JP6933918B2 - Cleaning system and ready-mixed concrete manufacturing equipment equipped with it - Google Patents

Description

The present invention relates to a cleaning system for cleaning a concrete mixer or a concrete hopper, for example, in a batcher plant as a ready-mixed concrete manufacturing apparatus.

Conventionally, for example, a batcher plant as a ready-mixed concrete manufacturing apparatus manufactures ready-mixed concrete by kneading materials such as gravel (coarse aggregate), sand (fine aggregate), cement, water, and an admixture. Inside the batcher plant, a concrete mixer (hereinafter, simply referred to as “mixer”) having a rotatable kneading blade for kneading the above materials is installed. By kneading the materials in the mixer, ready-mixed concrete is produced.

At the bottom of the mixer, a retractable discharge gate and a mechanism for opening and closing it are provided. The ready-mixed concrete produced by the mixer is usually discharged from an open discharge gate, and is discharged to an agitator vehicle through, for example, a hollow conical concrete hopper (hereinafter, simply referred to as “hopper”).

After the ready-mixed concrete is discharged to the agitator truck, the ready-mixed concrete scattered by kneading may remain as deposits on the inner surface of the mixer and the surface of the kneading blades. In addition, ready-mixed concrete scattered by the impact at the time of discharge may adhere to the discharge gate of the mixer, the mechanism for opening and closing the mixer, and the inner surface of the hopper.

If the attached ready-mixed concrete is left as it is, it solidifies and sticks to the inner surface of the mixer or the like. Therefore, after kneading, the inside of the mixer or the like is cleaned as necessary. In this case, it is conceivable to fix the cleaning nozzle on the inner surface of the mixer or hopper and clean the inner surface of the mixer with the cleaning water ejected from the cleaning nozzle. However, if the cleaning nozzle is installed on the inner surface of the mixer, etc. In some cases, the cleaning nozzle itself is covered with deposits and the cleaning water cannot be ejected, resulting in a problem that cleaning cannot be performed.

Therefore, a cleaning system has been proposed in which the cleaning nozzle is allowed to move forward and backward with respect to the mixer and the hopper, and when cleaning is required, the cleaning nozzle is allowed to penetrate into the mixer to remove the adhering deposits (cleaning system). For example, see Patent Document 1).

9 and 10 are views showing an example of the cleaning system in the mixer. In this cleaning system, a cleaning nozzle 61 for ejecting cleaning water, a tubular member 62 having a cleaning nozzle 61 at one end and guiding the cleaning water, and a tubular member 62 are provided inside the mixer 60 along the extending direction thereof. A moving / retreating mechanism 63 for entering and exiting the tubular member 62, a nozzle rotating motor 64 provided at the other end of the tubular member 62 for rotating the cleaning nozzle 61, and a pump for supplying cleaning water to the tubular member 62 ( (Illustrated).

The advancing / retreating mechanism 63 includes an annular chain for connecting the tubular member 62 and advancing / retreating the tubular member 62, and a chain motor (both not shown) for moving the annular chain. Reference numeral 65 in the drawing indicates a drive motor for rotating the kneading blade inside the mixer 60, and reference numeral 66 indicates a speed reducer.

When the annular chain is moved by the chain motor, the tubular member 62 moves so as to enter the inside of the mixer 60 (see B in FIG. 10). At this time, by driving the pump, high-pressure washing water is supplied to the tubular member 62, and the washing water is ejected from the washing nozzle 61. The cleaning nozzle 61 is rotated by a nozzle rotation motor 64 to eject cleaning water in various directions.

In this way, the cleaning nozzle 61 is moved inside the mixer 60, and the inside of the mixer 60 is cleaned by removing deposits with cleaning water. When the cleaning is completed, the tubular member 62 is moved so as to retract with respect to the mixer 60 by the advancing / retreating mechanism 63, and the cleaning nozzle 61 is also moved to the outside of the mixer 60.

However, in such a cleaning system, in order to move the cleaning nozzle 61 inside the mixer 60, it is necessary to provide the tubular member 62 and the advancing / retreating mechanism 63 so as to project to the outside of the mixer 60. A predetermined space is required separately from the mixer 60.

Further, in the above cleaning system, the cleaning nozzle 61 needs to move the inside of the mixer 60 in order to clean almost the entire area inside the mixer 60. Therefore, there is a problem that it takes time to move the mixer 60 and it takes time as a whole cleaning time. These problems also occur when the hopper is cleaned by the cleaning nozzle 61.

Japanese Unexamined Patent Publication No. 2008-21288

The present invention has been conceived under the above circumstances, and even if the cleaning nozzle is installed on the inner surface of the mixer or hopper, the cleaning can be performed satisfactorily, and space saving and cleaning time can be reduced. The challenge is to provide a cleaning system that can be shortened. Another object of the present invention is to provide a ready-mixed concrete manufacturing apparatus equipped with the cleaning system.

The cleaning system provided by the first aspect of the present invention includes a mixer that kneads a plurality of materials for producing ready-mixed concrete and a cleaning nozzle that is disposed inside the mixer and cleans the inner surface of the mixer. And a pump means for supplying cleaning water to the cleaning nozzle at a high pressure, the cleaning nozzle includes a head portion facing the inside of the mixer and a head drive portion having a motor for rotating the head portion. The head unit includes a head bearing connected to the head drive unit, an angle setting unit connected to the head bearing and for changing the radiation direction of water injected from the cleaning nozzle, and the angle setting unit. is connected to the part, and Roh nozzle body provided rotatably while being supported by the nozzle body, a nozzle cover which moves away relative to the nozzle body by pressure of washing water from said pump means A nozzle holder to which a plurality of nozzle tips are attached is provided inside the nozzle body, and the nozzle tips are provided radially at an angle of about 90 degrees and wash water is provided at the tip thereof. When the pressure of the washing water from the pump means is equal to or lower than a predetermined pressure, the first state in which the nozzle cover covers the nozzle tip of the nozzle tip and the pump When the pressure of the washing water from the means exceeds the predetermined pressure, the nozzle cover moves, the nozzle tip of the nozzle tip is exposed to the outside, and the washing water is ejected. It is a feature.

The cleaning system provided by the second aspect of the present invention includes a mixer for kneading a plurality of materials for producing ready-mixed concrete, and ready-made concrete provided under the mixer and discharged from the discharge gate of the mixer. A hopper for discharging the hopper further downward, a cleaning nozzle disposed inside the hopper and cleaning the discharge gate of the mixer and / or the inner surface of the hopper, and a high pressure cleaning water with respect to the cleaning nozzle. The cleaning nozzle includes a head portion facing the inside of the mixer and a head drive portion having a motor for rotating the head portion, and the head portion is provided on the head drive portion. A connected head bearing, an angle setting unit connected to the head bearing and for changing the radiation direction of water injected from the cleaning nozzle, and an angle setting unit connected to the angle setting unit and rotatably provided. and Bruno nozzle body, while being supported by the nozzle body, and a nozzle cover which moves away relative to the nozzle body by pressure of washing water from said pump means, in the interior of the nozzle body, a plurality of A nozzle holder to which a nozzle tip is attached is provided, and the nozzle tip is provided radially at an angle of about 90 degrees each, and outlets for ejecting wash water are formed, respectively, and the pump means. When the pressure of the washing water from the nozzle is equal to or lower than the predetermined pressure, the nozzle cover covers the nozzle tip of the nozzle tip, and the pressure of the washing water from the pump means exceeds the predetermined pressure. It is characterized in that the nozzle cover moves and the nozzle tip of the nozzle tip is exposed to the outside to have a second state in which cleaning water is ejected.

In the cleaning system of the present invention, the cleaning system is provided in the nozzle body and includes an urging means for urging the nozzle cover toward the nozzle body, and the pressure of the cleaning water by the pump means exerts an urging force by the urging means. When it exceeds, it is preferable that the cleaning nozzle is in the second state.

The ready-mixed concrete manufacturing apparatus provided by the third aspect of the present invention is characterized by comprising the cleaning system provided by the first and second aspects of the present invention.

According to the present invention, when the pressure of the cleaning water supplied by the pump means exceeds a predetermined water pressure, the nozzle cover of the cleaning nozzle moves in a direction away from the nozzle body, and the ejection port for ejecting the cleaning water is exposed. The cleaning water is ejected, while the nozzle cover covers the ejection port when the cleaning water is not supplied. Therefore, for example, even if a cleaning nozzle is installed on the inner surface of the mixer, the inner surface of the mixer can be satisfactorily cleaned, and the spout can be protected when not cleaning. In addition, since the cleaning nozzle can be installed on the inner surface of the mixer, it is not necessary to project the advancing / retreating mechanism to the outside of the mixer to save space, and it is also necessary to move the cleaning nozzle inside the mixer. Since there is no nozzle, the cleaning time can be shortened.

It is a figure which shows the schematic structure of the ready-mixed concrete manufacturing apparatus to which the cleaning system which concerns on this invention is applied. It is a figure which shows the schematic structure of the cleaning system. It is a schematic external view of a cleaning nozzle. It is a perspective view of a nozzle body and a nozzle cover, (a) shows a first state in which a nozzle cover has not moved, and (b) shows a second state in which a nozzle cover has moved. It is sectional drawing of a nozzle body and a nozzle cover, (a) shows the 1st state in which a nozzle cover has not moved, and (b) shows a 2nd state in which a nozzle cover has moved. It is a figure which shows the ejection state of a cleaning nozzle. It is a figure which shows the ejection state of a cleaning nozzle. It is a figure which shows the ejection state of a cleaning nozzle. It is a schematic external view of the conventional cleaning system provided in a mixer. It is a figure which shows the ejection state of the conventional cleaning system.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.

FIG. 1 is a diagram showing a schematic configuration of a ready-mixed concrete manufacturing apparatus to which the cleaning system according to the present invention is applied. The batcher plant 1 as the ready-mixed concrete manufacturing apparatus is an apparatus for producing ready-mixed concrete by, for example, kneading gravel (coarse aggregate), sand (fine aggregate), cement, water, an admixture and the like.

The batcher plant 1 includes a belt conveyor 2 for transporting, for example, aggregates from a storage silo (not shown) for storing aggregates such as sand and gravel. The aggregate carried by the belt conveyor 2 is distributed to the plurality of aggregate storage tanks 4 by the turn head 3. Cement is supplied from the cement silo to the cement storage tank 5 via an air transport device (all not shown) or the like.

The sand and gravel stored in the aggregate storage tank 4 are weighed by the aggregate measuring instrument 6 and charged into the concrete mixer (hereinafter, simply referred to as “mixer”) 8 via the aggregate input chute 7. The cement stored in the cement storage tank 5 is weighed by the cement measuring instrument 9 and charged into the mixer 8 via the cement charging chute 10.

Further, the water stored in the water storage tank 16 (described later) is mixed with the admixture in the water measuring instrument 11, the total amount of water and the admixture is measured by the water measuring instrument 11, and the water feeding chute 12 and the water are measured. It is charged into the mixer 8 via the charging pipe 13.

Materials such as gravel, sand, cement, water and admixtures charged into the mixer 8 are kneaded in the mixer 8 to become ready-mixed concrete. The ready-mixed concrete is transported to the construction site by an agitator truck (not shown) or the like via a concrete hopper (hereinafter, simply referred to as “hopper”) 14 provided below the mixer 8 and a hopper gate 15 that can be opened and closed.

Although not shown in FIG. 1, inside the batcher plant 1, the inside of the mixer 8 or the inner surface of the hopper 14, the discharge gate 24 of the mixer 8 (described later), a mechanism for opening and closing the gate 24 (not shown), etc. A cleaning system is provided for cleaning.

FIG. 2 is a diagram showing a schematic configuration of a cleaning system. The cleaning system is provided in the batcher plant 1 shown in FIG. The cleaning system is a system for cleaning the mixer 8 and the hopper 14, and is composed of a plurality of members. In this embodiment, any of the cleaning systems applied to the mixer 8 and the hopper 14 may not be provided.

The batcher plant 1 is provided with a water storage tank 16 for storing water as a material and water for washing the mixer 8 and the hopper 14. Since the washing water is drained as it is after washing the mixer 8 and the hopper 14, any of recovered water, sludge water, fresh water, and the like may be used.

One end of the pipeline 17 is connected to the water storage tank 16, and the drive pump 18 is connected to the other end of the pipeline 17. The drive pump 18 increases the pressure of the washing water from the water storage tank 16 and supplies it to the downstream side. When the drive pump 18 is turned on, high-pressure washing water is supplied to the downstream side (mixer 8 or hopper 14).

One end of the pipeline 19 is connected to the downstream side of the drive pump 18, and the first control valve 20 is interposed in the middle of the pipeline 19. A cleaning nozzle 21 that ejects cleaning water inside the mixer 8 to perform cleaning is connected to the other end of the pipeline 19. The cleaning nozzle 21 is attached to the ceiling surface of the mixer 8. The pipeline 19 is branched immediately before the mixer 8, and the cleaning nozzle 21 is connected to each of the branched tip portions. The first control valve 20 described above is normally in a closed state, but when it is in an open state, cleaning water from the drive pump 18 is supplied to the cleaning nozzle 21.

One end of the pipeline 22 is connected in the middle of the pipeline 19 between the drive pump 18 and the first control valve 20. A second control valve 23 is interposed in the middle of the pipeline 22. At the other end of the pipeline 22, a cleaning nozzle 21 for cleaning by ejecting cleaning water to a discharge gate 24 or the like provided inside the hopper 14 or below the mixer 8 so as to be openable and closable is connected.

The cleaning nozzle 21 is similar to the cleaning nozzle 21 that cleans the inside of the mixer 8, and is attached to a baffle 25 formed at the upper end of the hopper 14. The pipeline 22 is branched immediately before the hopper 14, and the cleaning nozzle 21 is connected to each of the branched tip portions. The second control valve 23 described above is normally in a closed state, but when it is in an open state, cleaning water from the drive pump 18 is supplied to the cleaning nozzle 21.

Although it is described in FIG. 2 that two cleaning nozzles 21 are installed on the mixer 8 and the hopper 14, the number of cleaning nozzles 21 is not limited to these numbers. Further, the installation position of the cleaning nozzle 21 is not limited to the position shown in FIG. Further, although not shown in FIGS. 1 and 2, a plurality of kneading blades for kneading the material are provided inside the mixer 8, and the kneading blades are attached around, for example, a columnar kneading shaft. Has been done.

FIG. 3 is a schematic external view of the cleaning nozzle 21. Hereinafter, the cleaning nozzle 21 attached to the mixer 8 will be described, but the cleaning nozzle 21 attached to the hopper 14 also has a similar attachment structure. The cleaning nozzle 21 includes, for example, a head portion 30 facing the inside of the mixer 8 and a head driving portion 31 attached to the outside of the mixer 8. The head portion 30 is connected to the head drive portion 31 via an opening 26 formed in the mixer 8.

The head drive unit 31 includes a drive unit main body 32, a motor 33, and a gearbox 34. The drive unit main body 32 is attached to the mixer 8 from the outside of the mixer 8 by a flange 35 provided on the drive unit main body 32. A water supply port (not shown) for introducing washing water is formed in the drive unit main body 32, and a pipeline 19 is connected to the water supply port. The motor 33 is for rotating the head portion 30, and the gearbox 34 is for converting the rotation direction of the motor 33 and transmitting it to the head portion 30.

The head portion 30 includes a head bearing 36 connected to the flange 35, an angle setting portion 37 connected to the head bearing 36, and a nozzle body 38 connected to the angle setting portion 37. Although not shown, a flow passage communicating with the cavity S of the nozzle body 38, which will be described later, is formed in the drive unit main body 32, the flange 35, the head bearing 36, and the angle setting unit 37.

The nozzle body 38 is provided with a nozzle cover 39 that is supported by the nozzle body 38 and is movable in a direction away from the nozzle body 38. Although the details will be described later, the nozzle cover 39 is moved away from the nozzle body 38 when the pressure of the washing water from the drive pump 18 exceeds a predetermined pressure. The angle setting unit 37 is provided to change the radiation direction of the water ejected from the cleaning nozzle 21. The angle setting unit 37 may not be provided.

4A and 4B are perspective views of the nozzle body 38 and the nozzle cover 39. FIG. 4A shows a first state in which the nozzle cover 39 has not moved, and FIG. 4B shows a second state in which the nozzle cover 39 has moved. Is shown. 5A and 5B are cross-sectional views of the nozzle body 38 and the nozzle cover 39. Similar to FIG. 4, FIG. 5A shows a first state in which the nozzle cover 39 is not moving, and FIG. 5B shows a first state in which the nozzle cover 39 is not moving. It shows the second state of movement.

As shown in FIG. 4B, at the tip of the head portion 30, when the nozzle cover 39 moves (see arrow A), a plurality of nozzle tips 40 provided inside are exposed to the outside, and the nozzle tips The structure is such that the washing water is ejected from 40.

Specifically, the nozzle body 38 is provided with a nozzle holder 41 to which four nozzle tips 40 are attached. Note that FIG. 4B shows only two nozzle tips 40. The four nozzle tips 40 are provided radially at an angle of about 90 degrees each. The nozzle tip 40 is formed with a spout 42 for ejecting washing water at the tip thereof, and the spouting direction is set obliquely with respect to the axial center of the nozzle body 38. The number of nozzle tips 40 attached to the nozzle holder 41 is not limited to four.

The nozzle body 38 is provided with a spring pin 44 (see FIG. 5) in which a spring 43 is wound between adjacent nozzle tips 40 so as to extend in the vertical direction. The spring 43 and the spring pin 44 will be described later.

Explaining the internal structure of the nozzle body 38 and the nozzle cover 39 with reference to FIG. 5, the nozzle body 38 has a flange portion 46 connected to the angle setting portion 37. The flange portion 46 is formed with a cavity S in which wash water flows in the central portion. The inner surface of the cavity S is provided so that the nozzle holder 41 is in contact with the inner surface. A nozzle tip 40 is attached to the nozzle holder 41, whereby the cavity S is communicated with the nozzle tip 42 of the nozzle tip 40. A flange 47 is formed on the upper portion of the nozzle holder 41.

A cylindrical pin receiver 48 is provided on the inner side surface of the flange 47, which is the upper part of the cavity S formed inside the nozzle holder 41, and the pin member 49 is slidable inside the pin receiver 48. It is provided. The pin member 49 blocks or allows the nozzle tip 40 to wash water from the conduit 19 in the cavity S. That is, as shown in FIG. 5A, in the first state in which the nozzle cover 39 does not move because the pressure of the washing water is equal to or lower than a predetermined pressure, the pin member 49 closes the cavity S. Further, as shown in FIG. 5B, in the second state in which the nozzle cover 39 has moved because the pressure of the washing water exceeds a predetermined pressure, the pin member 49 communicates the cavity S with the nozzle tip 40. ..

A nozzle cover 39 is provided on the upper portion of the pin member 49, and the nozzle cover 39 moves up and down based on the sliding of the pin member 49. That is, as shown in FIG. 5A, in the first state in which the nozzle cover 39 is not moving, the nozzle cover 39 covers the nozzle tip 40, while the nozzle cover 39 is as shown in FIG. 5B. In the second state in which the nozzle tip 40 is moved, the nozzle tip 40 is exposed to the outside.

One end of the spring pin 44 is fixed to the upper surface of the nozzle cover 39, and the other end of the spring pin 44 is movable. A spring 43 is wound around a portion between the other end of the spring pin 44 and the flange 47 of the nozzle holder 41. The nozzle cover 39 is urged toward the nozzle body 38 by the spring 43, and in the first state shown in FIG. 5 (a), the spring 43 is in an extended state, and the second state shown in FIG. 5 (b). In the state of, the spring 43 is in a contracted state. Therefore, when the pressure of the washing water falls below the urging force of the spring 43, the pressure is returned to the first state shown in FIG. 5 (a).

Next, the operation of the cleaning system using the cleaning nozzle 21 will be described.

After the materials are kneaded in the mixer 8 shown in FIGS. 1 and 2, the discharge gate 24 is opened, the produced ready-mixed concrete is supplied to the hopper 14, and then the hopper gate 15 is opened to, for example, an agitator truck. Supplied.

After the ready-mixed concrete is discharged, the mixer 8 is washed with the washing water stored in the water storage tank 16. That is, when the drive pump 18 (see FIG. 2) is driven and the first control valve 20 is opened, the washing water stored in the water storage tank 16 is mixed through the pipeline 17, the drive pump 18, and the pipeline 19. It is supplied to the cleaning nozzle 21 attached to 8. Almost at the same time, the motor 33 of the cleaning nozzle 21 is rotationally driven, and the head portion 30 rotates.

When the cleaning water is supplied to the cleaning nozzle 21 and the pressure of the cleaning water exceeds the urging force of the spring 43, the pin member 49 moves in the direction away from the nozzle body 38 (see FIG. 5B). When the pin member 49 moves, the nozzle cover 39 connected to the upper part of the pin member 49 also moves. As a result, the nozzle tip 40 attached to the nozzle holder 41 is exposed to the outside, the cavity S of the nozzle holder 41 and the nozzle tip 40 are communicated with each other, and the washing water is ejected from the ejection port 42 of the nozzle tip 40. (See FIG. 6).

The head portion 30 of the cleaning nozzle 21 is rotated as the motor 33 is rotationally driven, and the angle setting unit 37 changes the radiation direction of the water ejected from the cleaning nozzle 21 in all directions from the nozzle tip 40. Wash water is ejected (see FIGS. 7 and 8). As a result, deposits adhering to the inner surface of the mixer 8, the kneading shaft, the surface of the kneading blade, and the like around the cleaning nozzle 21 are satisfactorily removed and cleaned.

The wash water is continuously ejected from the nozzle tip 40 unless the pressure of the drive pump 18 falls below the urging force of the spring 43. After that, when the pressure of the washing water falls below the urging force of the spring 43, the pin member 49 moves in the direction approaching the nozzle body 38, and the nozzle holder 39 is connected to the nozzle body 38 so as to cover the nozzle tip 40. At this time, the pin member 49 closes the cavity S.

As described above, according to the cleaning system, when the pressure of the cleaning water supplied to the cleaning nozzle 21 exceeds a predetermined pressure (the urging force of the spring 43), the nozzle cover 39 is moved to expose the nozzle tip 40. The washing water can be ejected. Further, when the pressure of the washing water is equal to or lower than a predetermined pressure, the nozzle cover 39 moves so as to cover the nozzle tip 40. Therefore, even if deposits may adhere to the inside of the mixer 8 after the kneading is completed, the nozzle tip 40 is protected by the nozzle cover 39, so that the cleaning water cannot be ejected at the next cleaning. There is no such problem.

In the present embodiment, since the cleaning nozzle 21 can be arranged inside the mixer 8, it is not necessary to provide the advancing / retreating mechanism 63 of the cleaning nozzle 61 or the like so as to protrude to the outside of the mixer 8 as in the conventional configuration. , The entire system can be configured compactly. Further, unlike the conventional configuration, it is not necessary to move the cleaning nozzle 61 by the advancing / retreating mechanism 63, so that the cleaning time can be shortened.

The cleaning nozzle 21 according to the present embodiment can be set at an arbitrary position inside the mixer 8 only by forming an opening 26 on the surface of the mixer 8. Therefore, when it is desired to specify the cleaning position inside the mixer 8, the cleaning nozzle 21 may be installed in the vicinity thereof, and the versatility of the cleaning nozzle 21 can be enhanced.

Further, the above-mentioned action and effect can be obtained not only in the mixer 8 but also when the cleaning nozzle 21 is installed in the hopper 14 in the same manner as the action and effect in the mixer 8. In particular, in the hopper 14, the cleaning nozzle 21 can be effectively used for cleaning the discharge gate 24 provided on the lower surface of the mixer 8 and the mechanism for opening and closing the discharge gate 24.

The scope of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, the form, size, quantity, structure, etc. of each member in the above embodiment are not limited to the above embodiment, and the design can be changed as appropriate. For example, the head bearing 36 connected to the flange 35 of the head portion 30 may be provided with a substantially cylindrical rod-shaped member having a predetermined length, and the head portion 30 may be provided at the tip of the rod-shaped member. .. As a result, the cleaning nozzle 21 can be brought closer to the object to be cleaned.

1 Batcher plant 8 Concrete mixer 14 Concrete hopper 18 Drive pump 19, 22 Pipeline 20 1st control valve 21 Cleaning nozzle 22 2nd control valve 30 Head part 31 Head drive part 33 Motor 37 Angle setting part 38 Nozzle body 39 Nozzle cover 40 Nozzle tip 41 Nozzle holder 42 Spout 43 Spring

Claims (4)

With a mixer that kneads multiple materials to produce ready-mixed concrete,
A cleaning nozzle disposed inside the mixer and cleaning the inner surface of the mixer,
A pump means for supplying cleaning water at a high pressure to the cleaning nozzle is provided.
The cleaning nozzle
The head part facing the inside of the mixer and
A head drive unit having a motor for rotating this head unit is provided.
The head portion
The head bearing connected to the head drive unit and
An angle setting unit connected to the head bearing and for changing the radiation direction of water ejected from the cleaning nozzle.
Which is connected to the angle setting unit, and Roh nozzle body that is rotatably disposed,
It is provided with a nozzle cover that is supported by the nozzle body and moves in a direction away from the nozzle body by the pressure of the washing water from the pump means.
Inside the nozzle body,
There is a nozzle holder to which multiple nozzle tips can be attached.
The nozzle tip is
It is provided radially at an angle of about 90 degrees and is also provided.
Each spout is formed at the tip to eject wash water.
When the pressure of the washing water from the pump means is equal to or lower than a predetermined pressure, the first state in which the nozzle cover covers the outlet of the nozzle tip and the first state.
When the pressure of the washing water from the pump means exceeds the predetermined pressure, the nozzle cover moves, the ejection port of the nozzle tip is exposed to the outside, and the washing water is ejected. A cleaning system characterized by that. With a mixer that kneads multiple materials to produce ready-mixed concrete,
A hopper provided at the bottom of the mixer and for discharging the ready-mixed concrete discharged from the discharge gate of the mixer further downward.
A cleaning nozzle disposed inside the hopper and cleaning the discharge gate of the mixer and / or the inner surface of the hopper.
A pump means for supplying cleaning water at a high pressure to the cleaning nozzle is provided.
The cleaning nozzle
The head part facing the inside of the mixer and
A head drive unit having a motor for rotating this head unit is provided.
The head portion
The head bearing connected to the head drive unit and
An angle setting unit connected to the head bearing and for changing the radiation direction of water ejected from the cleaning nozzle.
Which is connected to the angle setting unit, and Roh nozzle body that is rotatably disposed,
It is provided with a nozzle cover that is supported by the nozzle body and moves in a direction away from the nozzle body by the pressure of the washing water from the pump means.
Inside the nozzle body,
There is a nozzle holder to which multiple nozzle tips can be attached.
The nozzle tip is
It is provided radially at an angle of about 90 degrees and is also provided.
Each spout for ejecting wash water is formed,
When the pressure of the washing water from the pump means is equal to or lower than a predetermined pressure, the first state in which the nozzle cover covers the outlet of the nozzle tip and the first state.
When the pressure of the cleaning water from the pump means exceeds the predetermined pressure, the nozzle cover moves and the ejection port of the nozzle tip is exposed to the outside to eject the cleaning water. A cleaning system characterized by that. Provided in the nozzle body and provided with an urging means for urging the nozzle cover toward the nozzle body.
The cleaning system according to claim 1 or 2, wherein when the pressure of the cleaning water by the pump means exceeds the urging force by the urging means, the cleaning nozzle is in the second state. A ready-mixed concrete manufacturing apparatus comprising the cleaning system according to any one of claims 1 to 3.

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