KR101220152B1 - cold forging mold - Google Patents

Abstract

The present invention enables the forced control of the supply flow rate to the lubricating oil without using a separate electronic opening and closing device such as a solenoid valve, and by accurately detecting the real-time temperature change for the mold to allow the operation control to proceed to the molded product The invention relates to a new type of cold forging mold, which can prevent the degradation of the quality.
To this end, the present invention comprises a lower mold and an upper mold installed correspondingly up and down; A die block provided on an upper surface of the lower mold and on which a molded product is mounted; The push mounting groove and the punch mounting groove are vertically formed on the bottom surface of the upper mold, respectively, and a lubricating oil supply hole is formed to penetrate through the push mounting groove from the circumferential surface to the punch mounting groove. Punch holder; A punch provided in the punch mounting groove of the punch holder and forging the molded product seated on the die block; In addition, while being installed in the push mounting groove of the punch holder to be elastically lifted by an elastic member, the molded product is pressed against the punch and prevented from being lifted together. Cold forging die is provided, characterized in that it comprises a push pin: a pumping operation for lubricating oil inflow and lubricating oil outflow toward the punch mounting groove.

Description

Cold Forging Mold

The present invention relates to a mold, and more particularly, to prevent frictional heat generated during cold forging molding, to prevent seizure between the punch and the molded product due to the frictional heat, and to allow operation control according to temperature change. It relates to a cold forging mold according to a new form.

In general, a forged mold is a mold which is processed into a desired shape by applying an impact or pressure with a hammer, a press, etc. in a cold or heated state of a molded product.

The forging mold is classified into hot forging and cold forging.

Here, the hot forging means forging at a temperature higher than the temperature at which the recrystallization proceeds in a molded product, and the cold forging is based on the temperature at which the recrystallization proceeds. It means forging at lower temperature.

Maintaining the proper temperature is very important in the forging press die of the cold forging method.

However, during the normal press operation, a large amount of frictional heat is generated between the punch and the molded product, and the frictional heat generated not only causes a problem due to sintering between the punch and the molded product, but also due to heat conduction to the upper and lower molds. There is a problem that a smooth cold forging does not proceed because the mold temperature is increased.

Accordingly, conventionally, by providing lubricating oil to the punch while the press work is in progress, frictional heat generated during cold forging molding is prevented.

The manner of providing such a lubricant may be provided in various ways, but in general, a method of directly providing a lubricant to a molded product has been mainly used.

However, as described above, the method of directly supplying the lubricant to the molded product has a problem that excessive consumption of the lubricant is caused due to the excessive supply of the lubricant, and furthermore, the application of the lubricant is also caused after the lubricant is not required. The disadvantage is that a separate process is required for washing the lubricant from the molded article.

Accordingly, in Korean Registered Utility Model No. 20-0446799 devised by the present applicant, a structure is provided so that the lubricant can be smoothly provided between the punch and the molded product.

That is, the supply flow passage is formed through the movable stripper, and the lubricating oil groove is formed in the punch so that the lubricating oil provided through the supply flow passage can be provided to the contact surface with the molded product during press molding by the punch.

However, the above-described prior art has the disadvantage that excessive provision of lubricating oil may occur because no separate structure for adjusting the flow rate for the lubricating oil is provided.

In particular, the above-described prior art has a problem that the supply of the smooth oil may not be performed smoothly in spite of the operation of the mold because the supply is simply made through the natural flow of the lubricating oil.

On the other hand, it is very important to maintain the temperature of the mold at an appropriate temperature in the forging operation using a common cold forging mold.

In other words, considering the huge influence on the quality of the molded product due to the change in the mold temperature, it is necessary to continuously check the change in the mold temperature during the forging operation and to control the temperature of the mold based on the change. will be.

However, in the related art, the operation of the forging die is performed by measuring the temperature of the space where the forging operation is performed, rather than sensing the direct temperature change of the forging die. There is a problem that the control was not made.

The present invention has been made to solve the various problems according to the prior art described above, the object of the present invention is to enable the forced control of the supply flow rate for the lubricating oil without using a separate electronic opening and closing device such as a solenoid valve In addition, the present invention provides a new type of cold forging mold that accurately detects a real-time temperature change of a mold so that motion control can be performed to prevent a deterioration of a molded product.

According to the cold forging die of the present invention for achieving the above object, the lower mold and the upper mold installed correspondingly up and down; A die block provided on an upper surface of the lower mold and on which a molded product is mounted; The push mounting groove and the punch mounting groove are vertically formed on the bottom surface of the upper mold, respectively, and a lubricating oil supply hole is formed to penetrate through the push mounting groove from the circumferential surface to the punch mounting groove. Punch holder; A punch provided in the punch mounting groove of the punch holder and forging the molded product seated on the die block; In addition, while being installed in the push mounting groove of the punch holder to be elastically lifted by an elastic member, the molded product is pressed against the punch and prevented from being lifted together. It is characterized in that it comprises a push pin: pumping operation so that the lubricating oil inflow and lubricating oil outflow toward the punch mounting groove is made.

Here, the punch circumferential surface is recessed along a circumference of a portion corresponding to a portion where the lubricating oil supply hole of the punch mounting groove communicates with the receiving groove for temporarily receiving the lubricating oil, and the punch from the portion where the receiving groove is formed. It is characterized in that each step is formed to form a gap so that the lubricating oil can flow into the molded product while stepping down to the exposed portion from the holder.

In addition, a portion of the lubricating oil supply hole communicating with the push mounting groove is closed by the push pin when the push pin is in close contact with the molded product, and is opened when the push pin is spaced apart from the molded product. Characterized in that formed.

In addition, a lubricating oil supply pipe for supplying the lubricating oil stored in the lubricating oil reservoir to the lubricating oil supply hole is installed at the inlet side of the lubricating oil supply hole in the circumferential surface of the punch holder, and the lubricating oil supply pipe is provided with a check valve for preventing the lubricating oil from flowing in the reverse direction. It is done.

In addition, the upper mold and the lower mold are each equipped with a temperature sensor for sensing the temperature, the temperature sensor is characterized in that configured to provide the sensing information to the control device through a data logger (data loger).

As described above, the cold forging die of the present invention is configured so that the lubricant flows through the outer circumferential surface of the punch to be provided as a processing part with the molded product, so that the lubricating oil can be supplied to the correct position. The sintering can be stably prevented and has the effect of achieving smooth frictional heat reduction.

In addition, the cold forging mold according to the present invention is configured to provide only a suitable amount of lubricating oil while the forced pumping of the lubricating oil by the lifting operation of the push pins can be prevented the problems caused by the excessive supply and lack of supply of lubricating oil Has

1 is a cross-sectional view showing a front view to explain the structure of a cold forging die according to a preferred embodiment of the present invention
FIG. 2 is an enlarged view of a portion “A” of FIG. 1.
Figure 3 is an enlarged cross-sectional view showing the main portion to explain the structure of the process of the upper die of the cold forging die is moved downward according to a preferred embodiment of the present invention
Figure 4 is a cross-sectional view showing a front view to explain the structure of the upper die of the cold forging die is moved downward according to a preferred embodiment of the present invention
5 is an enlarged view of a portion “B” of FIG. 4.
Figure 6 is an enlarged cross-sectional view showing the main portion to explain the structure of the process of the upper mold of the cold forging die is moved upward according to a preferred embodiment of the present invention

Hereinafter, a preferred embodiment of the cold forging die of the present invention will be described with reference to FIGS. 1 to 6.

1 and 4 show a cold forging die according to a preferred embodiment of the present invention, as can be seen based on this cold forging die according to an embodiment of the present invention largely lower mold 100 and upper mold 200 ), A die block 300, a punch holder 400, a punch 500, and a push pin 600.

This will be described in more detail below for each configuration.

First, the lower mold 100 and the upper mold 200 are installed to correspond to each other up and down as a configuration forming the lower mold and the upper mold of the cold forging die.

At this time, the lower mold 100 is fixed to the upper surface of the base frame 110, the upper mold 200 is fixed to the bottom surface of the press ram (210).

In addition, the upper mold 200 is configured to be elevated by the support of the guide post 220, one end of the guide post 220 is installed on the lower mold 100 and the other end of the guide post 220 Is installed in the upper mold 200.

Next, the die block 300 is a portion where the forging molding proceeds while the molded product 10 is seated, and is provided on an upper surface of the lower mold 100.

Next, the punch holder 400 is a portion for installing the punch 500, is provided on the bottom surface of the upper mold (200).

Here, the punch holder 400, the punch mounting groove 410 and the push mounting groove 420 is formed vertically, respectively, the upper end of the punch mounting groove 410 and the push mounting groove 420 is the punch When the holder 400 is coupled to the bottom of the upper mold 200, it is blocked by the bottom of the upper mold 200 to form a closed state.

In this case, the punch mounting groove 410 is formed to penetrate up and down the center portion of the punch holder 400, the punch 500 to be described later is installed in the punch mounting groove 410.

In addition, the push mounting groove 420 is formed to penetrate the punch holder 400 up and down at an adjacent side of the punch mounting groove 410, which will be described later in the push mounting groove 420. Push pin 600 is installed.

In addition, the embodiment of the present invention is characterized in that the lubricating oil supply hole 430 is further formed in the punch holder 400.

The lubricating oil supply hole 430 is formed to penetrate from one circumferential surface of the punch holder 400 to the punch mounting groove 410 through the push mounting groove 420 to provide a flow path through which lubricating oil is provided. Form.

That is, the lubricating oil supply hole 430 is a pipe for guiding the lubricating oil provided from the outside to be smoothly supplied to the inside of the punch mounting groove 410 via the inside of the push mounting groove 420.

At this time, the inlet side of the lubricating oil supply hole 430 of the circumferential surface of the punch holder 400 is provided with a lubricating oil supply pipe 450 for supplying the lubricating oil stored in the lubricating oil reservoir 440 to the lubricating oil supply hole 430.

In particular, the embodiment of the present invention is characterized in that the check valve 451 is further installed in the lubricant supply pipe 450. The check valve 451 is configured to prevent the lubricating oil present in the push mounting groove 420 from flowing back into the lubricating oil supply pipe 450 while flowing in the lubricating oil supply hole 430 in the reverse direction.

Next, the punch 500 is a series of components for forging a molded product seated on the die block 300, and is vertically provided in the punch mounting groove 410 of the punch holder 400.

In particular, the embodiment of the present invention is characterized in that the receiving groove 510 is formed in the periphery of the punch 500.

In this case, the receiving groove 510 is formed so as to be recessed along the circumference of the portion corresponding to the portion where the lubricating oil supply hole 430 of the punch mounting groove 410 of the circumferential surface of the punch 500 is communicated with the lubricating oil It serves to provide a region in which the lubricant oil flowing through the supply hole 430 can be temporarily accommodated.

In addition, according to the exemplary embodiment of the present invention, the step portion 520 may be formed at a portion of the periphery of the punch 500 from a portion where the receiving groove 510 is formed to a portion exposed to the outside of the punch holder 400. It is characterized by the fact that is formed.

That is, a clearance (gap) by the step portion 520 may be formed between the inner wall surface of the punch mounting groove 410 of the punch holder 400 and the outer circumferential surface of the punch 500, and through the clearance. It is to allow the lubricant to flow into the molded product (10).

Accordingly, the lubricating oil is precisely provided only at the contact portion between the punch 500 and the molded product 10, so that the lubricating oil can be prevented from being provided to an unwanted portion and the punch 500 and the molded product ( 10) has the advantage that the adhesion between the liver can be prevented.

Next, the push pin 600 is pressurized to prevent the molded product 10 is squeezed to the punch 500 to prevent the rising along with the punch 500 when the upper mold 200 is moved upward. A series of components that simultaneously play a role for forced pumping.

The push pin 600 is installed in the push mounting groove 420 formed in the punch holder 400 to be elastically lifted by the elastic member 610, the closing operation of the upper mold 200 (downward movement) ) Is pressed by the molded product 10 and moved upwardly in the push mounting groove 420. In the opening operation (upward movement) of the upper mold 200, the restoring force by the elastic member 610 is applied. It is moved downward in the push mounting groove 420 in close contact with the upper surface of the molded product 10.

In this case, a portion of the lubricant supply hole 430 that communicates with the push mounting groove 420 is closed by the push pin 600 when the push pin 600 is in close contact with the molded product 10. When the push pin 600 is spaced apart from the molded product 10, the push pin 600 is formed at an open position.

In particular, the space in the push mounting groove 420 forms a space in which the upper and lower ends are closed by the upper mold 200 and the punch 500 in the punch holder 400. The lifting and lowering of the lubricating oil from the lubricating oil supply hole 430 in communication with the push mounting groove 420 can be forced.

That is, the push mounting groove 420 serves as a cylinder and the push pin 600 serves as a piston while pumping operations such as suction of lubricant from the outside and discharge of lubricant to the punch mounting groove 410. Will be done.

In this case, when the push pin 600 is moved upward, the lubricating oil in the push mounting groove 420 flows in the reverse direction through the lubricating oil supply hole 430 and is prevented by the check valve 451 so that the punch mounting groove ( The lubricating oil supply to the 410 can be made stable.

Meanwhile, in the embodiment of the present invention, a temperature sensor 710 for temperature sensing is mounted on the upper mold 200 and the lower mold 100, respectively, and the temperature sensor 710 is a data logger. Further shown is configured to provide sensing information to a control device (eg, mold control computer) 730 via 720.

That is, each of the temperature sensors 710 directly senses the temperatures of the upper mold 200 and the lower mold 100 and provides them to the control device 730 through the data logger 720 in real time. Temperature sensing) enables operation control to allow the forging process to proceed to the optimum temperature.

In the following, the forging operation process by the cold forging die according to the embodiment of the present invention configured as described above will be described in more detail.

First, the molded product 10 to be molded is installed in the die block 300. Its state is as shown in Figure 1 attached.

Then, when the operation control by the control device 730 is made in the state in which the installation of the molded product 10 is completed, the molded product 10 installed in the die block 300 while the upper mold 200 is moved up and down. Forging is performed.

That is, when the downward movement of the upper mold 200 is made, the punch 500 mounted on the punch holder 400 processes the molded product 10 installed in the die block 300 while processing the upper mold 200. When the upward movement of the 200 is made, the punch 500 is spaced apart from the molded product 10.

In addition, during the above-described series of processes, the lubricating oil stored in the lubricating oil reservoir 440 is provided to the lubricating oil supply hole 430 formed in the punch holder 400 through the lubricating oil supply pipe 450, and subsequently, the lubricating oil supply. The push mounting groove 420 and the punch mounting groove 410 are sequentially provided along the hole 430.

In particular, as described above, the lubricating oil flowing along the lubricating oil supply hole 430 is forcibly pumped by the pumping force by the lifting operation of the push pin 600 while being sucked into the push mounting groove 420 and the punch mounting groove. Discharge to 410 is made.

That is, the push pin 600 is selectively in contact with the molded product 10 by the lifting operation of the upper mold 200, or moved up and down reciprocating in the push mounting groove 420 while being spaced, the process In the push pin 600 is to provide the lubricant into the punch mounting groove 410 while serving as a piston.

Hereinafter, the supply process of the lubricating oil will be described in more detail.

First, in the first state as shown in FIG. 1 and FIG. 2, there is no change in the flow of the lubricating oil. The pin 600 also moves downward with the upper mold 200.

In addition, when the push pin 600 comes into contact with the molded product 10 as shown in FIG. 3 attached in the above process, the upper mold 200 continuously moves downward while the push pin 600 is further moved. As the above downward movement is stopped, the space in the push mounting groove 420 is gradually compressed.

Accordingly, the lubricating oil present in the push mounting groove 420 is discharged to the lubricating oil supply groove 430 of the side in communication with the punch mounting groove 410 by the compression force in the push mounting groove 420. That is, considering that the check valve 451 is installed in the lubricating oil supply pipe 450 connected to provide the lubricating oil to the lubricating oil supply hole 430, a space in the push mounting groove 420 is formed in the push pin 600. When compressed by the upward movement (downward movement of the push mounting groove), the lubricating oil present in the push mounting groove 420 is not discharged into the lubricating oil supply hole 430 on the side to which the lubricating oil supply pipe 450 is connected, and the punch mounting is performed. It is discharged only to the lubricating oil supply hole 430 in communication with the groove 410.

Therefore, the lubricating oil provided into the punch mounting groove 410 is temporarily stored in the receiving groove 510 formed on the circumferential surface of the punch 500, and particularly, the stepped portion 520 formed on the circumferential surface of the punch 500. And the lubricating oil flows through the gap between the inner wall of the punch mounting groove 410 and the lower portion of the punch 500, for example, a portion where the forging between the punch 500 and the molded product 10 proceeds, that is, the punch 500. ) Is provided as a contact surface between the molded product 10 and prevents squeezing between the punch 500 and the molded product 10 and reduces frictional heat generated during cold forging molding.

Of course, the push pin 600 is also lubricated under the influence of the lubricating oil in the push mounting groove 420, so that the lifting operation can always be made stable.

On the contrary, when the upper mold 200 is moved upward in the state of FIGS. 4 and 5 in which the upper mold 200 is completely downwardly moved, the push pin 600 despite the upward movement of the upper mold 200. 6, the space in the push mounting groove 420 gradually expands as the lower end of the elastic member 610 is maintained by pressing the upper surface of the molded product 10 by the restoring force of the elastic member 610. Lubricant oil is forced into the lubricant supply hole 430 by the expansion force of the space.

Therefore, the lubricating oil introduced into the push mounting groove 420 is punch-mounted when a compression force is generated in the inner space of the push mounting groove 420 by the push pin 600 while the upper mold 200 is moved downward again. A groove 410 is provided to lubricate the punch 500.

Meanwhile, the temperature sensor 710 installed in the upper mold 200 and the lower mold 100 during the cold forging molding as described above senses the temperature of each of the molds 100 and 200 in real time. The sensed information is converted into log data through the data logger 720 and provided to the control device 730.

In this case, since the control device 730 performs an operation control for cold forging molding based on the information data provided through the data logger 720, cold forging may be performed at an optimal temperature. For example, when the temperature of each mold (100,200) exceeds the set temperature (temperature range suitable for cold forging) by performing the interruption of the temporary process to lower the temperature of each mold (100,200) can improve the quality of cold forging as much as possible To ensure that

As a result, the cold forging mold according to the present invention described above is configured to be provided to the processing site with the molded product 10 while flowing through the outer peripheral surface of the punch 500, it is possible to supply the correct lubricant, The seizure between the punch 500 and the molded article 10 can be prevented.

In particular, the cold forging die according to the present invention is configured to provide only a suitable amount of lubricating oil while the forced pumping of the lubricating oil by the lifting operation of the push pin 600 can be prevented problems due to the excessive supply and lack of supply of lubricating oil Has the advantage

100. Lower mold 110. Base frame
200. Upper mold 210. Press ram
220. Guide post 300. Die block
400. Punch Holder 410. Punch Mounting Groove
420. Push mounting groove 430. Lube supply hole
440. Lube reservoir 450. Lube supply line
451.Check Valve 500.Punch
510. Receiving groove 520. Step
600. Push pin 610. Elastic member
710. Temperature sensor 720. Data logger
730. Control

Claims (5)

A lower mold and an upper mold correspondingly installed up and down;
A die block provided on an upper surface of the lower mold and on which a molded product is mounted;
The push mounting groove and the punch mounting groove are vertically formed on the bottom surface of the upper mold, respectively, and a lubricating oil supply hole is formed to penetrate through the push mounting groove from the circumferential surface to the punch mounting groove. Punch holder;
A punch provided in the punch mounting groove of the punch holder and forging the molded product seated on the die block; And,
While being installed in the push mounting groove of the punch holder to be elastically lifted by an elastic member, the molded product is pressed against the punch and prevented from rising together, and the lubricant flows into the push mounting groove by the lifting operation. And a push pin pumped to pump the lubricating oil toward the punch mounting groove. The method of claim 1,
In the peripheral surface of the punch
An accommodation groove for temporarily accommodating the lubricating oil while being inserted along a circumference of a portion corresponding to a portion where the lubricating oil supply hole of the punch mounting groove is in communication;
Cold forging die, characterized in that each step is formed to form a gap so that the lubricating oil can flow into the molded product while stepping from the portion where the receiving groove is formed to the portion exposed to the outside of the punch holder. The method of claim 1,
The portion of the lubricant supply hole communicating with the push mounting groove is
And the push pin is closed by the push pin when the push pin is in close contact with the molded product, and is formed at a position to be opened when the push pin is spaced apart from the molded product. The method of claim 1,
Lubricating oil supply pipe for supplying the lubricant stored in the lubricating oil reservoir to the lubricating oil supply hole is installed at the inlet side of the lubricating oil supply hole of the peripheral surface of the punch holder,
Cold forging die, characterized in that the lubricating oil supply pipe is installed with a check valve to prevent the flow of lubricating oil in the reverse direction. The method of claim 1,
The upper mold and the lower mold are each equipped with a temperature sensor for sensing the temperature,
The temperature sensor is a cold forging die, characterized in that configured to provide the sensing information to the control device through a data logger (data loger).

Images