KR101897965B1 - lightweight aerated concrete supply - Google Patents

Abstract

An automatic lightweight foamed concrete supply device is disclosed. The automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention includes: a storage unit 100 in which materials to be charged into lightweight foamed concrete and water are separately stored; A metering unit 200 provided with a sensing unit 210 for receiving a material and water from the storage unit 100 and sensing weight; The first mixer 410 is provided with a first mixer 410 and a second mixer 420. The first mixer 410 mixes the various materials and water into a mixture. The first mixer 410 mixes the materials metered by the metering unit 200 and the water metered in a fixed amount, Unit 400; A second mixer unit (500) positioned below the first mixer unit (400) and introducing the mixture dropped from the first mixer unit (400); A feeding unit 600 connected to the second mixer unit 500 through a first connecting pipe 10 to feed the mixed mixture to a feeding position; And a bubble supply unit 800 connected to an arbitrary position in an extended path of the extension pipe 700 extending from the outlet end of the pressure transfer unit 600 to the injection position and supplying bubbles to the mixture.

Description

Lightweight aerated concrete supply < RTI ID = 0.0 >

The present invention relates to an automatic lightweight foamed concrete supply apparatus capable of collectively weighing materials and water constituting a lightweight foamed concrete, and collectively collecting the mixed materials, and then easily feeding the mixed materials to a charging position.

Generally, lightweight foamed concrete is used for insulation or backfilling in construction sites. The lightweight foamed concrete uses cement, lightweight aggregate and water as main materials, and additionally additives.

The lightweight foamed concrete is laid on the upper surface after the floor slab of the building is constructed, thereby improving the heat insulation performance, minimizing the occurrence of unnecessary cracks, mitigating the impact noise, and preventing noise between the rooms due to excellent sound insulation effect.

Further, after the lightweight foamed concrete is laid on the floor slab, defects such as cracks or deterioration of the heat insulation performance are not generated and the stable construction performance is maintained.

In order to blend lightweight foamed concrete having such characteristics, it is mostly due to the skilled worker's experience and guesswork, and lightweight foamed concrete blended in this manner causes a lot of defects in the construction site due to uneven quality have.

1, a worker inputs cement and a lightweight aggregate bag into the mixer 4 at an arbitrary weight in the field, and water stored in the water pack 6 is supplied to the mixer 4 do. When the bubbles generated in the compressor 2 are supplied to the mixer 4 through the hose, the blades located in the mixer 4 rotate and start mixing.

And a method of pumping mixed cement and lightweight aggregate to each required point by using a pump was mainly used. In this case, the exact amount of the cement, water, and lightweight aggregate must be kept constant, but the uniformity of quality can not be maintained stably due to the experience of the field or the worker.

Korean Patent Publication No. 10-2016-0015475

The embodiments of the present invention can collectively mix lightweight foamed concrete cement, lightweight aggregate, and water, which are charged into the floor slab of a building, in a batch manner, and mix and transport it exactly by a planned amount. Thus, uniformity of lightweight foamed concrete The present invention is to provide an automatic lightweight foamed concrete supply apparatus that maintains a constant amount of the foamed concrete.

The automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention includes: a storage unit 100 in which materials to be charged into lightweight foamed concrete and water are separately stored; A metering unit 200 provided with a sensing unit 210 for receiving a material and water from the storage unit 100 and sensing weight; The first mixer 410 is provided with a first mixer 410 and a second mixer 420. The first mixer 410 mixes the various materials and water into a mixture. The first mixer 410 mixes the materials metered by the metering unit 200 and the water metered in a fixed amount, Unit 400; A second mixer unit (500) positioned below the first mixer unit (400) and introducing the mixture dropped from the first mixer unit (400); A feeding unit 600 connected to the second mixer unit 500 through a first connecting pipe 10 to feed the mixed mixture to a feeding position; And a bubble supply unit 800 connected to an arbitrary position in an extended path of the extension pipe 700 extending from the outlet end of the pressure transfer unit 600 to the injection position and supplying bubbles to the mixture.

The storage unit 100 includes a first storage unit 110 for supplying cement; A second storage part (120) provided separately from the first storage part (110) and provided for supplying lightweight aggregate; And a third storage unit 130 provided separately from the first and second storage units 110 and 120 to supply water.

The metering unit 200 includes a first metering unit 201 having a predetermined size, the diameter of which decreases toward the first mixer unit 400, and the cement used as the material of the lightweight foamed concrete is introduced. A second metering unit 202 into which lightweight aggregate is injected; And a third metering unit 203 into which water is introduced, and the sensing unit 210 includes a first sensing unit 212 positioned at an inner lower portion of the first metering unit 201; A second sensing unit 214 located at an inner lower portion of the second metering unit 202; And a third sensing unit 216 positioned at the lower inner side of the third metering unit 203.

The conveyance unit 300 may further include a conveyance unit 300 for conveying the material of the lightweight foamed concrete to the metering unit 200. The conveyance unit 300 may be configured to convey the cement supplied from the first storage unit 110 A first conveying screw 310; A first conveying unit 310 having a first auxiliary screw 312 positioned horizontally above the first conveying screw 310 for horizontally conveying the cement conveyed to an upper end of the first conveying screw 310, A second conveyance screw 320 for conveying the lightweight aggregate supplied from the second storage unit 120 to a vertical upper portion; And a second conveying screw 322 having a second auxiliary screw 322 horizontally positioned above the second conveying screw 320 to convey the lightweight aggregate conveyed to the upper end of the second conveying screw 320 in a horizontal direction, (303).

The first mixer unit 400 and the second mixer unit 500 are positioned on the support frame 50 in a vertically opposed state and the second mixer unit 500 is positioned on the first mixer unit 400, And is positioned eccentrically from the lower side to the one side.

The first mixer unit (400) has an exhaust gate (402) on the lower side which is opened or closed to drop the mixture into the second mixer unit (500). And a door driving unit 404 provided for the movement of the discharge gate 402.

The first mixer unit 400 receives the rotational force generated by the first mixer 410 located at the center of the upper side and receives the rotational force generated by the first mixer 410 to rotate the first mixer unit 400, The first mixer unit 400 is provided with an agitator 420 and the first mixer unit 400 is provided with a first mixer unit 400 for dropping the residual mixture remaining in the first mixer unit 400 into the second mixer unit 500. [ And a first agitating blade 422 provided along a rim facing the inner side of the first agitating blade 422.

The second mixer unit 500 receives the rotational force generated by the second mixer 510 positioned at the upper center and rotates the second mixer unit 500 so that the mixture located inside the second mixer unit 500 is mixed with each other. And the second mixer unit 500 is provided with an agitator 520. The second mixer unit 500 is provided with the second mixer unit 500 along the rim of the second mixer unit 500 facing the inner side thereof so as to minimize the residual mixture remaining inside the second mixer unit 500 And a second agitating blade 522 provided thereon.

The first stirring blade 422 is made of a flexible material.

The bubble supplying unit 800 includes an air compressor 810 for generating compressed air; And a measuring unit 820 for measuring the amount of compressed air generated in the air compressor 810.

The extension pipe 700 is provided with a plurality of connection ports 710 provided in a path extended to connect the bubble supplying unit 800 and the connection port 710 is disposed at the outlet end of the pressure feeding unit 600 A first connection port 712; And a second connection port 714 provided near the extended end of the extension pipe 700. The bubble supply member 800 is connected to the first connection port 712 or the second connection port 714 And is selectively coupled to any one of the positions.

The automatic lightweight foamed concrete device according to another embodiment of the present invention includes: a storage part 100 in which a material to be charged into lightweight foamed concrete and water are separately stored; A metering unit 200 provided with a sensing unit 210 for receiving a material and water from the storage unit 100 and sensing weight; The first mixer 410 is provided with a first mixer 410 and a second mixer 420. The first mixer 410 mixes the various materials and water into a mixture. The first mixer 410 mixes the materials metered by the metering unit 200 and the water metered in a fixed amount, Unit 400; A second mixer unit (500) positioned below the first mixer unit (400) and introducing the mixture dropped from the first mixer unit (400); A feeding unit 600 connected to the second mixer unit 500 through a first connecting pipe 10 to feed the mixed mixture to a feeding position; A bubble supplying unit 800 connected to an arbitrary position in an extended path of the extension pipe 700 extending from the outlet end of the pressure transfer unit 600 to the injection position and supplying bubbles to the mixture; And a control unit 900 for controlling the quantity of the cement, the lightweight aggregate and the water in a predetermined amount, and selectively controlling the operation state of the first and second mixer units 400 and 500 and the amount of bubbles generated in the bubble supplying unit 800 The control unit 900 controls the amount of the cement, the lightweight aggregate and the water collectively, and the cement, the lightweight aggregate, and the water are supplied to the metering unit 200 The control unit controls the time required for the supply to be metered in a different amount.

The control unit 900 further includes a memory unit 306 for storing supply amounts of raw materials and water supplied from the storage unit 100. The control unit 900 includes an output unit for outputting data stored in the memory unit 306 by date and time, (308), and the physical properties of the lightweight foamed concrete are adjusted according to the concentration at which the lightweight foamed concrete is finally discharged via the pressure transfer unit (600).

The control unit 900 controls the mixing degree of the mixture through the speed control when mixing the mixture in the first and second mixer units 400 and 500.

And a wireless communication module 309 connected to the memory unit 306 and transmitting stored data using a local area network or the Internet.

The embodiments of the present invention can collect the cement, the lightweight aggregate and the water to be used as the lightweight foamed concrete collectively and collectively, and can supply precisely the predetermined amount, thereby improving the uniformity of the mixture.

In addition, the total input amount can be easily set by the operator, so that accurate input amount and usage amount can be measured and stored as data or outputted as separate output.

The embodiments of the present invention can accurately measure the amount of water to be supplied to the cement and the lightweight aggregate and then supply the same, so that the constant physical properties of the lightweight foamed concrete can be maintained even for a long time of work.

Embodiments of the present invention can automatically control cement, lightweight aggregate, and water when they are metered and controlled, thereby improving the workability of the operator, and safety and operation efficiency.

The embodiments of the present invention can easily select the position where the bubbles are supplied according to the field conditions, thereby improving the workability of the operator.

Embodiments of the present invention can minimize the breakage of bubbles when the bubble supply is performed, thereby improving the quality of the lightweight foamed concrete.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a device configuration for supplying conventional lightweight foamed concrete; FIG.
2 is a block diagram showing the construction of an automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention.
3 is a view schematically illustrating an automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention.
4 is a view showing a state in which cement, lightweight aggregate, and water are supplied according to an embodiment of the present invention.
5 is a view illustrating a state in which the discharge gate and the door driving unit according to the embodiment of the present invention are viewed from above.
6 is a view showing a first agitating blade provided in a first mixer unit according to an embodiment of the present invention.

The construction of an automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 2 is a block diagram showing the construction of an automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention. FIG. 3 is a view schematically showing an automatic lightweight foamed concrete supply apparatus according to an embodiment of the present invention. FIG. 4 is a view illustrating a state where cement, lightweight aggregate, and water are supplied to a first mixer unit according to an embodiment of the present invention.

Prior to the description of the present invention, the lightweight foamed concrete is mixed with cement, lightweight aggregate and water as a mixture, and bubbles are supplied to the mixture to be finally injected onto the upper surface of the slab. The lightweight foamed concrete is metered in a fixed amount of cement, lightweight aggregate, and water, and is mixed in a batch, and then supplied to the upper surface of the slab by adjusting the supply position of the bubble.

The input amount can be accurately calculated and output through a separate printer equipment (eg copier, multifunctional machine, inkjet or laser printer), so that accurate cost and material usage can be calculated for the job. Therefore, it is possible to precisely compute the work cost due to the supply of the lightweight foamed concrete and calculate the estimate for the similar work in advance, thereby minimizing unnecessary expenses.

2 to 5, the automatic lightweight foamed concrete supply apparatus according to the present embodiment includes a storage unit 100 in which a material to be charged into lightweight foamed concrete and water are separately stored, A metering unit 200 having a sensing unit 210 for receiving water and sensing the weight of the material, and a metering unit 200 for supplying the metered metered quantity of the material and the metered quantity of water at one time, A first mixer unit 400 for mixing the various materials and water with a mixture by a first mixer 410 provided in the first mixer unit 400 and a second mixer unit 400 located below the first mixer unit 400, A second mixer unit 500 connected to the second mixer unit 500 through a first connection pipe 10 to feed the mixed mixture to the feeding position, A feeding unit 600; And a bubble supply unit 800 connected to an arbitrary position in an extended path of the extension pipe 700 extending from the outlet end of the pressure transfer unit 600 to the injection position and supplying bubbles to the mixture.

The storage unit 100 includes a first storage unit 110 provided to supply cement, a second storage unit 120 disposed independently of the first storage unit 110 and provided to supply lightweight aggregate, And a third storage unit 130 provided separately from the first and second storage units 110 and 120 to supply water.

The storage unit 100 includes first to third storage units 110, 120 and 130, cement is stored in the first storage unit 110, lightweight aggregate is stored in the second storage unit 120, And the third storage unit 130 stores water.

The first storage unit 110 may be formed in a cylindrical shape, for example, and may be configured to maintain a constant diameter for supplying cement to the metering unit 200 and to reduce the diameter of the lower end. The first storage unit 110 may be provided with a separate inlet (not shown) on the upper side so that the cement may be injected inward, and a large amount of cement can be continuously supplied to the metering unit 200 through the inlet.

The second storage unit 120 is configured in the same manner as the first storage unit 110.

The metering unit 200 according to the present embodiment is located between the storage unit 100 and the first mixer unit 400. A first metering unit 201 formed to have a predetermined size and reduced in diameter toward the first mixer unit 400 and charged with cement used as a material of the lightweight foamed concrete, 2 metering section 202, and a third metering section 203 into which water is introduced.

The first to third metering units 210, 202, and 203 may be formed in a cylindrical shape and may have a reduced diameter toward the lower side, but may be changed to other shapes.

The sensing unit 210 includes a first sensing unit 212 positioned at an inner lower portion of the first metering unit 201 and a second sensing unit 214 positioned at an inner lower portion of the second metering unit 202 And a third sensing unit 216 located at an inner lower portion of the third metering unit 203.

For example, the first to third sensing units 212, 214, and 216 may be used for weight measurement, but they may be changed to other configurations, and the weight of each material is sensed and transmitted to the controller 900 .

In particular, the third sensing unit 216 senses the weight of the water and transmits the weight data sensed by the controller 900 to be described later.

The first metering unit 201 has a first opening / closing valve (not shown) opened and closed by a control unit 900 at an inner lower portion thereof. The second metering unit 202 is provided with a second opening / The third metering section 203 is provided with a third open / close valve.

The first to third open / close valves are controlled differently by the control unit 900 in the open state. For example, the time for the cement and lightweight aggregate to be supplied to the first and second metering units 201 and 202 and the inflow time for the water flowing into the third metering unit 203 are different from each other.

The controller 900 may vary the time required for quantitative metering depending on the amount of cement, lightweight aggregate, and water supplied.

In this case, the controller 900 controls the time for opening and closing the third opening / closing valve so as to open / close the first and second opening / closing valves simultaneously.

Therefore, when the cement, lightweight aggregate, and water are introduced, the quantities can be precisely metered and the quantities can be accurately supplied to the first mixer unit 400, thereby maintaining the uniformity of the lightweight foamed concrete.

The transfer unit 300 includes first and second transfer units 302 and 303. The first transfer unit 302 includes a first transfer screw for transferring the cement supplied from the first storage unit 110 to the vertical portion, (310) and a first auxiliary screw (312) horizontally positioned above the first conveyance screw (310) for horizontally conveying the cement conveyed to the upper end of the first conveyance screw (310) do.

The first conveying unit 302 moves the cement upward by the rotation of the first conveying screw 310 and is conveyed in the horizontal direction through the first auxiliary screw 312. The first conveying screw 310 and the first auxiliary screw 312 are connected to an extended shaft of the first conveying screw 310 and the first auxiliary screw 312 for rotation, The pulleys are wound around a belt (not shown) and configured to receive rotational force from a feed motor (not shown).

The second conveyance unit 303 includes a second conveyance screw 320 for conveying the lightweight aggregate supplied from the second storage unit 120 to the vertical upper portion and a second conveyance screw 320 for conveying the lightweight aggregate conveyed to the upper end of the second conveyance screw 320 And a second auxiliary screw 322 positioned horizontally above the second conveying screw 320 to convey the aggregate in the horizontal direction.

The second conveyance unit 303 is moved upward by a specific amount of the lightweight aggregate by the rotation of the second conveyance screw 320 and is horizontally conveyed through the second subscrew 322. The second feed screw 320 and the second auxiliary screw 322 are connected to a pulley (not shown) on the extended axis of the second feed screw 320 and the second auxiliary screw 322 for rotation, The pulleys are wound around a belt (not shown) and configured to receive rotational force from a feed motor (not shown).

The first and second conveyance screws 310 and 320 may be formed in a spiral shape since they are used to convey cement and lightweight aggregate.

The first mixer unit 400 according to the present embodiment receives the rotational force generated by the first mixer 410 located at the center of the upper side so that the mixture located inside the first mixer unit 400 is mixed with each other A first stirrer 420 is provided.

The first agitator 420 is mixed with a mixture having specific physical properties when cement and lightweight aggregate and water are mixed.

The first stirrer 420 is located at the center of the upper portion of the first mixer unit 400 and includes an O-shaped blade, thereby facilitating mixing of the mixture.

The first mixer unit 400 includes a first mixer unit 400 and a second mixer unit 500. The first mixer unit 400 includes a first mixer unit 400 and a second mixer unit 500, And a first stirring blade 422 provided along the first stirring blade 422. The first agitating blade 422 is made of a flexible material.

The first agitating blade 422 is made of rubber, but may be made of other materials. The first agitating blade 422 is closely attached along the outer edge of the blade, and is detachably installed in preparation for breakage or deformation.

The first stirring blade 422 scrapes a small amount of mixture remaining inside the first mixer unit 410 when the mixture moves to the second mixer unit 420 while stably mixing the mixture, .

Therefore, it is possible to move the accurate quantity to the second mixer unit 420, so that the conventional worker does not experience mixing of an appropriate amount in the eyes, and unnecessary material waste can be minimized.

4 to 5, the first mixer unit 400 according to the present embodiment includes an exhaust gate 402 which is opened or closed to drop the mixture into the second mixer unit 500, And a door driving unit 404 provided for the movement of the discharge gate 402. The discharge gate 402 may be configured to open in one direction or open in both directions. The door driving unit 404 includes a motor, a speed reducer, and a gear unit.

The discharge gate 402 may be composed of a reducer whose diameter decreases toward the lower side, but may be changed to another form. The discharge gate 402 is composed of one or a plurality of positions and is not limited to the position shown in the drawing.

The discharge gate 402 is provided with a valve formed by a disk plate, and the valve is connected to a rotation shaft of the door driving unit 404 and can be opened or closed by a rotational force generated from the motor.

The second mixer unit 500 receives the rotational force generated by the second mixer 510 positioned at the upper center and rotates the second mixer unit 500 so that the mixture located inside the second mixer unit 500 is mixed with each other. An agitator 520 is provided. Since the second stirrer 520 has the same structure as the first stirrer 420, detailed description is omitted.

The second agitator 520 is provided with a second agitating blade 522 provided along the rim facing the inside of the second mixer unit 500 so as to minimize the residual mixture remaining inside the second mixer unit 500 ).

The second agitating blades 522 can minimize the mixture remaining inside the second mixer unit 500 simultaneously with the stable mixing of the mixture.

Therefore, it is possible to supply an accurate amount to the pressure feeding unit 600, so that unnecessary material waste can be minimized.

Referring to FIG. 6, the first mixer unit 400 and the second mixer unit 500 according to the present embodiment are located in the support frame 50. For example, the first mixer unit 400 and the second mixer unit 500 may be vertically And is positioned in a facing state.

In this case, the second mixer unit 500 is positioned eccentrically in one direction from the lower side of the first mixer unit 400. This is because the worker moves the first mixer unit 400 or the second mixer unit 500 To ensure space for inspection or repair. Also, the second mixer unit 500 is eccentrically positioned within a specific distance so as to stably receive the mixture dropped in the first mixer unit 500 even when the second mixer unit 500 is eccentric.

The mixture stirred in the second mixer unit 500 according to the present embodiment is moved to the place where the pressure-feeding unit 600 is located via the first connection pipe 10. The pressure feeding unit 600 uses a pump for feeding the mixture to a high pressure at a predetermined pressure

The bubble supplying unit 800 according to the present embodiment includes an air compressor 810 for generating compressed air and a measuring unit 820 for measuring the amount of compressed air generated in the air compressor 810.

The extension pipe 700 according to the present embodiment is connected to the first connection pipe 10 described above, and is moved to a mixture state in which cement, lightweight aggregate, and water are mixed. The mixture is moved along the extension pipe 700 for stable movement before the bubbles are supplied and before being introduced into the floor slab, for example.

The extension pipe 700 may be composed of a single pipe or a plurality of pipes or pipes, and may be used by changing the number according to the site conditions. To this end, a plurality of coupling openings for coupling the extension pipe 700 to the end of the first connection pipe 10 extending from the second mixer unit 500 may be provided. The coupling hole has a plurality of coupling holes to facilitate disengagement of the coupling hole.

The extension pipe 700 according to the present embodiment is provided with a plurality of connection ports 710 provided in a path extended to connect the bubble supplying unit 800. The connection port 710 includes a first connection port 712 located at the outlet end of the pressure transfer unit 600 and a second connection port 714 located near the extended end of the extension pipe 700 .

The bubble supplying unit 800 may be selectively coupled to any one of the first connection port 712 and the second connection port 714 and may include a first connection port 712 Or the second connection port 714. In this case,

For example, the lightweight foamed concrete is scattered around the floor slab and inserted into the first connection port 712 to prevent splashing or contaminating the interior wall.

On the contrary, in order to minimize the breakage of the bubbles supplied to the mixture, the bubble supplying unit 800 can be used by being coupled to the second connection port 714, which is a position immediately before the lightweight foamed concrete is injected.

In this case, a large amount of bubbles can be stably injected through the extension pipe 700 without being destroyed, and the length of the movement along the extension pipe 700 can be remarkably reduced.

The automatic lightweight foamed concrete device according to another embodiment of the present invention includes a storage unit 100, a metering unit 200, a first mixer unit 400, a second mixer unit 500, a pressure transfer unit 600 And the configuration of the bubble supplying unit 800 are the same. The control unit 900 controls the amount of the cement, the lightweight aggregate and the water to a predetermined amount, and selectively controls the operation state of the first and second mixer units 400 and 500 and the amount of bubbles generated in the bubble supplying unit 800 The control unit 900 controls the amount of the cement, the lightweight aggregate and the water collectively, and the cement, the lightweight aggregate, and the water are supplied to the metering unit 200 The control unit controls the time required for the supply to be metered in a different amount.

The control unit 900 should measure the cement, lightweight aggregate, and water supplied to the first to third metering units 201, 202, and 203 in predetermined quantities. Preferably, both cement and lightweight aggregate and water can be supplied simultaneously and metered simultaneously.

In some cases, the cement or lightweight aggregate and water may take a relatively long time to be metered by the first to third metering units 201, 202, and 203.

The control unit 900 controls the first and second open / close valves to open and close in advance according to the time required for the metering metering by the first and second metering units 201 and 202 and the time required for the metering metering by the third metering unit 203, . Only when a predetermined amount of the cement and the lightweight aggregate are filled in the first and second metering units 201 and 202 and the water is also stored in the third metering unit 203 in a predetermined amount, 3 Opening / closing valve is opened.

Accordingly, the controller 900 controls the first mixer unit 400 to supply a uniform amount of cement, lightweight aggregate, and water, thereby maintaining the uniformity of the mixture mixed in the first mixer unit 400.

The control unit 900 further includes a memory unit 306 for storing supply amounts of raw materials and water supplied from the storage unit 100. The control unit 900 includes an output unit for outputting data stored in the memory unit 306 by date and time, (308), and controls the physical properties of the lightweight foamed concrete according to the concentration at which the lightweight foamed concrete is finally discharged via the pressure transfer unit (600). The output unit 308 may be a printer.

That is, when the concentration of the lightweight foamed concrete discharged from the end of the extension pipe 700 is different from the intended concentration, the weight of the cement, lightweight aggregate and water according to the current concentration is stored in the memory unit 306 in the controller 900 .

The control unit 900 can control the metering unit 200 to supply cement, lightweight aggregate, and water to the metering unit 200 based on the stored data and the added data.

The controller 900 controls the mixing degree of the mixture through the speed control when mixing the mixture in the first and second mixer units 400 and 500. For example, lightweight foamed concrete can be rapidly supplied to the input location when the mixing rate for the mixture is increased.

In addition, the control unit 900 can easily perform speed control even when mixing the mixture at a low speed.

The control unit 900 according to the present embodiment is provided to selectively control the amount of bubbles generated in the bubble supplying unit 800.

For example, it may be advantageous to calculate the correct input material that the input amounts of cement, lightweight aggregate and water are kept constant. In this case, it can be changed according to the area of the building, but it is possible to calculate the exact amount of lightweight foamed concrete supplied to the floor slab before or after the construction, and it can be applied to other buildings.

In addition, a touch panel (not shown) equipped with a panel that is operated by touching is provided so that the operator can additionally set the amount of input, so that the input amount of the material and the input amount of water can be easily set.

The transfer unit 300 includes a memory unit 306 for storing supply amounts of raw materials and water supplied from the storage unit 100 and an output unit 308 for outputting data stored in the memory unit 306 by date and time Respectively. The memory unit 306 may store the amount of cement, lightweight aggregate, and water that have been input, and may output the amount used at a specific date and time through the output unit 308. Therefore, a database on cement and lightweight aggregate and water usage can be secured, and the amount to be put in other buildings can be predicted.

The wireless communication module 309 is connected to the memory unit 306 and transmits data stored in the local area network or the Internet.

The wireless communication module 309 can access the Internet network even when the administrator is not in the field and can check the input amount of the cement and lightweight aggregate and water supplied to the current storage unit 100,

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

50: Support frame
100:
110, 120, and 130: first, second,
200:
210:
212, 214, and 216: first, second, and third sensing units
300:
400: first mixer unit
402: Discharge gate
404:
410: first mixer
420: first agitating blade
422: first auxiliary blade
500: second mixer unit
510: second mixer
520: Second stirrer
522: second agitating blade
600:
700: extension pipe
710: Connection port
800: bubble supply unit
810: Air compressor
820:
900:

Claims (6)

A first storage unit in which cement is stored, a second storage unit in which aggregate is stored, and a third storage unit in which water is stored;
A second metering section for metering and receiving aggregate from the second storage section; and a third metering section for receiving and measuring the water from the third storage section, Metering section;
A first on-off valve disposed in the first metering section, a second on-off valve disposed in the second metering section, a third on-off valve disposed in the third metering section,
Wherein when the first open / close valve, the second open / close valve, and the third open / close valve are opened, the cement discharged from the first metering section, the aggregate discharged from the second metering section, A first mixer unit for mixing and mixing the first mixer unit and the second mixer unit;
A second mixer unit for mixing the mixture of the first mixer unit;
A bubble supplying unit supplying bubbles to the mixture of the second mixer unit; And
And a memory unit for storing the supply amount of the cement supplied from the first storage unit, the supply amount of the aggregate supplied from the second storage unit, and the supply amount of the water supplied from the third storage unit, A controller for controlling the first opening / closing valve, the second opening / closing valve and the third opening / closing valve by receiving the weight of the cement, the weight of the aggregate detected by the second metering section, and the weight of the water sensed by the third metering section, Lt; / RTI >
The first metering unit, the second metering unit, and the third metering unit measure the weight of the cement, the weight of the aggregate and the weight of the water by the load cell,
Wherein the control unit controls the first opening and closing valve and the second opening and closing valve so that when a predetermined amount of cement is supplied to the first metering unit and a predetermined amount of aggregate is supplied to the second metering unit and a predetermined amount of water is supplied to the third metering unit, The valve and the third open / close valve are simultaneously opened,
Wherein the control unit is connected to the output unit through which data stored in the memory unit is output by date and time, and the data stored in the memory unit is transmitted to the wireless communication module through a local area network or an Internet network,
The first mixer unit includes a first mixer which is opposed to an inner surface of the first mixer unit and protrudes and rotates so as to be convexly curved toward the inner side of the first mixer unit, And a first agitating blade disposed between the inner surface of the unit and the first agitator,
The second mixer unit includes a second mixer which is opposed to the inner side surface of the second mixer unit and protrudes and rotates so as to form a convexly curved shape toward the inner side surface of the second mixer unit, And a second agitating blade disposed between the inner surface of the unit and the second agitator.
delete The method according to claim 1,
The automatic lightweight foamed concrete supply apparatus transfers cement of the first storage unit to the first metering unit, conveys aggregate of the second storage unit to the second metering unit, and transfers water of the third storage unit to the third metering unit Further comprising a conveying portion for conveying the foamed concrete.
delete The method according to claim 1,
Wherein the first mixer unit and the second mixer unit are positioned on the support frame in a vertically opposed state,
The second mixer unit is positioned eccentrically from the lower side of the first mixer unit in one direction,
Wherein the first mixer unit includes a discharge gate which is opened or closed to drop the mixture into the second mixer unit on the lower side, and a door driving unit provided for movement of the discharge gate.
The method according to claim 1,
Wherein the control unit controls the mixing degree of the mixture by controlling the rotation speeds of the first mixer unit and the second mixer unit and controls the amount of bubbles generated in the bubble supplying unit.

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