KR200421837Y1 - Transfer Equipment of Forging Material - Google Patents

Abstract

The present invention is a forging material conveying device for conveying a large amount of material to the side conveying device, the cylindrical shaft which is installed in the longitudinal direction at the position where the material is supplied from the material supply unit, and one end of the shaft A material transfer unit having a screw-shaped mount formed on an outer surface of the shaft to be mounted and driven to rotate the shaft, and the material supplied from the material supply part to the shaft being guided and slid to the upper end of the shaft; A support frame connected to a predetermined portion of the shaft to support the shaft such that the shaft is inclined upward; And at one side of the shaft such that one end of the material supplied from the material supply part to the material conveying part is guided to the ridge of the material conveying part and is slid to the upper end of the shaft so that both sides of the material are guided. It is provided with a predetermined distance perpendicular to the longitudinal direction of the shaft, and relates to a forging material conveying apparatus comprising a guide assembly including a pair of material guide plate having a predetermined interval.

 The forging material conveying apparatus according to the present invention uses a material conveying part and a guide assembly which can align various shapes of materials in the longitudinal direction, and thus does not require secondary processing of various shapes of materials supplied from a material supplier into a cylindrical shape. In addition, there is an effect that can reduce the working time and cost.

Forging, material, material transfer part, guide assembly

Description

Transfer Equipment of Forging Material

1 is a perspective view showing a conventional automatic forging device.

Figure 2 is a side cross-sectional view schematically showing a conventional material supply.

Figure 3 is a front view showing a forging material conveying apparatus according to a preferred embodiment of the present invention.

Figure 4 is a plan view showing a material transfer unit and the guide assembly of the forging material conveying apparatus according to a preferred embodiment of the present invention.

5 is a cross-sectional view showing a material transfer unit of the forging material transfer apparatus according to a preferred embodiment of the present invention.

Figure 6 is a plan view showing a guide chute of the forging material conveying apparatus according to a preferred embodiment of the present invention.

Figure 7 is a schematic front view showing the operating state of the forging material conveying apparatus according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: tilting device 12: sliding plate

14: hinge portion 16: lifting device

20: material transfer part 22 shaft

22a: mountain part 24: drive unit

25: drive motor 26: power train

30: support frame 32: inclined portion

34: frame portion 40: guide assembly

42: fixed guide plate 44: material guide plate

46: guide connecting portion 47: the first horizontal movement adjusting portion

48: first horizontal movement control bar 49: first handle

50: guide suit 52: suit

53: sliding portion 54: bending portion

56: sliding guide portion 58: chute connecting portion

60: second horizontal movement adjusting unit 62: second horizontal movement adjusting bar

64: second handle 70: material

100: hopper 102: material

105: material supply unit 200: flat feeder

300: side feeder 400: high frequency heating furnace

500: ejector

The present invention relates to a forging material conveying apparatus, and more particularly to a forging material conveying apparatus that can be aligned in the longitudinal direction of a variety of shapes, in particular, the square-shaped material supplied from the material supplier.

In general, forging refers to an operation of improving the mechanical properties while simultaneously pressing and molding a metal into a desired shape or dimension by hammering it with a suitable temperature.

Metal materials for forging include carbon steel, alloy steel, brass, and aluminum alloy, which are easily deformed even when beaten, and are generally forged at lower temperatures based on the temperature at which recrystallization proceeds. Cold forging and forging at a higher temperature are called hot forging.

The cold forging is a forging method that is formed by plastic working at room temperature, and is not suitable for making a product having a complicated shape, but due to the work hardening caused by deformation, a high strength product can be obtained, and the surface of the product is clean and dimensionally High precision products can be produced.

The hot forging feature is that the material is heated to a high temperature of 1000 to 1250 ℃. It is a forging method to reduce the deformation resistance and give a large deformation with a small force, so that the molding can be easily performed, and the annealing effect is added to improve the material.

In addition, the hot forging is generally used because the production speed is high, so that the productivity is good and easy to form a complex shape, the structure of the automatic forging device forging by the hot forging method is shown in FIG.

Referring to FIG. 1, the structure of a conventional automatic forging device includes a hopper 100 to which a raw material 102 is supplied, a flat feeder 200 for rearranging the supplied raw material 102 in a longitudinal direction, and the The side feeder 300 for transferring the material 102 transferred from the flat feeder 200 to a high frequency heating furnace 400 for heating to a high temperature, and the material 102 transferred from the side feeder 300 at a high temperature. And a discharger 500 for discharging the raw material 102 heated at a high temperature in the high frequency heating furnace 400 to a high-pressure press apparatus (not shown).

When the material 102 is heated in the high frequency heating furnace 400, if the structural material 102 of the high frequency heating furnace 400 is not aligned in the longitudinal direction, the material 102 of the high frequency heating furnace 400 may be formed. Since it is not easy to insert and the material 102 passes through the high frequency heating furnace 400 and the heating time is different, the material 102 may melt, so that the material 102 supplied to the flat feeder 200 When transported to the side conveying device, the worker has to align the longitudinal direction of the material 102 is not aligned in the longitudinal direction one by one, which has a problem that the productivity is significantly reduced and the labor cost increases due to increased working time.

In order to solve the above problems, before supplying the material 102 from the hopper 100 to the flat feeder 200, the material supply unit for aligning the material 102 in the longitudinal direction to supply to the flat feeder 200 was devised, The structure of the material supply portion is shown in FIG.

Referring to FIG. 2, the material supply unit 105 includes a plurality of fixing plates 130 fixed to the main body of the housing 110 to be inclined in a layered manner, and a hydraulic lifting device 124 coupled to the base plate (up and down). It consists of a plurality of slide plate 120 is fixed to the inclined 122, the slide plate 120 is disposed in the foremost, the fixed plate 130 is disposed in the rear, between the fixed plate 130 in front Positioning the slide plate 120 in a pair is configured to transfer the material 102 in the longitudinal direction of the slide plate 120 in the longitudinal direction and transported from the front to the rear to the feeder 200.

Operation of the material supply unit 105 is first administered the material 102 to the inlet of the housing 110 and operating the hydraulic lifting device 124, the foremost slide plate 120 is the top surface of the material 102 While rising on the fixed plate 130 while raising the slide plate 120 slightly higher than the top surface of the fixed plate 130, the material 102 naturally moves to the fixed plate 130.

Next, when the slide plate 120 descends slightly lower than the height of the fixed plate 130, the material 102 placed on the fixed plate 130 is moved to the slide plate 120. When the material 102 is transferred to the uppermost fixing plate 130 while going through this process, the material 102 is transferred to the flat feeder 200 installed at the rear of the material supply part 105.

When the material 102 is aligned in the longitudinal direction in the material supply part 105, when the shape of the material 102 is not cylindrical, the material 102 is not easily aligned in the longitudinal direction, so only the material 102 formed in the cylindrical shape is handled. can do.

However, the material 102 formed in a cylindrical shape is used by secondary processing of various shapes, in particular, a square shape material, which is processed and supplied from a material supplier, which needs to be reprocessed from the material supplier. Therefore, there was a problem that the work time and work costs are increased.

In order to solve the problems of the prior art as described above, an object of the present invention is to supply a material supplier using a material transfer unit and a guide assembly that can align a cylindrical as well as various shapes, in particular, a rectangular shape in a longitudinal direction. Since it is not necessary to secondary processing the material of various shapes into a cylindrical shape, to provide a material transfer device for forging that can reduce the working time and cost.

In order to achieve the above object, the present invention provides a forged material conveying apparatus for conveying a large amount of material to the side conveying apparatus, the cylindrical shaft being installed in the longitudinal direction at a position where the material is supplied from the material supply unit, and A driving device mounted to one end of the shaft to rotate the shaft, and a screw shape formed on an outer surface of the shaft so that the material supplied from the material supply part to the shaft is guided and slid to the upper end of the shaft. A material transfer part having an acid portion; A support frame connected to a predetermined portion of the shaft to support the shaft such that the shaft is inclined upward; And at one side of the shaft such that one end of the material supplied from the material supply part to the material conveying part is guided to the ridge of the material conveying part and is slid to the upper end of the shaft so that both sides of the material are guided. It is provided with a predetermined distance perpendicular to the longitudinal direction of the shaft, and provides a forging material conveying apparatus comprising a guide assembly including a pair of material guide plate having a predetermined interval.

In addition, the material supply unit of the present invention is a sliding plate on which the material is seated and the hinge portion mounted on one side of the sliding plate in order for the material supplied from the material supply unit is aligned in the longitudinal direction and sliding to the material transfer unit And a tilting device having a lifting device connected to one end of the sliding plate so that the material seated on the sliding plate is slid by tilting the sliding plate toward the material transfer part with the hinge portion as an axis. It provides a forging material feeder, characterized in that.

In addition, the guide assembly of the present invention is characterized in that it further comprises a first horizontal movement control unit connected to one side of the material guide plate to adjust the gap of the material guide plate in fluid according to the size of the material It provides a forging material feeder.

In addition, the present invention further comprises a guide chute inclined downward so as to slide down the material conveyed to the upper end of the shaft of the material conveying unit to the side conveying device is configured to further comprise to provide.

In addition, the guide chute of the present invention transfers the material falling from the material conveying portion to the side conveying device and some of the material is not aligned in the longitudinal direction of the material falling in the upper end of the shaft of the material conveying portion in the longitudinal direction A chute having a sliding part provided to be inclined at a predetermined angle at a position at which the material falls from an upper end of the shaft of the material transfer part, and a bent part that is bent vertically on one side and the other side of the sliding part; And a length direction of the chute on one surface of the chute in which the material dropped from the material transfer part is positioned so that when the material falling from the material transfer part is slid by the chute, the material does not escape to the outside. It is provided vertically and provides a forging material conveying apparatus, characterized in that further comprises a pair of sliding guide portion having a predetermined interval.

Hereinafter, with reference to the accompanying drawings will be described in more detail the forging material conveying apparatus according to a preferred embodiment of the present invention.

3 is a front view showing a forging material transfer apparatus according to a preferred embodiment of the present invention, Figure 4 is a plan view showing a material transfer unit and a guide assembly of the forging material transfer apparatus according to a preferred embodiment of the present invention, 5 is a cross-sectional view showing a material transfer unit of the forging material conveying apparatus according to a preferred embodiment of the present invention, Figure 6 is a plan view showing a guide chute of the forging material conveying apparatus according to a preferred embodiment of the present invention.

3 to 6, the forging material conveying device for conveying the material 70 supplied from the material supply unit 105 according to a preferred embodiment of the present invention up to a side conveying device (not shown) is a tilting device ( 10), the material transfer unit 20, the support frame 30, the guide assembly 40 and the guide chute 50 is configured to include.

The tilting device 10 slides the material 70 supplied from the material supply part 105 to the material transfer part 20, and includes a sliding plate 12, a hinge part 14, and a lifting device 16. It is configured by.

The sliding plate 12 is installed on one end of the material supply unit 105 so that the material 70 supplied from the material supply unit 105 is aligned in the longitudinal direction and slides into the material transfer unit 20. When the material 70 is transferred to the uppermost part of the 105, the material 70 is configured to be positioned by a sliding plate 12 installed at one end of the material supply part 105.

Thus, the material 70 supplied from the material supply part 105 is positioned while falling onto the sliding plate 12, wherein some of the material 70 is aligned in the longitudinal direction.

The hinge portion 14 is mounted on one side of the sliding plate 12 so that the sliding plate 12 is inclined, and the sliding plate 12 is inclined to the sliding plate 12 with the hinge portion 14 as an axis. The material 70 to be positioned is slid into the material transfer part 20.

The lifting device 16 lifts one end of the sliding plate 12 with the hinge portion 14 as the axis so that the material 70 positioned on the sliding plate 12 slides to the material transfer part 20. As the raising, one end is connected to one end of the sliding plate 12, the other end is configured to be connected to one side of the one end of the material supply portion 105.

Thus, when sliding the material 70 located in the sliding plate 12 to the material transfer part 20, one end of the sliding plate 12 is lifted by the elevating device 16 to the sliding plate 12 The material 70, which is dropped and positioned, is slid into the material transfer part 20.

The material transfer unit 20 is for transferring the material 70 sliding in the tilting device 10 to the guide chute 50, and includes a shaft 22 and a driving device 24.

The shaft 22 is formed in a cylindrical shape and is installed long in the longitudinal direction at the position where the material 70 is slid in the tilting device 10.

In addition, the outer surface of the shaft 22 is integrally formed with a screw-shaped hill portion 22a so that the material 70 is guided by the shaft 22 and moved to the upper end of the shaft 22 by slide.

The drive device 24 is composed of a drive motor 25 and a power transmission device 26. First, the drive motor 25 is composed of a conventional motor for generating power, and the power transmission device 26 is the drive motor. It is for transmitting the power generated by the (25) to the shaft 22, it is preferably composed of a universal joint (Universal Joint).

Therefore, one end of the power transmission device 26 is connected to one end of the shaft 22, and the other end of the power transmission device 26 is connected to the drive motor 25, so that the driving motor 25 The power is transmitted and rotated to the shaft 22 via the power transmission device 26.

The support frame 30 supports the upper end of the shaft 22 of the material transfer unit 20 to be inclined upward, and includes an inclined portion 32 and a frame portion 34. ) Is formed such that the upper end of the shaft 22 is inclined upward, one side thereof is connected to the shaft 22 in the longitudinal direction. More specifically, a predetermined portion of the side surface portion of the shaft 22 is connected to one side of the inclined portion 32 so that the upper end portion of the shaft 22 is inclined upward.

When the inclined portion 32 supports the shaft 22 to be inclined, the frame portion 34 is connected to the other side of the inclined portion 32 and serves to support the inclined portion 32.

The guide assembly 40 is formed on the shaft 22 of the material conveying part 20 when the material 70 supplied from the material supply part 105 is slid to the material conveying part 20 through the tilting device 10. One end of the material is guided to the formed mountain portion 22a and guided to the upper end of the shaft 22. The fixed guide plate 42, the material guide plate 44, the guide connection part 46, and the first part are guided. It is configured to include a horizontal movement control unit (47).

The fixed guide plate 42 has an upper end of the shaft 22 with one end of the material 70 sliding on the sliding plate 12 of the tilting device 10 being guided to the hill 22a of the shaft 22. In order to support the material guide plate 44 on which one side of the material 70 is guided through the guide connection part 46, the one side and the other side of the inclined part 32 of the support frame 30 are transferred. It is installed perpendicular to the longitudinal direction.

The material guide plate 44 is positioned on one side of the shaft 22 of the material transfer part 20 by sliding the material 70 supplied from the material supply part 105 through the tilting device 10. When the shaft 22 is rotated by the 24, the raw material 70 is guided to the ridge 22a of the shaft 22 and slides on the outer surface of the shaft 22 to the upper end of the shaft 22. When the shaft 22 is rotated, it is provided to be conveyed at a predetermined distance perpendicular to the longitudinal direction of the shaft 22 at the side of the shaft 22 so as not to be disturbed.

Thus, when the shaft 22 is rotated by the drive device 24, one end of the material 70 is guided to the hill 22a of the shaft 22, and one side of the material 70 is guide assembly 40. Guided to the material guide plate 44 of the), is to be transferred to the upper end of the shaft 22 while sliding to the side of the shaft (22).

Guide connecting portion 46 is one end of the penetrating through one side of the fixed guide plate 42, the other end is connected to one side of the material guide plate 44.

Thus, the material guide plate 44 is supported by the fixed guide plate 42 through the guide connecting portion 46.

And the first horizontal movement control unit 47 is provided at the lower end of one side of the fixed guide plate 42 to adjust the gap of the material guide plate 44 in accordance with the size of the material 70.

The first horizontal movement adjusting unit 47 includes a first horizontal movement adjusting bar 48 and a first handle 49. First, the first horizontal movement adjusting bar 48 is formed of the support frame 30. It is configured to penetrate the lower end of one side of the fixed guide plate 42 is installed on one side and the other side of the inclined portion (32).

That is, one side of the first horizontal movement control bar 48 passes through the lower end of one side of the fixed guide plate 42 installed on one side of the inclined portion 32 of the support frame 30, the first horizontal movement The other side of the adjustment bar 48 is to penetrate the lower end of one side of the fixed guide plate 42 installed on the other side of the inclined portion 32 of the support frame 30.

The first handle 49 is installed at one side and the other side of the first horizontal movement adjusting bar 48, and the fixed guide plate 42 is fixed to the first horizontal movement adjusting bar 48 by the rotation of the first handle 49. ) Is supported and flows to the left and right, the fixed guide plate 42 is moved to the left and right at the same time the gap of the material guide plate 44 connected to the other end of the guide connecting portion 46 is adjusted.

When the material 70 supplied through the material supply part 105 and the tilting device 10 is positioned at a predetermined portion of the side surface of the shaft 22 rotated by the driving device 24 as described above, the support frame 30 One end of the material 70 is guided to the peak portion 22a formed on the shaft 22 by the inclined portion 32 of the material, and both side surfaces of the material 70 are guide plates of the guide assembly 40. Guided by 44 is conveyed to the upper end of the shaft (22).

At this time, a part of the material 70 which is not aligned in the longitudinal direction of the material 70 guided to the ridge 22a of the shaft 22 connected to be inclined to the inclined portion 32 of the support frame 30 is a predetermined angle. The mountain 22a positioned at the lower end of the mountain 22a which guided the material 70 while moving from the mountain 22a of the shaft 22 toward the lower end of the shaft 22 by the shaft 22 inclined by the furnace 22. Guided in the longitudinal direction).

The guide chute 50 is the side conveying device (not shown) via a flat feeder 200 which describes the material 70 which is conveyed to the upper end of the shaft 22 of the material conveying part 20 by the guide assembly 40. ) And to be installed at the upper end of the material transfer part 20 to align in the longitudinal direction some of the material 70 is not aligned in the longitudinal direction of the material 70 transferred from the material transfer unit 20, chute 52, the sliding guide portion 56, the chute connecting portion 58 and the second horizontal movement control unit 60 is configured to include.

The chute 52 includes a sliding part 53 and a bent part 54. First, the sliding part 53 is not aligned in the longitudinal direction of the material 70 transferred from the material transfer part 20. Some of the material 70 is dropped from the upper end of the shaft 22 of the material conveying part 20 to one surface of the sliding part 53 while being aligned and sliding in the longitudinal direction of the shaft 22 of the material conveying part 20. In the upper end portion is provided to be inclined downward at the position where the material 70 falls.

The bent part 54 is for supporting the sliding guide part 56 and is vertically installed at one side and the other side of the sliding part 53.

The sliding guide 56 is for guiding the material 70 sliding from the sliding part 53 so as not to be separated to the outside. The sliding guide part 56 of the sliding part 53 is guided so that both sides of the material 70 are guided. On one side and the other side of one surface is installed perpendicular to the longitudinal direction of the sliding portion 53 of the chute (52).

One end of the sliding guide 56 is connected to the upper end of the material guide plate 44 of the guide assembly 40 so that the sliding guide 56 is fixed to the upper end of the material conveying part 20.

Thus, when the material 70 falling from the material transfer part 20 on one surface of the sliding part 53 of the chute 52 is slid from the sliding part 53, the sliding guide part 56 causes the The material 70 is guided so that it does not escape to the outside.

The chute connecting part 58 supports the sliding guide part 56, one end of which penetrates the bent part 54 of the chute 52, and the other end thereof is connected to the sliding guide part 56. The sliding guide part 56 is supported.

In addition, a second horizontal movement adjusting unit 60 is provided at the lower end of one side of the bent portion 54 to flexibly adjust the interval of the sliding guide part 56 according to the size of the material 70.

The second horizontal movement adjusting unit 60 includes a second horizontal movement adjusting bar 62 and a second handle 64. First, the second horizontal movement adjusting bar 62 is formed of the sliding part 53. It is configured to penetrate the lower end of one side of the bent portion 54 is installed on one side and the other side.

That is, one side of the second horizontal movement control bar 62 penetrates through the lower end of one side surface of the bent portion 54 provided on one side of the sliding portion 53, and the other side of the second horizontal movement control bar 62. The side penetrates the lower end of one side surface of the bent portion 54 provided at the other side of the sliding portion 53.

And the second handle 64 is provided on one side and the other side of the second horizontal movement control bar 62, the bent portion 54 to the second horizontal movement control bar 62 by the rotation of the second handle (64). Is supported and flows to the left and right, the bent portion 54 is moved to the left and right at the same time the interval of the sliding guide portion 56 connected to the other end of the chute connecting portion 58 is adjusted.

Thus, when the spacing of the material guide plate 44 of the guide assembly 40 is adjusted by the first horizontal movement adjusting unit 47, the spacing of the sliding guide 56 is connected to the upper end of the material guide plate 44 It is controlled by the second horizontal movement control unit 60.

As such, the material 70 transferred from the material transfer part 20 is slid to the chute 52 of the guide chute 50, and some of the material 70 which is not aligned in the longitudinal direction of the material 70 is chute 52. It is aligned and sliding in the longitudinal direction while falling to the), wherein the material 70 is configured to be guided by the sliding guide portion 56 so as not to be separated out.

The material 70 sliding in the chute 52 of the guide chute 50 is transferred to the side transfer device (not shown) by the flat feeder 200, the flat feeder 200 is the chute 52 In order to transfer the material 70 which is slid and dropped to the side conveying apparatus (not shown), it comprises a conveying belt 220 and the conveying roller 210.

The transfer belt 220 is installed at a position where the material 70 slides down from the chute 52.

The conveying roller 210 supports one side and the other side of the conveying belt 220, rotates in association with a motor (not shown), and the conveying belt 220 is circulated by the rotation of the conveying roller 210. The forging process is performed in which the material 70 falling from the chute 52 to the conveying belt 220 is heated to a high temperature through the side conveying apparatus (not shown) on the conveying belt 220.

In this way, the various shapes supplied from the material supplier, in particular, the square shape material 70 is aligned in the longitudinal direction through the tilting device 10, the material transfer part 20 and the guide chute 50, so that the material 102 It does not need to be aligned in the longitudinal direction one by one, it is possible to reduce the work time and work costs by not having to secondary processing a variety of shapes, in particular square-shaped material to the cylindrical again.

Hereinafter, with reference to the accompanying drawings will be described the operation of the forging material conveying apparatus according to a preferred embodiment of the present invention.

Figure 7 is a schematic front view showing the operating state of the forging material conveying apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 7, the forging material conveying apparatus for upwardly conveying the material 70 supplied from the material supply unit 105 (shown in FIG. 3) according to a preferred embodiment of the present invention to a side conveying apparatus (not shown) is the material. The material 70 supplied from the supply unit 105 (shown in FIG. 3) is dropped onto the sliding plate 12 (shown in FIG. 3) of the tilting device 10 (shown in FIG. 3), wherein some of the material 70 is in the longitudinal direction. Sorted by.

Then, the elevating device 16 connected to one end of the sliding plate 12 (shown in FIG. 3) so that the material 70 falling on the sliding plate 12 (shown in FIG. 3) is slid into the material transfer unit 20. 3), one end of the sliding plate 12 (shown in FIG. 3) is raised, and the material 70 falling on the sliding plate 12 (shown in FIG. 3) slides on the shaft 22 of the material transfer unit 20. do.

When the material 70 falling on the sliding plate 12 (shown in FIG. 3) is slid into the shaft 22 of the material transfer part 20, the shaft 22 supported by the inclined part 32 of the support frame 30 is supported. ) Is rotated by the drive device 24, the material 70 is slid to the shaft 22, one end is guided to the hill 22a formed in the shaft 22, both sides are predetermined in the shaft 22 It is guided to the material guide plate 44 (shown in FIG. 5) of the guide assembly 40 to be spaced apart and is moved to the upper side of the shaft 22 while sliding to the side surface of the shaft 22.

At this time, a part of the material 70 that is not aligned in the longitudinal direction of the material 70 guided to the mountain 22a of the shaft 22 is guided by the shaft 22 by the shaft 22 inclined at a predetermined angle. From the peak 22a of the shaft 22 to the lower end of the shaft 22, the guide is guided by the peak 22a positioned at the lower end of the peak 22a that guided the material 70 and aligned in the longitudinal direction. do.

And the first is provided at the bottom of one side of the fixed guide plate 42 (FIG. 5 shown) to flexibly adjust the interval of the pair of material guide plate 44 (Fig. 5) according to the size of the material 70 The fixed guide plate 42 (shown in FIG. 5) is moved by the first horizontal shift control bar (shown in FIG. 5) and the first handle 49 (shown in FIG. 5) of the horizontal shift control unit 47 (shown in FIG. 5). It flows from side to side, and at the same time the interval of the material guide plate 44 (shown in Figure 5) is connected to the other end of the guide connecting portion 46 (shown in Figure 5) is adjusted.

After the material 70 falling on the sliding plate 12 (shown in FIG. 3) is slid to the shaft 22 of the material transfer unit 20, the material guide plate 44 of the guide assembly 40 (shown in FIG. 5). When the material 70 is slid to the side surface of the shaft 22 and is transferred to the upper end of the shaft 22, the material 70 is dropped from the upper end of the shaft 22 of the material transfer part 20. It falls to the chute 52 (shown in FIG. 6) of the guide chute 50 provided in the position.

At this time, the material 70 is not aligned in the longitudinal direction of the material 70 is aligned in the longitudinal direction while falling from the upper end of the material transfer portion 20 to the chute 52 of the guide chute (50).

Since the chute 52 (shown in FIG. 6) of the guide chute 50 is inclined at a predetermined angle, the material 70 falling into the chute 52 (shown in FIG. 6) is slid, and the sliding guide part 56 6, both sides of the material 70 are guided smoothly in the chute 52 (shown in FIG. 6).

And a second horizontal movement adjusting part 60 (shown in FIG. 6) to adjust the distance between the sliding guide part 56 (shown in FIG. 6) according to the size of the material 70 guided by the sliding guide part 56 (shown in FIG. 6). By this, the interval of the sliding guide portion 56 (shown in Figure 6) is adjusted.

In addition, the material 70 sliding in the chute 52 (see FIG. 6) is transferred to the side conveying apparatus (not shown) by a flat feeder 200 composed of a conveying belt 220 and a conveying roller 210. do.

In this way, the material 70 supplied from the material supply unit 105 falls to the sliding plate 12 of the tilting device 10 (shown in FIG. 3), slides to the shaft 22 of the material transfer unit 20, and the material is The longitudinal direction is aligned while being guided to the peak 22a formed in the shaft 22 of the sending section 20 and transferred to the upper end of the shaft 22 and falling to the chute 52 of the guide chute 50. Some material 70 is not aligned in the longitudinal direction.

As described so far, the forging material feeder of the present invention has a merit of longitudinally aligning various shapes of materials supplied from a material supplier using a tilting device, a material feeder and a guide chute.

Although the present invention has been described in detail in the above embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended claims.

As described above, the forging material conveying apparatus according to the present invention, by using a material conveying unit that can be aligned in the longitudinal direction of the material of various shapes, the secondary processing of the material of various shapes supplied from the material supplier into a cylindrical shape Since it is not necessary, there is an effect that can reduce the work time and cost.

Claims (5)

In the forging material feeder for transferring a large amount of material to the side feeder, A cylindrical shaft installed in a longitudinal direction at a position where the material is supplied from the material supply unit, a driving device mounted on one end of the shaft to rotate the shaft, and the material supplied from the material supply unit to the shaft A material transfer part having a screw-shaped mount formed on an outer surface of the shaft such that the guide is guided and slides to an upper end of the shaft; A support frame connected to a predetermined portion of the shaft to support the shaft such that the shaft is inclined upward; And One end of the material supplied from the material supply part to the material conveying part is guided to the ridge of the material conveying part, and when the slide is conveyed to the upper end of the shaft, both sides of the material are guided so that the shaft at the side of the shaft A guide assembly including a pair of material guide plates having a predetermined spacing vertically and vertically spaced apart from each other; Forging material conveying apparatus, characterized in that comprises a. According to claim 1, wherein the material supply unit: In order for the material supplied from the material supply part to be aligned in the longitudinal direction and to be slid to the material transfer part, the sliding plate on which the material is seated, a hinge part mounted on one side of the sliding plate, and the hinge part as the axis And a tilting device having a lifting device connected to one end of the sliding plate such that the sliding plate is inclined toward the material transfer part and the material seated on the sliding plate is slid. . The method of claim 1, wherein the guide assembly is: And a first horizontal movement control unit connected to one side of the material guide plate to flexibly adjust the gap of the material guide plate according to the size of the material. The method of claim 1, And a guide chute inclined downward to slide down the material conveyed to the upper end of the shaft of the material conveying part by the side conveying apparatus. The method of claim 4, wherein the guide chute is: The material conveying part transfers the material falling from the material conveying part to the side conveying device so that some material which is not aligned in the longitudinal direction of the material falls from the upper end of the shaft of the material conveying part and is aligned in the longitudinal direction and slides. A chute including a sliding part provided to be inclined at a predetermined angle at a position at which the material falls at an upper end of the shaft of the chute; And When the material falling from the material transfer part is slid by the chute, in the longitudinal direction of the chute on one surface of the chute is located where the material is dropped from the material transfer part in order to guide the material not to escape to the outside A pair of sliding guides provided vertically and having a predetermined interval; Forging material conveying apparatus, characterized in that the configuration further comprises.

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