KR101391434B1 - Assembly type batcher plant - Google Patents

Abstract

The present invention relates to a prefabricated batcher plant which is manufactured by mixing cement, other aggregates, and water. The prefabricated batcher plant includes a silo which stores cement, a supply device which supplies cement, a mixer plant which mixes cement and other aggregates, and a water tank supplies water. In the prefabricated batcher plant, the supply device, the mixer plant, and the water tank can be inserted into the silo during the storage thereof.

Description

[0001] Assembly type batcher plant [0002]

The present invention relates to a granular plant for mixing cement with other aggregates and water. More particularly, the present invention relates to a granular plant for mixing cement, a feeder for feeding cement, a mixer plant for mixing cement and other aggregates, The present invention relates to a prefabricated plant that can insert the feeder, the mixer plant, and the water tank into the silo during storage.

Generally, a batcher plant is a facility that mixes mortar or concrete (also called "remicon") consumed at a construction site, that is, other aggregate materials such as gravel or sand, and water in a suitable ratio to cement .

On the other hand, in registration utility model No. 432529, etc., as shown in Fig. 1, there are provided a planting plant body 20, an aggregate conveyor 22, a mixing mixer 24, a cement silo 30 and a bucket elevator 40 The present invention proposes a plant 10 including the plant.

Therefore, the cement supplied from the cement silo 30 and the gravel, sand and water transferred through the aggregate conveyor 22 can be mixed to provide mortar or concrete as described above.

However, since the above-described conventional batch plant 10 has a structure in which it is supported and fixed by the support body 32, there is a problem in that construction for use is difficult and it is difficult to move to another construction site. In particular, it was more difficult to transfer or export the plant 10 to overseas.

It should be noted that any of the raw material plant body 20, the aggregate conveyor 22, the mixing mixer 24, the cement silo 30 and the bucket elevator 40 constituting the raw material plant 10 And since it is maintained in a fixed state, there is a problem that it is highly restricted in place due to its large volume.

The cement silo 30 is of a tower type and has a structure in which an aggregate conveyor 22 and a mixer 24 are installed around the cement silo 30 so that it is not possible to store a plurality of the source plants 10 in a stacked state there was.

Also, in order to supply the cement to the mixing mixer 24 from the cement silo 30, usually one conveying screw is used. In this case, the supply rate of the cement is slow and the supply of the amount required for the construction is impossible . Therefore, there is a problem that the construction period is increased by the waiting time.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a silo, a cement supply device, a mixer plant and a water tank in a prefabricated manner, And to provide a prefabricated plant for planting which can be produced by the method.

To this end, the prefabricated plant according to the present invention comprises a silo having a space for storing cement therein and an open bottom; A feeder installed to close the open lower portion of the silo, the feeder controlling the discharge of the cement stored in the silo; And a mixer plant installed at a lower portion of the feeder for receiving the cement and mixing the rutted material and the cement. In operation, the silo, the feeder and the mixer plant are spread in the vertical direction, The size of the feeder and the mixer plant is smaller than that of the silo so that the feeder and the mixer plant are inserted into the silo.

At this time, it is preferable that the silo has a container box shape having a length longer than a height.

Preferably, the feeder includes a receiving screw for horizontally transporting cement stored in the silo to a cement outlet and dropping the cement to the mixer plant.

The reciprocating screw is disposed in a plurality of rows (n), and each of the two reciprocating screws is arranged in each row so as to include a plurality of reciprocating screws (nx2), and the cement outlet is the same as the row of the reciprocating screw And the number (n).

The silo may further include a load cell for measuring the weight of the cement filled in the silo.

In addition, when the mixer plant is in operation, it is drawn out from a side surface of the mixer plant, and when stored, is inserted into the mixer plant to be inserted into the silo side together with the mixer plant. And a water tank for supplying water to the water tank.

The water tank may include a front plate that is parallel to the width direction of the mixer plant and a water tank that extends vertically at both ends of the front plate, Shaped water tank including a side plate to be inserted into the water tank, and the water tank of the 'C' shape is preferably provided with a water pool.

The present invention provides a silo, a cement supply device, a mixer plant, and a water tank in a prefabricated manner, thereby allowing a feeder, a mixer plant, and a water tank to be inserted into a silo during storage.

Therefore, it is easy to install at the construction site, the installation time can be shortened, and the movement to another construction site can be facilitated. Especially, if the silos are manufactured in accordance with the specifications of the import and export containers, they can be imported and exported as they are.

In addition, the present invention minimizes volume because the feeder, the mixer plant, and the water tank are both inserted into the silo at the time of storage, and if the silo is inserted and assembled into the silo as described above, a plurality of plant plants can be stacked and stored.

In addition, since the present invention supplies cement simultaneously using a plurality of receiving screws, the supply speed of cement is doubled, so that concrete or mortar necessary for construction can be provided in a timely manner.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
2 is a use state view of the assembled planting plant according to the present invention.
3 is a storage state diagram of the assembled planting plant according to the present invention.
FIG. 4 is a view showing a silo of a prefabricated planting plant according to the present invention. FIG.
5 is a view showing a feeder of a prefabricated guiding plant according to the present invention.
6 shows a mixer plant of a prefabricated planting plant according to the present invention.
7 is a view showing a bottom structure of a prefabricated planting plant according to the present invention.
8 is a view showing a water tank of a prefabricated planting plant according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully with reference to the accompanying drawings, in which preferred embodiments of the present invention are shown.

2, the prefabricated batcher plant includes a silo 100 for storing cement, a feeder 200 for feeding the cement stored in the silo 100, and a feeder And a mixer plant 300 for mixing cement and other aggregates (gravel, sand, etc.).

A water tank 400 for supplying water to the mixer plant 300, a floor structure B for installing the mixer plant 300 and a load cell for measuring the weight of the cement filled in the silo 100 ) ≪ / RTI > (L).

As shown in FIG. 2, when the granular plant is operated, the granular structures 100 to 400 are kept expanded so that cement, aggregate, and water are mixed to supply mortar or concrete to a construction site. That is, the silo 100 is disposed at the upper end of the feeder 200, and the water tank 400 is operated while being drawn to one side of the mixer plant 300.

The silo 100 is lifted by a hydraulic cylinder or a crane and then supported by a support arm A fitted to the side of the mixer plant 300 or by using a support leg (not shown) supporting the other silo 100 And the expanded state is maintained. The water tank 400 is taken out in the form of a drawer, and then a prefabricated pool (not shown) is installed to supply water.

Particularly, when the load cell L for measuring the weight of the cement filled in the silo 100 is further included, the load cell L is installed on the support arm A and the load applied by the silo 100 is measured Cement storage amount can be confirmed.

Of course, the load cell L can be installed anywhere as long as the remaining amount of the cement can be confirmed, including a method of installing the load cell L in the support leg or the floor structure B. [

When the remaining amount of cement is digitally displayed on the instrument panel through the load measured by the load cell L as described above, conventionally, the silo 100 is worn by a handmade hammer to check the remaining amount of cement, It greatly improves.

3 (a) and 3 (b), the water tank 400, the mixer plant 300, and the feeder (not shown) are used in the case of discontinuing use, storage, 200 are inserted into the silo 100 to minimize the volume.

3 (a), the water tank 400 is pushed to be inserted into the mixer plant 300, and then the silo 100 is lowered as shown in FIG. 3 (b) The mixer plant 300, and the feeder 200 to be inserted into the silo 100, respectively.

If the silo 100 is supported by the above-described support arm A, the support arm A is first taken out of the mixer plant 300 and then the silo 100 is lowered. When the silo 100 is placed on the floor If it is supported by a support leg (not shown), the support leg is first removed and the silo 100 is lowered.

The water tank 400 is formed to have a shape of 'c' so that the protrusions of both sides thereof can be inserted into both sides of the mixer plant 300 and can be incorporated into the mixer plant 300. As shown in FIG. have.

The size of the feeder 200 and the mixer plant 300 is relatively smaller than that of the silo 100 so that the silo 100, the feeder 200, and the mixer plant 300 are moved up and down The feeder 200 and the mixer plant 300 are inserted into the silo 100 at the time of storage.

According to the above-described structure, the present invention can be easily installed at the construction site, shorten the installation time, and facilitate the movement to another construction site. Particularly, if the silo 100 is manufactured in conformity with the specifications of the import / export container, it can be exported and imported as it is.

In addition, both the feeder 200, the mixer plant 300, and the water tank 400 are inserted into the silo 100 during storage, thereby minimizing the volume.

In addition, a plurality of plant plants can be stacked and stored. Since the feeder 200, the mixer plant 300 and the water tank 400 are inserted into the silo 100, if the silo 100 is stacked in the height direction, . ≪ / RTI >

More specifically, the silo 100 has an interior space for storing cement. The feeder 200, the mixer plant 300, and the water tank 400 are inserted and positioned in the space when the silo 100 has removed the cement.

Particularly, it is preferable that the silo 100 is formed in a container box shape having a relatively longer length than the height. For example, the silo 100 is a 40H (ft) container capable of storing about 100 tons of cement.

Since the load of the silo 100 is measured by the load cell L described above, the remaining amount of the cement filled in the silo 100 is digitally provided through the instrument panel.

An embodiment of this silo 100 is shown in FIG. 4 (a) is a plan view, Fig. 4 (b) is a side view, and Fig. 4 (c) is a front view. As shown in the drawing, a cement supply port 110 is provided on the upper surface of the silo 100, and an entrance 120 is provided on the side surface for maintenance and repair.

Next, the feeder 200 interrupts supply of the cement stored in the silo 100 to the mixer plant 300 disposed below the silo 100. To this end, the feeder 200 is installed to close the open lower portion of the silo 100 and controls the amount of cement stored in the silo 100.

An embodiment of this feeder 200 is shown in FIG. Fig. 5 (a) is a plan view, and Fig. 5 (b) is a side view. As shown in the drawing, the feeder 200 is a reciprocating screw 210 as an embodiment.

The receiving screw 210 is installed horizontally in the open lower portion of the silo 100 and is rotated by the operating motor. Accordingly, when the receiving screw 210 rotates, the cement stored in the silo 100 is horizontally transported to the cement outlet OUT1 and OUT2.

When the cement horizontally conveyed by the receiving screw 210 is conveyed to the cement outlets OUT1 and OUT2 of the feeder 200, the cement dropped through the cement outlets OUT1 and OUT2 is supplied into the mixer plant 300 .

The mixer plant 300 is provided with cement inlet ports IN1 and IN2 connected to the cement outlets OUT1 and OUT2 to receive cement dropped from the cement outlets OUT1 and OUT2.

The receiving screw 210 is arranged in a plurality of rows n so that a large amount of cement can be supplied at a rapid rate and two receiving screws 210 are arranged for each row to form a plurality of receiving screws 210 2).

Of course, the cement outlets OUT1 and OUT2 provided in the feeder 200 are also made of the same number (n) as the rows of the receiving screws 210, and the receiving screws 210 of each row are provided at the end portions Outlet).

In FIG. 5, the reciprocating screw 210 having two rows is taken as an example. At this time, a first receiving screw 210a and a second receiving screw 210b are installed in a first column, and a third receiving screw 210c and a fourth receiving screw 210d are installed in a second column.

The first reception screw 210a and the second reception screw 210b transport the cement toward the first cement outlet OUT1 disposed at the center of the first reception cage 210a and fall into the mixer plant 300, The second reception cage 210c and the fourth reception claw 210d transport the cement toward the second cement outlet OUT disposed at the center side thereof so as to be dropped into the mixer plant 300. [

At this time, the first to-be-received screws 210a to 210d are installed in the hopper-shaped guides 220, respectively, so that the cement filled in the guide 220 during the rotation of the receiving screw 210 is efficiently transported .

According to the construction as described above, conventionally, the cement supply speed (or supply amount) is about four times as much as that in the case where cement is supplied by using one delivery screw (not shown). Therefore, it is possible to provide a sufficient amount of mortar or concrete in a short time.

Next, the mixer plant 300 is installed at a lower portion of the feeder 200 to receive cement, and mixes cement with other aggregate such as gravel or sand. And receives water from the water tank 400.

The mixer plant 300 and the feeder 200 are generally integrally connected and the feeder 200 is fixed to the upper portion of the mixer plant 300 so as to receive the cement dropped from the feeder 200. The rudder material such as gravel or sand is supplied to the mixer plant 300 by a conveyor (not shown).

The feeder 200 and the mixer plant 300 are smaller than the silo 100 as described above and are inserted into the silo 100 when stored and moved. In order to stably move the mixer plant 300 and the feeder 200 toward the inside of the silo 100, various sliding guides (not shown) are formed on the inner wall surface of the silo 100 or the outer wall surface of the mixer plant 300 .

An embodiment of such a mixer plant 300 is shown in FIG. 6 is a top view of the silo 100. FIG. As shown in the figure, a mixer 310 is provided at the center of the mixer plant 300 to mix water, aggregate and cement. A first chamber 320 used as a field office and a tool storage box and a second chamber 330 provided with a control box, an engine power pack, a water pump, and the like are provided on the other side of the mixing unit 310.

At this time, a mixer, a filter, and the like are installed in the mixing unit 310, and water, aggregate, and cement are supplied to each other to produce mortar, concrete, and the like. On the upper surface of the mixing unit 310, cement inlet ports IN1 and IN2 through which cement dropped by the feeder 200 are formed.

A hopper or a drop guide hole may be used as the cement inlet IN1 or IN2 and a filter may be installed in the flow passage of the cement inlet IN1 or IN2 so that only fine particles of cement can be supplied.

In Fig. 6, two cement inlet ports IN1 and IN2 are shown as an example. As described above, since the receiving screws 210 of the feeder 200 are formed in two rows and the cement outlets OUT1 and OUT2 are also two, the cement inlet IN1 and IN2 are correspondingly two.

The mixer plant 300 is preferably placed on the floor structure B as shown in FIG. 7. The floor structure B is formed by crossing the horizontal frame and the vertical frame, for example, so as to support the mixer plant 300 do.

Particularly, when the mixer plant 300 is inserted into the silo 100, the bottom structure B blocks the open lower portion of the silo 100 so that the mixer plant 300 and the feeder 200 are released downward ≪ / RTI > The floor structure B may be fixed to the lower portion of the silo 100 by a screw coupling method or the like.

Next, the water tank 400 supplies water to the mixing portion 310 of the mixer plant 300, thereby mixing the cement supplied from the silo 100 and other aggregate supplied from the outside through the conveyor.

It is preferable that the width of the water tank 400 is designed to be equal to the width of the mixer plant 300 to maximally increase the water storage capacity. However, the width of the water tank 400 does not necessarily have to be the same as the width of the mixer plant 300. That is, the size of the water tank 400 is freely changeable.

When the water tank 400 is further provided, the water tank 400 is preferably inserted into the silo 100 together with the mixer plant 300 and the feeder 200 and stored.

Accordingly, the water tank 400 is drawn out from the side of the mixer plant 300 when the water tank 400 is operated as a drawer, and is drawn into the mixer plant 300 when the water tank 400 is stored.

8 illustrates a structure in which the water tank 400 can be drawn into the mixer plant 300 or drawn out from the mixer plant 300 as described above. 8 (a) is a plan view, and Fig. 8 (b) is a front view.

As shown in the figure, the water tank 400 includes a front plate that is parallel to the width direction of the mixer plant 300, and a side plate that extends vertically at both ends of the front plate and is inserted into the inlet space IS of the mixer plant 300. [ Quot; C " shape.

Therefore, both side plates of the 'C' shaped water tank 400 can be inserted into the mixer plant 300 so as to be in contact with both sides of the mixer plant 300. If the width of the water tank 400 is smaller than the width of the mixer plant 300, it is inserted into the mouth space IS as an example.

The water tank 400 is also inserted into the silo 100 together with the mixer plant 300 since the front plate of the water tank 400 is in close contact with the mixer plant 300 in a state where the water tank 400 is completely inserted. do.

However, if the water tank 400 is formed in a 'C' shape, water can not be stored in the water tank 400. In this case, a pool (not shown) capable of storing water should be additionally provided. The assembled pool is installed in the fixture of the water tank (400).

The prefabricated swimming pool is composed of a tent or the like as is well known, and is completely unfolded and fixed to the water tank 400. That is, the assembled pool is struck in the water tank 400. The water stored in the assembled pool is supplied to the mixing unit 310 of the mixer plant 300 by a water pump installed in the second chamber 330 of the mixer plant 300.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

100: silo
200: Feeder
210a, 210b, 210c, 210d:
300: Mixer plant
400: Water tank
B: floor structure
L: Load cell

Claims (6)

A silo 100 having a space for storing cement therein and an open bottom;
A feeder 200 installed to close the open bottom of the silo 100 and controlling the discharge of cement stored in the silo 100; And
And a mixer plant (300) installed at a lower portion of the feeder (200) to receive the cement and mix the rutting material and the cement,
The silo 100, the feeder 200 and the mixer plant 300 are opened in the vertical direction so that the feeder 200 and the mixer plant 300 are inserted into the silo 100 when the silo 100 is in operation. Wherein the feeder (200) and the mixer plant (300) are smaller in size than the silo (100). The method according to claim 1,
Wherein the feeder (200) comprises a reciprocating screw (210) for horizontally feeding the cement stored in the silo (100) to the cement outlets (OUT1, OUT2) and dropping the cement to the mixer plant (300) . 3. The method of claim 2,
The receiving screws 210 are arranged in a plurality of rows n and two rows of the receiving screws 210 are arranged in each row to include a plurality of receiving screws 210 (nx2) (OUT1, OUT2) are made of the same number (n) as the rows of the receiving screws (210). The method according to claim 1,
Further comprising a load cell (L) for measuring the weight of the cement filled in the silo (100). 5. The method according to any one of claims 1 to 4,
And is drawn out from the side of the mixer plant 300 at the time of operation and is inserted into the mixer plant 300 at the time of storage to be inserted into the silo 100 side together with the mixer plant 300, Further comprising a water tank (400) for providing water used for mixing the cement and the other aggregate in the water tank (300). 6. The method of claim 5,
In the front surface of the mixer plant 300, two inlet spaces IS are formed at positions spaced apart from each other,
The water tank 400 includes a front plate that is parallel to the width direction of the mixer plant 300 and a side plate that extends vertically at both ends of the front plate and is inserted into the mixer plant 300, Shaped water tank (400) is provided with a prefabricated pool for storing water. ≪ IMAGE >

Images