Production device of high-efficiency soil conditioner containing humic acid

The high-efficiency soil conditioner production device, which integrates a heating layer, a stirring component, and a permeation membrane component, solves the problems of humic acid treatment and uneven material mixing, and achieves efficient and precise soil conditioner production.

CN224405108UActive Publication Date: 2026-06-26XINJIANG ZHONGKUANG HUMIC ACID CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XINJIANG ZHONGKUANG HUMIC ACID CO LTD
Filing Date
2025-07-21
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing equipment cannot specifically process humic acid in the production of soil conditioners containing humic acid, resulting in low production quality and efficiency, requiring multiple pieces of equipment to assist in the process.

Method used

A high-efficiency soil conditioner production device containing humic acid was designed, integrating a heating layer, a stirring component, a switchable permeable membrane component, and a precise batching system to achieve efficient processing of humic acid and uniform mixing of materials.

Benefits of technology

It improves the efficiency and uniformity of humic acid treatment, ensures the quality and production efficiency of soil conditioners, reduces processes, and achieves integrated processing.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model discloses a kind of efficient soil conditioner production devices containing humic acid, including outer box, be equipped with mixing assembly and group assembly on the outer box;Still including coaxially nested in the inner box of outer box interior, heating layer is equipped on the inner box, stirring assembly, switchable osmotic membrane component, the inner box top and bottom are respectively communicated feed pipe and discharge pipe, valve is equipped on the discharge pipe;Still including the driving element being set on the inner box.Affinity effect lies in: heating layer in inner box and stirring assembly jointly act, can efficiently promote reaction temperature and material uniformity;Precise batching using group assembly, cooperate mixing assembly combination, ensure that material is stirred evenly;Device whole can be according to the needs "permeation" or "dehydration" operation by switchable osmotic membrane component, adjust moisture content, so that soil conditioner is more in accord with the demand of different soil.
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Description

Technical Field

[0001] This utility model relates to the field of soil conditioner production, specifically to a high-efficiency soil conditioner production device containing humic acid. Background Technology

[0002] With the continuous development of agriculture, soil degradation has become an increasingly prominent problem. Humic acid-containing soil conditioners are widely used because they can effectively improve soil structure and enhance soil fertility. In the production process of humic acid-containing soil conditioners, the performance of the production equipment directly affects product quality and production efficiency.

[0003] Compared with Chinese patent CN202411173965.0, which discloses an environmentally friendly composite soil conditioner production mixing equipment, including a mixing tank and a mixing paddle rotatably connected inside the mixing tank. The mixing tank is provided with a mixing chamber. A double-headed geared motor is fixedly installed at the bottom inside the mixing tank. The upper output end of the double-headed geared motor extends into the mixing chamber and is fixedly connected to the mixing paddle. The lower output end is fixedly connected to a cam plate. Multiple sets of sliding rods and moving rods are also radially slidably connected at the bottom inside the mixing tank. The bottom inside the mixing chamber is conical and has a radially provided fitting groove. A spraying structure is fitted into the fitting groove.

[0004] However, these existing devices still have certain limitations in practical applications. Although the combination of the stirring paddle and the spraying structure improves the mixing effect to some extent, they cannot be specifically processed when producing high-efficiency soil conditioners containing humic acid, such as adjusting the heating concentration of humic acid. As a result, the production of high-efficiency soil conditioners containing humic acid often requires the addition of multiple pieces of equipment to assist in the work, which increases the number of processes and affects the production quality and efficiency of the soil conditioner.

[0005] Therefore, there is a need for a high-efficiency humic acid-containing soil conditioner production device that integrates humic acid treatment functions to solve the above problems. Utility Model Content

[0006] The purpose of this invention is to provide a high-efficiency soil conditioner production device containing humic acid, so as to solve the problems of humic acid treatment, low batching accuracy, and uneven material mixing mentioned in the background art.

[0007] The purpose of this utility model is achieved as follows:

[0008] The present invention provides a high-efficiency soil conditioner production device containing humic acid, including an outer box, on which a mixing component for stirring the internal materials and a batching component for assisting in the batching of the internal materials are provided, and a discharge valve is connected to the bottom of the outer box.

[0009] It also includes an inner box coaxially nested inside the outer box, the inner box being provided with a heating layer, a stirring assembly, and a switchable permeation membrane assembly, the top and bottom of the inner box being connected to an inlet pipe and an outlet pipe respectively, and the outlet pipe being provided with a valve;

[0010] It also includes a drive unit installed on the inner casing to assist in driving the permeation membrane assembly to switch between "permeation" and "dehydration".

[0011] Further explanation is that the assembly includes multiple independently set mixing tanks, the discharge end of each mixing tank is connected to a metering pump via an electrically controlled valve, the output port of the metering pump is connected to the outer casing, and also includes a controller, the metering pump and the electrically controlled valve on the discharge end of the mixing tank are all electrically connected to the controller.

[0012] Further explanation is that a mixing tank is provided at the bottom of the outer casing, the discharge pipe of the metering pump is connected to the mixing tank, and a water supply pipe with an electrically controlled valve is connected to the mixing tank. The electrically controlled valve on the water supply pipe is electrically connected to the controller.

[0013] To further explain, the mixing assembly includes no fewer than three vibrators, with adjacent vibrators connected by a flexible hose. The vibrator is an electrically controlled vibrator or an ultrasonic vibration probe connected to the output end of an ultrasonic generator, and the vibrator is electrically connected to the controller.

[0014] Further explanation: The inner housing includes an annular support, and the side wall of the annular support is provided with a filter assembly corresponding to the inner wall of the outer housing. The filter assembly includes a filter membrane and an outer partition plate arranged at intervals. An inner ring frame is rotatably connected to the annular support, and the inner ring frame is provided with an inner partition plate corresponding to the outer filter membrane. The annular support is provided with a driving component for driving the inner ring frame to rotate. The driving component is an electric push cylinder electrically connected to the controller. When the inner partition plate corresponds to the filter membrane, the permeation membrane assembly is in "permeation" mode. When the inner partition plate and the filter membrane are staggered, the permeation membrane assembly is in "dehydration" mode.

[0015] To further explain, the stirring assembly includes a motor mounted on the inner casing, the output end of the motor extending into the interior of the inner casing and connected to a drive shaft, and multiple stirring blades mounted on the outside of the drive shaft.

[0016] To further explain, the outer casing is equipped with a monitoring component for detecting the liquid inside.

[0017] To further explain, the monitoring component includes a monitoring module installed on the outer wall of the outer casing. The monitoring module includes an integrated pH sensor, a conductivity sensor, and an organic matter detection sensor. The electrical input terminal of the monitoring module is provided with an electrode probe, which extends into the interior of the outer casing. The monitoring module is electrically connected to the controller.

[0018] To further explain, both the outer casing and the inner casing have annular pipes on their top surfaces. The annular pipes have multiple through holes, and the water inlet end of the annular pipes is connected to a high-pressure water supply device to assist in the self-cleaning of the outer casing and the inner casing.

[0019] Positive and beneficial effects:

[0020] The heating layer and stirring components in the inner chamber work together to use heating to assist in the extraction of dilute humic acid solution, thereby treating humic acid, efficiently improving reaction temperature and material uniformity, and accelerating the reaction process.

[0021] The device as a whole can perform "permeation" or "dehydration" operations as needed by switching permeation membrane components, adjusting the moisture content so that the soil conditioner can better meet the needs of different soils.

[0022] The precise ingredient mixing of the assembly components improves the accuracy of the proportions and ensures the quality of the final product. The combination of the outer casing and the mixing components ensures that the materials are mixed evenly.

[0023] The entire process achieves integrated processing of highly efficient soil conditioners containing humic acid, making the overall production more efficient and flexible. Attached Figure Description

[0024] Figure 1 This is a schematic diagram of the structure of this utility model;

[0025] Figure 2 This is a schematic diagram of the internal structure of the present invention;

[0026] Figure 3 This is a schematic diagram of the inner ring frame in this utility model;

[0027] Figure 4 This is a schematic diagram of the internal structure of the stirring assembly in this utility model;

[0028] The diagram shows: outer casing 1, mixing tank 101, water supply pipe 102, inner casing 2, ring support 201, upper frame 201a, lower ring 201b, connecting rod frame 201c, top cover 201d, filter assembly 202, filter membrane 202a, outer partition 202b, inner ring frame 203, upper support ring 203a, inner partition 203b, lower support ring 203c, drive component 204, guide frame 205, feed controller 208, monitoring component 4, mixing assembly 5, motor 501, drive shaft 502, mixing blade 503, assembly assembly 6, batching tank 601, metering pump 602, controller 603, mixing assembly 7, and vibrator 701. Detailed Implementation

[0029] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0030] First embodiment:

[0031] See Figures 1-4 As shown, the high-efficiency soil conditioner production device containing humic acid provided by this utility model includes an outer box 1, which serves as the outer load-bearing structure of the device. The bottom of the outer box 1 is provided with support legs for support. The outer box 1 is provided with a mixing component 7 for stirring the internal materials and an assembly component 6 for assisting in the batching of the internal materials. The bottom of the outer box 1 is connected to a discharge valve. The assembly component 6 plays the role of assisting in batching and can accurately control the input ratio of different raw materials, providing a basis for subsequent material mixing. The mixing component 7 is mainly used to stir and mix the materials in the box to ensure that various raw materials can be uniformly blended.

[0032] It also includes an inner box 2 coaxially nested inside the outer box 1. The outer wall of the inner box 2 and the outer box 1 form an annular cavity. In addition, the overall height of the inner box 2 is smaller than that of the outer box 1, so the inner box 2 is located inside the outer box 1. There is a large mixing space below the annular cavity. The inner box 2 is equipped with a heating layer, a stirring component 5, and a switchable permeation membrane component. The heating layer can assist in heating the internal materials and can assist in the extraction of the dilute humic acid solution, effectively improving the reaction temperature and material uniformity, and accelerating the reaction process.

[0033] The top and bottom of the inner box 2 are connected to the feed pipe and the discharge pipe, respectively. The bottom end of the discharge pipe extends out of the outer box 1, and a valve is provided on the discharge pipe. The discharge pipe can be used to assist in the slag discharge and cleaning operation inside the inner box 2.

[0034] It also includes a drive unit 204 installed on the inner casing 2. The main function of this component is to assist in driving the switchable permeable membrane assembly, so as to realize the flexible switching between the two modes of "permeation" and "dehydration", thereby meeting the different needs of material permeation treatment and dehydration treatment in the soil conditioner production process.

[0035] When using this high-efficiency soil conditioner production device containing humic acid, the first step is to extract a dilute humic acid solution: the raw material containing humic acid is fed into the inner chamber 2 through the feed pipe at the top of the inner chamber 2, and then the relevant valves of the feed pipe are closed; the heating layer on the inner chamber 2 is activated, and the heating layer begins to heat the internal material, while the stirring component 5 is turned on to continuously stir the material; with the combined heating effect of the heating layer and the stirring effect of the stirring component 5, the material is heated evenly, and the dilute humic acid solution can be extracted more efficiently. In this process, the reaction temperature is effectively increased, the uniformity of the material is enhanced, and the extraction reaction is greatly accelerated. During the above operation, the drive component 204 assists in driving the switchable permeable membrane component in the "dehydration" working mode, that is, the dilute humic acid solution is diluted and dehydrated to adjust the concentration of the solution to a suitable range.

[0036] After the dehydration operation is completed, the switchable permeate membrane module is assisted by drive component 204 to switch it to the "permeate" working mode according to production needs. At this time, the dilute solution will permeate into the annular cavity, preparing for subsequent treatment. After the treatment is completed, the valve on the discharge pipe at the bottom of the inner chamber 2 is opened to allow the treated humic acid dilute solution to be discharged through the discharge pipe and enter the outer chamber 1.

[0037] Next, we enter the mixing and production stage of the soil conditioner: the assembly component 6 on the outer casing 1 is activated. The assembly component 6 assists in the mixing of materials inside the outer casing 1 according to the preset formula ratio, and accurately puts the other required raw materials into the outer casing 1 to mix with the dilute humic acid solution. After the mixing is completed, the mixing component 7 is activated. The mixing component 7 thoroughly stirs and mixes all the materials in the casing to ensure that all kinds of raw materials and dilute humic acid solution are evenly integrated to form a soil conditioner that meets the requirements.

[0038] Once the soil conditioner is mixed, open the discharge valve connected to the bottom of the outer casing 1. The produced high-efficiency soil conditioner containing humic acid will then be discharged through the discharge valve, completing the entire production process.

[0039] Furthermore, the discharge valve at the bottom of the outer casing 1 is connected to a multi-stage filtration device, consisting of a 100-mesh stainless steel filter screen, a 3μm pleated filter element, and a 0.22μm sterilization filter membrane, ultimately ensuring that the suspended particulate content of the final product is ≤0.1mg / L.

[0040] The second embodiment differs from the first embodiment in that:

[0041] The assembly component 6 includes multiple independently configured mixing tanks 601, each responsible for storing different raw materials. These tanks can separately hold various auxiliary raw materials required for the production of the improver, such as additives and regulators. Independent configuration avoids premature mixing or contamination of different raw materials, ensuring the purity and accuracy of the proportions. The mixing tanks adopt a modular design, with a single tank volume of 50-500L. The inner wall of the tank is coated with polytetrafluoroethylene and equipped with a magnetic stir bar to prevent additives from settling and stratifying during storage. The discharge end of the mixing tank 601 is connected to a metering pump 602 via an electrically controlled valve. This valve acts as a switch for raw material output, directly controlling the flow and shut-off of raw materials within the mixing tank 601. The metering pump 602 is connected downstream of the electrically controlled valve. The main function of 602 is to precisely control the amount of raw materials conveyed. Through its own metering function, it can stably convey the raw materials in the mixing tank 601 according to the preset ratio. The output port of the metering pump 602 is connected to the outer casing 1 and also includes a controller 603. The metering pump 602 and the electrically controlled valve on the discharge end of the mixing tank 601 are all electrically connected to the controller 603. Through the unified control of the controller 603, multiple mixing tanks 601 can convey various raw materials into the outer casing 1 in the set order and ratio through the metering pump 602, realizing the automation and precision of the mixing process, effectively avoiding the errors that may occur in manual mixing, greatly improving the efficiency and accuracy of the mixing process in the soil conditioner production process, and providing a precise raw material basis for the subsequent mixing process.

[0042] During installation, the bottom of the outer casing 1 is connected to the mixing tank 101, and the discharge pipe of the metering pump 602 is connected to the mixing tank 101. The mixing tank 101 is connected to the water supply pipe 102 with an electrically controlled valve. The electrically controlled valve on the water supply pipe 102 is electrically connected to the controller 603. The mixing tank 101 is also connected to the water supply pipe 102, which is equipped with an electrically controlled valve to control the flow of water. The electrically controlled valve on the water supply pipe 102 is electrically connected to the controller 603. This connection allows the controller 603 to incorporate the water supply process into the overall automated control system.

[0043] The mixing assembly 7 includes at least three vibrators 701. The vibrators 701 are arranged in a ring structure within the mixing tank 101 for uniform mixing. Adjacent vibrators 701 are connected by a flexible hose. The vibrators 701 are either electrically controlled vibrators or ultrasonic vibration probes connected to the output end of an ultrasonic generator. The vibrators 701 are electrically connected to the controller 603. Preferably, a fixing component is installed on the top surface of the outer casing 1. A vertical flexible hose is provided at the bottom of the fixing component. The bottom end of the vertical flexible hose is connected to the vibrator 701. In the overall structure of the vibrator 701, the position of the vibrator 701 can be kept relatively stable, thereby ensuring the uniformity of mixing of materials inside the mixing tank 101.

[0044] Furthermore, the vibrator 701 offers two types of options: an electrically controlled vibrator and an ultrasonic vibration probe connected to the output of an ultrasonic generator. The electrically controlled vibrator directly converts electrical energy into mechanical vibration, and the vibration intensity and frequency can be adjusted as needed, making it suitable for general material mixing scenarios. The ultrasonic vibration probe, on the other hand, uses ultrasonic energy generated by the ultrasonic generator to vibrate, resulting in a higher vibration frequency and stronger cavitation and stirring effects. It is particularly suitable for viscous materials that are difficult to mix or for applications requiring fine mixing. The two types of vibrators can be flexibly selected according to actual production needs.

[0045] The vibrator 701 is electrically connected to the controller 603, enabling the controller 603 to precisely control the operating state of the vibrator 701. The controller 603 can set the start-up time, vibration frequency, and vibration intensity of the vibrator according to parameters such as material properties and mixing requirements, thus achieving automated adjustment of the vibration mixing process. By uniformly controlling the coordinated operation of multiple vibrators, the consistency of vibration effects can be ensured, and vibration parameters can be adjusted according to different mixing stages, further improving the efficiency and quality of material mixing and ensuring that the material inside the outer casing 1 achieves an ideal mixing state.

[0046] The third embodiment differs from the first embodiment in that:

[0047] The inner housing 2 includes an annular support 201, which comprises two 201a and 201b arranged vertically. The upper support 201a and the lower annular support 201b are connected by a connecting rod 201c. A cavity structure exists between the upper support 201a and the lower annular support 201b. This cavity structure contains a filter assembly 202 corresponding to the inner wall of the outer housing 1. The filter assembly 202 includes multiple filter membranes 202a and outer partitions 202b spaced apart. All filter membranes 202a and all outer partitions 202b form an annular structure. An inner ring frame 203 is rotatably connected to the inner wall of the 201a. The inner ring frame 203 includes an upper support ring 203a, which is rotatably connected to the inner side of the upper support 201a. The upper support ring 203a has a corresponding... The inner partition 203b corresponding to the outer filter membrane 202a is provided with a driving component 204 on the annular support 201 to drive the inner ring frame 203 to rotate. The driving component 204 is an electric push cylinder electrically connected to the controller 603. Preferably, there are two upper support rings 203a. The two upper support rings 203a are rotatably connected to the upper frame 201a and the lower ring 201b respectively. The inner partition 203b is set between the two upper support rings 203a. When the inner partition 203b corresponds to the filter membrane 202a, the permeation membrane assembly is in "permeation" mode. The permeation mode is used to assist the solution inside the inner box 2 to be permeated and discharged into the outer box 1 through the outer partition 202b. When the inner partition 203b and the filter membrane 202a are staggered, the permeation membrane assembly is in "dehydration" mode. The "dehydration" mode is mainly used for dehydrating the material inside 2.

[0048] The bottom of the lower ring 201b is provided with a guide frame 205. The guide frame 205 is an inverted cone shape. A discharge pipe is provided at its axis to pass through the outer box 1. The guide frame 205 has a double-layer structure. It has a cavity inside and an electric heating layer inside the cavity. The heating temperature of the electric heating layer is 30-70°C.

[0049] The upper frame 201a has a ring or disc-shaped structure. When the upper frame 201a is ring-shaped, the upper support ring 203a is installed on the inner ring wall of the upper frame 201a. The upper frame 201a is provided with multiple side ears, and the top cover 201d is connected to the side ears by bolts. The top cover 201d has a disc-shaped structure. The stirring component 5 can be installed on the upper surface of the top cover 201d. The driving component 204 can be set on the upper or lower surface of the top cover 201d.

[0050] Furthermore, when the upper frame 201a is disc-shaped, the inner ring frame 203 is rotatably connected to the inner top surface of the upper frame 201a, the stirring assembly 5 is installed on the upper surface of the top cover 201d, and the driving component 204 is set on the inner top surface of the top cover 201d. This arrangement facilitates the installation of the equipment and ensures the airtightness of the inner box 2, which is conducive to the installation of the vacuum equipment. After the vacuum equipment is installed, it can assist the internal permeation work of the inner box 2.

[0051] Furthermore, the stirring assembly 5 includes a motor 501 installed on the inner casing 2. The output end of the motor 501 extends into the inner casing 2 and is connected to a drive shaft 502. Multiple stirring blades 503 are installed on the outside of the drive shaft 502. Preferably, there are two stirring assemblies 5. The motor 501 drives the drive shaft 502 to rotate, thereby driving the multiple stirring blades 503 to rotate, realizing the stirring treatment of the materials inside the inner casing 2. From top to bottom, the blade diameters of these stirring blades 503 increase in a ratio of 1:1.5. The gradual diameter design can adapt to the spatial characteristics of different heights inside the inner casing 2, and at the same time apply more precise stirring force to the distribution state of materials at different depths. The larger diameter blades at the bottom can form a stronger pushing and turning effect on the lower layers of more or thicker materials. Through the combination of different diameters, the stirring dead corners are further reduced, and the overall mixing uniformity is improved. This not only helps to improve the heating uniformity during heating, but also accelerates the extraction reaction of the dilute humic acid solution, allowing the materials to react and mix in a more refined state.

[0052] The fourth embodiment differs from the first embodiment in that:

[0053] The monitoring component 4 installed on the outer casing 1 is an important component that monitors the liquid state inside the outer casing 1 in real time, and can provide data support for the production quality of soil conditioner.

[0054] The monitoring component 4 includes a monitoring module installed on the outer wall of the outer casing 1. The monitoring module includes, but is not limited to, a pH sensor, a conductivity sensor, and an organic matter detection sensor. In the monitoring module, the pH sensor can accurately detect the acidity or alkalinity of the liquid, the conductivity sensor can reflect the content of electrolytes in the liquid, and the organic matter detection sensor is specifically used to monitor the amount of organic matter in the liquid. The three are integrated together to comprehensively and synchronously obtain the key indicators of the liquid inside the outer casing 1.

[0055] The monitoring module's electrical input terminal is equipped with an electrode probe that extends directly into the outer casing 1, contacting the liquid inside. The probe collects various parameters of the liquid in real time. Simultaneously, the monitoring module is electrically connected to the controller 603 to ensure the accuracy and timeliness of the data. The controller 603 analyzes and processes this data, and when any indicator deviates from the preset range, it promptly issues instructions to adjust relevant components. For example, if the pH value is unsuitable, the controller 603 can control the electrically controlled valve of the corresponding mixing tank 601 and the metering pump 602 in the mixing assembly 6 to add an appropriate amount of regulator to adjust the liquid's pH, thereby ensuring that the liquid inside the outer casing 1 remains in a suitable state and guaranteeing the production quality of the soil conditioner.

[0056] The fifth embodiment differs from the first embodiment in that:

[0057] Both the outer casing 1 and the inner casing 2 have annular pipes on their inner top surfaces. These pipes have multiple through holes, and their inlets are connected to a high-pressure water supply system to assist in the self-cleaning process of the outer casing 1 and the inner casing 2.

[0058] Both the outer casing 1 and the inner casing 2 have annular pipes on their inner top surfaces. These pipes have multiple through-holes, the distribution of which matches the pipe's orientation, allowing high-pressure water to be evenly directed to every corner of the interior of both casings. The inlet of the annular pipes is connected to a high-pressure water supply system. During cleaning, the high-pressure water jets through the through-holes in the annular pipes, creating a strong impact and a multi-directional, multi-angle rinsing effect. This effectively washes away residues adhering to the inner walls of the outer casing 1 and inner casing 2, the mixing component 5, and other parts, preventing material residue from affecting the quality of the soil conditioner in subsequent production. It effectively removes stubborn stains and residues from the casing, improving cleaning efficiency and effectiveness. This self-cleaning method eliminates the need for manual entry into the casing, saving manpower, ensuring thorough cleaning, reducing equipment downtime, increasing production efficiency, and providing a clean environment for the next production run.

[0059] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. Humic acid-containing high-efficiency soil conditioner production device, comprising an outer box body (1), characterized in that: The outer casing (1) is provided with a mixing component (7) for stirring the internal materials and a batching component (6) for assisting in the batching of the internal materials of the outer casing (1). The bottom of the outer casing (1) is connected to a discharge valve. It also includes an inner casing (2) coaxially nested inside the outer casing (1). The inner casing (2) is provided with a heating layer, a stirring component (5), and a switchable permeation membrane component. The top and bottom of the inner casing (2) are respectively connected to a feed pipe and a discharge pipe. The discharge pipe is provided with a valve. It also includes a driving component (204) provided on the inner casing (2) to assist in driving the permeation membrane component to switch between "permeation" and "dehydration".

2. The humic acid-containing high-efficiency soil conditioner production device according to claim 1, characterized by: The assembly component (6) includes multiple independently set mixing tanks (601). The discharge end of the mixing tank (601) is connected to a metering pump (602) via an electrically controlled valve. The output port of the metering pump (602) is connected to the outer casing (1). The assembly component also includes a controller (603). The electrically controlled valves on the metering pump (602) and the discharge end of the mixing tank (601) are electrically connected to the controller (603).

3. The humic acid-containing highly effective soil conditioner production device according to claim 2, characterized by: The bottom of the outer casing (1) is provided with a mixing tank (101), the discharge pipe of the metering pump (602) is connected to the mixing tank (101), and a water supply pipe (102) with an electric control valve is connected to the mixing tank (101). The electric control valve on the water supply pipe (102) is electrically connected to the controller (603).

4. The humic acid-containing highly efficient soil amendment production device according to claim 3, characterized by: The mixing assembly (7) includes no less than three vibrators (701), with adjacent vibrators (701) connected by a hose. The vibrator (701) is an electrically controlled vibrator or an ultrasonic vibration probe connected to the output end of an ultrasonic generator. The vibrator (701) is electrically connected to the controller (603).

5. The humic acid-containing highly effective soil conditioner production device according to any one of claims 2 to 4, characterized by: The inner box (2) includes an annular support (201). The side wall of the annular support (201) is provided with a filter assembly (202) corresponding to the inner wall of the outer box (1). The filter assembly (202) includes a filter membrane (202a) and an outer partition (202b) arranged at intervals. An inner ring frame (203) is rotatably connected to the annular support (201). The inner ring frame (203) is provided with an inner partition (203b) corresponding to the outer filter membrane (202a). The annular support (201) is provided with a driving component (204) for driving the inner ring frame (203) to rotate. The driving component (204) is an electric push cylinder electrically connected to the controller (603). When the inner partition (203b) corresponds to the filter membrane (202a), the permeation membrane assembly is in "permeation" mode. When the inner partition (203b) and the filter membrane (202a) are staggered, the permeation membrane assembly is in "dehydration" mode.

6. The humic acid-containing highly efficient soil amendment production device according to claim 5, characterized by: The stirring assembly (5) includes a motor (501) mounted on the inner box (2), the output end of the motor (501) extending into the inner box (2) and connected to a drive shaft (502), and multiple stirring blades (503) mounted on the outside of the drive shaft (502).

7. The humic acid-containing highly efficient soil amendment production device according to claim 2, characterized by: The outer casing (1) is equipped with a monitoring component (4) for detecting the liquid inside.

8. The apparatus for producing a high-efficiency soil conditioner containing humic acid according to claim 7, characterized in that: The monitoring component (4) includes a monitoring module installed on the outer wall of the outer casing (1). The monitoring module includes an integrated pH sensor, a conductivity sensor and an organic matter detection sensor. The electrical input terminal of the monitoring module is provided with an electrode probe. The electrode probe extends into the interior of the outer casing (1), and the monitoring module is electrically connected to the controller (603).

9. The humic acid-containing efficient soil conditioner production device according to any one of claims 7-8, characterized by: Both the outer casing (1) and the inner casing (2) have annular pipes on their inner top surfaces. The annular pipes have multiple through holes. The water inlet end of the annular pipes is connected to a high-pressure water supply device to assist in the self-cleaning of the outer casing (1) and the inner casing (2).