KR100971935B1 - Soil recycler, hopper and conveying device used therefor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soil improver, a hopper and a conveying apparatus used therein, and aims to prevent soil clogging or crosslinking easily in a hopper into which raw soil is introduced.

According to the present invention, the raw material soil hopper 10 includes a hopper main body 16, an introduction portion 18, a pair of lower bent edge portions 20b, and a pair of upper bent edge portions 20a. Doing. The hopper body 16 includes a pair of inclined frame bodies 15 that are opened to open upward. The introduction part 18 is formed extending from the lower end of the pair of inclined frame bodies 15 downward, and a pair of lower parts for guiding the soil introduced into the inclined frame body 15 to the conveyer belt conveyor 11. The frame body 17 is included. The pair of lower bend edge portions 20b are formed at the boundary between the pair of inclined frame bodies 15 and the pair of lower frame bodies 17, and apply shear forces to the introduced soil ball. Let's do it. The pair of upper curved edge portions 20a are provided at a wider interval than the lower curved edge portions 20b above the lower curved edge portions 20b and exert a shearing force on the introduced clay ball.

Description

SOIL RECYCLER, HOPPER AND CONVEYING DEVICE USED THEREFOR}

The present invention relates to a soil improver, particularly a soil improver for improving soil by mixing soil and soil improver. The present invention also relates to a hopper installed in a soil improver, to which soil is introduced, to a hopper for guiding the introduced soil to a conveying belt conveyor at a lower side, and a conveying apparatus for conveying the introduced soil to a mixer for mixing with the soil improving material. will be.

For example, in the case of water and sewage and gas pipe embedding construction, it is common to embed the groove in its original state after embedding the pipe in a groove excavated by a construction machine such as a hydraulic excavator. However, the soil excavated in the grooves may not be used to fill the soil in the case of clay with high moisture or viscous soil. In addition, in the case of constructing a building on a soft ground, after excavating the soft soil of the site to a predetermined depth, it is performed to improve the ground by putting a good quality soil instead of the excavated soil.

In the case described above, a soil improvement treatment is performed in which soil improving agent such as lime or cement is mixed with soil or soft soil which cannot be used for reclamation in its original state, and solidified and reused. And the soil improver for this soil improvement process is proposed (for example, patent document 1).

[Patent Document 1] Japanese Patent Application Laid-Open No. 2001-73403

The soil improver as described above generally includes a raw material hopper into which raw soil is fed from a hydraulic excavator, a conveyer belt conveyor for conveying raw soil dropped from the raw material hopper, and an improving hopper to supply a soil improver; And a mixer for mixing the raw soil and the soil improving agent, and a discharge belt conveyor for discharging the mixed raw soil and the soil improving agent.

Here, when paying attention to a raw soil hopper, a raw soil hopper consists of a pair of inclination frame which spreads upwards, and a pair of vertical wall part extended downward from the lower end of a pair of inclination frame bodies. And the raw soil thrown in to the inclination frame body falls from the inclination frame body through the vertical wall part, and falls on the conveyance belt conveyor below.

At this time, when highly viscous clay (hereinafter referred to simply as viscous soil) is supplied to the soil improver with a hydraulic shovel, a soil mass having a shape similar to the bucket shape of the hydraulic excavator is often introduced into the raw material hopper as it is. The shape at this time is shown typically in FIG. In FIG. 1, the example of the case where the soil was thrown in from the bucket 101 of the hydraulic excavator with respect to the raw material soil hopper 100 is shown. As shown in FIG. 1, the soil mass 102 introduced by the bucket 101 generally has a width wider than an interval (input width) of a pair of vertical wall portions 10Oa of the raw soil hopper 10O. There are many cases. Therefore, the thrown-in soil mass 102 first collides with the inclined portion 100b and collapses, and thereafter, it hits the bent edge portion that is the boundary between the inclined portion 100b and the vertical wall portion 100a and shears. V) and fall downward.

However, when highly viscous clay is introduced into the raw material hopper, the soil mass does not shear well. Then, when the soil mass of clay soil is continuously introduced in the state that the soil mass does not completely collapse in the raw material soil hopper, as shown in FIG. 2 (a), it is blocked at the portion of the vertical wall portion 100a, or As shown in Fig. 2B, only the lower portion of the soil ball falls, the upper portion remains, and crosslinking may occur. When such a state occurs, the raw soil is not properly supplied to the conveyer belt conveyor side.

According to the applicant's research and experiment, it has been found that when the distance between the pair of vertical walls is widened, the crosslinking as described above is not easily generated. However, when the distance between the pair of vertical wall portions is widened, the width of the conveying belt conveyor disposed on the downstream side of the raw material hopper needs to be widened accordingly, but there is a limit in the configuration. Moreover, in the soil improver, generally, the fixed quantity supply mechanism for supplying fixed quantity of raw soil to a mixer is provided in the downstream part of the conveyance belt conveyor. That is, the conveyance amount of raw material soil is regulated by the fixed quantity supply mechanism. Therefore, in the raw material hopper which is upstream of the fixed-quantity supply mechanism, it is not possible to supply a large amount of raw material soil to the conveying belt conveyor at a time by widening the interval of the pair of vertical wall portions.

An object of the present invention is to prevent clogging or crosslinking of soil easily in a hopper into which raw soil is introduced.

Another object of the present invention is to provide a hopper capable of continuously and appropriately supplying raw soil to a downstream conveyor belt conveyor without affecting other configurations.

The hopper of the soil improver according to the first invention is a hopper installed in a soil improver which mixes soil and a soil improver to improve soil quality, and in which soil is introduced and guides the introduced soil to a lower conveying belt conveyor. And an introduction portion, a pair of charged ends and a pair of upper ends. The hopper body includes a pair of inclined frame bodies opened to open upward. The introduction portion is formed to extend downward from the lower end of the pair of inclined frame bodies, and includes a pair of lower frames for guiding the soil introduced into the inclined frame body to the conveyer belt conveyor. The pair of charged ends consists of a bent edge portion formed at the boundary between the pair of inclined frame bodies and the pair of lower frame bodies, and exerts a shearing force on the introduced clay ball. The pair of phase front ends are provided at a wider interval than the pair of charged ends above the pair of charged ends and exert a shearing force on the introduced soil ball.

In this hopper, soil as raw material soil is introduced into the hopper body from a hydraulic excavator or the like. The soil put into the hopper main body is guided downward along the pair of inclined frame bodies and is supplied to the lower conveyance belt conveyor via the introduction portion.

At this time, especially when highly viscous clay is introduced into the hopper from the bucket of the hydraulic excavator, in the conventional hopper, the soil lumps are not easily collapsed and may be deposited and clogging or crosslinking may occur. However, in the present invention, since two shear portions are formed on the upper and lower sides, since the introduced lump is easily collapsed, crosslinking does not occur easily. Specifically, the introduced clay ball is first sheared at the upper front end. Then, the soil ball remaining without shearing at the upper front end is pushed down from the top to the lower side by the soil ball introduced next, and is sheared at the lower front end at this time.

Therefore, in the hopper of the present invention, compared with the conventional hopper, the soil mass easily collapses, and an appropriate amount of raw soil can be continuously supplied to the conveying belt conveyor.

In the hopper of the soil improver according to the second aspect of the invention, in the hopper of the first aspect, the pair of inclined frame bodies of the hopper main body includes a first inclined portion, a first inclined portion and a lower portion inclined at a first inclination angle with respect to the horizontal plane, respectively. It is provided between frame bodies, and has the 2nd inclination part inclined by a 2nd inclination angle larger than a 1st inclination angle with respect to a horizontal plane. And a pair of upper front end consists of the curved edge part formed in the boundary part of a 1st inclination part and a 2nd inclination part.

In this hopper, the curved edge part is formed in a pair of inclined frame bodies. That is, the upper portion (first inclination portion) of the inclined frame body is inclined at the first inclination angle with respect to the horizontal plane, and the lower portion (second inclination portion) is inclined at a second inclination angle larger than the first inclination angle. And this boundary part becomes a curved edge part. Therefore, this curved edge portion functions as the phase front end portion.

Here, for example, by bending the upper portion of the inclined frame further to form a bent edge portion, the upper edge portion can be configured, and the upper edge portion can be realized at low cost.

In the hopper of the soil improver according to the third invention, in the hopper of the second invention, the second inclination angle of the second inclined portion is not less than 60 ° and not more than 75 °.

Here, the 2nd inclination angle of a 2nd inclination part is set to 60 degrees or more and 75 degrees or less exceeding 45 degrees which is the maximum repose angle of soil. Here, when the second inclination angle exceeds 75 °, the difference between the gap (shear width) of the pair of charged ends and the gap (shear width) of the pair of upper ends becomes smaller, and the effect of providing two shear portions becomes smaller. . On the other hand, if the second inclination angle is smaller than 60 °, the inclination of the second inclined portion becomes too gentle, and it becomes difficult for the dirt to fall down along the second inclined portion, and the soil is deposited on the second inclined portion.

Therefore, in the present invention, the second inclination angle of the second inclination portion is set to 60 ° or more and 75 ° or less exceeding the maximum repose angle of the soil, and the soil mass can be sheared effectively by two shear portions, It is configured to make the soil mass fall down easily.

In the hopper of the soil improver according to the fourth aspect, in the hopper of any one of the first to third aspects, the interval between the pair of upper ends is 125% or more and 145% or less of the interval between the pair of charged ends.

As described above, if the difference between the gap (shear width) of the pair of top shear ends and the gap (shear width) of the pair of lower shear ends is too small, the effect of providing two front ends cannot be expected very much. On the other hand, if the above-described difference is too large, that is, if (a) the shear width of the charge front end is made too small, or (b) the shear width of the top end is made too large, the following problems arise.

First, (a) When the shear width of the charged end portion is made small, the width of the inlet portion is made small, so that the soil block is easily clogged at the inlet portion, which is not preferable. In addition, in the case of (b) described above, since the height dimension of the second inclined portion has a certain limitation, when the shear width of the upper front end portion is widened among the height limitations of the predetermined limitation, the second inclination angle becomes small, as described above. It is not preferable because the soil ball is difficult to fall down along the second inclined portion.

Therefore, in this invention, the space | interval of a pair of upper end parts is made into 125% or more and 145% or less of the space | interval of a pair of charged end parts.

As for the hopper of the soil improver which concerns on 5th invention, in the hopper of any one of invention 1-4, the pair of lower frame bodies of an introduction part are arrange | positioned in parallel with each other.

In this case, since the upper end (inlet) and the lower end (outlet) of the introduction portion have the same width, the sheared soil can be smoothly supplied downward.

The hopper of the soil improver according to the sixth aspect is a hopper installed in a soil improver for mixing soil and a soil improver to improve soil quality, and is a hopper for introducing soil and guiding the introduced soil to a conveying belt conveyor below. And an introduction portion. The hopper body includes a pair of inclined frame bodies opened to open upward, and each of the pair of inclined frame bodies has at least one curved edge portion so that the upper side is wider than the lower side. The introduction portion is formed to extend downward from the lower end of the pair of inclined frame body, and includes a pair of lower frame bodies for guiding soil introduced into the inclined frame body to the conveying belt conveyor, and a pair of lower frames The connecting portion of the sieve and the pair of inclined frame bodies is the bent edge portion.

In this hopper, soil as raw material soil is introduced into the hopper body from a hydraulic excavator or the like. The soil put into the hopper main body is guided downward along the pair of inclined frame bodies and is supplied to the lower conveyance belt conveyor through the introduction portion.

At this time, particularly when viscous soils having high viscosity are introduced into the hopper from the bucket of the hydraulic excavator, the soil lumps are not easily collapsed and deposited in the conventional hopper, resulting in clogging or crosslinking. However, in the present invention, first, the soil ball is sheared at the bent edge portion formed in the inclined frame body. Then, the soil mass remaining unsheared at the bent edge portion of the inclined frame body is pushed down from the top by the soil mass which is then introduced, and at this time, at the bent edge portion of the connecting portion of the inclined frame body and the lower frame body. Sheared.

Therefore, in the hopper of the present invention, compared with the conventional hopper, the soil mass easily collapses, and an appropriate amount of raw soil can be continuously supplied to the conveying belt conveyor.

The hopper of the soil improver according to the seventh invention is a hopper installed in a soil improver for mixing soil and a soil improver to improve soil quality, and is a hopper for introducing soil and guiding the introduced soil to a conveying belt conveyor at the lower side. And an introduction portion. The hopper body includes a pair of inclined frame bodies opened to open upward, and each of the pair of inclined frames has at least one curved edge portion so that the upper side is further opened compared to the lower side. The introduction portion is formed to extend downward from the lower end of the pair of inclined frame bodies, and includes a pair of lower frame bodies for guiding the soil introduced into the hopper body to the conveyer belt conveyor. And the space | interval of the curved edge part formed in a pair of inclined frame body is wider than the space | interval of a pair of lower frame body.

Here, when the soil as raw material soil is introduced into the hopper main body from the hydraulic excavator, etc., the soil introduced into the hopper main body is guided downward along the pair of inclined frame bodies, and is supplied to the lower conveyance belt conveyor via the introduction portion. do.

At this time, particularly when viscous clay having high viscosity is introduced into the hopper from the bucket of the hydraulic excavator, the soil lump does not easily collapse in the conventional hopper and may be deposited and clogging or crosslinking may occur. However, in the present invention, the soil mass is sheared at the bent edge portion formed in the inclined frame body, and the soil mass is sheared at the portion from the hopper body to the introduction portion. At this time, since the bent edge portion is provided on the hopper main body side, the soil mass can be sheared with a wider width than in the conventional hopper, and crosslinking does not occur easily compared with the conventional.

The conveying apparatus of the soil improver which concerns on this invention 8 is an apparatus for conveying to the mixer which is installed in the soil improver which mixes soil and a soil improver, and improves soil, and mixes the thrown soil with a soil improver, invention 1-invention 7 The hopper as described in any one of these is provided, the conveyance belt conveyor for conveying the soil which fell from the hopper to a mixer, and fixed quantity supply means. The fixed-quantity supply means is arranged above the conveying path by the conveying belt conveyor at a predetermined interval from the conveying belt conveyor, and regulates the conveying amount to the downstream side of the conveyed soil.

Here, according to the researches and experiments of the applicant, it was found that in the soil improver, the larger the interval (introduction width) of the introduction portion of the hopper into which the soil is introduced, the easier it is to collapse the soil mass. However, generally, the conveying apparatus of a soil improver is provided with a fixed quantity supply means in order to supply soil to a mixer quantitatively, and the quantity of conveyance of soil is regulated by this fixed quantity supply means. Therefore, even in the hopper provided upstream of this fixed-quantity supply means, the supply amount of soil will be limited by itself, and there will also be a limit in extending the introduction width of the hopper. And, since the introduction width is limited, as a result, the soil lump is easily crosslinked at the upper end of the introduction portion.

Therefore, in this invention, the hopper as described in any one of the above-mentioned inventions 1-7 is provided, and it does not affect bridge | crosslinking, etc. by a lump in a hopper, without affecting another structure.

As for the conveying apparatus of the soil improver which concerns on 9th invention, in the apparatus of 8th invention, the fixed quantity supply means is arrange | positioned rotatably upward of a conveyance belt conveyor, and the several processus | protrusion for scraping off soil by rotation and conveying to a downstream side The member is a scraping rotor provided on the outer circumference.

Here, the conveyance amount to the downstream side of the soil is regulated by the rotor for scraping off the soil conveyed by the conveyer belt conveyor. Therefore, compared with the case where a control plate, such as a plate, is provided in the downstream of a rotor, a structure becomes simple.

The soil improver according to the tenth embodiment improves soil quality by mixing soil and a soil improver, and includes a conveying device according to the eighth or nineth invention, a hopper for improving, a mixer, and a discharge belt conveyor. The modifier hopper supplies a soil modifier mixed with the soil conveyed by the conveyer belt conveyor. The mixer is disposed on the downstream side of the conveyer belt conveyor and mixes the soil and the soil improver from the improver hopper. The discharge belt conveyor discharges the soil and soil improver mixed by the mixer to the outside of the soil improver.

In this soil improver, soil as raw material soil is introduced into the hopper body from a hydraulic excavator or the like. The soil put into the hopper main body is guided downward along a pair of inclined frame bodies, and is supplied to the lower conveyance belt conveyor through the introduction portion. Thereafter, the soil and the soil improver are mixed by the mixer, and the soil improved soil is discharged to the outside of the soil improver by the discharge belt conveyor.

Also in the soil improver, as described above, the lump is easily collapsed in the hopper, and an appropriate amount of raw soil can be continuously supplied to the conveyer belt conveyor.

As described above, in the present invention, clogging or crosslinking can easily be prevented from occurring in the hopper into which the raw soil is introduced. In addition, in the present invention, the raw material soil can be appropriately supplied to the conveyer belt conveyor on the downstream side without affecting other configurations.

[Overall configuration]

3 shows a self-propelled soil improver according to an embodiment of the present invention. In FIG. 3, a part thereof is shown in cross section. This self-propelled soil improver is provided with a crawler type lower traveling body 1 which can run by a traveling motor, etc., and a vehicle body 2 arranged above the lower traveling body 1.

On one side of the vehicle body 2, a conveying apparatus 3 for conveying raw soil is disposed. In addition, in the center part of the vehicle body 2, the improver supply part 4 which supplies a soil improver, and the mixer 5 for mixing a raw material soil and a soil improver are arrange | positioned. In addition, on the other side of the vehicle body 2, a drive belt 6 and a discharge belt conveyor 7 for discharging the mixed raw soil and the soil improver to the outside of the soil improver are disposed.

[Transfer device]

The conveying apparatus 3 is a conveying direction of a raw soil hopper 10 into which raw soil is fed, a conveying belt conveyor 11 disposed below the raw soil hopper 10, and a conveying belt conveyor 11. And a rotor 12 for scraping out, which is disposed substantially above the central portion of the.

<Raw material hopper>

As shown in FIG.4 and FIG.5, the raw material hopper 10 is a shape which spreads upwards, and is extended in the conveyance direction of soil (left-right direction in FIG. 1). The raw material soil hopper 10 is downwardly from the lower end of each of the hopper main body 16 including a pair of inclined frame bodies 15 opened to open upward and a pair of inclined bodies 15. It has the introduction part 18 containing the pair of lower frame bodies 17 extended and formed. Moreover, the connection part 19 which connects a pair of inclination frame bodies 15 is provided in the upper part of the conveyance direction both ends of the hopper main body 16. As shown in FIG.

Since the pair of inclined frame bodies 15 are formed symmetrically, only the inclined frame body on one side (right side in FIG. 5) will be described. The inclined frame 15 is provided between the first inclined portion 15a inclined at a first inclination angle θ1 with respect to the horizontal plane, and is provided between the first inclined portion 15a and the lower frame body 17 with respect to the horizontal plane. It has the 2nd inclination part 15b inclined by 2nd inclination angle (theta) 2 larger than 1 inclination angle (theta) 1. That is, the inclination frame 15 is bent in the middle so that an upper side may spread outward more than a lower side. This bent part is bent sharply and formed in an edge state, and becomes the upper curved edge part (upper front end part) 20a. Therefore, when the soil mass is put into the raw material hopper 10 from the bucket of the hydraulic excavator, the upper curved edge portion 20a shears and collapses the soil mass.

The pair of lower frame bodies 17 extend downward from the lower end of the second inclined portion 15b and are formed in parallel with each other. This pair of lower frame bodies 17 guide | induces the soil which falls along the hopper main body 16 to the conveyance belt conveyor 11 of the lower side. The boundary between the second inclined portion 15b and the lower frame body 17 is bent sharply and formed in an edge state similarly to the upper bent edge portion 20a, and the lower bent edge portion (charged front end portion) ( 20b).

As described above, in the raw material soil hopper 10, the bent edge portions 20a and 20b, that is, the shear portions for shearing the soil masses, are provided at two upper and lower positions, and the soil mass is easily collapsed as compared with the conventional hopper. Blocking and crosslinking do not occur easily.

<Specific dimensions of each part>

Here, with reference to FIG. 5, an example of the dimension of each part of the raw material hopper 10 is shown below.

First, the maximum opening width W3 of the hopper main body 16 is 2400 mm, and the width W1 of the introduction port of the introduction part 18 is 600 mm. Under the above conditions, simulation was performed when five buckets of raw soil (dirt) were put into the raw soil hopper 10 in a predetermined bucket. As a result of the following dimensional values, clogging or crosslinking could easily occur. It turned out that it did not. The width of the bucket (corresponding to the width of the soil pit) is wider than the width W1 of the inlet.

Width (feeding width) of upper curved edge portion 20a W2: 750 mm

1st inclination angle θ1: 17 °

Height H1 of the second inclined portion: 200 to 300 mm

     (2nd inclination angle θ2: 70 °)

From the above, when the shape where crosslinking does not easily occur with respect to the raw material soil hopper 10 is generalized, it becomes as follows.

(a) The width W2 of the pair of upper curved edge portions is preferably 125% or more and 145% or less of the width of the pair of lower curved edge portions (= introduction width) W1.

When the width W2 of the upper curved edge portion 20a is too wide to exceed 145% compared to the width W1 of the lower curved edge portion 20b, the soil mass sheared from the upper curved edge portion 20a is lower than the lower curved edge portion 20b. ) Is not easily sheared, and clogging and crosslinking are likely to occur. On the contrary, if the width W2 of the upper bend edge portion 20a is smaller than 125% compared to the width W1 of the lower bend edge portion 20b, the effect of providing two bent edge portions up and down is small. It is difficult for the soil mass to collapse, which leads to clogging and crosslinking.

(b) As for 2nd inclination-angle (theta) 2 of the 2nd inclination part 15b, 60 degrees or more and 75 degrees or less are preferable.

This angle range exceeds 45 degree which is the maximum repose angle of the soil. When the second inclination angle exceeds 75 °, as described above, the difference between the width W2 of the upper bent edge portion 20a and the width W1 of the lower bend edge portion 20b becomes small, and the two upper and lower bent edge portions are provided. The effect is small and clogging and crosslinking are likely to occur due to the difficulty of collapse of the clod. On the other hand, when the second inclination angle θ2 is made smaller than 60 °, the inclination of the second inclined portion 15b becomes too gentle, and it becomes difficult for the dirt to fall down along the second inclined portion 15b, thereby making the second inclined portion At 15b the soil is deposited.

<Conveyor Belt Conveyor>

The conveyer belt conveyor 11 is hung and circulated between two rollers, and the conveying path from the lower side of the raw material hopper 10 to the mixer 5 is passed through the lower side of the improving agent supply unit 4. It consists. This conveyance belt conveyor 11 is steel.

<Rotor for scraping>

As mentioned above, the rotor 12 for scraping-out is arrange | positioned above the center part of the conveyance direction of the conveyance belt conveyor 11, and this position is located in the edge part of the conveyance direction downstream of the raw material hopper 10 side. Corresponding. Moreover, the rotor 12 for scraping-out is arrange | positioned above the conveyance belt conveyor 11 at predetermined intervals with the conveyance belt conveyor 11. As shown in FIG.

The rotor 12 for scraping-out is provided with the some protrusion member in the outer periphery, and can be rotated by hydraulic drive. By this scraping-out rotor 12, conveyance of soil is accelerated | stimulated, for example when a moist soil slips on a belt. Moreover, this rotor 12 for scraping out also functions as a fixed quantity supply means which regulates the conveyance amount to the downstream side of the conveyed soil.

[Improving agent supply part]

The improving agent supply part 4 is arrange | positioned above the edge part of the conveyance direction downstream side of the conveyance belt conveyor 11. As shown in FIG. This improver supply part 4 is equipped with the improver hopper 25 in which the soil improver was accommodated, and the improver feeder 26 provided in the bottom part of the improver hopper 25. As shown in FIG.

The reformer hopper 25 is formed in a funnel shape at the lower side, and guides the stored soil improver to the portion of the reformer feeder 26. Although the refiner feeder 26 is abbreviate | omitted about a detailed structure, it is for supplying the soil improver in the improver hopper 25 on the conveyance belt conveyor 11, adjusting an appropriate supply amount.

[Mixer]

The mixer 5 is an apparatus for crushing or mixing the lump of dirt conveyed by the conveyance belt conveyor 11. This mixer 5 is equipped with the cutter 28 arrange | positioned so that it may be close to the conveyance belt conveyor 11 from the top, and the three rotary hammers 29 arrange | positioned under the cutter 28. As shown in FIG.

[drive]

The drive device 6 includes an engine, a radiator, an air cleaner, a hydraulic pump driven by the engine, and the like. In addition, around the drive device 6, a fuel tank, an operating oil tank, and an operation member for running the operation of the lower travel body 1 and the operation of each device are arranged.

[Discharge belt conveyor]

The discharge belt conveyor 7 is a hydraulically driven device, and extends from the lower side of the mixer 5 toward the inclined upper side. And this discharge belt conveyor 7 is for receiving the soil improvement which fell through the mixer 5, and discharge it to the exterior of a soil improver.

[action]

Next, the soil improvement work will be described. As shown in FIG. 3, the hydraulic shovel provided with the bucket is generally arrange | positioned at the raw material soil hopper 10 side of this self-propelled soil improver, and a dump truck etc. waits at the discharge end side of the discharge belt conveyor 7. As shown in FIG. have. Here, the case where the raw soil to be improved is viscous clay with high viscosity will be described.

First, the soil excavated by the bucket of the hydraulic excavator is introduced into the raw soil hopper 10. At this time, the viscous soil falls into the raw soil hopper 10 as a bucket-shaped soil ball. The soil ball dropped in the raw material hopper 10 collides with the bent edge portion 20a on the upper side of the hopper main body 16 and is sheared at this portion, so that a part of the soil ball collapses. A part of this collapsed soil ball and the remaining soil ball move downward along the slope of the second inclined portion 15b.

Then, when the next soil mass falls from the bucket into the raw material hopper 10, the soil mass is pushed further downward. Then, the lumps pushed to the bottom collide with the lower curved edge portion 20b having a smaller shear width than the upper curved edge portion 20a, and are more finely sheared at this portion. In addition, the upper (second) soil mass is to be sheared at the upper bent edge portion 20a in the same manner as the soil mass at the front.

The soil ball that is repeatedly injected as described above is subjected to two shears by the upper bent edge portion 20a and the lower bent edge portion 20b. Therefore, clogging caused in the conventional hopper and crosslinking near the upper end of the introduction portion do not easily occur, and the raw soil is continuously and continuously sent to the conveying belt conveyor 11 side.

Next, the raw soil dropped from the raw soil hopper 10 is conveyed to the mixer 5 side by the conveyer belt conveyor 11. At this time, the raw material soil to be conveyed is scraped off to the downstream side by the rotor 12 for scraping out, and the conveyance amount is regulated. Therefore, a quantity of raw soil is always supplied to the downstream side of the rotor 12 for scraping-out.

Moreover, the soil improver is supplied at the downstream end of the conveyance belt conveyor 11. At this time, the supply amount is adjusted by the improver feeder 26, and the soil improving agent is mixed with the raw material soil at a predetermined ratio.

In addition, the raw soil and the soil improving agent conveyed by the conveyance belt conveyor 11 are crushed and mixed in the mixer 5, and are improved by the soil which can be reused. The improved soil is dropped on the discharge belt conveyor 7, and then discharged to the outside of the soil improver by the discharge belt conveyor 7 and mounted on a dump truck or the like.

[Characteristic]

The present embodiment as described above has the following features.

Since the inclined frame 15 constituting the hopper main body 16 is bent in the middle to form the upper curved edge portion 20a, the lower curved edge portion formed at the boundary between the hopper main body 16 and the inlet portion 18. Along with (20b), the soil ball can be sheared at two places in total. Therefore, the mass is easily collapsed, and clogging and crosslinking at the top of the introduction portion 18 do not easily occur.

In addition, since the upper curved edge portion 20a capable of shearing the soil mass is provided on the inclined frame 15, the width of the front end portion can be set without being influenced by the shape and dimensions of the inlet portion 17. That is, although the shape and dimension of the introduction part 17 are restricted by the structure of the conveyance belt conveyor 11 or the scraping rotor 12, the upper curved edge part 20a formed in the inclination frame body 15a Since () is not limited to these, it is possible to secure a wider shear width, which is an interval of the upper curved edge portion 20a, and to effectively collapse the lump by the upper curved edge portion 20a having a wider shear width. On the contrary, since the hopper can be improved without changing the shape of the inlet 17 or the like, the inlet of the inlet 17 can be set to an appropriate width. Therefore, the soil is uniformly loaded on the conveyance belt conveyor 11, so that the fixed quantity supplyability is not impaired.

Since the upper curved edge portion 20a can be formed by bending a portion of the inclined frame body forming the conventional hopper body to the outside, it can be realized without increasing the manufacturing cost in particular compared with the conventional hopper.

In this embodiment, the shear width W2 of the upper curved edge portion 20a is set to 750 mm, which is 125% of the shear width W1 (600 mm) of the lower curved edge portion 20b, so that the soil ball is effectively sheared at two shear portions. In addition, it is possible to smoothly guide the soil mass sheared by the upper curved edge portion 20a downward.

In addition, since the second inclination angle of the second inclined portion 15b of the hopper main body 16 is set to 70 ° which is larger than the maximum repose angle of the soil, the soil mass can be sheared effectively at two front ends as described above. In addition, it is possible to smoothly guide the soil mass sheared by the upper curved edge portion 20a downward.

[Other Embodiments]

(a) The shape and dimension of each part of the raw material hopper 10 in the said Example are an example, This invention is not limited to these shape and dimension.

(b) The left and right inclined frame bodies 15 and the lower frame bodies 17 constituting the hopper main body 16 and the introduction portion 18 may be formed by bending one plate member, respectively, and the other members are used for welding. You may connect and form by connecting.

(c) In the above embodiment, one upper bent edge portion 20a is formed on the inclined frame 15, but two or more upper bent edge portions may be formed. In this case, however, it is necessary to widen the interval (shear width) by the upper bent edge portion.

(d) In the above embodiment, an example in which the present invention is applied to a self propellered soil improver is shown, but the present invention can be similarly applied to other soil improvers.

1 is a cross-sectional view of a conventional raw soil hopper.

Figure 2 is a schematic diagram for explaining the problem of the conventional raw material hopper.

3 is an overall side view of the self propellered soil improver according to an embodiment of the present invention.

4 is an external perspective view of a raw material hopper of the soil improver.

5 is a schematic cross-sectional view of the raw soil hopper.

[Description of the code]

3: conveying device

4: improver supply

5: mixer

7: discharge belt conveyor

10: raw soil hopper

11: conveying belt conveyor

12: Scraping rotor

15: inclined frame

15a: first inclined portion

15b: second inclined portion

16: hopper body

17: lower frame

18: Introduction

20a: upper bent edge (upper end)

20b: lower bend edge (charge end)

Claims (10)

As a hopper of the soil improver which is installed in the soil improver which mixes soil and a soil improver, and which introduces the soil and guides the thrown soil to the conveying belt conveyor of the lower side, A hopper body including a pair of inclined frame bodies opened to open upward; An introduction portion formed downwardly from a lower end of the pair of inclined frame bodies and including a pair of lower frame bodies for guiding soil introduced into the inclined frame body to the conveying belt conveyor; A pair of charged ends formed of a bent edge portion formed at a boundary between the pair of inclined frame bodies and the pair of lower frame bodies, and for applying a shearing force to the introduced soil mass; A pair of upper front ends, which are installed at a wider interval than the pair of charged ends above the pair of charged ends, for exerting a shear force on the introduced soil ball. Including, The pair of inclined frame bodies of the hopper main body are each provided with a first inclined portion inclined at a first inclined angle with respect to a horizontal plane, and is provided between the first inclined portion and the lower frame body and is less than the first inclined angle with respect to a horizontal plane. Has a second inclined portion inclined at a large second inclination angle, The pair of upper front end portions are formed of curved edge portions formed at a boundary between the first inclined portion and the second inclined portion, 2nd inclination angle of the said 2nd inclination part is 60 degrees or more and 75 degrees or less, Hopper of soil improver. The method of claim 1, The hopper of the soil improver, wherein the space between the pair of upper ends is 125% or more and 145% or less of the space between the pair of charged ends. The method of claim 1, A pair of lower frame bodies of the inlet part are disposed parallel to each other. As a hopper of the soil improver which is installed in the soil improver which mixes soil and a soil improver, and which introduces the soil and guides the thrown soil to the conveying belt conveyor of the lower side, A hopper body including a pair of inclined frame bodies opened to open upward, wherein each of the pair of inclined frame bodies has a larger upper side than the lower side, and has at least one curved edge portion; , It is formed extending from the lower end of the pair of inclined frame body, and comprises a pair of lower frame for guiding the soil introduced into the inclined frame to the conveying belt conveyor, the pair of lower frame An introduction portion in which a connection portion between the sieve and the pair of inclined frame bodies is a bent edge portion Including, The pair of inclined frame bodies of the hopper main body are each provided with a first inclined portion inclined at a first inclined angle with respect to a horizontal plane, and is provided between the first inclined portion and the lower frame body and is less than the first inclined angle with respect to a horizontal plane. Has a second inclined portion inclined at a large second inclination angle, The pair of upper front end portions are formed of curved edge portions formed at a boundary between the first inclined portion and the second inclined portion, The second inclination angle of the second inclined portion is 60 ° or more and 75 ° or less Hopper of soil improver. As a hopper of the soil improver which is installed in the soil improver which mixes soil and a soil improver, and which introduces the soil and guides the added soil to the conveying belt conveyor below, A hopper body including a pair of inclined frame bodies opened to open upward, wherein each of the pair of inclined frame bodies has a larger upper side than the lower side, and has at least one curved edge portion; , And a pair of lower frame bodies for guiding the soil introduced into the hopper body to the conveyer belt conveyor, wherein the pair of lower frame bodies are connected to the lower ends of the pair of inclined frame bodies and extend downward. Introduction Including, The interval of the bent edge portion formed in the pair of inclined frame body is 125% or more and 145% or less of the interval of the connection portion of the pair of lower frame body and the pair of inclined frame body, Hopper of soil improver. As a conveying apparatus of the soil improver, it is installed in the soil improver which mixes soil and a soil improver, and conveys the thrown soil to the mixer which mixes with the soil improver, The hopper according to any one of claims 1 to 5, A conveying belt conveyor for conveying the soil dropped from the hopper to the mixer; Fixed-quantity supply means which is arrange | positioned above the conveyance path by the said conveyance belt conveyor at predetermined intervals with the said conveyance belt conveyor, and regulates the conveyance amount to the downstream side of the conveyed soil. Containing, conveying device of the soil improver. The method of claim 6, The said fixed-quantity supply means is rotatably arrange | positioned above the said conveyance belt conveyor, and conveyance of the soil improver which is a scraping rotor provided with the outer periphery with the several protrusion member for scraping soil by rotation, and conveying to a downstream side. Device. Soil improver that improves soil by mixing soil and soil improver, The conveying apparatus of claim 6, A improver hopper for supplying a soil improver mixed with soil conveyed by the conveying belt conveyor; A mixer disposed on the downstream side of the conveying belt conveyor and mixing soil and soil improver from the improver hopper; Discharge belt conveyor for discharging the soil and soil improver mixed by the mixer to the outside of the soil improver Soil improver comprising. delete delete

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