KR101692984B1 - Powder metallurgy press die for manufacuturing helical gear - Google Patents

Abstract

The present invention relates to a powder metallurgy press mold. More specifically, male spiral gear teeth are formed on an outer surface in a longitudinal direction; an upper punch is attached to a bottom; and a guide punch, including a bearing assembly attached to the upper surface, is rotated in a guide die including female spiral gear teeth formed on an inner surface such that the present invention is structurally simple and produces stable rotation due to a relatively large diameter of the guide punch. As the upper punch is not attached to the guide die, but is attached to a bottom of the guide punch to secure space; the present invention is capable of making easy the movement of a hopper during formation work.

Description

POWDER METALLURGY PRESS DIE FOR MANUFACUTING HELICAL GEAR

The present invention relates to a powder metallurgical press die. More specifically, the present invention relates to a powder metallurgical press die, and more particularly to a powder metallurgical press die having a male spiral gear teeth in its longitudinal direction on its outer surface, an upper punch on its bottom surface and a guide punch, The guide punch is attached to the bottom surface of the guide punch so as to secure a space without being attached to the guide die, And to facilitate the movement of the hopper during the operation of the powder metallurgical press die.

Generally, various gears are installed in a power transmitting portion that is applied to a mechanical device, an automobile or the like to transmit power, or an accelerating / decelerating reducer. A gear is a mechanical component consisting of gears connected to a rotating shaft. The gears work in pairs, and the teeth of one gear engage with the teeth of the other gears to transmit or rotate the rotational and rotational forces without slip.

Most of the gears are circular, and the contact surfaces of the gear teeth must be precisely shaped in order to smoothly transfer the motion at a constant speed ratio at all times. The axes connecting these gears should be relatively close together, but in practice there is some spatial relationship between them. That is, not parallel to, not intersecting, and not intersecting.

And a spur gear and a helical gear as cylindrical gears for transmitting rotational motion between the two parallel shafts. Among them, the helical gear is formed by the teeth of the gears tilted to one side, and the transmission is smooth, vibration and noise are small, and it is mainly used for transmitting large power.

Conventional gear manufacturing methods including helical gears as described above can be largely divided into a cutting method and a non-cutting method. There are various methods such as hobbing and gear saving in the cutting method. However, in general, Polishing, lapping or the like. Non-cutting methods include gear forming by plastic forming using metal forming processes such as casting, forging, rolling, extrusion and powder metallurgy. Among them, the casting method is disadvantageous from the viewpoint of quality and productivity and is not widely used. Researches on gear forming method by plastic forming suitable for mass production have been actively carried out.

Examples of the gear forming method by the above-mentioned plastic working include cold extrusion, precision forging, tempering, and powder metallurgy. In powder metallurgy, the powder is hardened by press molding, This method is characterized in that a uniform and dense structure can be obtained without secondary processing as compared with other processing.

As a device for manufacturing a helical gear by such a powder metallurgy method, Chinese Utility Model Registration No. 201208648 is disclosed.

However, since the guide die is directly attached to the forming punch to obtain the rotational force, the bearing assembly rotating in a small diameter is rotated, so that the structure is unstable and the structure for imparting rotational force is not in the center, Since the upper punch is very long, it is difficult to precisely set the right angle. Therefore, mold accident frequently occurs in the field, the upper punch tooth shape is subjected to torsional rotational force, the upper punch teeth are frequently broken, And there is a problem in that it is difficult to set the mold due to the shortage of space between the hopper and the guide die which are the raw material feeding device for the product molding die.

In order to solve such a problem, U.S. Patent No. 5366363 is disclosed.

However, this U.S. Patent No. 5366363 discloses a structure in which two guide punches for imparting rotational forces on both sides are provided. It is difficult to precisely manufacture the guide punches so as to be symmetrical with respect to each other. Each of the guide punches is moved up and down, The side spur gear of the center spur gear is rotated and the center spur gear is rotated.

(Prior Art 1) China Utility Model Registration 201208648 (Prior art 2) US Patent No. 5366363

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and has as its object to provide a guide punch having a male helical gear teeth on its outer surface, an upper punch on its bottom surface and a bearing assembly on its upper surface, The upper punch is not attached to the guide die but is attached to the bottom surface of the guide punch to secure a space so that the molding operation The present invention provides a powder metallurgical press mold for manufacturing a helical gear which facilitates the movement of the hopper.

In addition, the present invention is easy to assemble a molding die and an upper punch to cause troubles after setting, and the length of the upper punch can be shortened, so that it is easy to set a right angle and each setting is difficult, It is another object of the present invention to provide a powder metallurgical press mold for manufacturing a helical gear which minimizes the twisting torque applied to the upper punch tooth profile to prevent the upper punch tooth profile from being broken.

Another object of the present invention is to provide a powder metallurgical press mold for manufacturing a helical gear, which has a structural dynamically stable structure by locating a place where a rotational force is generated at a structural center.

According to an aspect of the present invention,

An upper mold for forming a helical gear which is coupled to a press machine by a holder and is lifted and lowered and a shaft hole is formed at a central portion of the metal powder; A molding die having an inner diameter equal to that of the helical gear and having a female helical gear teeth on its inner side and a filling hole in which metal powder is seated, and a fixing stopper on one side; And a lower male helical gear tooth which is inserted in a lower portion of the filling hole of the molding die so as to be rotatable at the center of the upper surface of the lower bearing assembly provided on the lower plate and is coupled to the female helical gear teeth of the molding die, A lower punch having a lower guide hole formed at the center in the longitudinal direction thereof and a core fixed to the clamp to form a shaft hole of the helical gear and extending into the upper mold upon lifting and lowering of the clamp,

The upper mold includes:

An upper bearing assembly formed in a cylindrical shape and coupled to the lower surface of the holder and rotated; An upper plate bolted to a bottom surface of the upper bearing assembly and having a through hole; A guide punch formed in a cylindrical shape and bolted to a center of a bottom surface of the upper bearing assembly to penetrate the through hole of the upper plate and having a male screw gear teeth formed on the outer side surface in the longitudinal direction; And a movable stopper installed at a lower end of the upper plate and coupled to the upper plate by a plurality of upper guide posts and contacting a fixing stopper of the molding die at one side of the bottom surface, A guide plate in which the stopper is raised in contact with the fixed stopper; Wherein a guide hole is formed through the guide punch so that the guide punch is inserted into the guide hole and the guide hole is formed on the inner side surface of the guide hole so as to be engaged with the male screw gear teeth of the guide punch, A guide die rotating; And an upper guide helical gear coupled to a center of a bottom surface of the guide punch and having an upper guide hole for inserting a core of the lower mold therein and an outer male helical gear tooth engaging with a female helical gear of a charging hole of the molding die, And an upper punch.

Here, the molding die is provided with a die plate on its outer side, and a plurality of guide posts are installed perpendicularly to the die plate so as to penetrate the guide plate and the upper plate, thereby guiding up and down the guide plate and the upper plate, And the fixing stopper is installed at the lower end of the guide post.

Here, each of the upper guide posts is provided between the upper plate and the guide plate, and is provided with a coil spring for returning the guide plate to its original position when the upper mold is lifted.

Herein, the molding die and the guide punch are each provided with a plurality of pinholes symmetrical to each other in the longitudinal direction so as to match the concentricity, and when the pins are inserted while the respective pinholes are positioned in the same line at the time of assembly, And then assembled.

Here, the guide punch may be rotated in one direction by the guide die when the guide stopper comes into contact with the movable stopper when the upper mold is lowered, and the upper mold is unidirectionally rotated while being drawn into the fill hole, When the guide plate is lowered by the restoring force of the coil spring while the movable stopper is separated from the fixing stopper when the upper mold is lifted, the metal powder filled in the filling hole is pressed, The mold is rotated in the other direction and discharged from the filling hole.

Here, when the helical gear is completely pressed, the molding die is lowered by itself and the lower punch of the lower mold is rotated in one direction by the filling hole to rotate and discharge the helical gear of the filling hole, And the lower punch of the lower mold is rotated and discharged in the other direction in the filling hole while being raised.

Here, the male helical gear teeth of the guide punch, the female helical gear teeth of the guide die, the female helical gear teeth of the molding die, the lower male helical gear teeth of the lower punch, and the upper male helical gear teeth of the upper punch are the same Has a lead value.

According to the present invention, there is provided a powder metallurgical press die for manufacturing a helical gear, comprising: a spur gear tooth formed on an outer surface in a longitudinal direction thereof; an upper punch attached to a bottom surface; and a guide punch, The guide punch is not attached to the guide die and the rotation of the guide punch is prevented from being caused by the guide punch. By securing a space by attaching to the bottom surface, the hopper can be easily moved during a molding operation.

Further, according to the present invention, since the molding die and the upper punch are easily assembled, troubles after setting are not generated, and the length of the upper punch can be shortened, so that the right angle setting is easy and each setting is difficult, It is possible to minimize the torsional torque applied to the upper punch tooth profile, thereby preventing the upper punch tooth profile from being damaged, thereby minimizing the maintenance cost.

In addition, according to the present invention, the structure generating the rotational force is structurally positioned at the center, thereby having a stable structure in terms of structure mechanics, thereby reducing occurrence of vibration and torsional moment, maximizing transmission of force, have.

1 is a cross-sectional view showing the construction of a powder metallurgical press die for manufacturing a helical gear according to the present invention.
2 is a cross-sectional view illustrating a process of assembling a powder metallurgical press die for manufacturing a helical gear according to the present invention.
3 is a partially exploded perspective view showing a part of a powder metallurgical press mold for manufacturing a helical gear according to the present invention.
4 is a perspective view illustrating a helical gear manufactured by a powder metallurgical press die for manufacturing a helical gear according to the present invention.
5 is an explanatory view for explaining the operation of the powder metallurgical press die for manufacturing a helical gear according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the structure of a powder metallurgical press die for manufacturing a helical gear according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a cross-sectional view showing the constitution of a powder metallurgical press mold for manufacturing a helical gear according to the present invention, FIG. 2 is a sectional view for explaining a process of assembling a powder metallurgical press mold for manufacturing a helical gear according to the present invention, FIG. 4 is a perspective view showing a helical gear manufactured by a powder metallurgical press die for manufacturing a helical gear according to the present invention. FIG. 4 is a partially exploded perspective view showing a part of a powder metallurgical press mold for manufacturing a helical gear according to the present invention.

1 to 4, a powder metallurgical press mold 1 for manufacturing a helical gear according to the present invention comprises an upper mold 100, a molding die 200, and a lower mold 300.

The upper mold 100 includes an upper bearing assembly 110, an upper plate 120, a guide punch 130, a guide plate 140, a guide die 150 and an upper punch 160 do.

The upper bearing assembly 110 is formed in a cylindrical shape and its upper end is coupled to the press machine (not shown) by the holder 10, and the lower end is rotated by the thrust bearing TB.

The upper plate 120 is formed in the shape of a rectangular plate and is bolted to the bottom surface of the upper bearing assembly 110. A through hole 121 is formed to penetrate the guide punch 130 to be coupled with the upper bearing assembly 110 do.

The guide punch 130 is formed in a cylindrical shape and is bolted to the center of the bottom surface of the upper bearing assembly 110 to penetrate the through hole 121 of the upper plate 120 and has a male screw gear teeth 131 are formed. At this time, it is preferable that the diameter of the guide punch 130 is formed to be equal to or smaller than that of the upper bearing assembly 110, and formed larger than the upper punch 160.

The guide plate 140 is formed in the shape of a rectangular plate and is spaced apart from the lower end of the upper plate 120. The guide plate 140 is bolted to the upper plate 120 by a plurality of upper guide posts 141, And a movable stopper 143 that contacts the fixed stopper 240 of the upper mold 100. The movable stopper 143 is lifted by contacting the fixed stopper 240 when the upper mold 100 is lowered. Each of the upper guide posts 141 includes a coil spring 145 installed between the upper plate 120 and the guide plate 140 and returning the guide plate 140 to the original position when the upper mold 100 is lifted, Respectively. The upper guide post 141 and the coil spring 145 are installed diagonally on the guide plate 140 and the remaining diagonal angles are provided with air cylinders Alternatively, the air cylinder may be installed and operated in place of the upper guide post 141 and the coil spring 145.

The guide die 150 is formed with a coupling hole 151 at the center so that the guide punch 130 is inserted through the guide punch 130 in the form of a disk or a square plate and the male screw 151 of the guide punch 130 is coupled to the inner surface of the coupling hole 151, And the guide pin 140 is bolted to the guide plate 140. When the guide plate 140 is lifted up, the guide pin 140 is raised and the guide punch 130 is rotated.

The upper punch 160 is formed in a cylindrical shape that is reduced in number of steps from the upper end to the lower end and is coupled to the center of the bottom surface of the guide punch 130. The core 350 of the lower mold 300 is disposed at the center in the longitudinal direction, And an upper male helical gear tooth 163 is formed on the outer side of the lower end of the upper male helical gear 161 so as to be engaged with the female helical gear tooth 211 of the filling hole 210 of the molding die 200.

The molding die 200 has a filling hole 210 having the same inner diameter as that of the helical gear 10 and in which the metal powder is seated and a female helical gear tooth 211 is formed inside the filling hole 210 . The molding die 200 is provided with a die plate 220 on an outer side thereof and a plurality of guide posts 230 perpendicular to the die plate 220 so as to penetrate the guide plate 140 and the upper plate 120 And guides the lifting and lowering of the upper plate 120 and the guide plate 140 and a fixing stopper 240 is installed at the lower end of the guide post 230.

The lower mold 300 includes a lower plate 310, a lower bearing assembly 320, a lower punch 330, a clamp 340, and a core 350.

The lower plate 310 fixes the lower punch 330.

The lower bearing assembly 320 is formed in a cylindrical shape, the lower end is fixedly coupled to the lower plate 310, and the upper end is rotated by the thrust bearing TB.

The lower punch 330 is formed in a cylindrical shape that is reduced in number of steps from the lower end to the upper end and inserted into the lower part of the filling hole 210 of the molding die 200 so as to be rotatable at the center of the upper surface of the lower bearing assembly 320 And a lower guide hole 333 is formed at the center in the longitudinal direction of the lower male helical gear teeth 331. The lower male helical gear teeth 331 are engaged with the female helical gear teeth 211 of the molding die 200 on the outer side.

The clamp 340 moves the core 350 up and down.

4, the core 350 is fixed to the clamp 340 so as to form the shaft hole 21 of the helical gear 20 and enters the upper mold 100 as the clamp 340 ascends and descends.

2, the powder metallurgical press die 1 for manufacturing a helical gear according to the present invention includes a molding die 200 and a plurality of guide punches 130, which are symmetrical to each other in the longitudinal direction, The pin holes PH are formed and the pins P are inserted in the state in which the pin holes PH are arranged in the same line at the time of assembling, P) is removed.

The powder metallurgy press mold 1 for manufacturing a helical gear according to the present invention is characterized in that the male helical gear teeth 131 of the guide punch 130, the female helical gear teeth 153 of the guide die 150, The lower male helical gear teeth 331 of the lower punch 330 and the upper male helical gear teeth 163 of the upper punch 160 move in the same direction as the helical gear 20, It is preferable to have the same lead value.

Hereinafter, the operation of the powder metallurgical press die for manufacturing a helical gear according to the present invention will be described in detail with reference to the accompanying drawings.

5 is an explanatory view for explaining the operation of the powder metallurgical press die for manufacturing a helical gear according to the present invention.

A hopper (not shown) is drawn in a state where the upper mold 100 is lifted as shown in FIG. 5 (a), and the metal powder is filled in the filling hole 210 of the molding die 200. At this time, the lower punch 330 and the core 350 are inserted into the filling hole 210.

5 (b), the upper mold 100 is lowered. When the upper mold 100 is lowered, the upper bearing assembly 110, the upper plate 120, and the guide punch (not shown) The guide plate 140 and the guide die 150 and the upper punch 160 are all lowered and the upper plate 120 and the guide plate 130 are moved along the guide posts 230 of the molding die 200 140 are lowered in a straight line.

When the upper mold 100 is subsequently lowered, the movement stopper 143 of the guide plate 140 is brought into contact with the fixing stopper 240 of the molding die 200, thereby causing the guide plate 140 to contact the upper guide post 141 while increasing the tension of the coil spring 145 installed on the lower end of the coil spring 145.

When the guide plate 140 is lifted up, the guide punch 130 is rotated by the guide die 150 installed on the guide plate 140, and the upper bearing assembly 110 and the upper punch 130, which are coupled to the guide punch 130, (160) is rotated in one direction.

The upper male helical gear teeth 163 of the upper punch 160 are rotated while being engaged with the female helical gear teeth 211 of the filling hole 210 of the molding die 200, So that the helical gear 20 is manufactured.

When the pressing is completed, the upper mold 100 is lifted and the core 350 of the lower mold 300 and the molding die 200 are lowered as shown in (c) of FIG.

The movement stopper 143 of the guide plate 140 is released from the contact with the fixing stopper 240 of the molding die 200 so that the guide plate 140 is pressed against the coil spring 145 provided on the upper guide post 141 The guide punch 130, the upper bearing assembly 110 and the upper punch 160 are rotated in the other direction and returned to the original position while returning to the original position by the tension.

At the same time, the lower punch 330 is rotated in one direction in the filling hole 210 by the lower bearing assembly 320 due to the lowering of the molding die 200, so that the helical gear 20 .

5 (a), when the molding die 200 is lifted, the lower punch 330 is rotated in the other direction in the filling hole 210 by the lower bearing assembly 320 and is returned to the original position The core 350 is lifted up to its original position by the clamp 340 and then the hopper is inserted and the helical gear 20 produced is discharged to the outside and the metal powder is filled in the filling hole 210, .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

10: holder 20: helical gear
100: Upper mold 110: Upper bearing assembly
120: upper plate 130: guide punch
140: guide plate 150: guide die
160: Upper punch 200: Molding die
210: filling hole 220: die plate
230: Guide post 240: Fixing stopper
300: lower mold 310: lower plate
320: lower bearing assembly 330: lower punch
340: clamp 350: core
TB: Thrust bearing PH: Pin hole

Claims (7)

An upper mold for forming a helical gear which is coupled to a press machine by a holder and is lifted and lowered and a shaft hole is formed at the center of the metal powder;
A molding die having an inner diameter equal to that of the helical gear and having a female helical gear teeth on its inner side and a filling hole in which metal powder is seated, and a fixing stopper on one side; And
A lower male helical gear tooth is formed on the outer side of the lower male helical gear tooth so as to be rotatable at the center of the upper surface of the lower bearing assembly provided in the lower plate and inserted into the lower part of the filling hole of the molding die, And a lower mold fixed to the clamp to form a shaft hole of the helical gear and being inserted into the upper mold as the clamp moves up and down,
The upper mold includes:
An upper bearing assembly formed in a cylindrical shape and coupled to the lower surface of the holder and rotated;
An upper plate bolted to a bottom surface of the upper bearing assembly and having a through hole;
A guide punch formed in a cylindrical shape and bolted to a center of a bottom surface of the upper bearing assembly to penetrate the through hole of the upper plate and having a male screw gear teeth formed on the outer side surface in the longitudinal direction;
The upper guide post and the upper guide post are disposed to be spaced from each other at a lower end of the upper plate and diagonally installed to return the guide plate to an original position when the upper plate and the upper mold are lifted. And a movable stopper which is in contact with the fixing stopper of the molding die at one side of the bottom surface of the mold, and in which the movable stopper is raised in contact with the fixing stopper when the upper mold is lowered;
Wherein a guide hole is formed through the guide punch so that the guide punch is inserted into the guide hole and the guide hole is formed on the inner side surface of the guide hole so as to be engaged with the male screw gear teeth of the guide punch, A guide die rotating; And
An upper guide hole is provided at the center of the bottom of the guide punch to insert the core of the lower mold and an upper portion of the upper helical gear which is engaged with the female helical gear of the filling hole of the molding die Including a punch,
The molding die includes:
A plurality of guide posts are installed perpendicularly to the die plate so as to penetrate the guide plate and the upper plate to guide upward and downward movement of the guide plate and the upper plate, A fixing stopper is installed,
The guide punch includes:
When the guide stopper is lifted up by the movement stopper when the upper mold is lowered, the upper mold is unidirectionally rotated by the guide die while being unidirectionally rotated by the guide die to draw the metal powder filled in the filling hole, When the guide plate is lowered by the restoring force of the coil spring while the movable stopper is separated from the fixing stopper when the upper mold is lifted, the upper mold is rotated in the other direction by the guide die, Hole,
The molding die includes:
When the helical gear is completely pressed, the lower punch of the lower mold is rotated in one direction with the filling hole, and the helical gear of the filling hole is rotated and discharged. When the discharging is completed, the lower punch of the lower mold is raised, And the lower punch is rotated and discharged in the other direction in the filling hole to bring the lower punch in place. delete delete The method according to claim 1,
In the molding die and the guide punch,
A plurality of pinholes symmetrical to each other in the longitudinal direction are formed so as to match the concentricity, and the pinholes are inserted in a state in which the pinholes are aligned in a line while assembled, Powder metallurgical press mold for gear manufacturing. delete delete The method according to claim 1,
A male helical gear tooth of the guide punch, an female helical gear tooth of a guide die, a female helical gear tooth of a molding die, a lower male helical gear of a lower punch, and an upper male helical gear of an upper punch,
Wherein the lead wire has the same lead value in one direction.

Images