JP5632344B2 - Screw conveyor - Google Patents

Description

  The present invention relates to a screw conveying device, and more particularly, to a screw conveying device that increases the size range of a conveyed object that can be conveyed with a single screw without changing the screw (the combined use ratio of screws).

A screw conveying device is widely known as a means for conveying the object to be conveyed such as a container at the same timing for labeling or filling (Patent Document 1).
Referring to FIG. 8, the conventional screw conveying device includes a spiral screw 70 and a linear guide 73 arranged in parallel with the screw 70.
The screw 70 has a spiral blade 71 formed over the entire length thereof and a spiral groove 72 formed between the blades 71.
The spiral groove 72 has a valley diameter d ₂ and a crest diameter d ₁ that can accommodate the object to be conveyed 74, and leads of the spiral groove 72 so that the supply speed and supply interval of the object to be conveyed 74 toward the star wheel 75 gradually increase. A pitch is formed.
The valley diameter d ₂ and the mountain diameter d ₁ are equal over the entire length of the screw 70.

  Explaining the principle of conveyance by the conventional screw 70, the starting end of the spiral blade 71 enters between the peripheral surfaces of the object to be conveyed 74 that are supplied adjacently, and the pitch of the spiral blade 71 is increased as the screw 70 rotates. Accordingly, the conveyed object 74 is pulled away in the axial direction of the screw 70.

Japanese Patent Laid-Open No. 10-250838 (FIG. 2) JP 2004-115206 A (FIG. 3)

The conventional screw conveying device has the following problems.
<1> Since the groove width A of the spiral groove 72 of the screw 70 is basically formed in accordance with the diameter B (transverse dimension) of the object to be conveyed 74, the object to be conveyed 74 that can be conveyed by one screw 70. The dimension range of is very small.
This will be described in detail with reference to FIG. The screw 70 in the figure is for conveying the object to be conveyed 74 _S having a diameter X. For example, when the screw 70 is used to convey the object to be conveyed 74 _L having a diameter of 2X, the screw 70 having the diameter of 2X is used. to carry the carried object 74 _L is required to broaden the range shown a spiral groove 72 by hatching, but the widening of the groove width, since entering between the peripheral surface in close contact of the object to be conveyed 74 _S diameter X The spiral blades 71 (threads) on the inlet side are cut off and the conveyed object 74 _S having the diameter X cannot be pulled away. That is, the transported object 74 _S cannot be transported.
The combined use ratio of the transported object 74 can maintain the peak height at which the start end side of the spiral blade 71 placed between the closely contacted surfaces of the transported object 74 _S having the smallest diameter can retain the transported object 74. It becomes a range.
Although the combined ratio varies slightly depending on the dimensions of the valley diameter d ₂ and the peak diameter d ₁ of the screw 70, the maximum combined ratio has been limited to 1.4 times.
<2> If a single machine can handle the objects to be conveyed 74 having different diameters, the compatibility with the multi-item minority production is improved.
For the reason of <1> described above, in order to support the object 74 with different diameters in one machine, it is sufficient to have a plurality of screws 70 corresponding to the objects 74 with different diameters. There are problems of increasing costs and securing storage space.
Furthermore, the replacement of the screw 70 requires a lot of time and labor, and during that time, there is a problem that the operation of the machine is stopped and the operation efficiency is deteriorated.
<3> As a means for increasing the screw combined ratio, a method has been attempted in which the groove width A of the spiral groove 72 is formed larger than the diameter B of the conveyed object 74 (Patent Document 2).
In this method, since a large gap (A-B) is generated between the spiral groove 72 and the object to be conveyed 74, the object to be conveyed 74 is tilted back and forth during the conveyance or repeatedly oscillated. If the transported object 74 is tilted or slightly shaken, not only will the supply accuracy of the transported object 74 be adversely affected, but the transported object 74 may be damaged.
For the reasons described above, there is a limit to increasing the groove width A of the spiral groove 72.
<4> The conventional screw not only has a low combined use rate, but the combined use type screw is forced to have a low transfer speed, and the transfer processing efficiency of the object to be transferred 74 is poor.
In order to improve the production efficiency, there is a demand for a technique that can cope with an increase in the conveyance speed of the object to be conveyed 74 and that further increases the screw usage rate.

The present invention has been made in view of the above-described problems, and an object thereof is to provide the following screw conveying device.
<1> To achieve both improvement in the combined use ratio of the screw and increase in the conveying speed.
<2> Excellent compatibility with a wide variety of minority production.
<3> To reduce costs.

1st invention of this application arrange | positions above the conveyor which mounts a several to-be-conveyed object, and the bending body arrange | positioned facing the said screw main body above the said conveyor and the screw main body which has a spiral groove in the outer peripheral surface A screw conveying device that accommodates and conveys an object to be conveyed in a spiral groove of a screw body, wherein the conveying speed of the conveyor is superior to the conveying speed of the screw body, and the bending guide is It is installed so as to be movable in the orthogonal direction of the main body, and forms a different diameter shaft in which the valley diameter of the inlet portion of the screw main body is made smaller than other parts, and a small diameter shaft of uniform diameter constituting the different diameter shaft; forming a stepped surface for retention of the transported object between the large diameter shaft of uniform diameter, while the transported object was retained on the stepped surface between the large diameter shaft and the outer peripheral surface and the side surface of the blade of the large diameter shaft Sequentially to spiral grooves with constant groove width formed in Characterized thereby moving.
According to a second invention of the present application, in the first invention, the screw body includes a different-diameter shaft having an inlet portion having a small diameter and a spiral blade formed on an outer peripheral surface of the different-diameter shaft excluding the inlet portion. The different-diameter shaft is constituted by a small-diameter shaft formed over the range of the inlet portion and a large-diameter shaft formed over the other portion, and a step surface between the small-diameter shaft and the large-diameter shaft. And a spiral groove having a constant groove width is formed between the outer peripheral surface of the large-diameter shaft and the side surface of the blade.
A third invention of the present application is characterized in that, in the first invention or the second invention, the bending guide is formed with an inclined guide inclined at least on a part of the guide surface with respect to the axis of the screw body.
The fourth invention of the present application is characterized in that the screw body is integrally formed with a taper shaft on the upstream side in the transport direction of the small-diameter shaft.

The screw conveying device of the present invention has the following effects.
<1> The bending guide is installed so as to be movable in the orthogonal direction of the screw body, and the valley diameter of the inlet portion of the screw body is formed to be smaller than the other part, and the facing distance between the bending guide It is possible to achieve both an improvement in the combined use ratio of the screw and an increase in the conveyance speed of the object to be conveyed only by forming a conveyance space having the same width.
<2> A single screw conveying device can stably convey objects having different diameters, and has excellent compatibility with multi-product minority production.
<3> Since it is not necessary to replace the screw body, it is not necessary to store a large number of screw bodies, and the cost of the apparatus can be reduced.
<4> Since the bending guide can be changed to an irregularly-conveyed object only by adjusting the slide, the time required for the change can be greatly shortened, and a reduction in production efficiency can be avoided.
<5> If the taper shaft is integrally formed upstream of the small-diameter shaft of the screw body in the conveying direction, even if the object to be conveyed is flat or square, the object to be conveyed is prevented from being caught and smoothly conveyed. be able to.

The plane model figure of the screw conveying apparatus which concerns on Example 1 of this invention. Sectional drawing of the II-II in FIG. Explanatory drawing of a screw main body and a bending guide. The model figure for demonstrating the conveyance method of the to-be-conveyed object by a screw conveying apparatus. The model figure for demonstrating the conveyance method of the to-be-conveyed object by a screw conveying apparatus. The model figure for demonstrating the conveyance method of the to-be-conveyed object by a screw conveying apparatus. The model figure for demonstrating the conveyance method of the to-be-conveyed object by a screw conveying apparatus. Explanatory drawing of the screw conveying apparatus which conveys the to-be-conveyed object of a different diameter. Explanatory drawing of the screw conveying apparatus which concerns on Example 2 in which a spiral groove exhibits another shape. Explanatory drawing of the screw conveying apparatus which concerns on Example 3 which formed the taper axis | shaft in the screw main body. Explanatory drawing of the conventional screw conveying apparatus. Explanatory drawing of the combined use rate of the conventional screw conveying apparatus.

  Embodiments of the present invention will be described below with reference to the drawings.

<1> Outline of Screw Conveying Device FIG. 1 is a plan model diagram of the screw conveying device 10, FIG. 2 is a cross-sectional view thereof, and FIG. 3 is a plan model diagram of the screw conveying device 10 in which a conveyor is omitted.
In this example, the case where the transported object 74 has a circular cross section will be described for convenience, but the cross-sectional shape of the transported object 74 includes a known shape such as an ellipse or a polygon.

  The screw conveying device 10 is a device for conveying a large number of objects to be conveyed 74 at a predetermined interval and supplying them to a star wheel (not shown) in accordance with the supply timing. A main body 20 and a bending guide 30 provided side by side with the screw main body 20 are provided, and are disposed above a known conveyor 40.

  The left end of the screw body 20 is pivotally supported by a bearing 27, and the right end of the screw body 20 is pivotally supported by a drive source 28 such as a motor. Finally, the screw body 20 rotates in one direction.

  In this example, the transported object 74 mounted on the conveyor 40 moves from the left side to the right side of the drawing through the space facing the screw body 20 and the bending guide 30 (guidance space), and a star wheel (not shown). Etc.

<2> Screw Main Body The screw main body 20 is composed of a different diameter shaft 21 and a spiral blade 25 formed on the peripheral surface of the different diameter shaft 21, and the inlet portion in order from the left to the right of the screw main body 20. 20a, the transmission part 20b, and the exit part 20c are formed.

The outlet portion 20c is a section for transporting the transported object 74 at a constant speed, and the inlet section 20a and the transmission section 20b are sections for transporting the transported object 74 at a variable speed.
The lengths of the inlet portion 20 a, the transmission portion 20 b, and the outlet portion 20 c can be appropriately selected according to the usage of the screw conveyance device 10.
Hereinafter, each part of the screw body 20 will be described in detail.

<2.1> Different diameter shaft The conventional screw body has the same trough diameter in the spiral groove over the entire length of the screw body. Form with different diameters.
That is, in the present invention, the different diameter shaft 21 is constituted by the small diameter shaft 21a formed over the range of the inlet portion 20a and the large diameter shaft 21b formed over the range of the transmission portion 20b and the outlet portion 20c.

Diameter shaft 21a is located on the large diameter shaft 21b coaxially with, the shaft diameter d ₃ of the small-diameter shaft 21a is smaller than the shaft diameter d ₄ of the large-diameter shaft 21b.
Diameter shaft 21a is uniform whose shaft diameter d _3, the large-diameter shaft 21b also its shaft diameter d ₄ is uniform.

A step surface 21c for retaining the conveyed object 74 is formed between the end of the small diameter shaft 21a and the start end of the large diameter shaft 21b, and the spiral blade 25 is formed from the end of the step surface 21c. The formation was started.
That is, in the present invention, the conveyed object 74 is retained (delayed) at the step surface 21c between the small diameter shaft 21a and the large diameter shaft 21b, and the conveyed object 74 is orthogonal to the axis of the screw body 20 during this time. The spiral blades 25 are inserted between the peripheral surfaces of the closely conveyed object 74 by being displaced in the direction.
In other words, the diameter gradually increases over the formation range of the stepped surface 21c between the small diameter shaft 21a and the large diameter shaft 21b so that the transferred object 74 can be smoothly transferred from the small diameter shaft 21a to the large diameter shaft 21b. It has become.
“The diameter gradually increases” does not mean a tapered surface, but a surface whose outer peripheral surface expands in diameter while maintaining parallelism with the axis.

In short, the shaft diameter d ₃ of the inlet portion 20 a of the screw body 20 is formed smaller than the shaft diameter d ₄ (valley diameter) of the other speed change portion 20 b and outlet portion 20 c, and between the bent guide 30. What is necessary is just to form the conveyance space with equal opposing distance.

The present invention adopts the different diameter shaft 21 when the transferred object 74 is transferred from the terminal end of the inlet portion 20a to the starting end of the transmission unit 20b. This is because the object 74 is forcibly displaced in a direction perpendicular to the axis to separate the conveyed object 74.
In other words, the combined use rate of the screw main body 20 is increased by shifting the object to be conveyed 74 which is supplied adjacently without being influenced by the diameter of the object to be conveyed 74 in the direction perpendicular to the conveyance direction and separating them. Because.

A specific shaft diameter difference (d ₄ -d ₃ ) between the large-diameter shaft 21 b and the small-diameter shaft 21 a of the different-diameter shaft 21 is appropriately selected in consideration of the maximum diameter and the minimum diameter of the object 74 to be used. Shall.

<2.2> Spiral Blades The inlet portion 20a of the screw body 20 has no blades on the peripheral surface of the small-diameter shaft 21a, and is constituted only by the small-diameter shaft 21a.

Spiral blades 25 are formed on the outer peripheral surface of the large-diameter shaft 21b at the transmission portion 20b and the outlet portion 20c.
The crest diameter d ₅ of the spiral blade 25 is uniform over the ranges of the transmission portion 20b and the outlet portion 20c except for the start end portion.

  The lead and pitch of the spiral blade 25 are formed in accordance with the gradual increase of the supply speed and supply interval of the conveyed object 74.

<2.3> Spiral Groove A spiral groove 26 having a continuous valley diameter d ₄ is formed between the outer peripheral surface of the large-diameter shaft 21 b and the side surface of the blade 25.
The valley diameter d ₄ of the spiral groove 26 is uniform over the ranges of the transmission 20b and the outlet 20c.

  The lead and pitch of the spiral blade 25 are formed in accordance with the gradual increase of the supply speed and supply interval of the conveyed object 74.

<2.4> Groove Width of Spiral Groove The relationship between the groove width A of the spiral groove 26 and the transported object 74 will be described with reference to FIG.
Reference numeral 74 _L indicates a conveyed object having a maximum diameter B _{1 that} can be conveyed, and reference numeral 74 _S indicates a conveyed object having a minimum diameter B _{2 that} can be conveyed.
Over the entire length of the groove width A helical groove 72 of the helical groove 72 have a constant width, the transported object 74 _L of the maximum diameter B ₁ can be conveyed, of course, the transported object of minimum diameter B ₂ 74 _S Also has a size and depth that can be accommodated.

<3> Bending Guide In FIGS. 1 and 2, a bending guide 30 is disposed above the conveyor 40 in parallel with the screw body 20.
The bending guide 30 arranged to face the screw body 20 is a plate or bar guide member extending from the inlet 20a of the screw body 20 to the front of the delivery position of the outlet 20c. An inlet guide 31, an inclined guide 32, and an outlet straight guide 33 are successively formed on the opposing surface in order from the left to the right of the bending guide 30.

<3.1> Slide of bending guide The bending guide 30 can be slid in the orthogonal direction of the screw main body 20, and the bending guide 30 and the screw main body 20 are opposed to each other according to the diameter of the conveyed object 74. The distance can be adjusted.

  As shown in FIG. 2, in this example, a slide structure is shown in which a long hole 34 is provided in the bending guide 30 in a direction orthogonal to the screw main body 20 and supported by a fixing member 36 with bolts 35. Adjustment structure and mechanism can be applied.

<3.2> Guide Surface The bending guide 30 has a guide surface corresponding to the shaft diameter change of the different diameter shaft 21 of the screw body 20.
The guide surface of the bending guide 30 will be described in detail with reference to FIG.
In this example, both the inlet guide 31 and the outlet straight guide 33 are parallel to the axis of the screw body 20, and the inclined guide 32 is inclined with respect to the axis of the screw body 20 through an inclination angle θ. The continuous guides 31 to 33 function as a guide surface of the conveyed object 74.

The inclination angle θ of the inclination guide 32 is appropriately selected in consideration of the shaft diameter difference (d ₄ −d ₃ ) of the different diameter shafts 21 so that the object 74 can be smoothly conveyed in cooperation with the screw body 20. To do.

<3.3> Positional relationship between the bending guide and the screw main body The relative positional relationship between the bending guide 30 and the screw main body 20 will be described. The inlet guide 31 of the bending guide 30 corresponds to the inlet portion 20a of the screw main body 20. Located on the upstream side in the conveying direction, the inclined guide 32 is positioned facing the inlet 20a of the screw body 20 from the start end of the transmission 20b, and the outlet straight guide 33 is positioned facing the transmission 20b of the screw 20 To do.

<3.4> Referring to opposing distance also opposing distance folding guide 30 and the screw body 20, the distance L ₁ between the inlet guide 31 and the inlet portion 20a, distance L ₂ between the transmission portion 20b and the outlet linear guide 33 Are formed substantially equally so that the object to be conveyed 74 can be smoothly conveyed between the screw body 20 and the bending guide 30.

<4> Conveyor As shown in FIGS. 1 and 2, the conveyor 40 is a known conveyor that rotates in one direction.
In the present invention, the conveyance speed of the conveyor 40 is set slightly higher than the conveyance speed of the screw conveyance device 10 in order to accommodate conveyance of the object 74 having a different diameter.
The reason why the speed difference is provided so that the conveying speed of the conveyor 40 is superior to the conveying speed of the screw body 20 is that the object 74 is in contact with the side surface of the spiral blade 25 on the transfer side (downstream side). This is to prevent tilting and rattling of the conveyed object 74.

[Transport method]
Next, a method for conveying the object 74 having a different diameter by the screw conveying device 10 will be described.

<1> Conveying Method In FIG. 1, when the screw conveying device 10 starts operation, the object to be conveyed 74 that is mounted on the conveyor 40 and goes straight is a bending guide that has been slide-adjusted in advance according to the diameter of the object to be conveyed 74. 30 and the conveyance space on the inlet side of the screw body 20.

  The transported object 74 that continues to move straight is retained at the inclined guide 32 inclined by the bending guide 30 and the stepped surface 21c of the screw main body 20, while being guided by the stepped surface 21c and separated from the axis of the screw main body 20. It is displaced to. At this time, the transported object 74 moves from the end of the small diameter shaft 21a to the start end of the large diameter shaft 21b.

When the transferred object 74 displaced in the direction orthogonal to the axis of the screw main body 20 reaches the start end of the large-diameter shaft 21b of the screw main body 20, a spiral blade is interposed between the adjacent transferred object 74 and the transferred object 74. 25 starts and the preceding transported object 74 is separated from the subsequent transported object 74.
During this time, the transported object 74 that follows is retained on the step surface 21 c of the screw body 20.
The preceding transported object 74 accommodated in the spiral groove 26 is guided by the outlet straight guide 33 of the bending guide 30 and is transported to the right side of the drawing.

  4A to 4D are model diagrams for explaining the above-described method for conveying the object 74 to be conveyed by the screw body 20. 4A to 4D show the position of each conveyed object 74 and the positional relationship between the shafts 21a and 21b and the blades 25 when the screw body 20 is rotated in units of 90 degrees.

  Eventually, the object to be conveyed 74 is supplied to the outside of the screw conveying device 10 by encountering a star wheel or the like (not shown) at the delivery position of the outlet 20c of the screw body 20.

<2> When Changing the Diameter of the Conveyed Object In the present invention, as described with reference to FIG. 3, the shaft on the inlet side of the screw main body 20 is formed with a different diameter, and the diameter difference of the different diameter shaft 21 is accommodated. In this way, an inclined guide 32 is formed on a part of the bending guide 30.
Therefore, when changing from the large-diameter-sized object 74 (74 _L ) to the small-diameter-sized object 74 (74 _S ), as shown in FIG. By simply performing a simple operation of translating the bending guide 30 in the approaching direction of the screw main body 20, it is possible to supply the object 74 (74 _S ) having a different diameter.

When the object to be conveyed 74 is changed from the large diameter size to the small diameter size, a gap is formed between the spiral groove 26 and the object to be conveyed 74, but due to the difference in the conveying speed between the belt conveyor 40 and the screw conveying device 10, Regardless of the diameter of the object 74, the object to be conveyed 74 is biased and supported so as to abut on the side surface on the traveling side of the spiral blade 25, so that the object 74 can be effectively prevented from being tilted or shaken. can do.
Therefore, the transported object 74 can be transported at high speed.

As described above, in the present invention, when the object to be conveyed 74 is changed to one having a different diameter, it is only necessary to adjust the bending guide 30 by sliding. It is not necessary to exchange the main body 20 and the guide.
Therefore, the problem of parts cost and the problem of storage space can be solved.
Further, since the slide adjustment of the bending guide 30 can be performed in a short time, the operation stop time of the machine can be greatly shortened and the influence on the operation efficiency can be reduced.

<3> About the shared ratio of the screw As shown in FIG. 3, the shared ratio of the screw main body 20 is basically the difference between the diameters of the large diameter shaft 21b of the different diameter shaft 21 and the small diameter shaft 21a (d ₄ -d ₃ ). And the lead configuration based on the ratio of the maximum diameter and the minimum diameter.
For example, when the shaft diameter of the small-diameter shaft 21a is 40 mm and the shaft diameter of the large-diameter shaft 21b is 65 mm, the maximum diameter B ₂ of the transported object 74 _L is 80 mm, and the minimum diameter B ₂ of the transported object 74 _S is 40 mm. Thus, the combined use rate of the screw body 20 can be set to 2.0.
Therefore, it becomes possible to improve the combined use ratio of the screw.

  In the following, other embodiments will be described. In the description, the same parts as those in the above-described embodiments are denoted by the same reference numerals, and detailed description thereof will be omitted.

In the above-described embodiment, the case where the accommodation shape of the spiral groove 26 is a trapezoidal type has been described. However, as shown in FIG. 6, a type in which trapezoidal hem semicircles are combined may be applied. It is also possible to apply the semicircular type shown in FIG.
The accommodation shape of the spiral groove 72 may be any shape that can accommodate and convey the articles 74 _L and 74 _S having the maximum diameter B ₁ and the minimum diameter B _{2 that} can be conveyed.

  In this example as well, the shaft on the inlet side of the screw main body 20 is formed to have a different diameter, and the bending guide 30 is partially formed so as to correspond to the diameter difference of the different diameter shaft 21 as in the above-described embodiment. An inclined guide 32 is formed.

  FIG. 7 shows a screw conveying apparatus 10 according to another embodiment applied when the object 74 has a flat or square cross-sectional shape such as an eye drop container.

The basic configuration of the screw conveying device 10 of this example is the same as that of the above-described embodiment.
That is, the screw body 20 in this example is configured by a different diameter shaft 21 and a spiral blade 25 formed on the peripheral surface of the different diameter shaft 21, and the end and the large end of the small diameter shaft 21 a constituting the different diameter shaft 21. A stepped surface 21c is formed between the starting end of the radial shaft 21b and the transported object 74 stays and is displaced in the orthogonal direction of the screw body 20, and spirals from the end of the stepped surface 21c. The formation of the blade 25 is started.

  The folding guide 30 disposed opposite to the screw body 20 can slide in the direction orthogonal to the screw body 20, and the entrance guide 31 and the slope in order from the left to the right of the bending guide 30. A guide 32 and an outlet straight guide 33 are formed continuously.

  Further, the basic operation and effects of the screw conveying device 10 are the same as those of the above-described embodiments, and thus the description thereof is omitted.

In this example, the taper shaft 22 is integrally formed on the start end side of the different diameter shaft 21 corresponding to the inlet portion of the screw body 20, that is, on the upstream side in the transport direction of the small diameter shaft 21a.
The maximum left diameter of the taper shaft 22 is larger than the small diameter shaft 21a, and the minimum right diameter of the taper shaft 21d is equal to the small diameter shaft 21a.

The taper shaft 22 is integrally formed at the inlet portion of the screw body 20 for the following reason.
If there is no taper shaft 22 on the starting end side of the different diameter shaft 21 corresponding to the inlet portion of the screw main body 20, the tip end side of the conveyed object 74 supplied in parallel with the axis of the screw main body 20 is the location of the small diameter shaft 21a of the inlet portion. There is a risk that it will stick out and bite with the guide.

In this example, in order to prevent the object 74 from being caught, the object 74 just before reaching the small-diameter shaft 21a is directed in the centripetal direction of the screw body 20 by using the inclined tapered surface of the taper shaft 22. And tilted to supply.
If the object to be conveyed 74 is supplied while being tilted toward the centripetal direction of the screw main body 20, it is possible to prevent the tip end side of the object to be conveyed 74 from protruding outward at the small-diameter shaft 21a of the inlet portion. It is possible to prevent the object 74 from being caught between the guide 30 and smoothly convey it.

DESCRIPTION OF SYMBOLS 10 ... Screw conveying apparatus 20 ... Screw main body 20a ... Entrance part 20b ... Transmission part 20c ... Exit part 21 ... Different diameter shaft 21a ... ··· Small diameter shaft 21b ··· Large diameter shaft 21c ··· Step surface 22 · · · Tapered shaft 25 · · · Spiral blades 26 · · · Spiral groove 30 ···・ Bending guide 31... Entrance guide 32... Inclination guide 33... Straight exit guide 40.

Claims (4)

A screw body disposed above a conveyor carrying a plurality of objects to be conveyed, and having a spiral groove on an outer peripheral surface; and a bending guide disposed above the conveyor and facing the screw body; A screw conveying device that accommodates and conveys an object to be conveyed in a spiral groove of a main body,
The conveyor speed is superior to the screw speed,
The folding guide is installed so as to be movable in the direction orthogonal to the screw body,
Forming a different diameter shaft with a valley diameter of the inlet portion of the screw body smaller than other parts,
Forming a stepped surface that retains the object to be transported between a small-diameter shaft of uniform diameter and a large-diameter shaft of uniform diameter constituting the different-diameter shaft ;
The transported object retained on the step surface is sequentially moved to a spiral groove having a constant groove width formed between the large diameter shaft, the outer peripheral surface of the large diameter shaft and the side surface of the blade ,
Screw conveying device.   The screw body is composed of a different diameter shaft having an inlet portion formed in a small diameter and a spiral blade formed on the outer peripheral surface of the different diameter shaft excluding the inlet portion, and the different diameter shaft extends over the range of the inlet portion. And a large-diameter shaft formed over the other portion, a step surface is formed between the small-diameter shaft and the large-diameter shaft, and an outer peripheral surface of the large-diameter shaft and a blade The screw conveying device according to claim 1, wherein a spiral groove having a constant groove width is formed between the side surfaces of the screw conveying device.   The screw conveying device according to claim 1 or 2, wherein the bending guide is formed with an inclined guide inclined at least on a part of the guide surface with respect to the axis of the screw main body.   The screw conveying device according to claim 2 or 3, wherein the screw body is integrally formed with a taper shaft on the upstream side in the conveying direction of the small-diameter shaft.

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