KR20220072354A - Knuckle lilnk press apparatus having a guide for slider - Google Patents

Abstract

The present invention is a knuckle link press apparatus having a slider guide for press-working a material by receiving power from a motor and elevating a slider with a knuckle mechanism, wherein the knuckle mechanism receives the rotational force of the motor and is eccentric to one end side A connecting rod member rotating about the main rotational axis, the other end of the connecting rod member is hinged rotatably to the upper portion by a first connecting hinge portion, and is rotatably hinged from the upper side to the rod support body by a third connecting hinge portion and a lower rod member that is hinged rotatably from the other end of the connecting rod member to the lower portion by a second connecting hinge and is connected to the slider and the fourth connecting hinge at the lower end, and the connecting rod member A first ball support body that is in contact with the upper rod member and rotates when the upper rod member is rotated is positioned at the upper portion of the other end side, and is in contact with the lower rod member at the lower portion of the other end side to rotate the lower rod member The second ball support, which rotates at the time of rotation, is positioned to secure the durability of the link and greatly improve the stability of the press operation.

Description

Knuckle Link Press Apparatus with Slider Guide

The present invention relates to a knuckle link press device having a slider guide.

In general, press processing technology is widely used in various industrial fields from heavy industries such as automobiles and aircraft industries to semiconductor production equipment, medical devices, and electronic parts.

In principle, a press machine uses two or more corresponding tools such as molds or shear blades, places a workpiece such as metal or plastic between the tools, and the tool compresses the workpiece with a strong force to perform bending, drawing, compression, shearing, etc. A machine that performs processing operations.

The means for the press machine to generate the working pressure include a method using hydraulic pressure and a method using a mechanism, which is classified into a hydraulic press and a mechanical press.

Mechanical presses are overwhelmingly used in production sites, and hydraulic presses are used when the pressure (TON) is large and the processing cycle is long.

A mechanical press refers to a press machine driven by mechanisms such as cranks, eccentrics, knuckles, links, and cams.

A crank press that uses a crank mechanism for a press drive mechanism is called a crank press, and many of the mechanical presses use this mechanism.

The reason that the crank mechanism is used the most is that it is easy to manufacture, the position of the lower end of the stroke is accurately determined, and the slide motion curve is relatively smooth, so it is advantageous for various processing.

Therefore, crank press is used for all press work such as punching, bending, draw and cold forging.

However, the crank press is the simplest and most widely used method in which the rotational energy accumulated in the flywheel is converted into a linear reciprocating motion of the slider through the crankshaft and the connecting rod, but there are problems with respect to rigidity and noise and vibration.

A press using a knuckle mechanism as a press drive mechanism is called a knuckle press.

The knuckle press is suitable for the forging operation that requires high pressure near the bottom dead center and the unique slide motion curve that the speed of the slide becomes very slow near the bottom dead center.

Knuckle press is also suitable for compression processing such as coining, sizing, and embossing, as the position of the bottom dead center of the stroke is also accurately determined.

However, the knuckle press has a longer contact time between the upper and lower molds as the rotational energy of the flywheel asymmetrically reciprocates the slider through the rotating shaft, knuckle mechanism and connection configuration, so the molding quality is superior compared to other mechanical presses, but the production yield is lowered. In consideration of this, there is a problem in that the quality of parts that require precise processing and flatness is deteriorated during the molding of parts that require precise processing and flatness as the slide lowering operation, which determines the molding quality, is performed quickly.

The link press is a press that uses various link mechanisms to drive the slide, and can shorten the cycle time and improve productivity compared to the crank press. However, the link press improves productivity by changing the speed during machining, but it is difficult to create a motion curve that presses it down with a high load at the bottom dead center.

As a prior art to improve this, Korean Patent Registration Publication No. 10-0368009 (registration on February 31, 2002) 'double knuckle press device' has been proposed. According to this, by increasing the working area of the bolster by using the knuckle and the connecting rod as a double type, noise and vibration, which are disadvantages of the crank press using the knuckle, can be greatly reduced.

However, there is a disadvantage in that an excessively wide working space and installation space are occupied by providing the device including a plurality of knuckle mechanisms.

In addition, Korean Patent Registration Publication No. 10-1207430 (registration on November 27, 2012) 'a driving device for a knuckle press' has been proposed. This has the effect of reducing the manufacturing cost through a concise and simple configuration by minimizing the working space while at the same time improving the molding quality of the molded product by gently delaying the descending speed during the descending stroke of the slider.

However, as the driving force including the delayed eccentric cam is diversified by the link mechanism, the load reaching the molded product is relatively reduced, and frequent failure occurs due to the load between the link mechanisms.

In addition, the conventional knuckle press has a problem in that the upper rod and the lower rod are damaged due to friction generated during rotation of the upper rod and the lower rod rotatably connected to the connecting rod in the link mechanism. There was a problem that the durability of the upper and lower rods was lowered due to the clearance and frequent failures occurred.

0001) Korean Patent Registration No. 0368009 'Double Knuckle Press Device' (Registered on Feb. 31, 2002) 0002) Korean Patent Registration Publication No. 1207430 'Knuckle Press Driving Device' (Registered on November 27, 2012)

An object of the present invention is to improve the working environment by reducing the noise caused by the punching of the plate when processing the plate using a press, and to improve the durability of the link by supporting the upper rod and the lower rod rotatably connected to the connecting rod with a ball rotating body, respectively. An object of the present invention is to provide a knuckle link press device having a slider guide that enables secure and stable press work.

Another object of the present invention is to adjust the distance between the first connection hinge part and the second connection hinge part of the connecting rod part to adjust the positions of the top dead center and bottom dead center of the slider according to the processed product, and to adjust the operating speed of the slide. An object of the present invention is to provide a knuckle link press device having a slider guide.

In order to achieve the above object of the present invention, an embodiment of a knuckle link press apparatus having a slider guide according to the present invention is a knuckle link that receives power from a motor and raises and lowers the slider with a knuckle mechanism to press-work the material. A press device, wherein the knuckle mechanism is a connecting rod member that receives rotational force from the motor and rotates eccentrically about the main rotational shaft to one end side, and the other end of the connecting rod member can be rotated with a first connecting hinge on the upper side An upper rod member that is hinged below, and rotatably hingedly coupled to the rod support from the upper side by a third connecting hinge, from the other end side of the connecting rod member to a second connecting hinge at the lower portion is hinged to be rotatable and at the lower end A lower rod member connected to the slider and a fourth connecting hinge and located at a lower side of the lower rod member, the slider is positioned therein, and the inner surface is positioned in a vertical direction to support the outer surface of the slider It is characterized in that it includes a slider guide for guiding the slider to be moved up and down in a straight line in the vertical direction.

In the present invention, the connecting rod member is eccentrically connected to the main rotation shaft on one end side, and the first connection hinge portion is located on the other end side. It may include an elevating rod portion and the base rotating rod portion is located in the second connection hinge portion is located on the end side, the rod elevating portion for moving the elevating rod up and down.

In the present invention, the base rotating rod part is inserted into the lower side of the one end side of the elevating rod part and a rod insertion part positioned to be movable up and down is located, and the rod elevating part is the elevating part in the rod inserting part. It is screwed through the rod and is rotatably positioned to include an elevating screw member for elevating and lowering the elevating rod unit according to the rotational direction, wherein the connecting rod member is an interval adjustment for guiding the up and down movement of the elevating rod unit. Further comprising a guide portion, the interval adjustment guide portion is located on the other side of the guide projection and the base rotation rod portion and the elevating rod portion and the guide projection positioned to protrude on either side of the base rotation rod portion and the elevating rod portion and a guide protrusion insertion part into which the guide protrusion is movably inserted up and down, and a spring part positioned within the guide protrusion insertion part to support the guide protrusion part.

In the present invention, the rod elevating unit further includes a screw rotation locking unit capable of locking and unlocking the rotation of the elevating screw member, and the screw rotation locking unit is a screw head located outside the base rotating rod unit. and a screw fixing bolt fastened through the screw head to press the outer circumferential surface of the base rotation rod, wherein the screw fixing bolt is provided in plurality, and a part of the screw fixing bolt is inserted into the base rotation rod part A locking bolt insert is positioned, and a screw insert into which a portion of an upper side of the elevating screw member is inserted is positioned in the base rotary rod, and the rod elevating section is positioned on a side surface of the base rotary rod and the screw insert Further comprising an auxiliary locking unit for limiting rotation of the elevating screw member by pressing a portion of the elevating screw member positioned at a set for restricting rotation of the bolt for moving the jig at the head of the bolt for moving the jig, comprising a bolt for moving the jig that is fastened through the side surface of the base rotating rod and linearly reciprocates the screw lock jig according to the rotation direction The screw is penetrated and fastened to press the side surface of the base rotating rod to prevent loosening of the bolt for moving the jig.

In the present invention, the rod elevating unit measures the distance between the base rotating rod unit and the elevating rod unit to determine the distance between the first connecting hinge unit and the second connecting hinge unit in real time. A distance measuring sensor. may include more.

The present invention has the effect of improving the working environment by reducing the noise caused by the punching of the plate when processing the plate using the press, improving the press workability by accurately moving the slider in the vertical direction, and greatly improving the stability of the press work. have.

In addition, the present invention has a structure in which the upper link and the lower link are directly coupled to the connecting rod, thereby minimizing the working space as the link movement is performed in a narrow space.

In addition, the present invention can adjust the position of the bottom dead center of the slider according to the processed product by adjusting the interval between the first connection hinge part and the second connection hinge part of the connecting rod part, and the operating speed of the slide can be adjusted. It has the effect of efficiently performing the press operation.

1 is a schematic view of a conventional knuckle press.
Figure 2 is a slider diagram of the knuckle press according to the prior art.
Figure 3 is a view showing an embodiment of the knuckle link press apparatus having a slider guide of the present invention.
Figure 4 is a view showing an example in which the knuckle mechanism of the knuckle link press apparatus having a slider guide of the present invention is located at top dead center.
5 is a view showing an example in which the knuckle mechanism of the knuckle link press apparatus provided with the slider guide of the present invention is located at the bottom dead center.
6 is a slider diagram of a knuckle link press apparatus having a slider guide according to the present invention.
7 to 9 are views showing another embodiment of the knuckle mechanism in the knuckle link press apparatus having a slider guide of the present invention.
10 is a view showing another embodiment of the knuckle link press apparatus having a slider guide of the present invention.

The present invention will be described in more detail.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings as follows. Prior to the detailed description of the present invention, the terms or words used in the present specification and claims described below should not be construed as being limited to conventional or dictionary meanings. Therefore, the configuration shown in the embodiments and drawings described in the present specification is only the most preferred embodiment of the present invention and does not represent all of the technical spirit of the present invention, so at the time of the present application, various It should be understood that there may be equivalents and variations.

Figure 1 relates to a conventional knuckle press, a connecting rod 50 formed in a straight line from one side connected to a flywheel, an upper link 60 disposed upward with a lower side connected to the connecting rod, and an upper side connected to the connecting rod The lower link 70 is disposed downward and has a length L4 shorter than the length L3 of the upper link 60 . And, it is provided with a controller for pressing and fixing the plate material during punching, a hydraulic pressure generating device, and a plate material pressing and fixing means.

According to this, the vertical reciprocating speed of the slider 80 slows to some extent as it approaches the bottom dead center due to the difference in length between the length L3 of the upper link 60 and the length L4 of the lower link 70, but the slider Since the 80 is operated by the link movement of the upper link 60 and the lower link 70 operated by the connecting rod 50, the descending stroke (a region) of the slider 80 and The time and movement line of the ascending stroke (region b) appear the same.

2 is a graph showing a movement diagram of the slider 80 according to the conventional knuckle press. In the conventional knuckle press, although the movement speed is moderate to some extent when descending, it is not gentle enough to improve the molding quality. Therefore, there is a disadvantage that the productivity is transferred.

3 is a view showing an embodiment of a knuckle link press apparatus having a slider guide according to the present invention. Referring to FIG. 3 , the knuckle link press apparatus having a slider guide according to the present invention receives power from a motor. It is a knuckle link press device that press-works a material by elevating the slider 110 with the knuckle mechanism 300 .

An embodiment of the knuckle link press apparatus having a slider guide of the present invention includes a motor and a knuckle mechanism 300 for elevating and lowering the slider 110 by receiving power from the motor.

The knuckle mechanism 300 includes a plurality of rods that are rotatably connected and receives power from the motor to move the slider 110 up and down to pressurize the material to be pressed.

In addition, an embodiment of the knuckle link press apparatus having a slider guide of the present invention further includes a press work pedestal 120 on which a material to be pressed and pressed by the slider 110 is mounted.

One embodiment of the knuckle link press apparatus having a slider guide of the present invention is a motor, a knuckle mechanism 300, a power transmission unit that transmits the power of the motor to the knuckle mechanism, and a body 100 in which the pedestal 120 for press work is located. ) is further included.

The slider 110 may be raised and lowered by moving up and down in a straight line by the slider 110 guider.

In addition, an embodiment of the knuckle link press apparatus having the slider guide of the present invention further includes a power transmitting unit for transmitting the rotational force of the motor to the knuckle mechanism (300).

As an example, the power transmission unit transmits the power of the motor to the knuckle mechanism 300 to the gear structure 200 including a plurality of gears.

In more detail, the gear structure 200 is a flywheel 230 that rotates by receiving the rotational force generated by the motor to the belt, and is located on the first drive shaft 232 of the flywheel 230 and rotates together with the flywheel 230 . Gear 231 , the second gear 241 rotated by meshing with the first gear 231 , and the intermediate gear fixed to the second drive shaft 242 of the second gear 241 and rotated together with the second gear 241 . (240), the intermediate gear (240) is rotated and includes a main gear (250) rotating about the main rotation axis of the connecting rod member (400).

The knuckle mechanism 300 includes a connecting rod member 400 connected to one end side of the main rotation shaft of the main gear 250 eccentrically, and a first connecting hinge unit 310 on the other end side of the connecting rod member 400 . ) rotatably hinged to the upper rod member 320, the other end side of the connecting rod member 400 is hinged rotatably to a second connection hinge part 330 in the lower part and is connected to the slider 110 and a lower rod member 340 .

The lower rod member 340 has a lower end rotatably connected to the slider 110 by a fourth connection hinge part 510 .

In addition, the knuckle mechanism 300 is hinged rotatably to the upper end side of the upper rod member 320 by the third connection hinge part 360, the rod support body 350 for supporting the position of the upper rod member 320. may include more.

The upper rod member 320 is rotatably hinged to the rod support body 350 with the third connecting hinge unit 360, and the lower end is rotated around the third connecting hinge unit 360, that is, a translational motion. positioned to do

And, the angle α between the rotation center of the first connection hinge part 310 and the rotation center of the second connection hinge part 330 with respect to the rotation center of the main rotation shaft is formed as an acute angle.

In more detail, a first axis connecting straight line connecting the center of rotation of the main axis of rotation and the center of rotation of the first connection hinge unit 310 , and a second axis connecting the center of rotation of the main axis of rotation and the center of rotation of the second connection hinge unit 330 . The angle α between the connecting straight lines is formed as an acute angle.

An example is that the angle α between the rotation center of the first connection hinge part 310 and the rotation center of the second connection hinge part 330 with respect to the rotation center of the main rotation shaft is between 10° and 70°. .

When the angle β between the upper rod member 320 and the lower rod member 340 is 180°, the upper rod member 320 and the lower rod member 340 are positioned in a vertical direction, and at this time, the slider 110 is It is located at the bottom dead center.

In addition, the distance (D ₁ ) between the rotation center of the first connection hinge part 310 and the rotation center of the second connection hinge part 330 is the rotation center of the first connection hinge part 310 and the third connection hinge part ( 360) is equal to or longer than the distance D ₂ , and is formed shorter than the distance D ₃ between the rotation center of the second connection hinge part 330 and the fourth connection hinge part 510 and the slider 110 is When moving to TDC, the production speed is improved by moving to TDC faster than when moving to bottom dead center.

In addition, the rotation center of the main rotation shaft and the rotation center of the first connection hinge part 310 are positioned parallel to the pressing surface of the material, that is, the plate material. That is, a straight line connecting the rotation center of the main rotation shaft and the rotation center of the first connection hinge part 310 is positioned parallel to the pressing surface of the material, that is, the plate material.

In the slider guide 500, the slider 110 is positioned therein, and the inner surface is positioned in a vertical direction to support the outer surface of the slider 110 so that the slider 110 can move vertically up and down in a straight line. guide

The slider 110 presses the material P fixed to the pedestal 120 for press work as in a general press, and the upper part is coupled to the lower end of the lower rod member 340 by a fourth connection hinge part 510, It moves in the vertical direction along the slider guide 500 fixed to the body 100 .

The slider guide 500 is the length of the slider 110 so as to limit the translational movement of the lower rod member 340 to the elevating movement with respect to the lower rod member 340, which translates according to the horizontal rotation of the connecting rod member 400. It is positioned in a vertical direction parallel to the direction, and the slider 110 is penetrated and moved, and the outer surface of the slider 110 is supported in the vertical direction.

The slider guide 500 has the effect of securing the molding reproducibility of the material P positioned on the pedestal 120 for press work by limiting the power transmitted from the lower rod member 340 to the lifting motion.

On the other hand, in the connecting rod member 400, the first ball support 600 that is in contact with the upper rod member 320 and rotates when the upper rod member 320 rotates is located on the upper portion of the other end side, A second ball support 700 that is in contact with the lower rod member 340 and rotates when the lower rod member 340 is rotated is positioned at the lower portion.

In more detail, the upper rod member 320 has an arc-shaped first rod rotation guide arc groove into which the upper part of the other end side of the connecting rod member 400 is partially inserted, and the first ball support body 600 is the connecting rod. It is positioned to protrude from the upper portion of the other end of the member 400 and rolls while in contact with the inner surface of the first rod rotation guide arc groove of the upper rod member 320 .

The first ball support 600 is positioned to protrude from the outer surface of the connecting rod member 400 and is placed in contact with the inner surface of the arc groove for guiding the first rod rotation of the upper rod member 320, and the connecting rod member ( When the 400) and the upper rod member 320 are rotated, the position of the upper rod member 320 is stably supported, and the connecting rod member 400 and the upper rod member 320 can be rotated smoothly.

In addition, in the lower portion of the other end side of the connecting rod member 400, an arc-shaped second rod rotation guide arc groove into which a portion of the upper end side of the lower rod member 340 is inserted is located, and the second ball support body 700 is It protrudes from the inner surface of the arc groove for the second rod rotation guide and rolls in contact with the upper curved surface of the lower rod member 340 .

The first ball support 600 includes a first ball member 610 that rolls in contact with the upper rod member 320 , and a first ball support spring member that elastically supports the first ball member 610 .

The first ball member 610 is in contact with the upper rod member 320 in a state of being elastically supported by the first ball support spring member and rolls while being rotated around the third connection hinge part and the first connection hinge part. The rotation of the 320 is stably supported, and wear due to the contact between the connecting rod member 400 and the upper rod member 320 is minimized.

In addition, the second ball support 700 includes a second ball member 710 that rolls in contact with the lower rod member 340 , and a second ball support spring member 720 that elastically supports the second ball member 710 . do.

The second ball member 710 is in contact with the lower rod member 340 in a state of being elastically supported by the second ball support spring member 720, and the lower rod member 340 rotates around the second connection hinge while rolling. to stably support the rotation, and to minimize wear due to contact between the connecting rod member 400 and the upper rod member 320 .

4 is a view showing an example in which the knuckle mechanism 300 of the knuckle link press apparatus having a slider guide of the present invention is positioned at top dead center, and FIG. 5 is a view of the knuckle link press apparatus having a slider guide of the present invention. It is a view showing an example in which the knuckle mechanism 300 is located at the bottom dead center.

As shown in FIG. 4 , the inner diameter of one side of the connecting rod member 400 rotates about the main rotation shaft 251 , thereby moving the slider 110 from top dead center to bottom dead center when the motor 210 is driven. . If the central coordinate of the main rotation shaft 251 is F0(0,0) when the driving gear 200 is in the rest state, the central coordinate of the inner diameter of one side of the connecting rod member 400 is F1(x,y). When a signal is applied to the driving gear 200 for forming the material (P), the central coordinate of the inner diameter of one side of the connecting rod member 400 is F2 ( -x, +y).

As shown in FIG. 5 , one side of the connecting rod member 400 whose central coordinate is moved to F2 (-x, +y) is moved to the original position F1 (x, y) by the continuously rotating motor 210 do. As such, when the central coordinate of one side of the connecting rod member 400 moves from F1 (x, y) to F2 (-x, +y), the slider 110 moves from top dead center to bottom dead center, and the connecting rod member 400 ) moves from F2 (-x, +y) to F1 (x, y), the slider 110 moves from bottom dead center to top dead center again.

The knuckle mechanism 300 is coupled to the upper rod member 320 fixed to the inner upper end of the main body 100 and rotated left and right and the main rotation shaft 251 with one inner diameter of the connecting rod member 400 eccentrically coupled to the connecting rod member. The upper rod member 320, the lower end of the upper rod member 320 on the other side of the upper portion, and the connecting rod member 400, the lower end of which is coupled by the first connecting hinge portion 310, and the upper end of the second connecting hinge portion 330 at the other end of the connecting rod member 400 It includes a lower rod member 340 that is coupled by the left and right rotation. The lower end of the lower rod member 340 is coupled with the slider 110 to transmit power to vertically elevate the slider 110 as the motor 210 rotates.

In more detail, the upper rod member 320, the upper end is connected to the main body 100, the lower end is connected to the first connection hinge part 310 of the connecting rod member 400, and the upper end of the connecting rod member 400, the second The lower rod member 340 connected to the connecting hinge part 330 and having a lower end connected to the slider 110 is coupled to the other end of the connecting rod member 400 by a predetermined distance from the other end thereof.

In this way, the slider 110 rises faster by the second connecting hinge unit 330 coupled to the other end of the connecting rod member 400 at a predetermined distance from the first connecting hinge unit 310 to reduce production time. can be shortened

The first and second connecting hinge parts 310 and 330 are eccentrically connected to the main rotation shaft 251 formed in the center of the main gear 250 in the driving gear part 200 and the main rotation shaft 251 of the connecting rod member 400 connected to it. It has the minimum acute angle (α) of a triangle as a reference. That is, the first connection hinge part 310 coupled to the main rotation shaft 251 and the upper rod member 320 is positioned to be parallel to the same line, and the second connection hinge part 330 is separated from the first connection hinge part 310 . It is configured to have different axes that are spaced apart in the vertical direction and are parallel to each other.

Accordingly, the first and second connecting hinge portions 310 and 330 have a minimum acute angle of a right-angled triangle with respect to the main rotation shaft 251 of the connecting rod member 400 . In this case, the minimum acute angle α of the right-angled triangle is determined according to a distance from the first connection hinge part 310 to the second connection hinge part 330 spaced apart from each other in a vertical downward direction. The minimum acute angle α of the right triangle may be included between about 0 and 70 degrees.

3 to 5, when the motor 210 is driven, the flywheel 230 rotates by the rotational force transmitted through the belt 220, and is formed in the center of the rotating flywheel 230 at this time. The first gear 231 fixed to the first drive shaft 232 2 rotates.

As an example, the first gear 231 is a pinion gear having teeth.

And, the intermediate gear 240 fixed to the second drive shaft 241 formed in the center of the second gear 241 meshed with the first gear 231 and the main gear 250 meshed with the intermediate gear 240 ) will rotate

It is located at the center of rotation of the main gear 250 according to the rotation of the main gear 250 , is formed in the center of the connecting rod member 400 , and is coupled to one end of the connecting rod member 400 along the main rotation shaft 251 . The connecting rod member 400 performs a reciprocating linear motion in the horizontal direction.

The lower end of the upper rod member 320 is coupled to the upper portion of the other end of the connecting rod member 400 by the first connecting hinge portion 310 , and the lower rod member 340 is at the lower portion of the other end side of the connecting rod member 400 . ) is coupled by the second connecting hinge part 330 to form a right-angled triangle based on the main rotation shaft 251 of the main gear 250, and the connecting rod according to the rotation of the main gear 250 When the member 400 reciprocates linearly in the horizontal direction, the angle β between the upper rod member 320 and the lower rod member 340 increases and decreases repeatedly.

At this time, the slider 110 located at the lower end of the lower rod member 340 is raised and lowered to mold the material P fixed to the pedestal 120 for press work.

In other words, as the main gear 250 rotates, one end of the connecting rod member 400 rotates around the main rotation shaft 251 along the inner diameter.

When a signal is applied to the driving gear 200 for molding the material (P), the central coordinate of the inner diameter of one side of the connecting rod member 400 is F1 ( x,y) to F2(-x, +y). As a result, the connecting rod member 400 moves horizontally to the left, the angle β between the upper rod member 320 and the lower rod member 340 increases, and the slider 110 moves to the bottom dead center when the angle β is maximum. reach

As the main gear 250 continuously rotates, the central coordinate of the inner diameter of one side of the connecting rod member 400 based on the central coordinate F0 (0,0) of the main rotation shaft 251 is at F2 (-x, +y) Displace by F1(x,y). Thereby, the horizontal movement to the other end of the connecting rod member 400, the angle (β) between the upper rod member 320 and the lower rod member 340 is small, when the angle (β) is the minimum, the slider 110 is similar reach the point That is, when the connecting rod member 400 moves to the left end, the angle β between the upper rod member 320 and the lower rod member 340 increases to the maximum, that is, 180°, and the slider 110 moves to the bottom dead center. When it reaches and moves to the other end of the connecting rod member 400, the angle β between the upper rod member 320 and the lower rod member 340 is minimized so that the slider 110 reaches top dead center and is formed. One cycle for

6 is a graph showing a movement diagram of the slider 110 by the knuckle link press according to the present invention. Looking at the slider 110 shown by operating the knuckle link press according to the above-described driving operation, the rotation of the main gear 250 As the connecting rod member 400 moves to the left end according to the Given that the angle β between the upper rod member 320 and the lower rod member 340 is gradually increased, it can be seen that the movement speed to the bottom dead center of the slider 110 which determines the molding quality is gently delayed.

The slider 110 presses the material P with the maximum load from the start of molding before the slider 110 enters the bottom dead center to the time it reaches the bottom dead center so that the cross-section is smooth and flatness is ensured. molding takes place

Conversely, the section moving to the top dead center of the slider 110 moves to the other end of the connecting rod member 400 according to the rotation of the main gear 250 , with the upper rod member 320 and the lower rod member 340 and By pushing the first connecting hinge unit 310 and the second connecting hinge unit 330 to be coupled to each other, the angle β between the upper rod member 320 and the lower rod member 340 is gradually reduced, and the slider 110 is set to the bottom dead center. rapidly rises from to top dead center.

Therefore, in addition to the characteristic that the descending speed is gently delayed when the slider 110 is descending, the moving speed is faster when the slider 110 is ascended compared to the conventional knuckle press, and the ascending time is shortened. Reduction of the rise time of the descent compensates for the delay time during the descent, so it does not increase the overall stroke time of the molding operation, which has the effect of maintaining constant productivity.

Meanwhile, FIGS. 7 to 9 are views showing another embodiment of the knuckle mechanism 300 in the knuckle link press apparatus having a slider guide of the present invention, and FIG. 10 is a knuckle link press having a slider guide of the present invention. It is a diagram showing another embodiment of the device.

In more detail, Figure 7 is a schematic view showing another embodiment of the knuckle mechanism 300 in the knuckle link press apparatus having a slider guide of the present invention, Figure 8 is a knuckle in the knuckle link press apparatus provided with the slider guide of the present invention It is a cross-sectional view illustrating another embodiment of the instrument 300 .

In addition, Figure 9 is a cross-sectional view showing an embodiment of the auxiliary lock 470 in another embodiment of the knuckle mechanism 300, Figure 10 is a slider guide of the present invention to which another embodiment of the knuckle mechanism 300 is applied. It is a schematic diagram showing another embodiment of the provided knuckle link press device.

7 to 10, in another embodiment of the knuckle mechanism 300 in the knuckle link press apparatus having a slider guide of the present invention, the connecting rod member 400 is a first connection to which the upper rod member 320 is connected. It may have a structure in which the interval between the hinge part 310 and the second connection hinge part 330 to which the lower rod member 340 is connected can be adjusted.

The connecting rod member 400 is eccentrically connected to the main rotation shaft on one end side, and the first connection hinge portion 310 is positioned on the other end side of the base rotation rod portion 410 and the base rotation rod portion 410 on the , It is coupled to move downward and includes an elevating rod part 420 in which the second connection hinge part 330 is located on the other end side.

In addition, it may further include a rod elevating unit 430 positioned on the base rotating rod unit 410 to move the elevating rod unit 420 up and down.

The rod elevating unit 430 measures the distance between the base rotating rod unit 410 and the elevating rod unit 420 to measure the distance between the first connection hinge unit 310 and the second connection hinge unit 330 in real time. It further includes a distance measuring sensor 440 to confirm.

The distance measuring sensor 440 uses a known laser distance sensor as an example, and in addition, it can be implemented using various known sensors capable of measuring a distance, so a more detailed description will be omitted.

Although not shown, the distance measuring sensor 440 outputs the measured distance to a display, etc., and the operator checks in real time to determine the interval between the first connection hinge part 310 and the second connection hinge part 330 by pressing the material. Make sure to accurately position it at a preset interval.

It should be noted that the configuration of the output unit for outputting the distance measured by the distance measuring sensor 440 is a well-known technique and a more detailed description thereof will be omitted.

The base rotation rod part 410 includes a rotation support part 410a on which the main rotation shaft is located, a rod connection part 410b that protrudes to the other side of the rotation support part 410a and where the first connection hinge part 310 is located. .

The rod connection part 410b is located on the upper side of the rotation support part 410a, and one end side of the elevating rod part 420 is inserted into the lower side of the rotation support part 410a from the other side of the rod connection part 410b. , The rod insertion part 411 which is movably positioned down is located.

The elevating rod unit 420 has one end side inserted into the rod insertion unit 411 to be moved up and down, and is moved up and down by the rod elevating unit 430 to the first connection hinge unit 310 . and the distance between the second connection hinge part 330 is adjusted.

The rod elevating unit 430 may include an elevating screw member 431 that is screwed through the elevating rod unit 420 in the rod insertion unit 411 and is rotatably positioned.

The elevating screw member 431 is rotatably supported by the base rotating rod unit 410 and is screwed through the elevating rod unit 420 in the rod insertion unit 411 to thereby increase the elevating rod unit according to the rotational direction. (420) is moved up and down.

In addition, the connecting rod member 400 may further include a gap adjustment guide part 450 for guiding the upward and downward movement of the elevating rod part 420 .

The interval adjustment guide part 450 is a guide protrusion 451 positioned to protrude from either side of the base rotation rod part 410 and the elevating rod part 420, the base rotation rod part 410 and the elevating rod part It is positioned on the other side of the 420 and includes a guide protrusion insertion portion 452 into which the guide protrusion 451 is inserted to be movable up and down.

The guide protrusion 451 is inserted into the guide protrusion insertion part 452 so as to be movable up and down while the outer circumferential surface is supported on the inner circumferential surface of the guide protrusion insertion part 452, and the elevating rod part 420 moves up and down. to guide

In addition, the interval adjustment guide part 450 may further include a spring part 453 positioned in the guide projection insertion part 452 to support the guide projection part 451 .

The spring part 453 is positioned in the guide protrusion insertion part 452 to elastically support the guide protrusion part 451 , thereby buffering the impact received by the elevating rod part 420 during the press operation.

The elevating screw member 431 has a screw rotation shaft rotatably supported by the base rotation rod part 410 on the upper end side and the lower end side, respectively.

Each of the screw rotation shafts is supported by a bearing so that the elevating screw member 431 can rotate smoothly.

The screw rotation shaft located on the lower end side of the elevating screw member 431 is exposed to the lower surface of the base rotation rod part 410, and the elevating screw member 431 is the screw rotation shaft located at the lower end side is fixed and the base rotation rod It includes a screw head 431a positioned on the outside of the portion 410 .

The screw head 431a may be formed in a variety of known shapes that can easily rotate the elevating screw member 431 using a tool such as a hexagonal shape in a plane.

In addition, the screw head 431a may be configured to have a tool insertion groove such as a hexagon wrench groove to rotate the elevating screw member 431 using a tool such as a lens.

The rod elevating unit 430 may further include a screw rotation locking unit 460 capable of locking and unlocking the rotation of the elevating screw member 431 .

The screw rotation locking part 460 includes a screw fixing bolt 461 which is fastened through the screw head 431a and presses the outer circumferential surface of the base rotation rod part 410 .

A plurality of screw fixing bolts 461 may be provided to more stably lock the rotation of the elevating screw member 431 .

In addition, the base rotation rod part 410 has a locking bolt insertion part 412 into which a part of the screw fixing bolt 461 is inserted to more stably lock the rotation of the elevating screw member 431, and the screw fixing bolt Even if some loosening of the 461 occurs, it is possible to stably lock the rotation of the elevating screw member 431 .

In addition, the base rotation rod part 410 has a screw insertion part 413 into which a portion of the upper side of the elevating screw member 431 is inserted, and referring to FIG. 9 , the rod elevation part 430 is the base rotation rod part. It is located on the side of the 410 and presses a part of the elevating screw member 431 located in the screw insertion part 413 to limit the rotation of the elevating screw member 431 further includes an auxiliary locking part 470 By locking the rotation of the screw fixing bolt 461, that is, the screw rotation locking part 460, the rotation of the elevating screw member 431 is doubled to lock the rotation of the elevating screw member 431 more stably and firmly. have.

The auxiliary locking part 470 has one end rotatably positioned on the screw locking jig 471 and the screw locking jig 471, and is fastened through the side surface of the base rotating rod part 410, and according to the rotation direction, the screw locking jig ( 471) includes a jig movement bolt 472 for linear reciprocating movement, and is located on both sides of the base rotation rod part 410, respectively, to press the elevating screw member 431 from both sides with a screw locking jig 471. By locking, the rotation of the elevating screw member 431 can be more stably and firmly locked.

A set screw for limiting the rotation of the bolt 472 for moving the jig is penetrated and fastened to the head of the bolt 472 for moving the jig, and the set screw presses the side of the base rotating rod 410 to thereby move the bolt 472 for moving the jig. to prevent loosening of

In addition, the pedestal 120 for press work further includes a support elevating part 122 for vertically moving the support part 121 for press working on which the material is placed, the first connection hinge part 310 and the second connection hinge part 330 . ) As the spacing is adjusted, the height of the material can be adjusted to suit the press processing conditions.

The support elevating unit 122 is a hydraulic cylinder as an example, and in addition, it can be variously modified and implemented using a known linear moving device such as a linear actuator having a ball screw structure, and a more detailed description will be omitted.

The connecting rod member 400 moves the elevating rod 420 up and down by the rod elevating unit 430 to the first connecting hinge unit 310 and the lower rod member 340 to which the upper rod member 320 is connected. ), the position of the bottom dead center of the slider 110 can be adjusted according to the processed product by adjusting the interval between the second connection hinge parts 330 to which they are connected, and the operating speed of the slide can be adjusted.

In addition, the support elevating part 122 is a support part 121 for press working on which the material is seated according to the interval between the first connection hinge part 310 and the second connection hinge part 330 which are controlled by the operation of the rod elevation part 430 . ) can be moved up and down to adjust the height of the material.

On the other hand, the present invention is provided with an upper rod member 320 and a lower rod member 340 coupled to have different axes on the upper and lower portions of the other end of the connecting rod member 400, respectively, when the slide moves to the bottom dead center. It is possible to improve the molding quality by pressing as in the conventional knuckle press.

The present invention improves the working environment by reducing the noise caused by the punching of the plate when processing the plate using the press, and improves the press workability by moving the slider accurately in the vertical direction, and greatly improves the stability of the press work.

In addition, when the slider 110 moves to top dead center, the movement speed is faster than that of the conventional knuckle press, and the rise time is shortened. can do it

In addition, the main rotation shaft of the main gear that transmits the driving force is eccentric to further delay the descending speed of the slider 110, thereby maximizing the molding quality.

In addition, since the upper link and the lower link are directly coupled to the connecting rod, the working space can be minimized as the link movement is performed in a narrow space.

In addition, the present invention can adjust the position of the bottom dead center of the slider 110 according to the processed product by adjusting the interval between the first connection hinge part 310 and the second connection hinge part 330 of the connecting rod part, and the operation of the slide Because the speed can be adjusted, the press work for various products can be performed efficiently.

It should be noted that the present invention is not limited to the above-described embodiment, and can be implemented with various modifications without departing from the gist of the present invention, which is included in the configuration of the present invention.

100: body 110: slider
120: support for press work 121: support for press work
122: support elevating unit 200: gear structure
210: motor 220: belt
230: flywheel 231: first gear
232: first drive shaft 240: intermediate gear
241: second gear 242: second drive shaft
250: main gear 251: main rotation shaft
300: knuckle mechanism 310: first connection hinge portion
320: upper rod member 330: second connection hinge part
340: lower rod member 400: connecting rod member
410: base rotation rod 410a: rotation support
410b: rod connection part 411: rod insertion part
412: locking bolt insert 413: screw insert
420: elevating rod section 430: rod elevating section
431: elevating screw member 431a: screw head
440: distance measuring sensor 450: interval adjustment guide part
451: guide projection 452: guide projection insertion portion
453: spring part 460: screw rotation locking part
461: screw fixing bolt 470: auxiliary locking part
471: screw lock jig 472: jig moving bolt
500: slider guide 510: fourth connection hinge part
600: first ball support 610: first ball member
620: first ball support spring member
700: second ball support 710: second ball member
720: second ball support spring member

Claims (5)

It is a knuckle link press device that receives power from the motor and press-works the material by moving the slider up and down with the knuckle mechanism.
The knuckle mechanism is
a connecting rod member that receives the rotational force of the motor and rotates about the main rotational shaft eccentrically to one end side;
an upper rod member rotatably hinged to an upper portion from the other end of the connecting rod member by a first connection hinge, and rotatably hinged to the rod support from the upper side by a third connection hinge;
a lower rod member rotatably hinged from the other end of the connecting rod member to a lower portion by a second connecting hinge and connected to the slider and a fourth connecting hinge at a lower end; and
It is located on the lower side of the lower rod member, and the slider is located therein, and the inner surface is positioned in a vertical direction to support the outer surface of the slider, so that the slider passes through and moves vertically up and down in a straight line. A knuckle link press device having a slider guide, characterized in that it includes a slider guide.
The method according to claim 1,
The connecting rod member,
a base rotation rod part having a main rotation shaft connected to one end side eccentrically and a first connection hinge part located on the other end side;
an elevating rod part coupled to the base rotation rod part to be movable up and down and having a second connection hinge part positioned on the other end side; and
A knuckle link press device having a slider guide, which is located in the base rotating rod and includes a rod elevating unit for moving the elevating rod unit up and down.
3. The method according to claim 2,
The base rotating rod portion,
The rod insertion part is located on the lower side, the one end side of the elevating rod part is inserted so as to be movable up and down,
The rod elevating unit includes an elevating screw member that is screwed through the elevating rod unit in the rod insertion unit and is rotatably positioned to elevate the elevating rod unit according to the rotational direction,
The connecting rod member further comprises a gap adjustment guide for guiding the up and down movement of the elevating rod portion,
The interval adjustment guide part,
a guide protrusion positioned to protrude from either side of the base rotation rod and the elevating rod;
a guide protrusion insertion part positioned on the other side of the base rotating rod part and the elevating rod part and the guide protrusion part being inserted to be movable up and down; and
A knuckle link press device having a slider guide, characterized in that it is located in the guide projection insertion portion and includes a spring portion for supporting the guide projection.
4. The method according to claim 3,
The rod elevating unit further includes a screw rotation locking unit capable of locking and unlocking the rotation of the elevating screw member,
The screw rotation locking part,
a screw head located outside the base rotating rod; and
and a screw fixing bolt which is fastened through the screw head and presses the outer circumferential surface of the base rotating rod,
The screw fixing bolt is provided in plurality,
A locking bolt insertion part into which a part of the screw fixing bolt is inserted is located in the base rotation rod part,
A screw insertion portion into which a portion of the upper side of the elevating screw member is inserted is located in the base rotation rod portion,
The rod elevating part further comprises an auxiliary locking part located on the side of the base rotating rod part and limiting the rotation of the elevating screw member by pressing a portion of the elevating screw member located in the screw insertion part,
The auxiliary locking part,
screw locking jig;
and a jig movement bolt having one end rotatably positioned on the screw lock jig and fastened through a side surface of the base rotation rod part to linearly reciprocate the screw lock jig according to a rotation direction;
A set screw for limiting rotation of the bolt for moving the jig is passed through the head of the bolt for moving the jig and fastened to press the side of the base rotating rod to prevent loosening of the bolt for moving the jig is provided. One knuckle link press device.
4. The method according to claim 3,
The rod elevating unit,
Slider, characterized in that it further comprises a distance measuring sensor for measuring the distance between the base rotation rod and the elevating rod portion to check the distance between the first connection hinge portion and the second connection hinge portion in real time Knuckle link press device with guide.

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