₁ ) Reaches the rear end surface of the front wall portion at the free bottom 25 (position when contacting the contact portion β ₂ ), the rear end surface of the detonator 104 is placed so that the explosive 104b (FIG. 2) is ignited. enough to be deformed (shown in FIG. 3, the distance L ₁ is 0.1 in the front end face of the front wall portion 25b of the bolt 25 from the (surface to abut the rear end surface of the bullet 100) to the front end face of the firing pin 26 About 1.5 mm). While satisfying this condition, as shown in FIG. 4, when the contact portion alpha ₁ and the contact portion alpha ₂ is in contact (when the firing pin 26 is retracted to a hitting start position), the front end of the firing pin 26 The surface is set so as not to be rearward from the front end surface of the front wall portion 25b of the free bottom 25 (the front end surface of the firing pin 26 is substantially flush with the front end surface of the front wall portion 25b of the free bottom 25).

  As a result, even if the rear surface portion of the detonator 104 swells rearward from the state shown in FIG. 4 due to the explosive pressure of the explosive 102, the rear surface portion is supported by the front end surface of the firing pin 26, and the rear surface portion is further deformed rearward. It is possible not to. Therefore, it is possible to prevent the detonator breakthrough.

2. Rifle of the second embodiment Subsequently, the rifle of the second embodiment will be described. 5 to 7 are sectional views showing the internal structure around the engine unit 20 in the rifle according to the second embodiment. FIG. 5 shows a state before the trigger 21 is pulled, and FIG. 6 shows the trigger. FIG. 7 shows a state in which 21 is pulled and the firing pin 26 starts to strike the detonator 104, and FIG. 7 shows a state in which the firing needle 26 that strikes the detonator 104 has moved back to the strike start position. About the rifle of a 2nd embodiment, a different part from the rifle of a 1st embodiment is mainly demonstrated, and description is omitted about the part which is common with the rifle of a 1st embodiment.

In the rifle of the first embodiment, the trigger 21 and the reverse rod 22 are integrated, and the striking iron 23 and the firing needle 26 have a separate structure. In the rifle of the second embodiment, As shown in FIG. 5, the trigger 21 and the reverse rod 22 are separated from each other, while the hammering iron 23 and the hammer 26 are integrated. The reverse rod 22 is supported by the engine unit 20 via a support shaft 22a. Therefore, the reverse rod 22 can swing between the hammer hitting position shown in FIG. 5 and the hammer hitting release position shown in FIG. 6 around the point P ₁ (center of the support shaft 22a). It is possible. A front projection 22b is provided on the upper part of the reverse rod 22 on the front end side, and a rear projection 22c is provided on the rear end side upper portion of the reverse rod 22. Moreover, the hammer 23 is provided with a front projection 23b for hooking on the front projection 22b of the reverse rod 22, and a rear projection 23c for latching on the rear projection 22c of the reverse rod 22.

In the state shown in FIG. 5 before pulling the trigger 21, the rifle of the second embodiment is in the front end surface (contact portion γ) of the front projection 23b of the firing needle 23 in the state shown in FIG. ₁ ) is hooked on the rear end surface (contact portion γ ₂ ) of the front projection 22b of the reverse rod 22, and the firing pin 23 cannot move forward. When the trigger 21 is pulled from this state, the reverse rod 22 moves (swings) from the hammer hitting position shown in FIG. 5 to the hammer hitting release position shown in FIG. When the reverse rod 22 is in the firing pin locking release position, the rear end side of the reverse rod 22 is displaced upward, while the front end side of the reverse rod 22 is displaced downward, and the rear end surface (abutment portion γ _{2) of the} front protrusion 22b thereof. ), The front end face (contact portion γ ₁ ) of the front projection 23 b of the hammer 23 cannot be hooked.

  For this reason, the hammering iron 23 is in a state where it can move forward by the biasing force of the coil spring 24 (striking iron biasing means). As already described, the hammer 26 is integrated with the front end portion of the hammer 23 so that the hammer 26 also moves together with the hammer 23. The rear end surface of the detonator 104 (the rear surface of the cup 104a) is struck (pressed) by the front end surface of the firing pin 26, and the cup 104a (FIG. 6) of the detonator 104 is deformed so as to be recessed forward, and applied to the front side of the cup 104a. The explosive explosive 104b (FIG. 5) is pressed by the cup 104a and the ignition gold (anvil) 104c (FIG. 5) to ignite, and the explosive 102 in the cartridge case 101 explodes. By this explosion, the pressure in the cartridge case 101 increases and the bullet 103 is fired.

At this time, the firing pin 26 immediately after striking the detonator 104 is a striking start position (a position where the front end of the firing pin 26 starts to contact the rear surface of the detonator 104. In the rifle of the second embodiment, the firing needle 26 is located in FIG. If it moves rearward than the position, it may break through the detonator. In this regard, in the rifles of the second embodiment, as shown in FIG. 7, the striker 23 (the firing pin integral member), provided with an abutment alpha _1, contact portion to the sear 22 (firing pin peripheral member) α ₂ is provided, and immediately after the striker 26 strikes the detonator 104, the abutment part α ₁ and the abutment part α ₂ contact each other, so that the striker 26 immediately after hitting the detonator 104 is behind the strike start position. Try not to move on.

More specifically, the rear end surface of the side projections 23c after hammer 23 is made to be abutment alpha _1, as the front end surface of the side projections 22c after sear 22 is abutment alpha ₂ Even if the firing pin 26 tries to retreat from the position shown in FIG. 7, the contact portion α ₁ (the rear end surface of the rear projection 23c) and the contact portion α ₂ (the front end surface of the rear projection 22c) contact each other, The firing pin 26 is prevented from moving backward. The length of the firing pin 26 is the same as the length of the front shaft portion 26a in the rifle of the first embodiment.

  As a result, even if the rear surface portion of the detonator 104 swells rearward from the state shown in FIG. 7 due to the explosive pressure of the explosive 102, the rear surface portion is supported by the front end surface of the firing pin 26, and the rear surface portion is further deformed rearward. It is possible not to. Therefore, it is possible to prevent the detonator breakthrough.

By the way, in the rifle having the above structure, the lower limit point (point P ₂ in FIG. 7) in the contact range between the contact part α ₁ and the contact part α ₂ is the rotation center (point in FIG. 7). When located above P ₁ ), the contact portion α ₁ (the rear end surface of the rear projection 23c) of the hammer 23 changes to the contact portion α ₂ of the reverse rod 22 (the front end surface of the rear projection 22c). Due to the applied backward pressing force, the reverse rod 22 rotates counterclockwise in the figure, and the hammer 23 may be moved rearward from the position shown in FIG.

For this reason, in the rifle of the second embodiment, as shown in FIG. 7, the lower limit point P ₂ in the contact range between the contact portion α ₁ and the contact portion α ₂ is the rotation center P _{1 of the} reverse rod 22. It is located on the lower side. Thereby, even when a backward pressing force is applied from the contact portion α ₁ (rear end surface of the rear projection 23c) of the hammering iron 23 to the contact portion α ₂ of the reverse rod 22 (front end surface of the rear projection 22c), It is possible to prevent the hammer 22 from moving backward from the position shown in FIG. 7 by preventing the counter bar 22 from rotating counterclockwise. As a result, it is possible to more reliably prevent the detonator from breaking through.
Although how much the point P ₂ is positioned below the point P ₁ is not particularly limited, it is usually about 0.5 to 5 mm, preferably about 1 to 3 mm.

10 Barrel
20 Engine Department (Receiver)
21 Trigger
22 Shear
22a Support shaft 22b Front projection 22c Rear projection 23 Hammer
23b Front projection 23c Rear projection 24 Coil spring (striking force biasing means)
25 Free bottom (bolt)
25a Flange part 25b Front wall part 26 Firing pin (fire ring pin)
26a Front shaft part 26b Rear shaft part 26c Flange part 30 Core metal (trigger guard)
40 Grip
50 Gun stock (stock)
100 bullets (cartridge)
101 cartridge case (cartridge case)
102 Gunpowder (powder)
103 Bullet
104 Detonator (primer)
104a cup 104b detonator 104c ignition gold (anvil)
α ₁ contact portion α ₂ contact portion β ₁ contact portion β ₂ contact portion γ ₁ contact portion γ ₂ contact portion

Claims (3)

When the trigger is pulled, the hammer strikes away from the reverse trap and moves forward in the bottom of the bottom, and the shooting needle blows from behind the detonator of the bullet housed in the chamber, exploding the gunpowder in the cartridge and moving the bullet forward. A rifle having a firing structure,
The firing pin integral member provided integrally with the firing pin itself or firing pin, abutment alpha ₁ is provided,
The firing pin peripheral members formed of separate from the firing pin, abutment alpha ₂ for abutting the abutment alpha ₁ is provided,
From the state before the trigger is pulled, the firing pin, its front end is at a position to abut against the rear face of the detonator and the abutment alpha ₁ and the contact portion alpha ₂ is positioned in contact with the striking start position And
Drawn is triggered, firing pin has moved forwardly, when moving rearward after striking a detonator, a contact portion alpha ₁ and the contact portion alpha ₂ is again contacts, struck the detonator By preventing the immediately after hitting needle from moving backward from the hitting start position ,
A rifle that is designed to deter the detonation of detonators .
When the firing pin is separated from the hammer, and the front end of the hammer strikes the rear end of the hammer, the firing needle moves forward in the bottom,
A contact portion α ₁ is provided on the firing pin,
The rifle according to claim 1, wherein the contact portion α ₂ is provided in a firing pin housing portion that is a portion that houses the firing needle in the play bottom.
The firing pin is provided integrally with the hammer, so that the hammer and the hammer strike together to move forward in the playground,
On the contrary,
A hammer hitting position that keeps the hammer hitting on its front end side,
The rear end side is displaced upward, the front end side is displaced downward, and the hammer hitting release position at which the hammer can no longer be hooked on the front end side,
While swinging between
The contact portion α ₁ is provided on the hammering iron,
The rifle according to claim 1, wherein the contact portion α ₂ is provided on the rear end side of the reverse rod.

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