KR102152812B1 - Vertical type transporting apparatus of aggregate - Google Patents

Abstract

The present invention relates to a vertical aggregate transporting apparatus capable of maximizing space utilization through vertical transport of aggregate and preventing the aggregate from being frozen in winter. More specifically, the vertical aggregate transporting apparatus comprises: at least one hopper including a storage space having aggregate stored therein, an opening/closing hole disposed on the lower part of the storage space to selectively discharge the aggregate stored in the storage space, and a transport conveyor transporting the aggregate discharged through the opening/closing hole to a selected transfer position; and a vertical transport unit vertically installed at a position spaced apart from the hopper and transporting the aggregate transported to the transfer position from a lower part to an upper part.

Description

Vertical type transporting apparatus of aggregate}

The present invention relates to a vertical aggregate transport device configured to maximize space utilization through vertical transport of aggregates and prevent freezing of aggregates in winter.

Shotcrete refers to a mortar that blows cement, coarse aggregate, sand, steel fiber, water, and quick-setting agents into compressed air. Because it is high, it is used for waterproofing mortar finish, protection of rock, repair of concrete and rust prevention of steel materials.

In particular, at the tunnel construction site, shotcrete is used in linings for building tunnels. The shotcrete used to construct a tunnel is manufactured to be clearly distinguished from general concrete, so that the shotcrete sprayed during tunnel construction adheres well to the ceiling and must be cured (cured) within a short time, and after it is cured, it must be able to block moisture. It should have some high strength characteristics.

Such shotcrete is made to be discharged after mixing coarse aggregates such as cement and gravel, sand, steel fibers, and fluidization such as water and hardener, which are required for one batch, into a mixer, stirred, and then discharged.

As an example of the prior art, the'concrete batch plant' described in Patent Registration No. 10-1224550 (registered on January 15, 2013) is exemplified.

In the batch plant according to the prior art, a fine aggregate storage unit for storing fine aggregates such as sand, a mineral storage unit, and a coarse aggregate storage unit such as gravel are arranged in series toward a concrete mixer, and a cement silo for storing cement on the opposite side thereof, and Arranged in mineral silos. Fine aggregates, minerals, coarse aggregates, etc. discharged from the respective storage units are dropped to the top of a conveyor arranged in series at the bottom thereof and transferred to a concrete mixer.

However, in the batch plant of the prior art, horizontal structures are applied as a transfer means for individual transfer for each aggregate or other additives such as steel fibers as a serial arrangement. As a large site area must be secured, it is narrow in terms of structure. There was a problem that it could not be installed in the place.

Korean Patent Registration No. 10-1224550

Accordingly, an object of the present invention is to provide a vertical aggregate conveying device capable of constructing a mixing plant even in a narrow space and excellent space utilization by having a vertical conveying structure of aggregate.

The vertical aggregate conveying device of the present invention for achieving the above-described objects includes an accommodation space in which aggregates are stored, an opening and closing opening for selectively discharging the aggregate stored in the accommodation space and the aggregate discharged through the opening. One or more hoppers including a transfer conveyor for transferring the transport to the selected delivery point; And a vertical transfer unit installed in a vertical direction at a position spaced apart from the hopper and for transferring the aggregate transferred to the transfer point from the bottom to the top.

As an example, the vertical transfer unit may include a first sprocket rotating by a rotational force transmitted from the outside; A second sprocket installed at a lower portion of the first sprocket and connected to the first sprocket through a power transmission member to rotate and interlock; A plurality of transfer trays coupled to the power transmission member at a predetermined interval to rotate between the first sprocket and the second sprocket, providing a transfer space therein, and having an opening formed on an upper surface based on an ascending direction; A loading unit installed adjacent to the opening of the transfer box that rises by turning the second sprocket and receives the aggregate discharged from the transfer point and loads it into the opening of the adjacent transfer box; And a discharge unit installed to be adjacent to the opening of the transfer box that rotates and descends the first sprocket and receives the aggregate discharged through the opening in the process of turning the first sprocket and discharges the aggregate at a selected discharge point. It is a feature.

As an example, the upper surface of the transfer box is characterized in that a downward slope is formed from the inner side adjacent to the power transmission member toward the outer side.

As an example, the vertical transfer unit may further include a housing for accommodating the first sprocket, the second sprocket, and a transfer box and having an inlet port and an outlet port respectively at positions facing the loading unit and the discharge unit. It is a feature.

As an example, the vertical transfer unit is mounted inside the housing and sprays hot air according to an external control signal to maintain a temperature inside the housing at a preset temperature.

As an example, the vertical transfer unit may further include a heating coil mounted along the inner surface of the housing and heated according to an external control signal to maintain a temperature inside the housing at a preset temperature.

The vertical aggregate conveying device of the present invention can improve the problem of the conventional mixing plant in which sufficient land area must be secured by the horizontal conveying structure by having excellent space utilization through the vertical conveying of aggregates. As a result, it is possible to build a mixing plant even in a narrow space.

In addition, the vertical aggregate transfer device of the present invention provides a heating means inside the vertical transfer unit for transferring the aggregate so that the moisture contained in the voids between the aggregates is not frozen, so that the transfer and discharge of the aggregate can be maintained normally even in winter. It has the effect of making it possible.

1 is a side view showing the configuration of a vertical aggregate transfer device according to an embodiment of the present invention.
Figure 2 is a perspective view showing the configuration of a vertical aggregate transport device according to an embodiment of the present invention.
Figure 3 is a side cross-sectional view illustrating a vertical transfer unit aggregate delivery process according to an embodiment of the present invention.
Figure 4 is a side cross-sectional view for explaining the aggregate discharge process of the vertical transfer unit according to an embodiment of the present invention.
Figures 5a to 5c is a side cross-sectional view showing the operating state of the vertical aggregate transfer device according to an embodiment of the present invention.
6A and 6B are side cross-sectional views showing a heating means of a vertical transfer unit according to an embodiment of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, terms or words used in the present specification and claims are the present invention based on the principle that the inventor can appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as a meaning and concept consistent with the technical idea of

Referring to FIG. 1, the vertical aggregate transfer device of the present invention includes a hopper 10 for receiving aggregates such as sand, and a vertical transfer unit for receiving aggregates received in the hopper 10 and transferring them to a selected discharge point. It includes (20).

The hopper 10 is provided in a receiving space 110 in which aggregates containing sand are stored, and an opening 120 provided below the receiving space 110 to selectively discharge the aggregates stored in the receiving space 110, and the It includes a transport conveyor 100 for transporting the aggregate discharged through the opening 120 to the selected delivery point.

The hopper 10 may have a conventional structure having a shape in which the width of the accommodation space 100 becomes narrower toward the bottom for smooth aggregate discharge through the opening and closing opening 120.

The hopper 10 is provided for each particle size or type of aggregate, and FIG. 1 shows an example in which two hoppers 10 are provided.

When the hopper 10 is configured in plural, the transfer conveyor 100 of each hopper 10 is arranged so that the aggregate can be transferred to different delivery points, as shown in FIG. 2, and at each delivery point Aggregate is transferred to the vertical transfer unit 20 that is installed independently so that it can be transferred individually.

In addition, the hopper 10 is provided with a screen 130 composed of a mesh structure at the inlet and a vibrator 140 for imparting vibration to the screen 130, so that foreign matter having a particle diameter larger than that of the aggregate to be accommodated in the storage process of the aggregate is Make it possible to pre-screen.

The vertical transfer unit 20 is fixedly installed in a vertical direction at a position spaced apart from the hopper 10 and transfers the aggregate transferred to the transfer point from the bottom to the top.

That is, in the present invention, the aggregate discharged from the hopper 10 is transported in a vertical direction, so that it does not have to occupy a large area compared to the horizontal transport method of the conventional blending plant, so there is an excellent advantage in terms of space utilization.

Hereinafter, a vertical transfer unit 20 according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4.

The vertical transfer unit 20 includes a first sprocket 200 and a second sprocket 210, a transfer box 220, a loading unit 230, and a discharge unit 240.

The first sprocket 200 is rotated by a rotational force transmitted from the outside.

For example, the vertical transfer unit 20 may further include a rotation motor 290 that imparts a rotational force, and the rotation axis of the rotation motor 290 and the rotation axis of the first sprocket 200 are connected through a belt or a chain. Connect it so that the rotational force can be transmitted.

The second sprocket 210 is spaced apart from the lower portion of the first sprocket 200 and is connected to the first sprocket 200 through a power transmission member 280 and interlocked in the same rotation direction, thereby allowing vertical transfer of the aggregate. To form a vertical structure.

At this time, the power transmission member 280 may be a normal chain connected to be engaged with the sprocket, and the first sprocket 200 and the second sprocket 210 may be installed spaced apart from each other in a parallel position. In this case, it is natural that the power transmission member 280 is also configured as a pair.

Two or more of the transfer boxes 220 are coupled to the power transmission member 280 at predetermined intervals to rotate around a vertical structure formed between the first sprocket 200 and the second sprocket 210, and the The aggregate is transferred to the delivery point and transferred to the top so that it can be discharged.

For example, the transfer box 220 is composed of a plurality of side plates to provide a transfer space capable of accommodating aggregates transmitted from a delivery point, and one side plate in contact with the power transmission member 280 among the plurality of side plates is a power transmission member. The pin 224 is coupled to the 280, and an opening 221 communicating with the transfer space is formed on the upper surface based on the rising direction.

At this time, the upper surface of the transfer box 220 has a downward slope from the inside to the outside adjacent to the power transmission member 280, and the transfer space has a shape whose width becomes narrower from the top to the bottom. By doing so, it is possible to efficiently load and discharge the aggregate into the transport space through the loading unit 230 described below.

The loading part 230 is installed to be adjacent to the opening 221 of the transfer box 220 that rises from one side of the vertical structure by turning the second sprocket 210, and receives the aggregate discharged from the delivery point. It is loaded into the transfer space through the opening 221 of the adjacent transfer box 220.

Preferably, the loading part 230 is a shatterproof box 231 that prevents scattering of the conveyed aggregate by opening one side and the lower surface facing the conveying conveyor 100 at the delivery point as shown in FIG. 3. ) And, while forming an inclined surface on one side, the upper surface that comes into contact with the open lower surface of the scattering prevention box 231 is opened, and the second sprocket 210 is rotated on one side facing the transfer box 220 It includes a loading box 232 in which a through hole is formed in a portion adjacent to the opening 221 of the rising transfer box 220.

The discharge unit 240 is installed to be adjacent to the opening 221 of the transfer box 220 that is lowered from the other side of the vertical structure by turning the first sprocket 200, and rotating the first sprocket 200 In the process, the aggregate to be poured through the opening 221 is delivered and discharged from the selected discharge point.

It is preferable that the discharge unit 240 is also configured in a box shape having a downward inclined surface like the loading unit 230 so that the delivered aggregate is discharged naturally by potential energy.

Meanwhile, the vertical transfer unit 20 according to the present embodiment may further include a housing 250 for protecting a vertical structure formed by the first sprocket 200 and the second sprocket 210.

That is, the housing 250 accommodates the first sprocket 200, the second sprocket 210, and the transfer box 220, and at positions facing the loading part 230 and the discharge part 240, respectively An inlet port 251 and an outlet port 252 are configured.

Here, the housing 250 not only has the purpose of protecting the aggregate being transported from external environments such as snow or rain, but also has a function of preventing moisture contained in the voids between aggregates in winter.

That is, in the case of sand, since the particles are relatively smaller than other aggregates, when moisture is frozen in winter, they are fixed to each other in the transfer space of the transfer box 230 and are not easily separated, so that the transfer of the aggregates through the vertical transfer unit 20 and Since the discharge is not smooth, the vertical transfer unit 20 of the present invention further includes a heating means for preventing the temperature inside the housing 250 from dropping below zero as a configuration for solving the above problem.

For example, as shown in FIG. 6A, at least one heating means is mounted inside the housing 250, that is, on the inner surface of the housing 250, and sprays hot air according to an external control signal to reduce the temperature inside the housing 250. It may include a hot air spray unit 260 to be kept constant.

The hot air spray unit 260 is not shown in the drawing, but a hot air transfer pipe along the inner side of the housing 250 and a discharge hole are installed in the hot air transfer pipe at specified intervals to transfer hot air to the inside of the housing 250 In the case of temperature control, a PID control method and a tube heater are used to control a constant temperature, and hot air can be supplied by forced injection of hot air using a ring blower or an air compressor.

As another example, the heating means is a heating coil mounted along the inner surface of the housing 250 as shown in FIG. 6B and heated according to an external control signal so that the internal temperature of the housing 250 is maintained at a preset temperature. 270) may be included.

Hereinafter, an operating state of the present invention will be described with reference to FIGS. 5A to 5C.

First, the aggregate stored in the hopper 10 is discharged with a set blending weight or a set discharge weight through the opening 120 of the hopper 10, and is dropped and settled on the transfer conveyor 100.

The aggregate seated on the transfer conveyor 100 of the hopper 10 is transferred in one direction according to the operation of the transfer conveyor 100 and reaches the transfer point.

The aggregate transferred to the delivery point of the hopper 10 freely falls through the scattering prevention box 231 and the loading box 232 of the loading section 230 and introduced into the vertical transfer section 20, FIG. 5B As shown in Fig. 1, the first sprocket 200 and the second sprocket 210 continuously ascend and descend by the plurality of conveying boxes 220 that rise past the loading part 230 and rise. Aggregate falling through the through hole of the loading box 232 is loaded in 220.

Meanwhile, the transport boxes 220 containing aggregates rise toward the first sprocket 200 from one side of the vertical structure, and the angle of the opening 221 is changed in the process of rotating the circumference of the first sprocket 200. The position gradually goes downward, and when it is in a position to descend from the other side of the vertical structure by completely passing the first sprocket 200, the opening 221 is directed toward the ground. In the above-described process, the transfer box 220 The aggregate accommodated in is discharged through the opening 221.

That is, as shown in FIG. 5C, the aggregate accommodated in the transfer box 220 is discharged in a certain section in which the transfer box 220 rotates the first sprocket 200 and descends from the other side of the vertical structure.

And the discharged aggregate is delivered to the discharge unit 240 that covers the above-mentioned predetermined section, and freely falls through the structure of the discharge unit 240 having a downward inclined surface to be discharged to the selected discharge point. While the process is repeated, the discharge of the aggregate is carried out continuously.

Such vertical transport of aggregates by the operation of the present invention can be applied to a vertical blending plant system.

As an example, the above-mentioned vertical mixing plant is a tower structure composed of a plurality of layers, and may include a mixing device for producing shotcrete by mixing at least one aggregate storage tank and aggregate discharged from the aggregate storage tank according to a preset mixing ratio. In addition, the vertical aggregate transfer device of the present invention is capable of selecting an aggregate storage tank of the vertical mixing plant as a discharge point.

As described above, the vertical aggregate transport device of the present invention improves the problem of a conventional blending plant, that is, the disadvantage of securing a sufficient land area by a horizontal transport structure, by allowing the vertical transport of aggregate to be implemented. It is excellent and it provides a structure that allows the construction of a blending plant even in a relatively narrow space.

As described above, although the present invention has been described by a limited embodiment, the present invention is not limited thereto, and the technical idea of the present invention and the patents to be described below by those of ordinary skill in the art to which the present invention pertains. It will be said that various modifications and variations are possible within the scope of the claims.

10: hopper 20: vertical transfer unit
100: transfer conveyor 200: first sprocket
210: second sprocket 220: transfer
221: opening 230: loading portion
240: discharge unit 250: housing
251: inlet 252: outlet
260: hot air spray unit 270: heating coil

Claims (6)

One or more hoppers including a receiving space in which aggregates are stored, an opening provided below the receiving space and selectively discharging the aggregates stored in the receiving space, and a transfer conveyor transferring the aggregates discharged through the openings to a selected delivery point; And
Including; a vertical transfer unit installed in a vertical direction at a position spaced apart from the hopper and for transferring the aggregate transferred to the transfer point from the bottom to the top,
The vertical transfer unit,
A first sprocket rotating by a rotational force transmitted from an external driving source;
A second sprocket installed at a lower portion of the first sprocket and connected to the first sprocket through a power transmission member configured to engage with the first sprocket and rotated in the same direction;
It is coupled to the power transmission member at a predetermined interval and rotates around a vertical structure formed between the first sprocket and the second sprocket according to the operation of the driving source, and an opening is formed on the upper surface based on the rising direction. A transfer space is provided in the transfer space, and when the second sprocket is rotated and ascended, the aggregate moved to the transfer point is accommodated in the transfer space to move upward, and the opening when descending by turning the first sprocket A plurality of transfer boxes inclined in a downward direction to discharge aggregates accommodated in the transfer space;
A loading unit installed adjacent to the opening of the transfer box that rises by turning the second sprocket and receives the aggregate discharged from the transfer point and loads it into the opening of the adjacent transfer box; And
And a discharge unit installed to be adjacent to the opening of the transfer box that rotates and descends the first sprocket and receives the aggregate discharged through the opening in the course of turning the first sprocket and discharges the aggregate at a selected discharge point. Vertical aggregate transfer device.
delete The method of claim 1,
The vertical aggregate transfer device, characterized in that the upper surface of the transfer box is formed with a downward slope from the inside to the outside adjacent to the power transmission member.
The method of claim 1,
The vertical transfer unit,
A vertical aggregate transfer device comprising: a housing that accommodates the first sprocket, the second sprocket, and a transfer box and has an inlet port and an outlet port respectively at positions facing the loading part and the discharge part.
The method of claim 4,
The vertical transfer unit,
And a hot air spray unit mounted inside the housing and spraying hot air according to an external control signal to maintain a temperature inside the housing at a preset temperature.
The method of claim 4,
The vertical transfer unit,
A heating coil mounted along the inner side of the housing and heated according to an external control signal so that the temperature inside the housing is maintained at a preset temperature.

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