CN114261021B - Light soil production cloth integrated system - Google Patents

Abstract

The application provides a light soil production cloth integration system relates to light soil construction technical field, and its technical scheme main points are: comprises a movable carrier, wherein the movable carrier is provided with a gas supply part, a water supply part, a foaming agent supply part, a water slurry supply part and a distributing rod; the material distribution rod comprises a support frame, a mixing cavity and a material conveying pipe, the support frame is arranged on the movable carrier, the mixer is arranged on the support frame, and the material conveying pipe is communicated with the mixing cavity; the air supply component, the water supply component, the foaming agent supply component and the slurry supply component are respectively communicated with the mixing cavity; the device also comprises a power component which provides power for the air supply component, the water supply component, the foaming agent supply component and the water supply mud component, so that light soil formed by mixing air, water, foaming agent and cement paste enters the mixing cavity and is poured through the conveying pipe. The application provides a light soil production cloth integration system has that light soil production cloth integration, efficiency of construction are high and construction quality is good advantage.

Description

Light soil production cloth integrated system

Technical Field

The application relates to the technical field of light soil construction, in particular to a light soil production and distribution integrated system.

Background

Lightweight soil is a building material that is currently in wide use, however, lightweight soil construction is currently mainly manufactured by fixed production equipment at a construction site, and then the lightweight soil is transported to a working surface through a pipeline.

At present, when the roadbed construction of a highway or the filling of a bridge head of a bridge is aimed at, the working face is small in width and huge in length, and the length is even more than 2000 meters, so that frequent turnover equipment and corresponding pipelines are required, and the labor intensity is high. When in concrete construction, people are required to stand outside the edges of the square, the pipe orifice is held by hands, light soil is poured into the square, and the general conveying pipe is provided with one or two outlets and is arranged on one side or two sides of the square, so that the square is filled by the fluidity of the light soil.

However, since the interior of the lightweight soil is filled with bubbles, bubble breakage or bubble aggregation occurs during flowing or strong scouring, thereby destroying the uniformity and quality of the lightweight soil, and when serious, delamination of the lightweight soil with different wet densities occurs, and the risk of insufficient strength and collapse defects caused by the exceeding of local foam rate is caused, which is a definitely great hidden danger for building construction.

In view of the above problems, the applicant has proposed a new solution.

Disclosure of Invention

The utility model aims at providing a light soil production cloth integration system has that light soil production cloth integration, efficiency of construction are high and construction quality is good.

In a first aspect, the present application provides a light soil production and distribution integrated system, which has the following technical scheme:

the device comprises a movable carrier, wherein the movable carrier is provided with an air supply part, a water supply part, a foaming agent supply part, a mud supply part and a distributing rod;

the material distribution rod comprises a supporting frame, a mixing cavity and a material conveying pipe, wherein the supporting frame is arranged on the movable carrier, the mixing cavity is arranged on the supporting frame, and the material conveying pipe is communicated with the mixing cavity;

the air supply component, the water supply component, the foaming agent supply component and the water slurry supply component are respectively communicated with the mixing cavity;

the device comprises a water supply pipe, a foaming agent supply component, a water supply component, a cement slurry supply component, a power component, a mixing cavity, a conveying pipe and a mixing cavity, wherein the water supply component is used for supplying power to the water supply component, the foaming agent supply component and the cement slurry supply component, and light soil formed by mixing air, water, the foaming agent and cement slurry enters the mixing cavity and is poured through the conveying pipe under the driving of the power component.

The air supply component, the water supply component, the foaming agent supply component and the water supply slurry component are arranged on the movable carrier, so that light soil can be formed by mixing on the movable carrier, the movable carrier is also provided with the distributing rod, the formed light soil is conveyed to the distributing rod, pouring is carried out through the distributing rod, the efficiency is effectively improved, the distributing rod is composed of the supporting frame, the mixing cavity and the conveying pipe, and the conveying of the light soil is naturally generated by the flowing of the air, the water, the foaming agent and the cement slurry when the power component is used for conveying the air, the water, the foaming agent and the cement slurry, and the mixed light soil is not required to be pressurized and conveyed by providing additional power, so that bubble cracking in the light soil can be avoided, and the integrated light soil production and distribution device has the advantages of high construction efficiency and good construction quality.

Further, in the present application, the air supply part includes at least an air compressor, the water supply part includes at least a water tank and a water pump, the foaming agent supply part includes at least a foaming agent storage tank and a foaming agent pump, and the water supply mud part includes at least a mud hopper and a mud pump;

the air compressor, the water pump, the foaming agent pump and the slurry pump share an output shaft, and the output shaft is connected with the power component.

Further, in the present application, the device further comprises a foaming gun and a mixer, wherein one end of the foaming gun is communicated with the air compressor, the water pump and the foaming agent pump, the other end of the foaming gun is communicated with the mixer, one end of the mixer is communicated with the slurry pump, and the other end of the mixer is communicated with the mixing cavity.

Further, in the present application, the water pump is combined with the foaming agent pump to form a multistage pump, and the multistage pump is connected with the water tank and the foaming agent storage tank, respectively, for mixing water and the foaming agent to form a diluent and outputting the diluent to the foaming gun.

Further, in the application, a first flow proportional valve is arranged between the air compressor and the foaming gun, a second flow proportional valve is arranged between the multistage pump and the foaming gun, and a third flow proportional valve is arranged between the slurry pump and the mixer.

Further, in the present application, a fourth flow rate proportional valve is provided between the multistage pump and the water tank, and a fifth flow rate proportional valve is provided between the multistage pump and the blowing agent storage tank.

Further, in this application, the output shaft includes first power shaft, second power shaft and third power shaft, first power shaft connects on the air compressor machine, the second power shaft connects on the multistage pump, the third power shaft connects on the slush pump, first power shaft second power shaft and be between the third power shaft loops through the coupling joint, power component with first power shaft or second power shaft or third power shaft transmission connection.

Further, in the present application, a transmission is sequentially disposed between the first power shaft, the second power shaft, and the third power shaft.

Further, in the present application, the feed delivery tube comprises a support section, a curved section and a first vertical section, the support section is in communication with the mixing chamber, the curved section is connected with the support section, and the first vertical section is connected with the curved section.

Further, in the present application, the support section includes a second vertical section and an inclined section, the second vertical section is rotationally connected to the mixing chamber, one end of the inclined section is connected to the second vertical section, the other end is connected to the curved section, and a support rod is further provided outside the inclined section.

According to the light soil production and distribution integrated system, the air supply component, the water supply component, the foaming agent supply component and the water supply slurry component are arranged on the movable carrier, so that light soil can be formed by mixing on the movable carrier, the distribution rod is further arranged on the movable carrier, the formed light soil is conveyed to the distribution rod, pouring is carried out through the distribution rod, efficiency is effectively improved, the distribution rod consists of the supporting frame, the mixing cavity and the conveying pipeline, and when the power component is used for conveying air, water, the foaming agent and cement slurry, the air, the water, the foaming agent and the cement slurry flow naturally occur, additional power is not needed to be provided for pressurizing and conveying the mixed light soil, so that bubble cracking in the light soil can be avoided, and the light soil production and distribution integrated system has the advantages of high construction efficiency and good construction quality.

Additional features and advantages of the application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application. The objectives and other advantages of the application will be realized and attained by the structure particularly pointed out in the written description and claims thereof as well as the appended drawings.

Drawings

Fig. 1 is a schematic diagram of the overall structure of an integrated system for producing and distributing light soil.

Fig. 2 is a schematic diagram of a local structure of an integrated system for producing and distributing light soil.

Fig. 3 is a schematic diagram of a local structure of an integrated system for producing and distributing light soil.

Fig. 4 is a schematic diagram of the overall structure of the integrated system for producing and distributing light soil.

In the figure: 100. moving the carrier; 200. a gas supply part; 300. a water supply part; 400. a foaming agent supplying part; 500. a water slurry supply part; 600. a power component; 700. an output shaft; 800. a foaming gun; 900. a mixer; 110. a cloth rod; 120. a support frame; 130. a mixing chamber; 140. a material conveying pipe; 150. a support leg; 141. a second vertical section; 142. an inclined section; 143. a support rod; 144. a curved section; 145. a first vertical section; 210. an air compressor; 310. a water pump; 320. a water tank; 410. a blowing agent pump; 420. a blowing agent storage tank; 510. a slurry pump; 520. a slurry hopper; 710. a first power shaft; 720. a second power shaft; 730. and a third power shaft.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. The components of the present application, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present application, as provided in the accompanying drawings, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without making any inventive effort, are intended to be within the scope of the present application.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only to distinguish the description, and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 4, a system for integrating light soil production and distribution comprises

A moving carrier 100, wherein the moving carrier 100 is provided with a gas supply part 200, a water supply part 300, a foaming agent supply part 400, a slurry supply part 500 and a distributing rod 110;

the distributing rod 110 comprises a supporting frame 120, a mixing cavity 130 and a conveying pipe 140, wherein the supporting frame 120 is arranged on the movable carrier 100, the mixing cavity 130 is arranged on the supporting frame 120, and the conveying pipe 140 is communicated with the mixing cavity 130;

the air supply part 200, the water supply part 300, the foaming agent supply part 400, and the cement slurry supply part 500 are respectively communicated with the mixing chamber 130;

the device also comprises a power component 600, wherein the power component 600 provides power for the air supply component 200, the water supply component 300, the foaming agent supply component 400 and the water supply mud component 500, and light soil formed by mixing air, water, foaming agent and cement paste enters the mixing cavity 130 and is poured through the conveying pipe 140 under the driving of the power component 600.

The mobile carrier 100 may be a common automobile, a truck or a truck, and the bottom of the mobile carrier 100 is further provided with a telescopic supporting leg 150, and the supporting leg 150 may be used for supporting when the mobile carrier 100 is under a static condition for reducing shaking caused by vibration, so as to improve stability of a construction process.

Through the above technical scheme, the air supply part 200, the water supply part 300, the foaming agent supply part 400 and the water supply slurry part 500 are arranged on the mobile carrier 100, so that the light soil can be mixed on the mobile carrier 100, the distribution rod 110 is further arranged on the mobile carrier 100, the formed light soil is conveyed to the distribution rod 110, pouring is performed through the distribution rod 110, the efficiency is effectively improved, the distribution rod 110 is composed of the supporting frame 120, the mixing cavity 130 and the conveying pipe 140, and when the power part 600 supplies power to convey air, water, the foaming agent and cement slurry, the flow of the air, the water, the foaming agent and the cement slurry naturally occurs, and no additional power is required to supply pressure to convey the mixed light soil, so that bubble breakage in the light soil can be avoided, and the integrated light soil production and distribution, high construction efficiency and good construction quality are achieved.

It is noted that in some concrete constructions at present, a spreader is also used to spread concrete, however, conventional spreaders cannot be used to spread light soil, because after the concrete is fed into the spreader, the concrete is output by the spreader's own power pump to spread the concrete, and in light soil, the light soil has many bubbles and foams, which would cause the bubbles and foams in the light soil to break if pumped by the power pump, thereby seriously affecting the quality of the light soil construction. Therefore, the distributing rod 110 provided by the application is only composed of the supporting frame 120, the mixing cavity 130 and the conveying pipe 140, and is conveyed by the power generated when the air, the water, the foaming agent and the cement slurry flow, so that the foam in the light soil can be prevented from being broken, and the construction efficiency can be improved and the construction quality can be ensured.

Wherein the mixing chamber 130 may buffer the light earth and may prevent the light earth on the feed conveyor pipe 140 from flowing back.

For the construction efficiency, the air supply part 200, the water supply part 300, the foaming agent supply part 400, and the water supply mud part 500 are provided on the moving carrier 100, and the space of the moving carrier 100 is generally small, so how to reduce the space occupation of the air supply part 200, the water supply part 300, the foaming agent supply part 400, and the water supply mud part 500 is a very important problem.

Thus, further, in some of these embodiments, the air supply assembly 200 includes at least the air compressor 210, the water supply assembly 300 includes at least the water tank 320 and the water pump 310, the foaming agent supply assembly 400 includes at least the foaming agent storage tank 420 and the foaming agent pump 410, and the water supply mud assembly 500 includes at least the mud hopper 520 and the mud pump 510;

the air compressor 210, the water pump 310, the foaming agent pump 410, and the slurry pump 510 share one output shaft 700, and the output shaft 700 is connected to the power unit 600.

Wherein the power unit 600 may be a motor, and the power of the motor may be obtained from the mobile carrier 100.

Through the above technical scheme, the air compressor 210, the water pump 310, the foaming agent pump 410 and the slurry pump 510 share the same output shaft 700, the output shaft 700 is connected with the power component 600, and only one power component 600 is needed to drive the air compressor 210, the water pump 310, the foaming agent pump 410 and the slurry pump 510 to operate, so that the air compressor 210, the water pump 310, the foaming agent pump 410 and the slurry pump 510 are integrated through the same output shaft 700, and compared with the traditional existing lightweight soil production scheme, the air supply component 200, the water supply component 300, the foaming agent supply component 400 and the slurry supply component 500 are all independently arranged and are driven by independent power sources, so that the occupied space is large.

The above scheme can greatly reduce the space occupation, so that the air supply part 200, the water supply part 300, the foaming agent supply part 400 and the water supply mud part 500 can be integrated on the mobile carrier 100, thereby ensuring that the light soil can be produced in the mobile carrier 100, and ensuring that the light soil can be directly poured in the mobile carrier 100 so as to prevent the situation that the light soil is solidified due to overlong waiting time, and the light soil pouring can be performed, although the light soil produced can be stored in the mobile carrier 100 and then moved by the mobile carrier 100, and the construction pouring is performed through the distributing rod 110. However, when the distance to be poured is long, the moving carrier 100 needs to be moved for a long time, and the light soil gradually solidifies with the increase of time, and finally the pouring work cannot be performed, so that in order to solve this problem, it is necessary to integrate the air supply unit 200, the water supply unit 300, the foaming agent supply unit 400, and the water supply slurry supply unit 500 on the moving carrier 100, and the pouring work can be performed on the produced light soil while the production of the light soil is performed, and thus the problem of solidification of the light soil can be effectively solved.

Further, in some embodiments, the foaming gun 800 and the mixer 900 are further included, wherein one end of the foaming gun 800 is communicated with the air compressor 210, the water pump 310 and the foaming agent pump 410, the other end is communicated with the mixer 900, one end of the mixer 900 is communicated with the slurry pump 510, and the other end is communicated with the mixing cavity 130.

Through the above technical scheme, the air compressor 210 sends air into the foaming gun 800, the water pump 310 sends water into the foaming gun 800, the foaming agent pump 410 sends foaming agent into the foaming gun 800, wherein the foaming gun 800 is internally provided with foam metal, the foam metal is provided with a plurality of through holes which are staggered in space, the air, the water and the foaming agent enter the foaming gun 800 to contact with the foam metal, the foam metal is cut by the through holes on the foam metal to form required foam, the foam is input into the mixer 900, the slurry pump 510 sends cement slurry into the mixer 900, the foam and the cement slurry are mixed to form light soil in the mixer 900, and the formed light soil is sent into the mixing cavity 130 under the common pushing of the air compressor 210, the water pump 310, the foaming agent pump 410 and the slurry pump 510 and is output through the material conveying pipe 140, so that pouring construction is completed.

Specifically, in some embodiments, the water pump 310 and the blowing agent pump 410 combine to form a multi-stage pump that is connected to the water tank 320 and the blowing agent storage tank 420, respectively, for mixing water and blowing agent to form a diluent and outputting to the blowing gun 800.

Further, in some embodiments, a first flow rate proportional valve is disposed between the air compressor 210 and the foaming gun 800, a second flow rate proportional valve is disposed between the multistage pump and the foaming gun 800, and a third flow rate proportional valve is disposed between the slurry pump 510 and the mixer 900.

Through the technical scheme, the first flow proportioning valve is utilized to control the input quantity of air, the second flow proportioning valve is utilized to control the input quantity of diluent, and the third flow proportioning valve is utilized to control the input quantity of cement paste, so that the control of the light soil raw material proportioning is realized.

Further, in some of these embodiments, a fourth flow proportioning valve is provided between the multistage pump and the tank 320 and a fifth flow proportioning valve is provided between the multistage pump and the blowing agent storage tank 420.

According to the technical scheme, the fourth flow proportioning valve is utilized to control the water input quantity, the fifth flow proportioning valve is utilized to control the foaming agent input quantity, and further the control of the diluent proportioning is realized.

Further, referring to fig. 3, in some embodiments, the output shaft 700 includes a first power shaft 710, a second power shaft 720, and a third power shaft 730, the first power shaft 710 is connected to the air compressor 210, the second power shaft 720 is connected to the multistage pump, the third power shaft 730 is connected to the slurry pump 510, and the first power shaft 710, the second power shaft 720, and the third power shaft 730 are sequentially connected through a coupling, and the power unit 600 is in driving connection with the first power shaft 710 or the second power shaft 720 or the third power shaft 730.

Through the above technical scheme, the first power shaft 710 and the second power shaft 720 can be connected and installed through the coupling, and the second power shaft 720 and the third power shaft 730 can be installed through the coupling, so that the air compressor 210, the multistage pump and the slurry pump 510 can be quickly assembled and disassembled. When the movable carrier 100 is needed to be used, the three parts can be simply and quickly connected into a whole by using the coupler, and when the movable carrier 100 is not needed to be used, the movable carrier 100 can be quickly disassembled and then independently used.

Further, in some of these embodiments, a transmission is disposed in sequence between the first power shaft 710, the second power shaft 720, and the third power shaft 730.

Through the above technical solution, a transmission is connected between the first power shaft 710 and the second power shaft 720, a transmission is connected between the second power shaft 720 and the third power shaft 730, and the power unit 600 is connected with the first power shaft 710 or the second power shaft 720 or the third power shaft 730, so that different rotation speeds can be realized between the first power shaft 710, the second power shaft 720 and the third power shaft 730 under the driving of one power unit 600, that is, the air compressor 210, the multistage pump and the slurry pump 510 can be operated under different output amounts to control air, diluent and cement slurry.

In the production of light soil, the relevant proportional valve used is easy to fail, and particularly for cement paste, the valve has higher density and viscosity, so that when the relevant valve fails, the proportion of the light soil can be controlled to ensure the stability of construction quality. Therefore, different rotational speeds of the air compressor 210, the multistage pump and the slurry pump 510 are realized through the transmission, so that the air compressor has different output powers, and further, different output amounts of air, diluent and cement slurry can be controlled, and further, the required light soil proportioning is realized. Moreover, the different rotational speeds of the first power shaft 710, the second power shaft 720 and the third power shaft 730 may vary with respect to the pressure of the air, the diluent and the cement slurry, and in general, the cement slurry may have a relatively large driving force due to its high density and viscosity, and the foam formed by mixing the diluent and the air may not have a large driving force, or the foam may be broken and dissipated easily, so that the lightweight soil with stable quality may not be formed, and thus, the air, the diluent and the cement slurry may need to have different driving forces, and the speed changer may be provided between the first power shaft 710 and the second power shaft 720, and the speed changer may be provided between the second power shaft 720 and the third power shaft 730.

Further, in some of these embodiments, the feed conveyor pipe 140 includes a support section in communication with the mixing chamber 130, a curved section 144 connected to the support section, and a first vertical section 145 connected to the curved section 144.

Through the above technical scheme, the supporting section is used for providing a supporting foundation for the bending section 144, and the first vertical section 145 is used for reducing the height between the light soil and the target ground when discharging, so as to prevent the excessive impact generated by the excessive height, and cause excessive collapse dissipation of bubbles and foam in the light soil, thereby affecting the construction quality.

Further, in some embodiments, the support section includes a second vertical section 141 and an inclined section 142, the second vertical section 141 is rotatably connected to the mixing chamber 130, one end of the inclined section 142 is connected to the second vertical section 141, the other end is connected to the curved section 144, and a support rod 143 is further provided outside the inclined section 142.

In addition, a rotational connection between the mixing chamber 130 and the support 120 may be provided.

Through the above technical scheme, the second vertical section 141 is rotatably connected to the mixing chamber 130, so that the whole conveying pipe 140 can be rotated, and the construction flexibility is better, the inclined section 142 is used for guiding the transmission direction of the lightweight soil, and the supporting rod 143 is used for supporting the inclined section 142, so that the inclined section 142 is prevented from collapsing.

Further, the second vertical section 141 and the inclined section 142 may be rotatably connected, and the support rod 143 may be an electric push rod, so that the inclination angle of the inclined section 142 may be adjusted, and the height of the highest point of the inclined section 142 may be adjusted.

The foregoing is merely exemplary embodiments of the present application and is not intended to limit the scope of the present application, and various modifications and variations may be suggested to one skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (5)

1. The integrated system for producing and distributing light soil comprises a movable carrier (100), and is characterized in that an air supply component (200), a water supply component (300), a foaming agent supply component (400), a water and slurry supply component (500) and a distributing rod (110) are arranged on the movable carrier (100);

the distributing rod (110) is only composed of a supporting frame (120), a mixing cavity (130) and a conveying pipe (140), the supporting frame (120) is arranged on the mobile carrier (100), the mixing cavity (130) is arranged on the supporting frame (120), and the conveying pipe (140) is communicated with the mixing cavity (130);

the air supply part (200), the water supply part (300), the foaming agent supply part (400) and the water supply mud part (500) are respectively communicated with the mixing cavity (130);

the device also comprises a power component (600), wherein the power component (600) provides power for the air supply component (200), the water supply component (300), the foaming agent supply component (400) and the water supply mud component (500), and under the driving of the power component (600), light soil formed by mixing air, water, foaming agent and cement paste enters the mixing cavity (130) and is naturally conveyed to the conveying pipe (140) for pouring through the flows of the air, the water, the foaming agent and the cement paste;

the air supply part (200) at least comprises an air compressor (210), the water supply part (300) at least comprises a water tank (320) and a water pump (310), the foaming agent supply part (400) at least comprises a foaming agent storage tank (420) and a foaming agent pump (410), and the water supply mud part (500) at least comprises a mud hopper (520) and a mud pump (510);

the air compressor (210), the water pump (310), the foaming agent pump (410) and the slurry pump (510) share one output shaft (700), and the output shaft (700) is connected with the power component (600);

the device further comprises a foaming gun (800) and a mixer (900), wherein one end of the foaming gun (800) is communicated with the air compressor (210), the water pump (310) and the foaming agent pump (410), the other end of the foaming gun is communicated with the mixer (900), one end of the mixer (900) is communicated with the slurry pump (510), and the other end of the mixer is communicated with the mixing cavity (130);

the water pump (310) is combined with the foaming agent pump (410) to form a multi-stage pump, and the multi-stage pump is respectively connected with the water tank (320) and the foaming agent storage tank (420) and is used for mixing water and the foaming agent to form a diluent and outputting the diluent to the foaming gun (800);

the output shaft (700) comprises a first power shaft (710), a second power shaft (720) and a third power shaft (730), the first power shaft (710) is connected to the air compressor (210), the second power shaft (720) is connected to the multistage pump, the third power shaft (730) is connected to the slurry pump (510), the first power shaft (710), the second power shaft (720) and the third power shaft (730) are sequentially connected through a coupling, and the power component (600) is in transmission connection with the first power shaft (710) or the second power shaft (720) or the third power shaft (730);

a transmission is sequentially arranged among the first power shaft (710), the second power shaft (720) and the third power shaft (730).

2. The integrated system for producing and distributing light soil according to claim 1, wherein a first flow proportioning valve is arranged between the air compressor (210) and the foaming gun (800), a second flow proportioning valve is arranged between the multistage pump and the foaming gun (800), and a third flow proportioning valve is arranged between the slurry pump (510) and the mixer (900).

3. The integrated system for producing and distributing light soil according to claim 2, wherein a fourth flow proportioning valve is arranged between the multistage pump and the water tank (320), and a fifth flow proportioning valve is arranged between the multistage pump and the foaming agent storage tank (420).

4. The lightweight soil production and distribution integrated system as claimed in claim 1, wherein the feed conveyor pipe (140) comprises a support section, a curved section (144) and a first vertical section (145), the support section being in communication with the mixing chamber (130), the curved section (144) being connected to the support section, the first vertical section (145) being connected to the curved section (144).

5. The integrated lightweight soil production and distribution system as claimed in claim 4, wherein the support section comprises a second vertical section (141) and an inclined section (142), the second vertical section (141) is rotatably connected to the mixing chamber (130), one end of the inclined section (142) is connected to the second vertical section (141), the other end is connected to the curved section (144), and a support rod (143) is further provided outside the inclined section (142).