CN222906447U - Novel corrosion-resistant glass fiber reinforced plastic tank body - Google Patents

Abstract

The utility model relates to the technical field of glass fiber reinforced plastic tank bodies, in particular to a novel corrosion-resistant glass fiber reinforced plastic tank body. The technical scheme includes that a feeding pipe is arranged at the top end of a tank body, a discharging pipe is arranged at one side end face of the tank body, a liquid outlet pipe is arranged at one end of the tank body, which is away from the discharging pipe, a partition plate is arranged in the tank body, the tank body is divided into a liquid cavity and a solid cavity through the partition plate, the discharging pipe and the liquid outlet pipe are respectively communicated with the solid cavity and the liquid cavity, a sieve plate is arranged on the partition plate, the sieve plate is obliquely erected above the partition plate, an overhaul port is arranged at the bottom end of the tank body, a manhole is formed in one side of the top end of the tank body, and support steel rings are arranged in the tank body, which are close to two ends. The utility model improves the durability of the tank body, enhances the solid-liquid separation efficiency and the structural stability of the tank body, and is suitable for sewage treatment and waste treatment systems with various complex working conditions.

Description

Novel corrosion-resistant glass fiber reinforced plastic tank body

Technical Field

The utility model relates to the technical field of glass fiber reinforced plastic tank bodies, in particular to a novel corrosion-resistant glass fiber reinforced plastic tank body.

Background

By a fecal sewage tank is meant a container for collecting and disposing of human or animal excreta, particularly where there is no sewer system or sewage disposal facility. Such devices are commonly used in rural areas, open-air toilets, camps, and in some special environments. A glass fiber reinforced plastic fecal sewage tank is a common fecal sewage treatment device commonly used for collecting and storing fecal sewage. The material of manufacture of such cans is Fiberglass Reinforced Plastic (FRP), also known as fiberglass. The glass fiber reinforced plastic has the advantages of corrosion resistance, good weather resistance, light weight, high strength and the like, so that the glass fiber reinforced plastic is widely applied to the field of fecal sewage treatment. However, the existing technology of the fecal sewage glass fiber reinforced plastic tank body in the market has the defects of insufficient rigidity, easy deformation and no solid-liquid separation function, so that the solid and the liquid are easy to mix in the discharging process, and the treatment effect is affected.

Disclosure of utility model

The utility model provides a novel corrosion-resistant glass fiber reinforced plastic tank body, which solves the technical problems.

The scheme for solving the technical problems is as follows:

The utility model provides a novel corrosion-resistant glass steel jar body, includes jar body, sieve, baffle and access hole, the top of the jar body is equipped with the inlet pipe, one side terminal surface of the jar body is equipped with the discharging pipe, the one end that the jar body deviates from the discharging pipe is equipped with the drain pipe, the inside of the jar body is equipped with the baffle, the inside of the jar body is separated for liquid chamber and solid chamber through the baffle, just discharging pipe and drain pipe communicate with solid chamber and liquid chamber respectively, be equipped with the sieve on the baffle, just the sieve slope is erect in the top of baffle, the bottom of the jar body is equipped with the access hole, the manhole has been seted up to one side that the top of the jar body is located the inlet pipe, the inside of the jar body is close to both ends department and is equipped with the support steel ring.

On the basis of the technical scheme, the utility model can be improved as follows.

Further, the lower end of the sieve plate faces the solid cavity.

The beneficial effects of adopting the further scheme are as follows:

The inclined design of the sieve plate enables solid materials to naturally slide downwards under the action of gravity and enter the solid cavity, so that the solid materials piled on the sieve plate are reduced, and the risk of blockage is reduced. The natural material separation mode does not need additional power driving or mechanical operation, and saves energy and maintenance cost.

Further, a flexible sheet is arranged at the joint of the sieve plate and the partition plate, and the flexible sheet is positioned in the solid cavity.

The beneficial effects of adopting the further scheme are as follows:

The flexible sheet is positioned in the solid cavity, when the solid materials are accumulated excessively, the dead weight can bend the flexible sheet, so that the materials slide into the solid cavity, and the solid-liquid separation effect is further improved. The design prevents solid materials from accumulating at the joint of the sieve plate and the partition plate, reduces the risk of blockage and ensures continuous and efficient operation of equipment.

Further, the discharging pipe and the liquid outlet pipe are symmetrically distributed on two sides of the tank body.

The beneficial effects of adopting the further scheme are as follows:

The discharging pipe and the liquid outlet pipe are symmetrically distributed, so that solids and liquid can be discharged simultaneously and independently, material flow can be effectively dispersed, the risk of pipeline blockage is reduced, waiting time in the discharging process is shortened, the overall discharging efficiency is improved, and continuous and stable operation of the system is ensured.

Further, the access opening corresponds in position to the solid cavity and the liquid cavity.

The beneficial effects of adopting the further scheme are as follows:

So that operators can directly enter the solid cavity and the liquid cavity through the access opening to carry out cleaning and maintenance work. Thus, accumulated solid materials and deposited liquid residues can be rapidly removed, and the cleaning and normal operation of the inside of the tank body are ensured. The solid cavity and the liquid cavity are cleaned regularly through the access hole, so that the separation effect of the solid-liquid separation system can be prevented from being influenced due to blockage or excessive sediment, and the efficient operation of equipment is ensured.

The beneficial effects of the utility model are as follows:

The liquid cavity and the solid cavity are separated by the partition plate in the tank body, and the partition plate also plays a role in supporting the tank body structure. The baffle and the supporting steel ring strengthen the overall rigidity of the tank body, reduce the deformation risk of the tank body in the transportation and use processes, and also help to maintain the structural stability of the inside of the tank body and ensure the safety and reliability in the operation process.

The baffle in the jar body not only is used for supporting jar body structure, can also realize solid-liquid separation function effectively. The inclined sieve plate is arranged on the partition plate, so that solids naturally slide down to the solid cavity under the action of gravity, and liquid can enter the liquid cavity through holes on the sieve plate. The discharging pipe and the liquid outlet pipe are respectively positioned at the solid cavity and the liquid cavity, so that the separated solid and liquid can be conveniently and efficiently discharged and treated. Meanwhile, the flexible thin plate is arranged at the joint of the sieve plate and the partition plate, when solid materials are excessively accumulated on the flexible thin plate, the self weight of the flexible thin plate bends the flexible thin plate, so that the accumulated materials automatically fall into the solid cavity, and the design simplifies the operation and maintenance processes and improves the convenience and efficiency of operation.

The maintenance convenience and the operation efficiency of the equipment are improved, and the safety and the reliability of the equipment are enhanced due to the design that the positions of the access holes are corresponding to the solid cavity and the liquid cavity, so that the stable operation and the long-term use of the system are ensured.

The foregoing description is only an overview of the present utility model, and is intended to provide a better understanding of the present utility model, as it is embodied in the following description, with reference to the preferred embodiments of the present utility model and the accompanying drawings. Specific embodiments of the present utility model are given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model.

In the drawings:

FIG. 1 is a schematic view of the axial side appearance of the present utility model;

FIG. 2 is a schematic axial side cross-sectional view of the present utility model;

Fig. 3 is a schematic view of the axial side of the screen deck of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. A tank body; 2, a feed pipe, 3, a discharge pipe, 4, a liquid cavity, 5, a sieve plate, 6, a flexible thin plate, 7, a solid cavity, 8, a baffle plate, 9, a liquid outlet pipe, 10, an overhaul port, 11, a manhole, 12 and a supporting steel ring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 to 3, an embodiment of the present utility model is as follows:

Example 1

The utility model provides a novel corrosion-resistant glass steel jar body, including jar body 1, sieve 5, baffle 8 and access hole 10, the top of jar body 1 is equipped with inlet pipe 2, one side terminal surface of jar body 1 is equipped with discharging pipe 3, discharging pipe 3 and drain pipe 9 are at the both sides symmetric distribution of jar body 1, discharging pipe 3 and drain pipe 9 symmetric distribution make solid and liquid can simultaneously, independently discharge, can effectively disperse the material flow, reduce the risk of pipeline jam, and latency in the emission process has been reduced, whole emission efficiency has been improved, guarantee the continuous and the steady operation of system, jar body 1 deviates from the one end of discharging pipe 3 and is equipped with drain pipe 9, manhole 11 has been seted up on one side of inlet pipe 2 to the top of jar body 1, the inside condition of jar body 1 is observed to user's accessible manhole 11, the inside of jar body 1 is close to both ends department and is equipped with support steel ring 12, the inside of jar body 1 is equipped with baffle 8, support through baffle 8 and support steel ring 12 in jar body 1 inside, increase the rigidity of jar body 1, the inside of jar body 1 separates for liquid chamber 4 and solid chamber 7 through baffle 8, and solid chamber 7, and the slope 3 and 9 and solid chamber 7 have been equipped with the solid chamber 7 down in the design, the solid chamber 5 is gone up to the slope 5, the solid chamber 5 is down to the slope is equipped with the solid chamber 7, the solid chamber is down, the slope is lower to the solid chamber 5 is down to the slope 5, the solid chamber is opened, the slope is lower to the solid chamber is more difficult for the solid chamber 5, the material is down to the slope 5, the slope 5 is lower down the top down. The natural material separation mode does not need extra power driving or mechanical operation, energy sources and maintenance cost are saved, the flexible thin plate 6 is arranged at the joint of the sieve plate 5 and the partition plate 8, when excessive materials are accumulated on the flexible thin plate 6, the self weight of the materials bends the flexible thin plate 6, the materials on the flexible thin plate 6 automatically fall into the solid cavity, the flexible thin plate 6 is positioned in the solid cavity 7, and when excessive solid materials are accumulated, the self weight can bend the flexible thin plate 6, so that the materials slide into the solid cavity 7, and the solid-liquid separation effect is further improved. This kind of design has prevented that solid material from piling up in sieve 5 and baffle 8 junction, has reduced the risk of jam, ensures the continuous high-efficient operation of equipment, the bottom of jar body 1 is equipped with access opening 10 with the corresponding department in solid chamber 7 and liquid chamber 4, and operating personnel can directly get into solid chamber 7 and liquid chamber 4 through access opening 10, clear up and maintain the work. Thus, the accumulated solid materials and deposited liquid residues can be rapidly removed, and the cleaning and normal operation of the inside of the tank body 1 are ensured. The solid cavity 7 and the liquid cavity 4 are periodically cleaned through the access hole 10, so that the separation effect of the solid-liquid separation system can be prevented from being influenced by blockage or excessive sediment, and the efficient operation of equipment is ensured.

When the novel corrosion-resistant glass fiber reinforced plastic tank body based on the embodiment 1 is used:

The liquid cavity 4 and the solid cavity 7 are separated by the partition plate 8 in the tank body 1, and the partition plate 8 also plays a role in supporting the structure of the tank body 1. The baffle plate 8 and the supporting steel ring 12 strengthen the overall rigidity of the tank body 1, reduce the deformation risk of the tank body 1 in the transportation and use processes, and also help to maintain the structural stability of the inside of the tank body 1 and ensure the safety and reliability in the operation process.

The baffle plate 8 in the tank body 1 is not only used for supporting the structure of the tank body 1, but also can effectively realize the solid-liquid separation function. The inclined sieve plate 5 is arranged on the partition plate 8, so that the solid naturally slides to the solid cavity 7 under the action of gravity, and the liquid can enter the liquid cavity 4 through the holes on the sieve plate 5. The discharging pipe 3 and the liquid outlet pipe 9 are respectively positioned at the solid cavity 7 and the liquid cavity 4, so that the separated solid and liquid can be conveniently and efficiently discharged and treated. Meanwhile, the flexible thin plate 6 is arranged at the joint of the screen plate 5 and the partition plate 8, when solid materials are excessively stacked on the flexible thin plate 6, the self weight of the flexible thin plate is used for bending the flexible thin plate 6, so that the stacked materials automatically fall into the solid cavity 7.

The design that access hole 10 position is corresponding with solid chamber 7 and liquid chamber 4 has not only improved the maintenance convenience and the operating efficiency of equipment, has still strengthened the security and the reliability of equipment to the stable operation and the long-term use of system have been ensured.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the utility model in any way, and those skilled in the art may easily implement the present utility model as shown in the drawings and described above, but many modifications, adaptations and variations of the present utility model using the above disclosed technical matters without departing from the scope of the present utility model, and meanwhile, any equivalent modifications, adaptations and variations of the above embodiments according to the essential technology of the present utility model are within the scope of the technical matters of the present utility model.

Claims (5)

1. A novel corrosion-resistant glass fiber reinforced plastic tank, characterized in that it comprises a tank body (1), a sieve plate (5), a partition plate (8) and an inspection port (10), wherein a feed pipe (2) is provided at the top of the tank body (1), a discharge pipe (3) is provided at one end surface of the tank body (1), a liquid discharge pipe (9) is provided at one end of the tank body (1) away from the discharge pipe (3), a partition plate (8) is provided inside the tank body (1), and the inside of the tank body (1) is divided into a liquid chamber (4) by the partition plate (8) ) and a solid cavity (7), and the discharge pipe (3) and the liquid discharge pipe (9) are respectively connected to the solid cavity (7) and the liquid cavity (4); a sieve plate (5) is provided on the partition (8), and the sieve plate (5) is tilted and erected above the partition (8); an inspection port (10) is provided at the bottom end of the tank body (1); a manhole (11) is provided at the top end of the tank body (1) on one side of the feed pipe (2); and support steel rings (12) are provided inside the tank body (1) near both ends. 2. A novel corrosion-resistant glass fiber reinforced plastic tank according to claim 1, characterized in that: the lower end of the sieve plate (5) faces the solid cavity (7). 3. A novel corrosion-resistant glass fiber reinforced plastic tank body according to claim 1, characterized in that a flexible thin plate (6) is provided at the connection between the sieve plate (5) and the partition plate (8), and the flexible thin plate (6) is located in the solid cavity (7). 4. A novel corrosion-resistant glass fiber reinforced plastic tank body according to claim 1, characterized in that: the material discharge pipe (3) and the liquid discharge pipe (9) are symmetrically distributed on both sides of the tank body (1). 5. The novel corrosion-resistant glass fiber reinforced plastic tank body according to claim 1, characterized in that the position of the inspection port (10) corresponds to the solid cavity (7) and the liquid cavity (4).