JP2014172741A - Flow conveyor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flow conveyor to prevent the sagging of a chain and a scraper at an intermediate discharge port and powdery and granular matter from remaining at the bottom corner of a conveyor case.SOLUTION: In a flow conveyor 100, a scraper 150 has a linear part 150a linear in a chain width direction W at the outer peripheral side of a chain and an inclination part 150b connected to the linear part 150a and inclined to the inner peripheral side of the chain according to advance to the outside of the chain width direction. A conveyor case bottom 111 has a center flat surface 111a at a center in the chain width direction and an inclination surface 111b connected to the center flat surface 111a and inclined to the inner peripheral side of the chain according to advance to the outside of the chain width direction. The linear part 150a is in sliding contact with the center flat surface 111a, and the inclination part 150b is in sliding contact with the inclination surface 111b.

Description

The present invention includes a chain wound around a drive sprocket and a driven sprocket in a conveyor case, and a plurality of scrapers that extend on both sides in the chain width direction and are respectively attached to the chain at predetermined intervals in the chain longitudinal direction. The present invention relates to a flow conveyor that conveys powder particles substantially horizontally.
Here, “powder and granular material” refers to powder and granular materials such as cereal powder, granular material, pulverized coal, food, medicine, and resin.

Conventionally, a flow comprising a chain wound around a drive sprocket and a driven sprocket in a conveyor case, and a plurality of scrapers that are extended on both sides in the width direction of the chain and attached to the chain at predetermined intervals in the longitudinal direction of the chain. A conveyor is known (for example, refer to Patent Documents 1 and 2).
An example of such a conventional flow conveyor is a flow conveyor 700 as shown in FIG.

Here, FIG. 7 is a cross-sectional view of the prior art flow conveyor 700 as viewed from the longitudinal direction of the chain.
As shown in FIG. 7, the conventional flow conveyor 700 includes a plurality of scrapers 750 that extend on both sides in the chain width direction and are respectively attached to the chain 740 at predetermined intervals in the chain longitudinal direction. I was prepared.

Of the plurality of scrapers 750 circulating in the conveyor case 710, the scraper 750 on the feed side, which is the conveyor case bottom 711 side, acts on the rail material 770 without the chain 740 being guided to the rail material 770 and acts on the weights of the scraper 750 and chain 740. Thus, the powder body is configured to be slidably brought into contact with the conveyor case bottom 711 and conveyed from the inlet to the outlet.
On the other hand, the upper scraper 750 among the plurality of scrapers 750 circulating in the conveyor case 710 is moved from the discharge port to the input port while the chain 740 is guided by the rail member 770 supported by the rail support member 771. Was configured to go back.

  The scraper 750 is connected to the linear portion 750a that is linear in the chain width direction W on the outer peripheral side of the chain, and linearly extends to the inner peripheral side of the chain while being connected to the linear portion 750a on the outer side of the linear portion 750a in the chain width direction. The vertical portion 750d and the inclined portion 750b that is connected to the vertical portion 750d on the inner peripheral side of the chain at the vertical portion 750d and is inclined toward the inner peripheral side of the chain as it goes outward in the chain width direction.

  On the other hand, the conveyor case bottom 711 has a central flat surface 711a that is flat at the center in the chain width direction, and a vertical surface 711e that is connected to the central flat surface 711a on both sides of the central flat surface 711a in the chain width direction and extends toward the inner periphery of the chain. And an inclined surface 711b that is connected to the vertical surface 711e on the inner peripheral side of the chain at the vertical surface 711e and is inclined toward the inner peripheral side of the chain as it goes outward in the chain width direction.

And in order to convey a granular material, it was the structure which the linear part 750a of the scraper 750 of the sending side slidably contacts with the center flat surface 711a of the conveyor case bottom part 711. FIG.
Further, in order to prevent the scraper 750 and the chain 740 from hanging down at the intermediate outlet between the inlet and outlet, the inclined portion 750b of the scraper 750 on the feed side slides on the inclined surface 711b of the conveyor case bottom 711. It was a structure that touched.

Japanese Patent No. 4889463 Japanese Patent No. 3605590

  However, the conventional flow conveyor 700 described above has a vertical portion 750d between the straight portion 750a and the inclined portion 750b of the scraper 750, and between the central flat surface 711a and the inclined surface 711b of the conveyor case bottom 711. Since the structure has the vertical surface 711 e, the weight of the scraper 750 does not act on the vertical surface 711 e of the conveyor case bottom 711 via the vertical portion 750 d of the scraper 750, and the vertical portion 750 d and the vertical surface 711 e are interposed between them. There was a problem that gaps were generated and powder particles remained.

  Therefore, the present invention solves the problems of the prior art as described above, that is, the object of the present invention is to prevent the chain and scraper from sagging at the intermediate discharge port, and to prevent the corner of the conveyor case bottom. It is providing the flow conveyor which prevents that a granular material remains on the surface.

  The invention according to claim 1 includes a chain wound around the drive sprocket and the driven sprocket in the conveyor case, and a plurality of chains extending on both sides in the chain width direction and attached to the chain at predetermined intervals in the chain longitudinal direction. A scraper on the feed side which is the bottom side of the conveyor case among the plurality of scrapers circulating in the conveyor case. In the flow conveyor that discharges from a discharge port on the other end side of the conveyor case or an intermediate discharge port that is openable and closable provided at the bottom of the conveyor case between the input port and the discharge port, the scraper has a chain on the outer periphery side of the chain. Straight linear part in the width direction, and straight on both sides of the chain width direction at the straight part And an inclined portion that is inclined toward the inner circumferential side of the chain as it goes outward in the chain width direction, and the conveyor case bottom is formed by a central flat surface that is flat at the center of the chain width direction, and the central flat surface. And a slanted surface that is inclined toward the inner periphery of the chain as it goes outward in the chain width direction, and the linear portion of the scraper on the feed side is formed on the bottom of the conveyor case. While being in sliding contact with the central flat surface, the inclined portion of the scraper on the feeding side is configured to be in sliding contact with the inclined surface of the bottom of the conveyor case, thereby solving the above-described problems.

  In addition to the structure of the flow conveyor described in claim 1, the invention according to claim 2 includes a case bottom side member and a conveyor case side that constitute a part of the conveyor case bottom and the lower side of the conveyor case side. The above-mentioned problem is further solved by the fact that the position of the joint with the case side part side member that constitutes a part of the upper part of the part is configured vertically above the position of the scraper on the feed side. is there.

  In the invention according to claim 3, in addition to the configuration of the flow conveyor according to claim 1 or 2, the scraper is connected to the inclined portion on the outer side in the chain width direction of the inclined portion and the inner periphery of the chain. A linear side end portion extending linearly to the side, and the linear side end portion is configured to be in sliding contact with the inner side surface of the conveyor case in the conveyor case, thereby further solving the above-described problem Is.

  The invention according to claim 4 is the above-described problem in that, in addition to the configuration of the flow conveyor according to any one of claims 1 to 3, the scraper is formed of an elastic material. Is a further solution.

  The flow conveyor according to the present invention includes a chain wound around a drive sprocket and a driven sprocket in a conveyor case, and a plurality of scrapers that extend on both sides in the chain width direction and are respectively attached to the chain at a predetermined interval in the chain longitudinal direction. In this way, the granular material charged from the inlet on the one end side of the conveyor case is transported by the scraper on the feed side, which is the bottom side of the conveyor case among the multiple scrapers circulating in the conveyor case. In addition to being able to discharge from the discharge port on the other end side of the conveyor case or the intermediate discharge port that is openable and closable provided at the bottom of the conveyor case between the input port and the discharge port, There is an effect.

  According to the flow conveyor of the first aspect of the present invention, the scraper is connected to the linear portion that is linear in the chain width direction on the outer periphery side of the chain and the linear portion on both sides in the chain width direction of the linear portion. The conveyor case bottom has a flat central surface that is flat at the center of the chain width direction, and both sides of the central flat surface in the width direction of the chain. It has an inclined surface that is connected to the central flat surface and is inclined to the inner circumferential side of the chain as it goes outward in the chain width direction, and the linear portion of the scraper on the feed side is in sliding contact with the central flat surface at the bottom of the conveyor case, When the intermediate discharge port is open because the inclined part of the scraper on the feed side is in sliding contact with the inclined surface of the bottom of the conveyor case Even though the scraper moves while the inclined parts on both sides in the width direction of the feed side scraper are supported by the inclined surfaces on both sides in the width direction of the conveyor case bottom, the position of the scraper in the vertical direction is maintained. This prevents the chain and scraper from hanging down and prevents the scraper from being caught at the intermediate discharge port.

  Furthermore, the scraper's own weight acts in the range from the central flat surface of the conveyor case bottom to the inclined surfaces on both sides in the chain width direction, and the range from the straight portion to the inclined portion of the scraper and the central flat surface of the conveyor case bottom to the chain. Since the contact state with the range to the inclined surfaces on both sides in the width direction is clean, it is possible to prevent the powder particles from remaining in the corner formed by the central flat surface and the inclined surface of the bottom of the conveyor case.

  According to the flow conveyor of the invention according to claim 2, in addition to the effect produced by the invention according to claim 1, the case bottom side member and the conveyor constituting the conveyor case bottom part and the lower part of the conveyor case side part Since the position of the joint with the case side member that forms part of the upper part of the case side is configured to be vertically higher than the position of the scraper on the feed side, it contacts the scraper inside the conveyor case. Since the part to be smoothed is a smooth surface with no irregularities and the granular material is scraped cleanly by the scraper, the position of the joint between the case bottom side member and the case side side member when viewed from the side is the position of the scraper on the feeding side Compared to the same configuration as the above, it is possible to reliably prevent the powder particles from remaining.

  According to the flow conveyor of the invention according to claim 3, in addition to the effect produced by the invention according to claim 1 or 2, the scraper is connected to the inclined portion on the outer side in the chain width direction at the inclined portion, and in the chain. It has a linear side end portion that extends linearly to the circumferential side, and this linear side end portion is configured to be in sliding contact with the inner side surface of the conveyor case in the conveyor case, so that powder particles at both corners in the width direction can be obtained. Since the body is scraped cleanly at the linear side end portion of the scraper, it is possible to more reliably prevent the powder particles from remaining as compared with a configuration in which both ends in the width direction of the scraper are not in sliding contact with the inner side surface of the conveyor case.

  According to the flow conveyor of the invention according to claim 4, in addition to the effect of the invention according to any one of claims 1 to 3, the scraper is formed of an elastic material. Since the scraper on the side is somewhat elastically deformed and the contact state with the inner surface of the conveyor case becomes clean, it is possible to more reliably prevent the powder particles from remaining.

The schematic side view of the flow conveyor of 1st Example of this invention. The top view and side view of a chain which attached the scraper of 1st Example of this invention. Sectional drawing seen with the code | symbol 3-3 shown in FIG. Sectional drawing seen with the code | symbol 4-4 shown in FIG. Sectional drawing of the flow conveyor of 2nd Example of this invention. Sectional drawing in the intermediate | middle discharge port of the flow conveyor of 2nd Example of this invention. Sectional drawing of the prior art flow conveyor.

  The present invention includes a chain wound around a drive sprocket and a driven sprocket in a conveyor case, and a plurality of scrapers that extend on both sides in the chain width direction and are respectively attached to the chain at predetermined intervals in the chain longitudinal direction. The other side of the conveyor case is conveyed by a feed-side scraper at the bottom of the conveyor case among a plurality of scrapers circulating in the conveyor case. In a flow conveyor that discharges from an intermediate discharge port that is openable and closable at the bottom of the conveyor case between the discharge port or the input port and the discharge port, the scraper is linear in the chain width direction on the outer periphery of the chain Connected to the linear part on both sides in the chain width direction at this part and the chain The conveyor case bottom has a flat central surface that is flat at the center of the chain width direction and both sides of the central flat surface in the chain width direction. It has an inclined surface that is connected to the central flat surface and is inclined to the inner circumferential side of the chain as it goes outward in the chain width direction, and the linear portion of the scraper on the feed side is in sliding contact with the central flat surface at the bottom of the conveyor case, The sloping part of the scraper on the feed side is in sliding contact with the sloping surface of the bottom of the conveyor case, preventing the chain and scraper from hanging down at the intermediate discharge port and preventing the scraper from being caught at the intermediate discharge port. , Prevents powder particles from remaining in the corner formed by the central flat surface and the inclined surface at the bottom of the conveyor case. Lever, specific embodiments thereof are may be any one.

For example, the scraper may be formed of an elastic material such as a resin.
Moreover, a scraper may be used in combination with a steel scraper, or only a scraper may be used without using a steel scraper.
Furthermore, the location where the scraper is attached may be either the inner plate or the outer plate of the chain.
Moreover, the conveyance direction of a granular material should just be substantially horizontal, and the front surface of a scraper should just be substantially perpendicular | vertical with respect to the advancing direction of this scraper.

Below, the flow conveyor 100 which is 1st Example of this invention is demonstrated based on FIG. 1 thru | or FIG.
Here, FIG. 2A is a schematic side view of the flow conveyor 100 of the first embodiment of the present invention, and FIG. 2A is a plan view of the chain 140 to which the scraper 150 of the first embodiment of the present invention is attached. 2 (B) is a side view of the chain 140 viewed by reference numeral 2B shown in FIG. 2 (A), and FIG. 3 is a sectional view of the flow conveyor 100 viewed by reference numeral 3-3 shown in FIG. FIG. 4 is a cross-sectional view when the open / close door 116 of the intermediate discharge port 115 of the flow conveyor 100 viewed in the reference numeral 4-4 shown in FIG. 1 is in an open state.
1 and 4, the opening / closing mechanism for the intermediate discharge port 115 is not shown.
In FIG. 4, the opening / closing door 116 of the intermediate discharge port 115 is not shown.

  As shown in FIGS. 1 to 4, the flow conveyor 100 according to the first embodiment of the present invention includes a chain 140 wound around the drive sprocket 120 and the driven sprocket 130 in the conveyor case 110, and extends to both sides in the chain width direction. And a plurality of scrapers 150 attached to the chain 140 at predetermined intervals in the longitudinal direction of the chain.

Of these, the drive sprocket 120 is provided to be driven by the power of the motor.
On the other hand, the driven sprocket 130 is provided so as to be adjustable by a known take-up mechanism 180 in the chain tension direction.
The take-up mechanism 180 tends to decrease the tension of the chain 140 when the chain 140 is gradually extended by use. The take-up mechanism 180 moves the shaft portion of the driven sprocket 130 on the side where the tension of the chain 140 is increased, thereby predetermining the tension. It is a mechanism to keep the size of the.

In addition, a loading port 113 is provided on one end side of the long conveyor case 110, and a discharge port 114 is provided on the other end side.
Further, an intermediate discharge port 115 having an openable / closable door 116 is provided on the conveyor case bottom 111 between the input port 113 and the discharge port 114.
Although a detailed description of the mechanism for opening and closing the door 116 is omitted, for example, a structure that opens and closes by the power of a motor may be used, or a structure that opens and closes manually.
Moreover, the open / close door 116 in the closed state is flush with the upper side of a later-described central flat surface 111a of the conveyor case bottom 111.

  And the scraper 150 of the feed side which is the conveyor case bottom part 111 side among the scrapers 150 as a plurality of flights which circulates the granular material M injected | thrown-in from the inlet 113 of the one end side of the conveyor case 110 in the conveyor case 110 The sheet is conveyed at 150 and discharged from the discharge port 114 or the intermediate discharge port 115 on the other end side of the conveyor case 110.

Specifically, when the open / close door 116 of the intermediate discharge port 115 is closed, the drive sprocket 120 is driven so that the scraper 150 on the feeding side removes the powder M injected from the input port 113 from the bottom of the conveyor case. The powder M is discharged from the discharge port 114 by being transported to the discharge port 114 while being scraped off on 111.
On the other hand, when the open / close door 116 of the intermediate discharge port 115 is open, the drive sprocket 120 is driven, so that the scraper 150 on the feed side causes the granular material M introduced from the input port 113 to move on the conveyor case bottom 111. The powder M is discharged from the intermediate discharge port 115 by being conveyed to the intermediate discharge port 115 while being scraped off.

The feed side chain 140 and the scraper 150 that have moved to the discharge port 114 side on the bottom of the conveyor case 110 in the conveyor case 110 are reversed to become the return side chain 140 and the scraper 150 in the conveyor case 110. It is guided by the rail material 170 supported by the upper rail support member 171 and moves to the insertion port 113 side.
Then, it is reversed again to become a feed side chain 140 and a scraper 150 and move on the conveyor case bottom 111 in the lower part of the conveyor case 110 to the discharge port 114 side.

Here, a specific configuration of the chain 140 will be described.
As shown in FIGS. 2A and 2B, the chain 140 includes a pair of left and right inner plates 141 and a bush (not shown) in which a bush end is press-fitted into a bush hole of the inner plate 141. A pair of left and right outer plates 143 disposed on both outer sides of the pair of left and right inner plates 141, and a pin 144 that is rotatably fitted to the bushing and press-fits the pin end portion into the pin hole of the outer plate 143, A roller 142 is provided between each of the pair of left and right inner plates 141 and is rotatably fitted to the outer periphery of the bush.
As an example, the scraper 150 is pressed by attachment plates 145 provided on both the left and right sides of the inner plate 141 by a pressing plate 160 and attached by bolts B and nuts N.

Next, the shape of the scraper 150 and the shape of the conveyor case bottom 111 will be described.
As shown in FIGS. 3 and 4, the scraper 150 is connected to the linear portion 150a that is linear in the chain width direction W on the outer periphery side of the chain and the linear portion 150a on both sides of the linear portion 150a in the chain width direction. In addition, it has an inclined portion 150b inclined toward the inner periphery of the chain as it goes outward in the chain width direction.

On the other hand, the conveyor case bottom 111 is connected to the central flat surface 111a which is flat at the center in the chain width direction, and to the central flat surface 111a on both sides of the central flat surface 111a in the chain width direction, and as it goes outward in the chain width direction. And an inclined surface 111b inclined to the circumferential side.
The linear portion 150 a of the feed-side scraper 150 is configured to be in sliding contact with the central flat surface 111 a of the conveyor case bottom 111.
Similarly, the inclined portion 150 b of the feed-side scraper 150 is configured to be in sliding contact with the inclined surface 111 b of the conveyor case bottom 111.

  Accordingly, even when the intermediate discharge port 115 is open, the scraper 150 is supported while the inclined portions 150b on both sides in the width direction of the scraper 150 on the feeding side are supported by the inclined surfaces 111b on both sides in the width direction of the conveyor case bottom 111. And the position of the scraper 150 in the vertical direction is maintained.

  Furthermore, the weight of the scraper 150 acts in the range from the central flat surface 111a of the conveyor case bottom 111 to the inclined surfaces 111b on both sides in the chain width direction, and the range from the straight portion 150a to the inclined portion 150b of the scraper 150 and the conveyor case The state of contact with the range from the central flat surface 111a of the bottom 111 to the inclined surfaces 111b on both sides in the chain width direction is clean.

Further, the scraper 150 has a linear side end portion 150c that is connected to the inclined portion 150b on the outer side in the chain width direction at the inclined portion 150b and extends linearly toward the inner peripheral side of the chain.
In the first embodiment, a gap is provided between the linear side end portion 150c and the conveyor case inner side surface 112a in the conveyor case 110. However, the linear side end portion 150c is formed in the conveyor case. 110 may be configured to be in sliding contact with the conveyor case inner side surface 112a.
Thereby, the granular material M at the corners on both sides in the width direction is scraped cleanly by the linear side end portion 150 c of the scraper 150.

Furthermore, in the first embodiment, the scraper 150 is formed of an elastic material.
Thereby, the scraper 150 on the feeding side is somewhat elastically deformed, and the contact state with the central flat surface 111a and the inclined surface 111b in the conveyor case 110 becomes clean.
In the first embodiment, the position of the joint J between the case bottom side member 111D constituting the conveyor case bottom 111 and the case side side member 112B constituting the conveyor case side 112 is the feed side in the vertical direction. This is the same as the position of the scraper 150.

  In the flow conveyor 100 according to the first embodiment of the present invention thus obtained, the scraper 150 includes a linear portion 150a that is linear in the chain width direction W on the outer periphery side of the chain, and the linear portion 150a. The conveyor case bottom 111 is connected to the linear portion 150a on both sides in the chain width direction and has an inclined portion 150b inclined toward the inner periphery of the chain as it goes outward in the chain width direction. A feed-side scraper having a surface 111a and an inclined surface 111b that is connected to the central flat surface 111a on both sides of the central flat surface 111a in the chain width direction and is inclined toward the inner circumferential side of the chain as it goes outward in the chain width direction. 150 linear portions 150a are in sliding contact with the central flat surface 111a of the conveyor case bottom 111. In both cases, the inclined portion 150b of the feed-side scraper 150 is in sliding contact with the inclined surface 111b of the conveyor case bottom 111, so that the chain 140 and the scraper 150 are prevented from hanging down at the intermediate discharge port 115. 115, the scraper 150 can be prevented from being caught at 115, and powder particles can be prevented from remaining in the corner formed by the central flat surface 111a and the inclined surface 111b of the conveyor case bottom 111.

  Further, the scraper 150 has a linear side end portion 150c that is connected to the inclined portion 150b on the outer side in the chain width direction at the inclined portion 150b and extends linearly toward the inner circumferential side of the chain. The structure in which the conveyor case 110 is in sliding contact with the inner side surface 112a of the conveyor case makes it possible to reduce the residual of the powder M more than in the configuration in which both ends in the width direction of the scraper 150 are not in sliding contact with the inner side surface 112a of the conveyor case. It can be surely prevented.

  Moreover, since the scraper 150 is formed of an elastic material, the effect of the powder particles M can be prevented more reliably and the effect is enormous.

Then, the flow conveyor 200 which is 2nd Example of this invention is demonstrated based on FIG. 5 and FIG.
Here, FIG. 5 is a cross-sectional view of the flow conveyor 200 of the second embodiment of the present invention, and FIG. 6 is a cross-sectional view of the flow conveyor 200 of the second embodiment of the present invention at the intermediate discharge port 215. .
FIG. 5 is a diagram corresponding to FIG. 3 of the first embodiment, and FIG. 6 is a diagram corresponding to FIG. 4 of the first embodiment.

  In the flow conveyor 200 of the second embodiment, the position of the joint J between the case bottom member 111D and the case side member 112B of the flow conveyor 100 of the first embodiment is vertically higher than the position of the scraper 150 on the feed side. Since many elements are the same as those of the flow conveyor 100 of the first embodiment, detailed description of the common matters is omitted, and only the reference numerals of the 200 series in which the last two digits are common are attached.

In the flow conveyor 200 according to the second embodiment of the present invention, as shown in FIGS. 5 and 6, the case bottom side member 211 </ b> D constitutes the lower side of the conveyor case bottom 211 and the conveyor case side 212.
Further, the case side portion member 212 </ b> B constitutes the upper side of the conveyor case side portion 212.
The position of the joint J between the case bottom side member 211D and the case side side member 212B is configured to be vertically higher than the position of the scraper 250 on the feed side.
Thereby, the location which contacts with the scraper 250 inside a conveyor case turns into a smooth surface without an unevenness | corrugation, and the granular material M is scraped off by the scraper 250 neatly.

Further, the case bottom portion side member 211D and the case side portion side member 212B are connected at a joint J by angle members 217 and 218 having an L-shaped cross section.
As a result, the conveyor case inner side surface 211c and the conveyor case inner side surface 212a are flush with each other at the joint J, and it is possible to reliably prevent the powder M from remaining.
That is, in the first embodiment, since the corners at the joint J are bent, there is a possibility that the powder M is slightly left in the gap due to the rounding of the bending at the joint J. In the second embodiment, by using the angle members 217 and 218 to connect the case bottom side member 211D and the case side side member 212B, the joint J is flush with no gap, and the powder M remains. Can be reliably prevented.
That is, it becomes the flow conveyor 200 which can be discharged intermediately without the powder M remaining.
The angle member 217 is connected to the case bottom side member 211D by welding. Similarly, the angle member 218 is connected to the case side member 212B by welding, and the angle member 217 and the angle member 218 are connected by bolts and nuts. ing.

In the second embodiment, a gap is provided between the linear side end portion 250a of the scraper 250 and the conveyor case inner side surface 211c of the case bottom side member 211D. However, the linear side end portion 250c of the scraper 250 is provided. However, you may comprise so that it may slidably contact with the conveyor case inner side surface 211c of case bottom part side member 211D.
In this case, without being affected by the joint J, the granular material M at both corners in the width direction is scraped cleanly by the straight side end portion 250c of the scraper 250.

  The flow conveyor 200 according to the second embodiment of the present invention thus obtained includes a case bottom side member 211D and a conveyor case side part constituting the conveyor case bottom 211 and a part of the lower side of the conveyor case side 212. Since the position of the joint J with the case side member 212B that constitutes a part of the upper side of 212 is configured to be vertically higher than the position of the scraper 250 on the feed side, the bottom of the case as viewed from the side. Compared with the configuration in which the position of the joint J between the side member 211D and the case side portion side member 212B is the same as the position of the scraper 250 on the feeding side, it is possible to reliably prevent the powder M from remaining, and the effect is enormous. is there.

100, 200, 700 ... Flow conveyors 110, 210, 710 ... Conveyor cases 111, 211, 711 ... Conveyor case bottoms 111a, 211a, 711a ... Central flat surfaces 111b, 211b, 711b ... Inclined surface
211c: Conveyor case inner side surface 111D, 211D: Case bottom side member
711e ... Vertical surface 112, 212 ... Conveyor case side part 112a, 212a ... Conveyor case inner side surface 112B, 212B ... Case side part side member 113 ... Input port 114 ... Discharge port 115 ,..., Intermediate discharge ports 116, 216, opening / closing door 120, driving sprocket 130, driven sprockets 140, 240, 740, chains 141, 241, inner plates 142, 242. · Rollers 143, 243 ... Outer plate 144 ... Pins 145, 245 ... Attachments 150, 250, 750 ... Scrapers 150a, 250a, 750a ... Linear portions 150b, 250b, 750b ... Inclined portion 150c, 250c ... linear side end portion
750d ... Vertical portion 160, 260 ... Holding plates 170, 270, 770 ... Rail members 171, 271, 771 ... Rail support member 180 ... Take-up mechanism B ... Bolt N ...・ Nut J ・ ・ ・ Joint M ・ ・ ・ Powder body W ・ ・ ・ Chain width direction

Claims (4)

A chain wound around a drive sprocket and a driven sprocket in the conveyor case, and a plurality of scrapers extending on both sides in the width direction of the chain and attached to the chain at predetermined intervals in the longitudinal direction of the chain. The granular material charged from the inlet on one end of the conveyor is transported by a feed-side scraper at the bottom of the conveyor case among the plurality of scrapers circulating in the conveyor case, and discharged on the other end of the conveyor case. In the flow conveyor that discharges from the intermediate discharge port that can be opened and closed switchably provided at the bottom of the conveyor case between the outlet or the input port and the discharge port,
The scraper is connected to the linear part in the chain width direction on the outer periphery side of the chain, and to the linear part on both sides of the chain width direction in the linear part, and toward the inner periphery side of the chain as it goes outward in the chain width direction. An inclined portion,
The conveyor case bottom is connected to the central flat surface flat at the center in the chain width direction, and to the central flat surface on both sides in the chain width direction at the center flat surface, and is inclined toward the inner periphery of the chain as going outward in the chain width direction. An inclined surface,
The linear portion of the feeding-side scraper is in sliding contact with the central flat surface of the conveyor case bottom, and the inclined portion of the feeding-side scraper is in sliding contact with the inclined surface of the conveyor case bottom. And flow conveyor.   The position of the joint between the case bottom side member constituting the lower part of the conveyor case bottom and the conveyor case side and the case side side member constituting the upper part of the conveyor case side is the feed The flow conveyor according to claim 1, wherein the flow conveyor is configured vertically above the position of the side scraper.   The scraper has a linear side end portion that is connected to the inclined portion on the outer side in the chain width direction at the inclined portion and extends linearly toward the inner circumferential side of the chain, and the linear side end portion is provided in the conveyor case. The flow conveyor according to claim 1, wherein the flow conveyor is in sliding contact with the inner side surface of the conveyor case.   The flow conveyor according to any one of claims 1 to 3, wherein the scraper is formed of an elastic material.

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