A continuous maintenance apparatus

Abstract

The utility model discloses a kind of continuous maintenance equipment, including distributing device, high bin, material turning device, low bin, discharging device and control system, distributing device is used to transport artificial aggregate to high bin and distribute;High bin is provided with cavity of head-to-tail, and humidity adjusting device and temperature adjusting device are respectively installed on high bin;Material turning device is set to high bin bottom, and material turning device includes multiple material turning mechanisms, and multiple material turning mechanisms are sequentially arranged along the direction of material at the bottom of cavity;Low bin is located below material turning mechanism, and there is a certain distance between the top of low bin and the bottom of high bin;Discharging device is located below low bin, for outputting artificial aggregate discharged from low bin;Control system is used to control distributing device, humidity adjusting device, temperature adjusting device, material turning mechanism and discharging device respectively, to achieve the effect of ensuring continuous production, preventing maintenance process caking and sticking, small footprint and low construction cost.

Description

Technical Field

[0001] This utility model relates to the field of building materials equipment, and in particular to a continuous curing equipment. Background Technology

[0002] With increasing environmental awareness, the mining of natural aggregates is facing increasingly stringent restrictions. As a result, the production of synthetic aggregates is booming. Most synthetic aggregates are produced using various solid powders, granules, and chemical agents as raw materials, which are then mixed and undergo a curing reaction to form a stable and durable structure. During the production process, the product generally has very low strength in the initial molding stage and requires several hours, even tens of hours, in a warm and humid environment to slowly increase its strength; this process is called curing. During the initial curing stage, turning the product should be avoided, but if it is not turned at all, the product is prone to clumping and sticking together. The curing process is crucial and directly affects the quality of the product.

[0003] Currently, artificial aggregate production plants use methods such as stockpiles, fixed silos, and vans for curing. However, practice has shown that these methods all have certain shortcomings and are not yet ideal curing methods.

[0004] 1. Stockpile Curing: This method involves stacking the product on the ground with simple fencing around the pile. The advantage of this method is low equipment investment, but it has many disadvantages. First, because artificial aggregates have relatively small angles of repose, they are difficult to stack high, resulting in a large production footprint. Second, the temperature and humidity during curing are difficult to control. Third, using forklifts or other equipment to move the product can easily cause breakage. Furthermore, if the product is not turned over promptly after curing, it can clump and stick together.

[0005] 2. Fixed Silo Curing: Steel silos are used as curing equipment. Products are loaded from the top and discharged from the bottom outlet after the curing time is reached. In this method, top loading and bottom unloading cannot be carried out simultaneously; multiple fixed silos must be used in rotation for curing. Furthermore, the curing time cannot exceed 8 hours; otherwise, clumping and adhesion will occur, making discharge impossible.

[0006] 3. Box-type maintenance: Similar to the fixed-bin method, this involves multiple maintenance devices rotating. The box-shaped maintenance trucks are equipped with wheels. Once full, they move to the maintenance area. After the required maintenance time is reached, unloading is done via side unloading or a tipper. This method has a large unloading opening, which helps avoid material clumping and difficulty in unloading. However, the truck body cannot be too high, otherwise the artificial aggregate will break during loading. This method has low space utilization, occupies a large area, and requires auxiliary equipment such as tippers and tracks.

[0007] A very small number of companies use large-scale static curing equipment for maintenance, but the investment in such equipment is large, and due to structural limitations, a complete shutdown is required in case of a malfunction, affecting normal production.

[0008] To address the practical problems in the existing curing process of artificial aggregates, there is an urgent need to develop a new curing method. This method should have advantages such as ensuring continuous production, preventing clumping and adhesion during the curing process, higher space utilization, smaller footprint, lower construction cost, and ease of maintenance. Utility Model Content

[0009] To solve the above-mentioned technical problems, this utility model provides a continuous curing equipment, which has the advantages of ensuring continuous production, preventing caking and sticking during the curing process, higher space utilization, small footprint, and low construction cost.

[0010] To achieve the above objectives, the present invention adopts the following technical solution:

[0011] A continuous curing device includes a material distribution device, a high-level bin, a material turning device, a low-level bin, a material discharge device, and a control system.

[0012] The fabric spreading device is used to transport the artificial aggregate to the silo and spread it;

[0013] The high chamber is provided with cavities connected end to end, and a humidity regulating device and a temperature regulating device are respectively installed on the high chamber.

[0014] The material turning device is located at the bottom of the high silo. The material turning device includes multiple material turning mechanisms, which are arranged sequentially along the material distribution direction at the bottom of the cavity. The material turning mechanisms are used to open and close the bottom of the cavity.

[0015] The lower bin is located below the tipping mechanism, and there is a certain distance between the top of the lower bin and the bottom of the upper bin;

[0016] The discharge device is located below the low bin and is used to output the artificial aggregate discharged from the low bin;

[0017] The control system is used to control the fabric feeding device, humidity regulating device, temperature regulating device, material turning mechanism, and material discharging device respectively.

[0018] Preferably, the fabric feeding device includes a track and an unloading trolley. The track is erected on the top of the silo, and the unloading trolley is installed on the track and can move on the track. A feeding belt is arranged on the track along the track direction, and a bracket is installed on the unloading trolley. The bracket and the unloading trolley are used to jointly support the feeding belt.

[0019] Preferably, the unloading trolley is equipped with a belt conveyor, which includes an unloading belt that is perpendicular to the guide rail. The belt conveyor can transport materials in both forward and reverse directions and is used to unload artificial aggregates to both sides of the track.

[0020] Preferably, an electric rotating disk is provided on the discharging trolley, and a discharging belt conveyor is installed on the electric rotating disk. The discharging belt conveyor can rotate with the electric rotating disk and is used to discharge artificial aggregate at any angle.

[0021] Preferably, the high silo is provided with a flat and long "return" - shaped cavity. A plurality of material turning mechanisms are arranged along the cavity in the length direction of the "return" shape. A guiding plate is arranged in the cavity in the width direction of the "return" shape on the high silo. The guiding plate is used to guide the artificial aggregate in the cavity in the width direction of the "return" shape into the cavity in the length direction of the "return" shape during material turning. The guiding plate is located in the middle in the height direction of the high silo.

[0022] Preferably, the track is installed on the top of the high silo along the length direction of the "return" shape in the high silo. An up - feeding belt is arranged along the track direction on the track. A support is installed on the discharging trolley. The support and the discharging trolley are used to jointly support the up - feeding belt.

[0023] Preferably, a baffle plate is arranged at the bottom of the high silo. The baffle plate is located above the gap between the turning plates of adjacent material turning mechanisms. When the baffle plate is closed, the baffle plate and the turning plate cooperate to block the artificial aggregate in the high silo.

[0024] Preferably, the humidity regulating device includes a water supply pipeline, a spray head and a humidity sensor. The spray head is located above the high silo. The spray head is connected to the water supply pipeline. The humidity sensor is used to detect the humidity in the high silo. A plurality of spray heads and humidity sensors are distributed in sections on the high silo. The humidity regulating device can regulate the humidity in sections respectively.

[0025] Preferably, the temperature regulating device includes a heating pipeline and a temperature sensor. The heating pipeline is arranged on the silo wall of the high silo. The temperature sensor is used to detect the temperature in the high silo. A plurality of heating pipelines and temperature sensors are distributed in sections on the high silo. The temperature regulating device can regulate the temperature in sections respectively.

[0026] Preferably, the material turning mechanism includes a turning plate, a first support rod, a second support rod, a third support rod and a telescopic rod. One end of the first support rod is fixedly connected to the turning plate, and the other end is hinged to the bottom of the high silo. The second support rod is hinged to the bottom of the high silo. The third support rod is hinged to the turning plate. The third support rod is hinged to the second support rod. The telescopic rod is respectively hinged to the high silo and the third support rod.

[0027] Preferably, a discharger is installed at the bottom of the low silo. The discharging device includes a discharging belt conveyor. The discharging belt of the discharging belt conveyor is located below the discharger.

[0028] Compared with the prior art, the utility model has the following technical effects:

[0029] 1. Continuous production: The feeding device and the discharging device work together to achieve continuous feeding and discharging in different sections of the high-bay.

[0030] 2. Controllable curing environment: Automated zone control is adopted to make the curing environment closer to the process requirements;

[0031] 3. Artificial aggregates are not prone to clumping and sticking: Equipped with a turning mechanism and an automated control system, the artificial aggregates are turned over in time before clumping. In addition, the downward rolling of the artificial aggregates during turning helps to minimize clumping while ensuring product quality.

[0032] 4. High space utilization: The two silos, one high and one low, reduce the area for artificial aggregate to be piled up and increase the stacking height, which greatly saves production land compared with existing technologies;

[0033] 5. Energy saving: The artificial aggregate moves from top to bottom, and gravity is well utilized in the feeding, discharging and turning processes;

[0034] 6. Environmental protection: The entire maintenance process is completed inside the equipment, and the humidity is controlled by spraying water, which avoids dust.

[0035] 7. Less breakage of artificial aggregates: During feeding, although the strength of artificial aggregates is very low, they basically do not fall directly, but slide down the slope of the pile. During the turning process, the artificial aggregates do not move violently, and the unloading is also a natural outflow. Therefore, there are basically no conditions for the artificial aggregates to break during the curing process. Attached Figure Description

[0036] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:

[0037] Figure 1 This is a schematic diagram of the structure of Example 1;

[0038] Figure 2 This is a schematic diagram of the fabric feeding device structure in Example 1;

[0039] Figure 3 This is a schematic diagram of the high-bay structure in Example 1;

[0040] Figure 4 This is a schematic diagram of the high-temperature humidity control device and temperature control device in Example 1;

[0041] Figure 5 This is a schematic diagram of the material turning mechanism in Example 1;

[0042] Figure 6 This is a schematic diagram of the open and closed states of the material turning mechanism in Example 1, where a represents the closed state and b represents the open state;

[0043] Figure 7 This is a schematic diagram of the structure of Example 2;

[0044] Figure 8 This is a schematic diagram of the fabric feeding device structure in Example 2;

[0045] Fabric feeding device 1, track 11, unloading trolley 12, support 13, feeding belt 14, unloading belt conveyor 15, electric rotary table 16, high bin 2, guide plate 21, baffle plate 22, water pipe 23, nozzle 24, heating pipe 25, turning device 3, turning plate 31, first support rod 32, second support rod 33, third support rod 34, telescopic rod 35, low bin 4, unloader 41, discharge device 5, discharge belt conveyor 51, discharge belt 52. Detailed Implementation

[0046] To make the above-mentioned objectives, features, and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings. Many specific details are set forth in the following description to provide a full understanding of this utility model; however, this utility model may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of this utility model. Therefore, this utility model is not limited to the specific embodiments disclosed below.

[0047] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that excludes other embodiments.

[0048] Example 1

[0049] like Figure 1-6 As shown, a continuous curing device includes a material feeding device 1, a high-level bin 2, a material turning device 3, a low-level bin 4, a material discharging device 5, and a control system. The material turning device 3 includes multiple material turning mechanisms arranged along the high-level bin 2. The control system includes a hydraulic control system and an electrical control system.

[0050] The cloth-feeding device 1 is located at the uppermost part of the equipment and has the function of loading artificial aggregates into the designated position. The cloth-feeding device 1 consists of a track 11, a discharging trolley 12, a support 13, a feeding belt 14, and a discharging belt conveyor 15. The discharging trolley 12 can move back and forth on the track 11. The discharging trolley 11 and the support 13 jointly support the feeding belt 14. A discharging belt conveyor 15 is installed in front of the discharging trolley 12. The discharging trolley 11 drags the discharging belt conveyor 15 to move together. By moving the discharging trolley 12 back and forth and rotating the discharging belt conveyor 15 forward and backward, cloth-feeding can be completed along both sides of the feeding belt 14. Specifically, the artificial aggregates are carried by the feeding belt 14, climb onto the discharging trolley 12, and then fall into the discharging belt conveyor 15. Under the drive of the discharging belt conveyor 15, the artificial aggregates are discharged to the left or right side of the track and finally fall into the designated position in the high bin. The discharging trolley 12 and the discharging belt conveyor 15 are respectively connected to the electric control system to control the movement of the discharging trolley 12 and the discharging direction of the discharging belt conveyor 15.

[0051] The high bin 2 is located below the cloth-feeding device 1. The high bin 2 is in the shape of a flat and long "return" shape, and a "return"-shaped cavity is formed inside it. The track 11 of the cloth-feeding device 1 is installed along the length direction of the "return"-shaped cavity. There are two identical cavities on both sides of the track 11. The cavities are open at the top and bottom. The bin wall of the high bin 2 is vertical, with feeding at the upper part and discharging at the lower part. The vertical bin wall can cause the artificial aggregates to fall from the high bin to the low bin during the turnover process, breaking up the slightly agglomerated artificial aggregates. A guiding plate 21 is arranged in the cavity in the width direction of the "return" shape. The guiding plate 21 is arranged in the middle in the height direction of the cavity, making the bottom of the cavity in the width direction of the "return" shape in an "A" shape. The two "feet" of the "A" shape are both connected to a small section of vertical bin wall. The small section of vertical bin wall is for the artificial aggregates to roll down along the top of the "A" shape and then fall downward in the vertical bin wall section during the turnover process, so as to break up the slightly agglomerated artificial aggregates. The guiding plate 21 is used to guide the artificial aggregates in the cavity in the width direction of the "return" shape into the cavity in the length direction of the "return" shape during the turnover process. At the bottom of the high bin 2, there is a "field"-shaped baffle 22 welded by angle steel. The baffle 22 is the gap between the turnover mechanisms 3. When the turnover plate is closed, the baffle 22 cooperates with the turnover mechanism 3 to block the artificial aggregates in the high bin.

[0052] A humidity adjustment device and a temperature adjustment device are provided on the high bin 2.

[0053] The humidity adjustment device includes a water supply pipeline 23, a nozzle 24, and a humidity sensor. The nozzle 24 is located above the high bin 2. The nozzle 24 is connected to the water supply pipeline 23. The humidity sensor is used to detect the humidity in the high bin. Multiple nozzles 24 and multiple humidity sensors are distributed in sections on the high bin 2. The multiple nozzles 24 and the multiple humidity sensors are respectively connected to the electric control system. The electric control system can freely open and close the nozzles according to the feedback of the humidity sensor, playing a role in controlling the humidity in the bin.

[0054] The temperature control device includes heating pipes 25 and temperature sensors. Heating pipes 25 are installed on the wall of the elevated chamber 2. The temperature sensors detect the temperature inside the elevated chamber. Heating pipes 25 can flow with appropriate amounts of hot water or steam, or other high-temperature media, to transfer heat to the elevated chamber as needed. Multiple heating pipes 25 and multiple temperature sensors are distributed in sections on the elevated chamber. These multiple heating pipes 25 and multiple temperature sensors are connected to an electrical control system. The electrical control system can control the temperature inside the chamber by controlling the flow rate of hot water or steam in each section of the heating pipes 25 based on feedback from the temperature sensors.

[0055] The tipping mechanism 3 includes a tipping plate 31, a first support rod 32, a second support rod 33, a third support rod 34, and a telescopic rod 35. One end of the first support rod 32 is fixedly connected to the tipping plate 31, and the other end is hinged to the bottom of the hopper 2. The second support rod 32 is hinged to the bottom of the hopper 2, the third support rod 34 is hinged to the tipping plate 31, and the third support rod 34 is hinged to the second support rod 33. The telescopic rod 35 is hinged to both the hopper 2 and the third support rod 34. In this embodiment, the telescopic rod 35 is a hydraulic rod, which is connected to a hydraulic control system to control the opening and closing of the tipping plate 31.

[0056] The low bin 4 is located below the bottom of the high bin 2, with a distance of 0.5-1m between them. A discharge device 41 is installed at the bottom of the low bin 4. The discharge device 41 is connected to the electrical control system to control its opening and closing. The discharge device 5 includes a discharge belt conveyor 51, with its discharge belt 52 located below the discharge device 41, used to output the artificial aggregate unloaded from the low bin when the discharge device 41 is opened. Malfunctions in the flip-plate mechanism and discharge valve can be manually operated or repaired while waiting for material. The equipment structure is simple and intuitive, faults are easy to diagnose, and maintenance is simple.

[0057] A maintenance method for a continuous maintenance device includes the following steps:

[0058] S1 During the initial placement of materials, artificial aggregates are naturally stacked to a predetermined height at the top of the silo at the starting position, forming an inclined stacking surface;

[0059] S2 then controls the material distribution trolley to move forward while distributing material. The artificial aggregate at the bottom of the high silo is dropped from the material distribution trolley onto the top of the original pile and then rolls down to the bottom of the high silo. The time it takes for the material distribution device to fill the high silo is longer than the curing time of the artificial aggregate. The artificial aggregate piles in the high silo are not connected end to end.

[0060] The S3 control system controls the humidity and temperature control devices to adjust the temperature and humidity in the high chamber to the preset values, and performs initial curing for 6-12 hours.

[0061] S4 After the initial curing is completed, the control system controls the flip-top mechanism to open, and the artificial aggregate falls from the high silo into the low silo and is cured in the low silo for a period of time.

[0062] After the curing process is completed, the artificial aggregate is unloaded by the unloader to the discharge device, and then the artificial aggregate is output by the discharge device.

[0063] In the initial state of the equipment, all the tilting mechanisms have their tilting plates in a horizontal position, and all the unloaders in the lower compartments are in a closed position.

[0064] Example 2

[0065] The material placing device 1 is located at the top of the equipment and has the function of loading artificial aggregate into designated positions. The material placing device 1 consists of a track 11, a discharge trolley 12, a support 13, a feeding belt 14, a rotary table 16, and a discharge belt conveyor 15. The discharge trolley 12 can move back and forth on the track 11, and the discharge trolley 11 and the support 13 together support the feeding belt 14. The rotary table 16 is mounted on the discharge trolley 11, and the discharge belt conveyor 15 is mounted on the rotary table 16. The discharge trolley 12 can drag the electric rotary table 16 and the discharge belt conveyor 15 together. By moving the discharge trolley 12 back and forth, the electric rotary table can drive the discharge belt conveyor 15 to rotate on the discharge trolley, so that the discharge belt conveyor 15 can discharge material in front of and to the left and right sides of the discharge trolley 12. Specifically, the artificial aggregate is driven by the feeding belt 14, climbs onto the unloading trolley 12, and then falls into the unloading belt conveyor 15. Driven by the unloading belt conveyor 15, it finally falls into the designated position in the high bin. The unloading trolley 12, the electric rotary table, and the unloading belt conveyor 15 are all connected to the electrical control system to control the movement of the unloading trolley 12 and the unloading direction of the unloading belt conveyor 15.

[0066] The rest is the same as in Example 1.

[0067] Continuous feeding function: Artificial aggregate enters the feeding belt of the feeding device, moves with the belt, then climbs onto the unloading trolley and falls into the unloading conveyor. Because the unloading trolley can move on a track, and the unloading belt can rotate under the drive of a rotary disc, the unloading point can be adjusted arbitrarily as needed, allowing unloading from the left, right, front, and other angles of the feeding device. Feeding can begin at any position in the silo. Once the artificial aggregate reaches the designated height, the unloading trolley is started, continuously unloading the aggregate into the silo along the trolley's forward direction. After falling in, the aggregate rolls downwards along the pile's inclination, with new material covering the old, forming a new sloping surface. By adjusting the unloading trolley's speed to match the amount of artificial aggregate entering the silo, the aggregate forms a continuous pile of uniform height within the silo.

[0068] When the unloading trolley moves to the end of one side of the high bin, the artificial aggregate will roll along the guide plate to the left (right) side of the high bin and then fall into the other side of the high bin. At this time, stop the unloading trolley and continue unloading. Adjust the unloading direction in time according to the height of the artificial aggregate pile so that the unloading point transitions to the other side of the high bin. After a new pile is formed in the high bin on that side and the height meets the requirements, start the unloading trolley to move backward until it reaches the other end of the high bin. Repeat the previous action to complete the continuous unloading of artificial aggregate along the "U"-shaped high bin, forming a continuous feeding process.

[0069] Time-controlled material turning function: When the artificial aggregate that has fallen into the high bin has been in place for 6-12 hours, the flap below the corresponding pile slope is opened, allowing the artificial aggregate to slide down the slope into the low bin, with the flap remaining open. At this time, the unloading point of the material distribution device is still behind the flap opening position, and the bottom of the unloading slope formed is still a certain distance from the flap opening position, ensuring that new material does not fall into the lower bin and is not mixed with the artificial aggregate in front. Since the artificial aggregate in the high bin falls sequentially, the sequence in which it reaches 6-12 hours is also consistent with the unloading sequence. By continuously opening the flap at the bottom of the high bin sequentially, it can be ensured that the artificial aggregate is turned over once after resting for 6-12 hours, forming continuous turning.

[0070] Continuous unloading function: After the artificial aggregate falling into the lower bin reaches the required curing time according to the falling time, the unloading valve at the bottom of the lower bin is opened, allowing the artificial aggregate to fall into the discharge conveyor belt. The artificial aggregate then enters the subsequent process with the discharge conveyor belt, completing the discharge. Subsequently, the unloading valve and the corresponding upper flap are closed, and the equipment continues to wait for new material to enter.

[0071] It is important to emphasize that the three actions of placing, turning, and unloading materials at any location within the bin are performed sequentially. All three actions are carried out in the same direction of rotation along the U-shaped bin. For example, placing materials is done clockwise along the U-shaped bin, turning is also done by sequentially activating the flip plates clockwise, and unloading is done by sequentially opening the unloading gate clockwise. Furthermore, it is ensured that the equipment returns to its initial state after unloading is complete.

[0072] Personalized Curing Function: The continuous curing equipment allows for temperature and humidity adjustments based on the curing process and technological requirements. It uses temperature and humidity sensors to measure the temperature and humidity of the curing environment in real time, feeding the data back to the control system to initiate actions such as water spraying and adjusting the flow rate of the heating pipeline. The equipment is equipped with multiple temperature and humidity sensors and nozzles and heating pipelines at various locations, enabling zoned temperature and humidity control. Furthermore, the timing of the artificial aggregate's entry into the equipment, as well as the turning and discharge times, can be preset to ensure optimal curing results. This design fully meets the varying temperature and humidity requirements at different stages of the artificial aggregate curing process, satisfying the diverse temperature, humidity, and time requirements for different types of artificial aggregate.

[0073] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.

Claims

1. A continuous curing device, characterized in that, Includes a material feeding device, a high-level bin, a material turning device, a low-level bin, a material discharge device, and a control system. The fabric spreading device is used to transport the artificial aggregate to the silo and spread it; The high chamber is provided with cavities connected end to end, and a humidity regulating device and a temperature regulating device are respectively installed on the high chamber. The material turning device is located at the bottom of the high silo. The material turning device includes multiple material turning mechanisms, which are arranged sequentially along the material distribution direction at the bottom of the cavity. The material turning mechanisms are used to open and close the bottom of the cavity. The lower bin is located below the tipping mechanism, and there is a certain distance between the top of the lower bin and the bottom of the upper bin; The discharge device is located below the low bin and is used to output the artificial aggregate discharged from the low bin; The control system is used to control the fabric feeding device, humidity regulating device, temperature regulating device, material turning mechanism, and material discharging device respectively.

2. The continuous curing equipment according to claim 1, characterized in that, The material feeding device includes a track and an unloading trolley. The track is erected on the top of the silo, and the unloading trolley is installed on the track and can move on the track. A feeding belt is arranged along the track direction. A bracket is installed on the unloading trolley. The bracket and the unloading trolley are used to jointly support the feeding belt.

3. The continuous maintenance equipment according to claim 2, characterized in that, The unloading trolley is equipped with a belt conveyor, which includes an unloading belt that is perpendicular to the guide rail. The belt conveyor can transport materials in both forward and reverse directions and is used to unload artificial aggregates to both sides of the track.

4. The continuous maintenance equipment according to claim 2, characterized in that, The unloading trolley is equipped with an electric rotary table, and an unloading belt conveyor is installed on the electric rotary table. The unloading belt conveyor can rotate with the electric rotary table and is used to unload artificial aggregates at any angle.

5. The continuous curing equipment according to claim 1, characterized in that, The silo is equipped with a flat, elongated "U"-shaped cavity. Multiple material turning mechanisms are arranged along the length of the "U"-shaped cavity. A guide plate is installed in the "U"-shaped cavity in the width direction of the silo. The guide plate is used to guide the artificial aggregate in the "U"-shaped cavity in the width direction to the "U"-shaped cavity in the length direction of the silo during material turning. The guide plate is located in the middle of the height direction of the silo.

6. The continuous curing equipment according to claim 5, characterized in that, The bottom of the silo is equipped with a baffle plate, which is located above the gap between the flip plates of the adjacent flipping mechanism. When the baffle plate is closed, it cooperates with the flip plate to block the artificial aggregate in the silo.

7. The continuous maintenance equipment according to claim 1, characterized in that, The humidity control device includes a water supply pipeline, a nozzle, and a humidity sensor. The nozzle is located above the caisson and is connected to the water supply pipeline. The humidity sensor is used to detect the humidity inside the caisson. Multiple nozzles and humidity sensors are distributed in sections on the caisson, and the humidity control device can adjust the humidity in each section separately.

8. The continuous maintenance equipment according to claim 1, characterized in that, The temperature regulation device includes heating pipes and temperature sensors. The heating pipes are installed on the walls of the high-rise warehouse, and the temperature sensors are used to detect the temperature inside the high-rise warehouse. Multiple heating pipes and temperature sensors are distributed in sections on the high-rise warehouse, and the temperature regulation device can adjust the temperature of each section separately.

9. The continuous maintenance equipment according to claim 1, characterized in that, The material turning mechanism includes a flip plate, a first support rod, a second support rod, a third support rod, and a telescopic rod. One end of the first support rod is fixedly connected to the flip plate, and the other end is hinged to the bottom of the silo. The second support rod is hinged to the bottom of the silo. The third support rod is hinged to the flip plate and the second support rod. The telescopic rod is hinged to the silo and the third support rod, respectively.

10. The continuous maintenance equipment according to claim 1, characterized in that, The bottom of the low silo is equipped with a discharge device, and the discharge device includes a discharge belt conveyor, the discharge belt of which is located below the discharge device.

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