CN209820091U - Microbial organic fertilizer's dewatering equipment - Google Patents

Abstract

The utility model discloses a microbial organic fertilizer's dewatering equipment can guarantee that the temperature is appropriate, can guarantee again that moisture evenly gets rid of. Firstly, materials enter through a first feeding hole and are transported through a conveyor belt, and due to the fact that the distance between the materials and the conveyor belt is reduced and the limiting effect of a guide plate, moisture in the materials is extruded out through a water outlet and falls into a water collecting tank; the conveying belt is conveyed to the conveying opening, and the pressing plate is positioned above the conveying opening at the moment; secondly, when all the materials in the first dewatering box fall into the second dewatering box, starting a motor, enabling a forward rotation pressing plate of the motor to move downwards along the threads on the rotating shaft, enabling the pressing plate and a supporting plate to be matched for extruding the materials, enabling water to fall into a circular groove at the bottom through a water permeable hole, and taking out the materials from a discharge hole; and finally, the motor reverse rotation pressing plate moves upwards along the threads on the rotating shaft to the position above the conveying port to wait for the next batch of materials to enter.

Description

Microbial organic fertilizer's dewatering equipment

Technical Field

The utility model relates to a production facility technical field, more specifically the dewatering equipment who relates to a microbial organic fertilizer that says so.

Background

At present, beneficial microorganisms in the bio-organic fertilizer enter soil and then form a symbiotic proliferation relationship with microorganisms in the soil, harmful bacteria are inhibited from growing and are converted into beneficial bacteria, the beneficial bacteria interact and mutually promote to play a group synergistic effect, the beneficial bacteria generate a large amount of metabolites in the growth and reproduction process to promote the decomposition and conversion of organic matters, and can directly or indirectly provide various nutrients and irritant substances for crops to promote and regulate the growth of the crops. Improving the porosity, permeability and exchangeability of soil and the survival rate of plants, and increasing beneficial bacteria, soil microorganisms and populations. Meanwhile, the dominant beneficial flora formed on the root system of the crop can inhibit the propagation of harmful pathogenic bacteria, enhance the stress resistance and disease resistance of the crop, reduce the disease index of the continuous cropping crop, and greatly relieve continuous cropping obstacles after continuous application. Reducing environmental pollution, being safe and nontoxic to human, livestock and environment and being an environment-friendly fertilizer.

However, the existing low-temperature microbial organic fertilizer dehydration equipment has some defects in the use process, firstly, the temperature of the microbial organic fertilizer which is required to be processed at low temperature is difficult to control, so that the moisture of the microbial organic fertilizer is difficult to remove, secondly, the moisture of the existing microbial organic fertilizer is difficult to remove uniformly, the microbial organic fertilizer cannot be uniformly distributed, and the moisture removal efficiency of the microbial organic fertilizer is low.

Therefore, how to provide a dewatering device which can ensure proper temperature and uniform water removal is a problem that needs to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a microbial organic fertilizer's dewatering equipment can guarantee that the temperature is suitable, can guarantee again that moisture evenly gets rid of, guarantees the inside temperature of dewatering device through the heat preservation, and the moisture through first dewatering box and the twice dehydration of second dewatering box is handled and is guaranteed microbial organic fertilizer and get rid of.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a microbial organic fertilizer's dewatering equipment includes: a first dewatering box and a second dewatering box; a first feed inlet is formed in one side of the first dewatering box; the other side plate of the first dewatering box is fixedly connected with one side of the second dewatering box, and a conveying port is formed in the connecting position of the first dewatering box and the second dewatering box; a conveyor belt is arranged in the first dewatering box; a first dewatering device is arranged at one end of the conveying belt close to the conveying opening; a second dewatering device is arranged in the second dewatering box; and a discharge hole is formed in the bottom of the second dehydration device.

Through foretell technical scheme, the utility model discloses a technological effect lies in: materials enter through the first feeding hole and are conveyed through the conveyor belt under the action of the conveyor belt and the first dehydration device, so that primary dehydration is realized; and the sewage enters a second dewatering box through a conveying port to be dewatered uniformly.

Preferably, in the above dewatering equipment for microbial organic fertilizer, the first dewatering device includes: the device comprises an extrusion belt, an upper supporting roller, a lower supporting roller, an upper supporting belt and a lower supporting belt;

the conveyer belt is close to the one end top installation extrusion area of transfer port, install the backing roll on the inboard first dewatering box inner wall in extrusion area, cup joint the backing roll on going up the backing roll, it is inboard to go up the backing roll in the in close contact with extrusion area, install backing roll down on the inboard first dewatering box inner wall of conveyer belt, cup joint the lower support area on the backing roll down, the lower support area in close contact with conveyer belt is inboard.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the distance between the extrusion belt and the conveyor belt plays a role of extrusion as the conveyor belt is smaller and smaller.

Preferably, in the above dewatering equipment for microbial organic fertilizer, two guide plates are fixedly installed on the inner wall of the first dewatering box, the guide plates are in close contact with two sides of the conveyor belt, and the guide plates are provided with water outlets.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the deflector that the conveyer belt both sides set up in the data send process restricts the trend of material to water in with the material is got rid of through the apopore on the deflector.

Preferably, in the above dewatering equipment for microbial organic fertilizer, scrapers are mounted on the upper and lower inner walls of the conveying opening in the first dewatering box, and the scrapers are in close contact with the surfaces of the conveying belt and the extrusion belt.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the setting of scraper blade prevents to glue the material that glues on conveyer belt or extrusion area and falls into the bottom, causes the waste, influences the collection of getting rid of moisture.

Preferably, in the above dewatering equipment for microbial organic fertilizer, the water collecting tank is fixedly installed at the bottom of the first dewatering tank.

Through foretell technical scheme, the utility model discloses a technological effect lies in: and collecting the water passing through the water outlet on the guide plate.

Preferably, in the above apparatus for dehydrating microbial organic fertilizer, the second dehydration tank includes: the device comprises a pressing plate, a supporting plate, a rotating shaft and a motor; the second dewatering box is cylindrical, and internal threads are arranged on the inner wall of the second dewatering box; the rotating shaft is provided with an external thread; a through hole is formed in the center of the pressing plate; the through hole is provided with internal threads; the internal thread of the through hole is matched with the external thread of the rotating shaft; the periphery of the pressing plate is matched with the internal threads of the second dewatering box; the supporting plate is arranged at the bottom of the second dewatering box, and a bearing seat is arranged in the center of the supporting plate; the supporting plate is matched with the pressing plate; the supporting plate is provided with water permeable holes; one end of the rotating shaft is fixedly connected with an output shaft of the motor; and the other end is provided with a bearing, and the bearing is matched with the bearing seat.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the motor can carry out reversal and corotation, and the motor rotates and drives the pivot rotation, can reciprocate along the pivot in the second dewatering box with pivot threaded connection's clamp plate, and the clamp plate is evenly got rid of moisture with the layer board cooperation. Wherein evenly get rid of and reflect in, the clamp plate gets rid of moisture to all materials in the second dewatering box, and the stress that the whole action made the material is impartial to realize evenly getting rid of.

Preferably, in the above dewatering equipment for microbial organic fertilizer, a circular groove is formed on the inner wall of the bottom corresponding to the water permeable hole.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the water flowing out of the water permeable holes is divided into the circular grooves.

Preferably, in the above dewatering equipment for microbial organic fertilizer, the water permeable holes are covered with a filter screen.

Through foretell technical scheme, the utility model discloses a technological effect lies in: prevent the material with the water permeable holes from being extruded out.

Preferably, in the above dewatering equipment for microbial organic fertilizer, heat insulating layers are arranged inside the first dewatering box and the second dewatering box.

Through foretell technical scheme, the utility model discloses a technological effect lies in: the temperature of the dehydration equipment is ensured to be proper.

According to the technical scheme, compare with prior art, the utility model discloses a microbial organic fertilizer's dewatering equipment can guarantee that the temperature is appropriate, can guarantee again that moisture evenly gets rid of, guarantees the inside temperature of dewatering device through the heat preservation, and the moisture through first dewatering box and the twice dehydration of second dewatering box is handled and is guaranteed microbial organic fertilizer and get rid of. Firstly, materials enter through a first feeding hole and are transported through a conveyor belt, and under the action of the conveyor belt and an extrusion belt, due to the fact that the distance between the conveyor belt and the extrusion belt is small and the limiting effect of a guide plate, moisture in the materials is extruded out through a water outlet and falls into a water collecting tank; the conveying belt is conveyed to the conveying opening, and the pressing plate is positioned above the conveying opening at the moment; secondly, when all the materials in the first dewatering box fall into the second dewatering box, starting a motor, enabling a forward rotation pressing plate of the motor to move downwards along the threads on the rotating shaft, enabling the pressing plate and a supporting plate to be matched for extruding the materials, enabling water to fall into a circular groove at the bottom through a water permeable hole, and taking out the materials from a discharge hole; and finally, the motor reverse rotation pressing plate moves upwards along the threads on the rotating shaft to the position above the conveying port to wait for the next batch of materials to enter.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a first view illustrating a first usage state of the present invention;

fig. 2 is a diagram illustrating a second usage state of the present invention.

In the figure: 1 first dewatering box, 11 first feeding hole, 12 conveying hole, 13 conveying belt, 141 squeezing belt, 142 upper supporting roller, 143 upper supporting belt, 144 lower supporting belt, 145 lower supporting roller, 15 scraping plate, 16 water collecting box, 2 second dewatering box, 21 pressing plate, 22 supporting plate, 23 rotating shaft, 24 motor and 25 discharging hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment of the utility model discloses microbial organic fertilizer's dewatering equipment can guarantee that the temperature is appropriate, can guarantee again that moisture evenly gets rid of, guarantees the inside temperature of dewatering device through the heat preservation, and the moisture through first dewatering box and the twice dehydration of second dewatering box guarantees microbial organic fertilizer gets rid of.

A microbial organic fertilizer's dewatering equipment includes: a first dewatering box 1 and a second dewatering box 2; a first feed inlet 11 is formed in one side of the first dewatering box 1; the other side plate of the first dewatering box 1 is fixedly connected with one side of the second dewatering box 2, and a conveying port 12 is formed at the joint of the first dewatering box 1 and the second dewatering box 2; a conveyor belt 13 is arranged in the first dewatering box 1; a first dewatering device is arranged at one end of the conveyor belt 13 close to the conveying opening 12; a second dewatering device is arranged in the second dewatering box 2; the bottom of the second dewatering device is provided with a discharge hole.

In order to further optimize the above technical solution, the first dehydration apparatus includes: a pressing belt 141, an upper support roller 142, a lower support roller 145, an upper support belt 143, and a lower support belt 144; an extrusion belt 141 is installed above one end of the conveyor belt 13 close to the conveying opening 12, an upper supporting roller 142 is installed on the inner wall of the first dewatering box 1 on the inner side of the extrusion belt 141, an upper supporting belt 143 is sleeved on the upper supporting roller 142, the upper supporting belt 143 is in close contact with the inner side of the extrusion belt 141, a lower supporting roller 145 is installed on the inner wall of the first dewatering box 1 on the inner side of the conveyor belt 13, a lower supporting belt 144 is sleeved on the lower supporting roller 145, and the lower supporting belt 144 is in close contact with the inner side of the.

In order to further optimize the technical scheme, two guide plates are fixedly arranged on the inner wall of the first dewatering box 1, the guide plates are tightly contacted with the two sides of the conveyor belt 13, and water outlets are formed in the guide plates.

In order to further optimize the technical scheme, scrapers 15 are arranged on the upper inner wall and the lower inner wall of the conveying opening 12 in the first dewatering box 1, and the scrapers 15 are tightly contacted with the surfaces of the conveying belt 13 and the pressing belt 141.

In order to further optimize the above technical solution, the water collection tank 16 is fixedly installed at the bottom of the first dewatering tank 1.

In order to further optimize the above solution, the second dewatering box 2 comprises: a pressure plate 21, a supporting plate 22, a rotating shaft 23 and a motor 24; the second dewatering box 2 is cylindrical, and internal threads are arranged on the inner wall of the second dewatering box 2; the rotating shaft 23 is provided with an external thread; a through hole is formed in the center of the pressing plate 21; the through hole is provided with internal threads; the internal thread of the through hole is matched with the external thread of the rotating shaft 23; the periphery of the pressing plate 21 is matched with the internal thread of the second dewatering box 2; the supporting plate 22 is arranged at the bottom of the second dewatering box 2 and a bearing seat is arranged in the center; the supporting plate 22 is matched with the pressing plate 21; the supporting plate 22 is provided with water permeable holes; one end of the rotating shaft 23 is fixedly connected with an output shaft of the motor 24; the other end is provided with a bearing which is matched with the bearing seat.

In order to further optimize the technical scheme, a circular groove is formed in the inner wall of the bottom corresponding to the water permeable hole.

In order to further optimize the technical scheme, the water permeable holes are covered with filter screens.

In order to further optimize the technical scheme, the first dewatering box 1 and the second dewatering box 2 are internally provided with heat insulation layers.

The working process is as follows: firstly, the material gets into through first feed inlet 11, transports through conveyer belt 13, under conveyer belt 13 and extrusion band 141's effect, because the two interval diminishes, the restriction of deflector simultaneously extrudes the moisture in the material through the delivery port, falls into header tank 16: the conveyor belt 13 is transported to the delivery port 12 with the platen 21 above the delivery port 12, as shown in fig. 1; secondly, when all the materials in the first dewatering box 1 fall into the second dewatering box 2, the motor 24 is started, the motor 24 rotates forward, the pressing plate 21 moves downwards along the threads on the rotating shaft 23, the pressing plate 21 is matched with the supporting plate 22 to extrude the materials, as shown in figure 2, moisture falls into a circular groove at the bottom through a water permeable hole, and the materials are taken out from a discharge hole 25; finally, the motor 24 reverses the rotation of the platen 21 and moves it up along the threads on the shaft 23 and over the delivery port 12, as shown in FIG. 1, awaiting the entry of the next batch of material.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. The utility model provides a microbial organic fertilizer's dewatering equipment which characterized in that includes: a first dewatering box and a second dewatering box; a first feed inlet is formed in one side of the first dewatering box; the other side plate of the first dewatering box is fixedly connected with one side of the second dewatering box, and a conveying port is formed in the connecting position of the first dewatering box and the second dewatering box; a conveyor belt is arranged in the first dewatering box; a first dewatering device is arranged at one end of the conveying belt close to the conveying opening; a second dewatering device is arranged in the second dewatering box; and a discharge hole is formed in the bottom of the second dehydration device.

2. The microbial organic fertilizer dehydration equipment of claim 1, wherein said first dehydration device comprises: the device comprises an extrusion belt, an upper supporting roller, a lower supporting roller, an upper supporting belt and a lower supporting belt; the conveyer belt is close to the one end top installation extrusion area of transfer port, install the backing roll on the inboard first dewatering box inner wall in extrusion area, cup joint the backing roll on going up the backing roll, it is inboard to go up the backing roll in the in close contact with extrusion area, install backing roll down on the inboard first dewatering box inner wall of conveyer belt, cup joint the lower support area on the backing roll down, the lower support area in close contact with conveyer belt is inboard.

3. The microbial organic fertilizer dewatering equipment as claimed in claim 2, wherein two guide plates are fixedly mounted on the inner wall of the first dewatering box, the guide plates are in close contact with two sides of the conveyor belt, and water outlets are formed in the guide plates

4. The microbial organic fertilizer dewatering equipment as claimed in claim 2, wherein scrapers are mounted on the upper and lower inner walls of the conveying opening in the first dewatering box, and the scrapers are in close contact with the surfaces of the conveying belt and the pressing belt.

5. The microbial organic fertilizer dewatering equipment as claimed in claim 2, wherein a water collecting tank is fixedly mounted at the bottom of the first dewatering tank.

6. The microbial organic fertilizer dehydration apparatus of claim 1, wherein said second dehydration tank comprises: the device comprises a pressing plate, a supporting plate, a rotating shaft and a motor; the second dewatering box is cylindrical, and internal threads are arranged on the inner wall of the second dewatering box; the rotating shaft is provided with an external thread; a through hole is formed in the center of the pressing plate; the through hole is provided with internal threads; the internal thread of the through hole is matched with the external thread of the rotating shaft; the periphery of the pressing plate is matched with the internal threads of the second dewatering box; the supporting plate is arranged at the bottom of the second dewatering box, and a bearing seat is arranged in the center of the supporting plate; the supporting plate is matched with the pressing plate; the supporting plate is provided with water permeable holes; one end of the rotating shaft is fixedly connected with an output shaft of the motor; and the other end is provided with a bearing, and the bearing is matched with the bearing seat.

7. The microbial organic fertilizer dewatering equipment as claimed in claim 6, wherein the inner walls of the bottoms of the water permeable holes are provided with circular grooves.

8. The microbial organic fertilizer dewatering equipment of claim 6, wherein the water permeable holes are covered with a filter screen.

9. The microbial organic fertilizer dewatering equipment according to any one of claims 1-8, wherein an insulating layer is arranged inside the first dewatering box and the second dewatering box.