JP7281233B1 - Chip conveyor - Google Patents

Abstract

An object of the present invention is to provide a chip conveyor in which an opening can be opened while a side chain and a hinge belt are connected. A hinge belt (29) of a chip conveyor (28) has a belt body (30) and an opening/closing part (60). The opening/closing unit 60 has a door 50 that can open and close an opening, a frame W that defines the opening, and bolts 49 for attaching the door 50 to the frame W. The door 50 has a plurality of door hinge plates 51 and connection plates 58 that protrude from both ends of the door hinge plate 51 in the width direction Y and are connected to the frame W. The frame W has a first frame forming plate 61 and a second frame forming plate 64 that are connected in the longitudinal direction X. As shown in FIG. The frame W has a nut 48 . The bolt 49 attaches the connecting plate 58 to the nut 48 of the frame W so as to be detachable. [Selection drawing] Fig. 4

Description

TECHNICAL FIELD The present invention relates to a chip conveyor for conveying chips discharged from a machine tool.

Conventionally, a chip conveyor is mounted on a chip collection device that conveys chips discharged from a machine tool.
The endless chip conveyor has a hinge belt having a plurality of hinge plates interconnected by hinges, and side chains attached to both sides of the hinge belt in the width direction. The width direction of the hinge belt is the lateral direction of the hinge belt and the direction orthogonal to the longitudinal direction of the hinge belt.

Hinge plates adjacent to each other in the longitudinal direction of the hinge belt are connected by hinges. Hinge plates adjacent to each other in the longitudinal direction of the hinge belt can be bent around the hinge. The hinge belt has side plates on both sides in the width direction. The side chains are mounted outside the side plates in the width direction. The chip collector also has a frame that covers the side chain to protect the side chain.

The side chain of the chip conveyor is suspended between the sprockets of the scrap collector. The orbit of the sidechain causes the chip conveyor to orbit. The side plates keep debris carried by the hinge belt from spilling off the hinge belt.

In such a chip conveyor, an operation is performed to remove cutting waste accumulated on the back side of the chip conveyor. Patent Literature 1 discloses a hinge-belt conveyor that enables chip removal.

The hinge belt type conveyor of Patent Document 1 has endless side chains facing each other and a hinge belt positioned between the side chains. The hinge belt is composed of a first hinge belt and a second hinge belt. Each of the first hinge belt and the second hinge belt is hingedly connected by a belt pin. The second hinge belt is attached to the side chain by mounting bolts. By attaching and detaching the mounting bolt, the second hinge belt can be detached from the side chain. Therefore, the second hinge belt can be removed from the side chain in an endless state without cutting the side chain. Removal of the second hinge belt opens an opening in the hinge belt. This opening is used to remove chips.

JP-A-2004-83163

In the hinge belt type conveyor of Patent Document 1, the second hinge plate is attached to the side chain. Therefore, in order to open the opening, it is necessary to remove the mounting bolt from the side chain and remove the second hinge plate from the side chain.

A chip conveyor for solving the above problems has an endless hinge belt and endless side chains mounted on both sides in the width direction of the hinge belt, and the conveying surface of the hinge belt that rotates. In the chip conveyor for conveying chips by means of the The opening/closing unit has a frame that defines an opening that opens onto the conveying surface, a door that opens and closes the opening, and a mounting member that mounts the door to the frame. are a plurality of door hinge plates connected in the longitudinal direction by hinges, integral with the door hinge plate, protruding from both ends of the door hinge plate in the width direction and connected to the frame. and a connecting plate that defines the opening from both sides of the opening in the longitudinal direction and both sides of the opening in the width direction, and is connected in the longitudinal direction by a hinge. and connecting portions provided on both sides of the opening in the width direction for connecting the connecting plates, wherein the mounting member connects the connecting plates to the frame portion. is detachably attached to the connecting portion of the.

Regarding the chip conveyor, the connection plate may be provided over the entire length of the door hinge plate in the width direction.
For the chip conveyor, the door may be removable from the frame.

Regarding the chip conveyor, the opening/closing part may be formed by unitizing the frame part and the door, and the opening/closing part may be detachable from the belt body.

According to the present invention, the opening can be opened while the side chain and the hinge belt are connected.

1 is a perspective view showing a chip collecting device of an embodiment; FIG. It is a side view which shows the chip collection|recovery apparatus of embodiment. 3 is a cross-sectional view along line 3-3 of FIG. 2 showing the chip conveyor and lower horizontal frame; FIG. It is a partial plan view showing a hinge belt. It is a perspective view which shows an opening-and-closing part. FIG. 4 is an exploded perspective view showing constituent elements of the opening/closing part; It is the figure which removed the door from the frame part. It is a partial perspective view which shows the state which opened the opening part.

An embodiment in which a chip conveyor is mounted on a chip collecting device will be described below with reference to FIGS. 1 to 8. FIG.
<Cutting Waste Collection Device 11>
As shown in FIGS. 1 and 2, the chip collecting device 11 is arranged near a machine tool 12 such as a lathe. Note that FIG. 1 schematically shows the chip conveyor 28 in order to show the entire chip collecting device 11 . The shooter 13 is arranged in front of the machine tool 12 . The shooter 13 discharges cutting waste K generated by the machine tool 12 forward. The support base 14 is arranged directly below the shooter 13 .

The chip collection device 11 is supported by a support base 14 arranged on the installation surface S. As shown in FIG. A direction orthogonal to the installation surface S is defined as a vertical direction Z. As shown in FIG.
The chip collection device 11 has a frame 19 and a chip conveyor 28 .

The chip conveyor 28 has a hinge belt 29 which will be detailed later. The hinge belt 29 has a conveying surface 29a for cutting chips K and an opposite surface 29b opposite to the conveying surface 29a. A longitudinal direction X is a direction in which the chip conveyor 28 extends along the conveying surface 29a and the opposite surface 29b. A width direction Y is a direction orthogonal to the longitudinal direction X along the transport surface 29a and the opposite surface 29b.

<Frame 19>
The frame 19 has a cover 20 , a lower horizontal frame 21 , an inclined frame 22 and an upper horizontal frame 23 . The lower horizontal frame 21 sandwiches the chip conveyor 28 from both sides in the width direction Y. As shown in FIG. Inclined frame 22 and upper horizontal frame 23 surround chip conveyor 28 .

The lower horizontal frame 21 is supported by the support base 14 . The lower horizontal frame 21 is arranged directly below the shooter 13 . The lower horizontal frame 21 has a box shape with an open upper surface and a closed lower surface. The inclined frame 22 is in the shape of a square tube that is open at both ends in the longitudinal direction X. As shown in FIG. The upper horizontal frame 23 is in the shape of a square tube with the end opposite to the end connected to the inclined frame 22 closed.

The lower horizontal frame 21 has a first end 21a at one end in the longitudinal direction X and a second end 21b at the other end in the longitudinal direction X. As shown in FIG. The cover 20 is connected to the first end 21 a of the lower horizontal frame 21 . The inclined frame 22 is connected to the second end 21b of the lower horizontal frame 21 . The inclined frame 22 rises obliquely upward from the second end 21b of the lower horizontal frame 21 . The upper horizontal frame 23 is connected to the upper end of the inclined frame 22 .

As shown in FIG. 3 , each of the lower horizontal frame 21 , the tilt frame 22 and the upper horizontal frame 23 has a bottom plate 31 and a pair of guide rails 32 . Each of the lengths of the bottom plate 31 and the guide rail 32 extends in the longitudinal direction X. As shown in FIG. 3 shows the lower horizontal frame 21. As shown in FIG.

One of the pair of guide rails 32 is joined to one end in the width direction Y of the bottom plate 31 , and the other of the pair of guide rails 32 is joined to the other end in the width direction Y of the bottom plate 31 . Each guide rail 32 has a cross-hat shape when viewed in cross section along the vertical direction Z. As shown in FIG.

Each of the pair of guide rails 32 has a side plate 32a, a lower horizontal guide rail 32b, an upper horizontal guide rail 32c, and a cover portion 32d. The lower horizontal guide rail 32b extends in the width direction Y toward the chip conveyor 28 from the lower edge of the side plate 32a. The upper horizontal guide rail 32c extends in the width direction Y toward the chip conveyor 28 from the middle of the side plate 32a in the vertical direction Z. As shown in FIG. The cover portion 32d extends in the width direction Y from the upper edge of the side plate 32a.

The pair of guide rails 32 face each other in the width direction Y. As shown in FIG. The pair of lower horizontal guide rails 32b are opposed in the width direction Y, and the pair of upper horizontal guide rails 32c are opposed in the width direction Y. As shown in FIG. Also, the pair of cover portions 32d face each other in the width direction Y. As shown in FIG.

As shown in FIG. 2 , the frame 19 has a fixed support shaft 24 , a driven sprocket wheel 25 , a movable support shaft 26 and a drive sprocket wheel 27 .
A fixed support shaft 24 and a driven sprocket wheel 25 are arranged on the cover 20 . The axis of the fixed support shaft 24 extends in the width direction Y. As shown in FIG. The driven sprocket wheel 25 is supported on both ends of the fixed support shaft 24 in the axial direction. A movable support shaft 26 and a drive sprocket wheel 27 are arranged on the upper horizontal frame 23 . The axis of the movable support shaft 26 extends in the width direction Y. As shown in FIG. The drive sprocket wheel 27 is supported on both ends of the movable support shaft 26 in the axial direction.

A side chain 36 of the chip conveyor 28 is attached to the driving sprocket wheel 27 and the driven sprocket wheel 25 .
<Chip conveyor 28>
The chip conveyor 28 is endless. The chip conveyor 28 can circulate in the circulating direction R. As shown in FIG. A drive mechanism (not shown) is attached to the upper horizontal frame 23 . A drive mechanism (not shown) has a motor, a belt, and the like. A drive mechanism (not shown) rotates the movable support shaft 26 and the drive sprocket wheel 27 to rotate the chip conveyor 28 .

As shown in FIG. 4, the chip conveyor 28 has an endless hinge belt 29 and endless side chains 36 attached to both sides of the hinge belt 29 in the width direction Y. As shown in FIG. The chip conveyor 28 conveys the chips K by the conveying surface 29a of the hinge belt 29 that rotates.

<Hinge belt 29>
The hinge belt 29 has a belt body 30 and an opening/closing portion 60 which is a part of the hinge belt 29 in the longitudinal direction and is connected to the belt body 30 by a hinge H1. In addition, in FIG. 1 , the opening/closing portion 60 is hatched in order to distinguish between the opening/closing portion 60 and the belt body 30 .

<Belt body 30>
The belt body 30 is a portion of the hinge belt 29 other than the opening/closing portion 60 . A first end of the belt body 30 in the longitudinal direction X is connected to a first end of the opening/closing portion 60 in the longitudinal direction X, and a second end of the belt body 30 in the longitudinal direction X is connected to the opening/closing portion 60 in the longitudinal direction X. is connected to the second end of the

As shown in FIG. 4, the belt body 30 has a large number of hinge plates 37, a large number of connecting shafts 38, and side plates 39 that are connected to each other by hinges H1.
All of the multiple hinge plates 37 have the same configuration. The hinge plate 37 has an elongated plate shape. Let L be the length of the hinge plate 37 in the longitudinal direction. Hinge plate 37 has a pair of long side edges 37b. The pair of long side edges 37b are parallel. Each of the pair of long side edges 37b of the hinge plate 37 is provided with a plurality of bushings 37a. The number of bushings 37a is the same for the two long side edges 37b. The bushing portion 37a is cylindrical. The length of the shaft bearing portion 37a in the direction in which the center axis extends is referred to as the axial length of the shaft bearing portion 37a.

At each long side edge 37b, the plurality of bearing sleeve portions 37a are arranged at regular intervals with a gap corresponding to the axial length of the bearing sleeve portion 37a. The bearing tube portion 37a arranged on one long side edge 37b and the bearing tube portion 37a arranged on the other long side edge 37b do not face each other in the lateral direction of the hinge plate 37. As shown in FIG.

Each of the many connecting shafts 38 connects the hinge plates 37 adjacent to each other in the longitudinal direction X. As shown in FIG. The connecting shaft 38 is inserted into the bushing portion 37a of the hinge plate 37 on the leading side in the circumferential direction R and the bushing portion 37a of the hinge plate 37 on the trailing side in the circumferential direction R. A hinge H1 is formed by inserting the connecting shaft 38 into the bushing portion 37a. The hinge plates 37 adjacent to each other in the longitudinal direction X are connected by a hinge H1 and are connected so as to be bendable around the hinge H1. Therefore, the hinge belt 29 can be bent by the hinge H1.

As shown in FIG. 3 , the side plates 39 are arranged at both ends in the width direction Y of each hinge plate 37 . Each side plate 39 is attached to the belt body 30 using a connecting shaft 38 inserted into the bushing portion 37a. Each side plate 39 has a shaft hole 39a at its lower end. A connecting shaft 38 is inserted through each shaft hole 39a.

<Side chain 36>
As shown in FIGS. 3 and 4 , each of the pair of side chains 36 has multiple connecting links 40 and multiple rollers 41 . Rollers 41 are connected to both ends of each connecting shaft 38 in the axial direction. Each connecting link 40 is arranged outside the rollers 41 in the width direction Y. As shown in FIG. Each connecting link 40 connects adjacent connecting shafts 38 in the longitudinal direction X. As shown in FIG. At the end of each connecting shaft 38, a retaining projection 38a is formed by pressing. The retaining protrusion 38a prevents the connecting link 40 from coming off. The method of connecting the connecting shafts 38 by the connecting link 40 may be changed as appropriate. The side chain 36 is formed endlessly by connecting the connecting shaft 38 in the longitudinal direction X with a plurality of connecting links 40 .

Each of the pair of side chains 36 is supported on both sides of the hinge belt 29 in the width direction Y by the driven sprocket wheel 25 and the driving sprocket wheel 27 . The side chain 36 has two stages, a portion passing over the driven sprocket wheel 25 and the driving sprocket wheel 27 and a portion passing under the driven sprocket wheel 25 .

As shown in FIG. 3, the lower rollers 41 are supported on the upper surface of the lower horizontal guide rail 32b. The upper roller 41 is supported on the upper surface of the upper horizontal guide rail 32c. Each side chain 36 is covered from the upper side in the vertical direction Z by the cover portion 32d, and is covered from the lower side in the vertical direction Z by the lower horizontal guide rail 32b. Each side chain 36 is covered from the outside in the width direction Y by the side plate 32a. Each side chain 36 is therefore covered by the lower horizontal frame 21 .

Also, the hinge belt 29 is connected to the side chain 36 by a connecting shaft 38 . Therefore, the hinge belt 29 has two stages, an upper stage portion 29A passing above the driven sprocket wheel 25 and the driving sprocket wheel 27 and a lower stage portion 29B passing below the driven sprocket wheel 25 and the driving sprocket wheel 27. becomes. The winding direction R of the upper stage portion 29A and the winding direction R of the lower stage portion 29B are opposite to each other.

<Opening and closing part 60>
As shown in FIGS. 4 and 8, the opening/closing portion 60 is provided in a part of the hinge belt 29 in the longitudinal direction X. As shown in FIGS.

The opening/closing unit 60 includes a frame W that defines an opening T that opens to the conveying surface 29a, a door 50 that can open and close the opening T, and bolts 49 that serve as mounting members for mounting the door 50 to the frame W. and have

<Frame W>
First, the frame portion W will be described.
The frame portion W is a frame-shaped portion surrounding the opening T in the hinge belt 29 . The frame portion W is provided on a part of the hinge belt 29 in the longitudinal direction X. As shown in FIG. The frame W defines an opening T that opens onto the transport surface 29a. When the opening T is positioned in the upper part 29A of the hinge belt 29, the lower part 29B, which is the back side of the hinge belt 29, can be seen through the opening T. As shown in FIG. At this time, the opposite surface 29b of the lower part 29B faces the opening T. As shown in FIG.

The frame W has a plurality of frame-forming plates connected in the longitudinal direction X by hinges H2. The frame forming plates are a pair of first frame forming plates 61 and six second frame forming plates 64 .

<First frame forming plate 61>
As shown in FIGS. 4, 5, 6, and 7, each of the first frame forming plates 61 has a long plate shape. The pair of first frame forming plates 61 have the same configuration. The longitudinal dimension of the first frame forming plate 61 is the same as the longitudinal dimension of the hinge plate 37 .

The first frame forming plate 61 has a long plate-like plate body 62 and a plurality of bushings 63 . The plate main body 62 is rectangular plate-shaped. The plate body 62 has a first long side edge 62a and a second long side edge 62b. The first long side edge 62a and the second long side edge 62b are parallel. The plate body 62 also has a first short side edge 62c and a second short side edge 62d. The first short side edge 62c and the second short side edge 62d are parallel.

The length of the plate body 62 in the longitudinal direction is referred to as a first length L1. This first length L1 is the same as the length L of the hinge plate 37 . Further, the axial length of the bearing tube portion 63 is defined as the axial length.

Six bearing cylinder portions 63 are provided on the first long side edge 62a. The six bearing sleeve portions 63 are provided on the first long side edge 62a from the first short side edge 62c toward the second short side edge 62d with an axial length of one bearing sleeve portion 63 spaced therebetween. The six bearing sleeve portions 63 are arranged at equal intervals with the axial length of the bearing sleeve portion 63 spaced apart. Each of the bearing cylinder portions 63 provided on the first long side edge 62a is open at both ends in the axial direction.

The two bearing sleeve portions 63 provided on the second long side edge 62b may be referred to as a first bearing sleeve portion 63a and a second bearing sleeve portion 63b. The first bearing sleeve portion 63a is provided so as to extend from the first short side edge 62c toward the second short side edge 62d. The second bearing tube portion 63b is provided on the second long side edge 62b with an axial length of one bearing tube portion 63 spaced from the second short side edge 62d. Of the two ends in the axial direction of the second bearing cylinder portion 63b, the end surface located inside in the width direction Y is closed by the closing portion 63c. Both axial ends of the first bushing portion 63a are open. The bearing tube portion 63 provided on the first long side edge 62 a and the bearing tube portion 63 provided on the second long side edge 62 b do not face each other in the lateral direction of the plate body 62 .

The plate body 62 is provided with three through holes 62e. Each of the three through-holes 62e opens on both sides of the plate body 62 in the plate thickness direction. The three through-holes 62e are opened at regular intervals in the longitudinal direction of the plate body 62 . The shaft portion 49a of the bolt 49 can be inserted through the through hole 62e. The bolt 49 has a shaft portion 49a and a head portion 49b. A hexagonal hole 49c is opened in the end face of the head 49b.

<Second frame forming plate 64>
The multiple second frame forming plates 64 have the same configuration. The second frame forming plate 64 has a long plate-like plate main body 65 and two bushings 66 . The plate main body 65 is rectangular plate-shaped. The plate body 65 has a first long side edge 65a and a second long side edge 65b. The first long side edge 65a and the second long side edge 65b are parallel. Also, the plate body 65 has a first short side edge 65c and a second short side edge 65d. The first short side edge 65c and the second short side edge 65d are parallel. The second frame forming plate 64 is arranged with the first short side edge 65c directed inward in the width direction Y. As shown in FIG. The length of the plate body 65 in the longitudinal direction is referred to as a second length L2.

One bushing portion 66 is provided on the first long side edge 65a. The bearing tube portion 66 is provided along the first long side edge 65a from the first short side edge 65c. Of the two ends in the axial direction of the bearing tube portion 66 provided on the first long side edge 65a, the end surface located near the first short side edge 65c is closed by a closing portion 66c. One bushing portion 66 is provided on the second long side edge 65b. The bearing tube portion 66 is provided along the second long side edge 65b from the second short side edge 65d. The bearing tube portion 66 provided on the first long side edge 65 a and the bearing tube portion 66 provided on the second long side edge 65 b do not face each other in the lateral direction of the plate body 65 .

The plate body 65 is provided with one through hole 65e. The through holes 65e are opened on both sides of the plate body 65 in the plate thickness direction. The through hole 65e is located closer to the first short side edge 65c than to the second short side edge 65d. A nut 48 is joined to one side of the plate body 65 in the plate thickness direction. The nut 48 communicates with the through hole 65e. A shaft portion 49 a of the bolt 49 inserted through the through hole 65 e can be screwed onto the nut 48 . The nut 48 functions as a connecting portion for connecting the door 50 to the frame portion W. As shown in FIG.

The frame portion W is formed by connecting the pair of first frame forming plates 61 and the six second frame forming plates 64 with hinges H2.
A second frame forming plate 64 is connected to both ends of the first frame forming plate 61 in the longitudinal direction. The second frame forming plate 64 at one end in the longitudinal direction of the first frame forming plate 61 and the second frame forming plate 64 at the other end of the first frame forming plate 61 are arranged so that the first short side edges 65c face the inner side in the width direction Y. It is rotated 180 degrees and used.

Therefore, the second frame forming plate 64 at one end in the longitudinal direction of the first frame forming plate 61 is arranged with the first long side edge 65a opposed to the second long side edge 62b of the first frame forming plate 61. there is The second frame forming plate 64 at the other end in the longitudinal direction of the first frame forming plate 61 is arranged with the second long side edge 65b facing the second long side edge 62b of the first frame forming plate 61 . .

A frame connecting shaft 69 is inserted into the bearing tube portion 63 provided on the second long side edge 62b of the first frame forming plate 61 and the bearing tube portion 66 provided on the second frame forming plate 64. there is A hinge H2 is thus formed. The first frame forming plate 61 and the second frame forming plate 64 are connected by the hinge H2.

Each of the second frame forming plates 64 connected to the first frame forming plate 61 is connected to another second frame forming plate 64 . The second frame forming plates 64 are arranged with the first long side edge 65a and the second long side edge 65b facing each other. The bearing tube portion 66 provided on the first long side edge 65a of one second frame forming plate 64 and the bearing tube portion 66 provided on the second long side edge 65b of the other second frame forming plate 64 , the frame connecting shaft 69 is inserted. A hinge H2 is thus formed. The hinge H2 connects the second frame forming plates 64 to each other.

The opening T is defined in a square shape by the second long side edges 62 b of the pair of first frame forming plates 61 and the first short side edges 65 c of the plurality of second frame forming plates 64 . As a result, the frame W defines the opening T from both sides of the opening T in the longitudinal direction X and from both sides of the opening T in the width direction Y. As shown in FIG.

The through holes 65e and the nuts 48 of each second frame forming plate 64 are provided on both sides of the opening T in the width direction Y. As shown in FIG. The through hole 65e and the nut 48 are arranged at positions sandwiching the opening T from both sides in the width direction Y. As shown in FIG. Therefore, the nuts 48 as connecting portions are provided on both sides of the opening T in the width direction Y. As shown in FIG.

In addition, in the opening/closing portion 60 , the side plate 39 is arranged outside the second frame forming plate 64 in the width direction Y. As shown in FIG.
The frame portion W is connected to the belt body 30 by connecting each first frame forming plate 61 to the hinge plate 37 . Each of the first frame forming plates 61 is arranged with a first long side edge 62 a facing the long side edge 37 b of the hinge plate 37 . A connecting shaft 38 is inserted into the bushing portion 37a of the hinge plate 37 and the bushing portion 63 of the first long side edge 62a to form a hinge H1. The hinge H1 connects the hinge plate 37 and the first frame forming plate 61 . That is, the hinge belt 29 and the first frame forming plate 61 are connected.

<Female screw plate 67>
The frame W may have a female screw plate 67 . The female screw plate 67 has a long plate shape. Female screws 68 are formed at three locations on the female screw plate 67 . The female screw 68 opens on both sides of the female screw plate 67 in the plate thickness direction.

The female screw plate 67 is joined to one side of the first frame forming plate 61 in the plate thickness direction. The female screw plate 67 is arranged on the opposite surface 29 b side of the hinge belt 29 . The female screw 68 of the female screw plate 67 and the through hole 62e of the first frame forming plate 61 communicate in the plate thickness direction.

<Door 50>
The door 50 has a door hinge plate 51 , a connecting plate 58 , and a door connecting shaft 56 . The door hinge plate 51 is connected in the longitudinal direction X by a hinge H3. The connection plate 58 is integral with the door hinge plate 51 , protrudes from both ends of the door hinge plate 51 in the width direction Y, and is connected to the frame W.

<Door Hinge Plate 51>
The door hinge plate 51 has a long plate-like plate body 52 and a plurality of bushings 53 . The plate main body 52 is rectangular plate-shaped. The plate body 52 has a first long side edge 52a and a second long side edge 52b. The first long side edge 52a and the second long side edge 52b are parallel. The plate body 52 also has a first short side edge 52c and a second short side edge 52d. The first short side edge 52c and the second short side edge 52d are parallel. The length of the door hinge plate 51 in the longitudinal direction of the plate body 52 is referred to as a third length L3. The first length L1 of the first frame forming plate 61 is substantially equal to the sum of the third length L3 of the door hinge plate 51 and twice the second length L2 of the second frame forming plate 64. is. Therefore, it can be said that one hinge plate 37 is formed by one door hinge plate 51 and two second frame forming plates 64 .

Four bearing sleeve portions 53 are provided on each of the first long side edge 52a and the second long side edge 52b. The four bearing sleeve portions 53 provided on the first long side edge 52a are arranged at equal intervals from the second short side edge 52d toward the first short side edge 52c with the axial length of the bearing sleeve portion 53 spaced therebetween. It is Of the bushing portions 53 of the first long side edge 52a, the bushing portion 53 closest to the second short side edge 52d is referred to as a first bushing portion 53A. The first bushing portion 53A opens at both ends in the axial direction.

The four bearing sleeve portions 53 provided on the second long side edge 52b are arranged at equal intervals from the first short side edge 52c toward the second short side edge 52d with the axial length of the bearing sleeve portion 53 spaced therebetween. It is Of the bearing sleeve portions 53 of the second long side edge 52b, the bearing sleeve portion 53 closest to the second short side edge 52d is referred to as a second bearing sleeve portion 53B. The second bearing sleeve portion 53B has a closed portion 53c at one end in the axial direction. The closing portion 53c is provided on an end face near the first short side edge 52c of both ends in the axial direction of the second bushing portion 53B.

The bearing tube portion 53 provided on the first long side edge 52 a and the bearing tube portion 53 provided on the second long side edge 52 b do not face each other in the lateral direction of the plate body 52 .
The door hinge plates 51 adjacent in the longitudinal direction X are arranged such that the first long side edge 52a of one door hinge plate 51 and the second long side edge 52b of the other door hinge plate 51 face each other. ing. The bearing tube portion 53 provided on the first long side edge 52a of one of the door hinge plates 51 and the bearing tube portion 53 provided on the second long side edge 52b of the other door hinge plate 51 are: A door connecting shaft 56 is inserted. A hinge H<b>3 is formed by inserting the door connecting shaft 56 through the plurality of bushings 53 . The hinge H3 connects the door hinge plates 51 to each other.

<Connecting plate 58>
The connection plate 58 is rectangular plate-shaped. The connecting plate 58 has a first long side edge 58a and a second long side edge 58b. The first long side edge 58a and the second long side edge 58b are parallel. The length of the connecting plate 58 in the longitudinal direction is described as a fifth length L5. The fifth length L5 of the connecting plate 58 is longer than the third length L3 of the door hinge plate 51 .

Connection holes 59 are provided on both ends of the connection plate 58 in the longitudinal direction. The connecting holes 59 are open on both sides of the connecting plate 58 in the plate thickness direction. A shaft portion 49 a of the bolt 49 can be inserted through the connecting hole 59 .

The connecting plate 58 has a plurality of welding recesses 58c in a first long side edge 58a and a second long side edge 58b. The welding recess 58c is recessed in the lateral direction of the connecting plate 58 from the first long side edge 58a and the second long side edge 58b. The welding recess 58c penetrates the connecting plate 58 in the plate thickness direction.

The connecting plate 58 is welded to the plate body 52 of the door hinge plate 51 . The connecting plate 58 is provided over the entire length of the door hinge plate 51 in the width direction Y. As shown in FIG. The number of welding recesses 58c is arbitrary as long as the connecting plate 58 can be welded to the door hinge plate 51 using the welding recesses 58c.

The connecting plate 58 is welded to the plate body 52 using the welding recesses 58 c of the connecting plate 58 . One longitudinal end of the connecting plate 58 protrudes from the first short side edge 52 c of the door hinge plate 51 , and the other longitudinal end of the connecting plate 58 protrudes from the second short side edge of the door hinge plate 51 . It protrudes from 52d. Therefore, one of the pair of connecting holes 59 is arranged at a position protruding from the first short side edge 52c of the door hinge plate 51, and the other of the pair of connecting holes 59 is located on the door hinge plate. 51 at a position protruding from the second short side edge 52d.

<Fixing plate 70>
Door 50 may have fixing plate 70 .
The fixing plate 70 has a long plate-like plate body 71 and a plurality of bushings 72 . The plate main body 71 is rectangular plate-shaped. The plate body 71 has a first long side edge 71a and a second long side edge 71b. The first long side edge 71a and the second long side edge 71b are parallel. Also, the plate body 71 has a first short side edge 71c and a second short side edge 71d. The first short side edge 71c and the second short side edge 71d are parallel. The length of the fixing plate 70 in the longitudinal direction of the plate main body 71 is referred to as a fourth length L4. The fourth length L4 of the fixing plate 70 is substantially the same as the third length L3 of the door hinge plate 51 .

Four bearing cylinder portions 72 are provided on the second long side edge 71b. The four bearing sleeve portions 72 are arranged at regular intervals from the first short side edge 71c toward the second short side edge 71d.
The fixing plate 70 is arranged so as to be adjacent to the door hinge plate 51 in the longitudinal direction X. As shown in FIG. The fixing plate 70 and the door hinge plate 51 are arranged such that the second long side edge 71b of the fixing plate 70 and the first long side edge 52a of the door hinge plate 51 face each other. A door coupling shaft 56 is inserted through the bearing tube portion 72 provided on the fixing plate 70 and the bearing tube portion 53 provided on the door hinge plate 51 . A hinge H4 is thus formed. The hinge H4 connects the door hinge plate 51 and the fixing plate 70 together.

Three insertion holes 74 are provided in the fixing plate 70 . The insertion holes 74 are arranged at regular intervals in the longitudinal direction of the fixing plate 70 . The insertion holes 74 are open on both sides of the fixing plate 70 in the plate thickness direction. The shaft portion 49 a of the bolt 49 can be inserted through the insertion hole 74 .

<Installation of door 50>
The door 50 is attached to the frame W by connecting a pair of fixing plates 70 and a plurality of connecting plates 58 to the frame W with bolts 49 .

The shaft portion 49 a of the bolt 49 inserted through each insertion hole 74 of the fixing plate 70 passes through the through hole 62 e of the first frame forming plate 61 and is screwed into the female screw 68 of the female screw plate 67 . A shaft portion 49 a of the bolt 49 inserted through the connecting hole 59 of the connecting plate 58 passes through the through hole 65 e of the second frame forming plate 64 and is screwed to the nut 48 . The door 50 is attached to the frame W by these screws. The door 50 is arranged inside the frame W. As shown in FIG. The door 50 closes the opening T. As shown in FIG.

On both sides of the door 50 in the width direction Y, a plurality of second frame forming plates 64 forming the frame portion W are arranged. The door connecting shaft 56 of the door 50 is within the dimension of the width direction Y of the door 50 . The first frame forming plate 61 and the second frame forming plate 64 of the frame portion W, and the second frame forming plates 64 are connected by a frame connecting shaft 69 . That is, the door connecting shaft 56 that connects the door 50 and the frame connecting shaft 69 that connects the frame portion W are separated in the width direction Y. As shown in FIG. Therefore, the door 50 can be rotated independently of the frame W. That is, only the door 50 can be rotated within the dimension of the hinge belt 29 in the width direction Y.

There are two ways to open the opening T. In order to open the opening T, the opening/closing part 60 is arranged at an arbitrary position of the lower horizontal frame 21 .
In the first method, first, the bolt 49 inserted through each of the pair of fixing plates 70 is screwed out from the female screw 68 to remove both fixing plates 70 from the first frame forming plate 61 . Next, the bolts 49 inserted through all the connecting plates 58 are screwed out from the nuts 48 to remove all the connecting plates 58 from the second frame forming plate 64 .

The door 50 is removed from the frame W as shown in FIG. Then, the opening T is opened.
In the second method, first, the bolt 49 inserted through one of the pair of fixing plates 70 is screwed away from the female screw 68 to remove the one fixing plate 70 from the first frame forming plate 61. Remove. At this time, the other fixing plate 70 remains fixed to the first frame forming plate 61 with the bolts 49 . Next, the bolts 49 inserted through all the connecting plates 58 are screwed out from the nuts 48 to remove all the connecting plates 58 from the second frame forming plate 64 . Then, the door 50 is rotated in the direction away from the chip conveyor 28 with the door connecting shaft 56 connecting the other fixing plate 70 and the first frame forming plate 61 as the center of rotation.

As shown in FIG. 8, the opening T opens.
As described above, the bolt 49 attaches the connecting plate 58 to the nut 48 of the frame W so as to be detachable.

The frame portion W can be removed from the belt body 30 by separating the first frame forming plates 61 from the hinge plate 37 . By attaching the door 50 to the frame portion W, the frame portion W and the door 50 are unitized to form the opening/closing portion 60 .

The unitized opening/closing part 60 can be connected to the belt body 30 by connecting each first frame forming plate 61 of the frame part W to the hinge plate 37 and connecting to the belt body 30 . Therefore, the unitized opening/closing part 60 is attachable to and detachable from the belt body 30 .

<Action of Embodiment>
The chip conveyor 28 conveys the chips K dropped from the shooter 13 onto the conveying surface 29a. Some of the cutting waste K falls from the upper step portion 29A to the lower step portion 29B of the hinge belt 29 from between the adjacent hinge plates 37 and between the adjacent side plates 39 . Therefore, cutting waste K accumulates on the opposite surface 29b of the lower step portion 29B. When removing the accumulated cutting waste K, the operator positions the opening/closing part 60 at an arbitrary position on the lower horizontal frame 21 . Next, the operator opens the opening T by operating the door 50 by one of the two methods described above. Then, the operator removes the shavings K from the opening T. As shown in FIG.

According to the above embodiment, the following effects can be obtained.
(1) Remove the bolts 49 from at least one of the fixing plate 70 and the frame W to perform the work of removing the cutting waste K. Then, the connection of the door 50 to the frame portion W by the fixing plate 70 and the connection plate 58 is released, so that the opening portion T can be opened by the door 50 . Since the bolt 49 is removed from the frame W at this time, the bolt 49 is not removed from the side chain 36 . That is, the opening T can be opened while the side chain 36 and the hinge belt 29 are connected. The opening T is defined inside both ends of the hinge belt 29 in the width direction Y by the frame W. As shown in FIG. Therefore, the opening T can be opened inside both ends of the hinge belt 29 in the width direction Y. As shown in FIG. As a result, it is not necessary to remove the hinge plate 37 from the side chain 36 when opening the opening T to remove the shavings K. The hinge plate 37 is a member extending in the entire width direction Y of the hinge belt 29 . Therefore, it is not necessary to remove the guide rail 32 from the bottom plate 31 of the lower horizontal frame 21 for example to remove the hinge plate 37 .

Here, if the guide rail 32 is removed from the bottom plate 31 of the lower horizontal frame 21 in order to remove the cutting waste K, a space for moving the guide rail 32 in the width direction Y is required. However, it is difficult to secure a space for moving the guide rail 32 because other machines and the like are installed in the vicinity of the chip collection device 11 .

On the other hand, since the opening T of the chip conveyor 28 can be opened without removing the guide rail 32, the chip K can be removed even if there is no space for removing the guide rail 32. Also, the guide rail 32 can be removed only at a predetermined position of the lower horizontal frame 21 . Therefore, removal of the cutting waste K by removing the guide rail 32 can be performed only at a position where the guide rail 32 can be removed. However, since the opening T of the chip conveyor 28 can be opened without removing the guide rail 32 , the cutting scraps K can be removed at any position in the longitudinal direction X of the lower horizontal frame 21 .

In addition, since the chip conveyor 28 does not need to release the connection between the side chain 36 and the hinge belt 29 in order to remove the shavings K, the side chain 36 does not cause a rotation failure due to the release of the connection.

(2) The connecting plate 58 is provided over the entire length of the door hinge plate 51 in the width direction Y. As shown in FIG. The connecting plate 58 can reinforce the door hinge plate 51 over its entire length. Therefore, the connection plate 58 can suppress the bending of the door 50 in the width direction Y. As shown in FIG. Therefore, the connecting plate 58 has two functions: a function for connecting the door 50 to the frame W and a function for suppressing the bending of the door 50 . Therefore, the number of components of the chip conveyor 28 can be reduced as compared with the case where the door 50 is separately provided with plates having two functions.

(3) The door 50 is removable from the frame W. Therefore, when the door 50 is removed from the frame W, the entire opening T opens to the transport surface 29a. As a result, work such as removal of cutting waste K through the opening T can be easily performed.

(4) The opening/closing part 60 is formed by unitizing the frame part W and the door 50 . The opening/closing portion 60 is attachable/detachable to/from the belt body 30 . When the chip conveyor without the opening/closing part 60 is modified into a chip conveyor with the opening/closing part 60 , the unitized opening/closing part 60 may be connected to the belt body 30 . Therefore, the chip conveyor without the opening/closing part 60 can be easily modified into a chip conveyor with the opening/closing part 60 .

(5) A connection plate 58 is joined to the door hinge plate 51 . Both ends of the connecting plate 58 in the longitudinal direction are connected to the frame W by bolts 49 . Therefore, it is possible to suppress bending of both longitudinal ends of the door hinge plate 51 . As a result, it is possible to suppress the formation of gaps at the boundaries between both ends of the door 50 and the frame portion W in the width direction Y. Therefore, it is possible to suppress the cutting waste K from falling from the boundary between the door 50 and the frame W.

(6) The bolts 49 inserted through each of the pair of fixing plates 70 are screwed out from the internal threads 68 to remove both fixing plates 70 from the first frame forming plate 61 . Also, the bolts 49 inserted through all the connecting plates 58 are screwed out from the nuts 48 to remove all the connecting plates 58 from the second frame forming plate 64 . Then, the door 50 can be removed from the frame W. Therefore, the door 50 does not interfere with the work of removing the cutting waste K.

(7) By adjusting the third length L3 of the door hinge plate 51, the dimension of the door 50 in the width direction Y can be adjusted. The second length L2 of the plate body 65 is also adjusted so that the sum of the lengths of the door hinge plate 51 and the two second frame forming plates 64 is matched with the length L of the hinge plate 37 . In this way, the opening width of the opening T can be adjusted.

This embodiment can be implemented with the following modifications. This embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.
(circle) the frame part W may be fixed with respect to the belt main body 30 non-detachably. In this case, only the door 50 of the opening/closing part 60 is detachable from the frame W.

(circle) the connection plate 58 may be divided and provided in the longitudinal direction both sides of the hinge plate 51 for doors. In this case, each of the two connecting plates 58 may be joined to the plate body 52 of the door hinge plate 51 by welding, or may be fastened with bolts or screws.

O Three or more connecting plates 58 may be joined to the door hinge plate 51 . Each of the two connecting plates 58 is joined to both ends of the door hinge plate 51 in the longitudinal direction, and another connecting plate 58 is joined to the plate main body 52 between the two connecting plates 58. be done. The connecting plate 58 may be welded to the plate main body 52, or may be fastened with bolts or screws.

O The fixing plate 70 may be omitted. In this case, the door 50 is connected to the frame W only by the connecting plate 58 .
O One of the pair of fixing plates 70 may be omitted.

(circle) the number of the 2nd frame formation plates 64 which form the frame part W may be changed. If it is desired to increase the dimension of the opening T in the longitudinal direction X, the number of the second frame forming plates 64 is increased. If it is desired to reduce the dimension of the opening T in the longitudinal direction X, the number of second frame forming plates 64 is reduced.

(circle) the attachment member which attaches the connection plate 58 to the frame part W may not be the bolt 49 but a screw. In this case, the connecting portion becomes a press-fitting hole into which the screw is press-fitted.
(circle) although the connection part was formed by the nut 48 joined to the 2nd frame formation plate 64, while eliminating the nut 48, it is good also as a connection part by using the through-hole 65e as an internal thread.

T... Opening, X... Longitudinal direction, Y... Width direction, W... Frame part, 28... Chip conveyor, 29... Hinge belt, 29a... Conveying surface, 30... Belt main body, 36... Side chain, 48... As connecting part Nut 49 Bolt as mounting member 50 Door 51 Hinge plate for door 58 Connecting plate 60 Opening/closing portion 61 First frame forming plate 64 Second frame forming plate.

Claims (4)

an endless hinge belt;
Endless side chains attached to both sides of the hinge belt in the width direction,
In a chip conveyor that conveys chips by the conveying surface of the revolving hinge belt,
The hinge belt has a belt main body and an opening/closing section that is a part of the hinge belt in the longitudinal direction and is connected to the belt main body by a hinge,
The opening/closing part is
a frame defining an opening that opens to the conveying surface, a door that can open and close the opening, and an attachment member for attaching the door to the frame,
The door is
a plurality of door hinge plates connected in the longitudinal direction by hinges;
a connecting plate that is integral with the door hinge plate and that protrudes from both ends of the door hinge plate in the width direction and is connected to the frame;
The frame portion
a plurality of frame-forming plates defining the opening from both sides of the opening in the longitudinal direction and from both sides of the opening in the width direction, and connected in the longitudinal direction by hinges;
connecting portions provided on both sides of the opening in the width direction for connecting the connecting plates;
The chip conveyor, wherein the mounting member detachably mounts the connecting plate to the connecting portion of the frame. 2. The chip conveyor according to claim 1, wherein the connecting plate is provided over the entire length of the door hinge plate in the width direction. 3. The chip conveyor according to claim 1, wherein the door is removable from the frame. The opening/closing portion is formed by unitizing the frame portion and the door, and the opening/closing portion is detachable from the belt body. The chip conveyor described in .

Images