CN211948653U

CN211948653U - Water supply pipeline system in concrete production line

Info

Publication number: CN211948653U
Application number: CN201921704052.1U
Authority: CN
Inventors: 王学书; 包鸿飞; 严亮; 杨斌
Original assignee: Zhangjiagang Yongji Commercial Concrete Co ltd
Current assignee: Zhangjiagang Yongji Commercial Concrete Co ltd
Priority date: 2019-10-12
Filing date: 2019-10-12
Publication date: 2020-11-17
Anticipated expiration: 2029-10-12

Abstract

The invention discloses a water supply pipeline system in a concrete production line, which comprises a water pool, a first main pipeline, a second main pipeline, an auxiliary pipeline, a first water channel pipeline and a second water channel pipeline, wherein the water pool is arranged in the water pool; the first main pipeline, the second main pipeline and the auxiliary pipeline are all provided with a water supply pump; the pond is all connected to the one end of first trunk line, second trunk line, auxiliary conduit, the first water route pipeline of T type tee junction is all passed through to the other end of first trunk line, auxiliary conduit, first water route pipeline of F type tee junction and second water route pipeline are passed through to the second trunk line. The invention discloses a water supply pipeline system in a concrete production line, which effectively and reasonably designs pipelines, reduces the maintenance cost, saves the cost while facilitating the maintenance and improves the production efficiency.

Description

Water supply pipeline system in concrete production line

Technical Field

The invention relates to the field of water supply pipelines of concrete production lines, in particular to a water supply pipeline system in a concrete production line.

Background

The water supply system in the concrete production route is an important component of the production route, and in the existing production, if 1 water pump goes wrong, the production is stopped for maintenance, so that the production is wrong, the quality of the produced concrete is unqualified seriously, the material is wasted, and the great economic loss is caused.

Disclosure of Invention

In order to solve the problems, the invention discloses a water supply pipeline system in a concrete production line, which effectively and reasonably designs pipelines, reduces the maintenance cost, saves the cost while facilitating the maintenance and improves the production efficiency.

In order to achieve the above purpose, the invention provides the following technical scheme:

a water supply pipeline system in a concrete production line comprises a water pool, a first main pipeline, a second main pipeline, an auxiliary pipeline, a first water channel pipeline and a second water channel pipeline; the first main pipeline, the second main pipeline and the auxiliary pipeline are all provided with a water supply pump; the pond is all connected to the one end of first trunk line, second trunk line, auxiliary conduit, the first water route pipeline of T type tee junction is all passed through to the other end of first trunk line, auxiliary conduit, first water route pipeline of F type tee junction and second water route pipeline are passed through to the second trunk line.

Furthermore, valves are arranged on the first main pipeline and the second main pipeline.

Furthermore, on the first waterway pipeline, a valve is arranged between the first main pipeline and the auxiliary pipeline, and a valve is arranged between the second main pipeline and the auxiliary pipeline.

Furthermore, the valve is one of a ball valve, a check valve and a stop valve.

Further, the valves on the first main pipeline and the second main pipeline are arranged between the water supply pump and the first waterway pipeline.

The invention also discloses a use method of the water supply pipeline system on the concrete production line, the use method is convenient and convenient to maintain, the smooth production is ensured, and the mistiming is reduced, the method comprises the following steps:

opening valves of the first main pipeline and the second main pipeline, and opening water pumps of the first main pipeline and the second main pipeline; closing a valve on the first waterway pipeline; the first main pipeline is communicated to the first waterway pipeline, and the second main pipeline is communicated to the second waterway pipeline; the first water channel pipeline and the second water channel pipeline respectively supply water;

if the water pump on the first main pipeline breaks down, closing a valve on the first main pipeline; and the water pumps of the auxiliary pipeline and the second main pipeline are opened; opening a valve on the first waterway pipeline between the first main pipeline and the auxiliary pipeline, and closing a valve between the second main pipeline and the auxiliary pipeline; the auxiliary pipeline is communicated to the first waterway pipeline, the second main pipeline is communicated to the second waterway pipeline, and the first waterway pipeline and the second waterway pipeline respectively supply water;

if the water pump on the second main pipeline breaks down, closing a valve on the second main pipeline; and the water pumps of the first main pipeline and the auxiliary pipeline are opened; opening a valve between the second main pipeline and the auxiliary pipeline; close the valve that is located between first trunk line and the auxiliary conduit on the first water route pipeline for first trunk line circulation is to first water route pipeline, and auxiliary conduit circulation is to second water route pipeline, and first water route pipeline and second water route pipeline supply water respectively.

The invention has the following beneficial effects:

1. the continuous production is powerfully guaranteed, and mistiming is reduced. 2. Sufficient time is left for the maintenance of the feed pump. 3. Greatly reducing the concrete quality problem caused by untimely water supply, the waste of materials and the like.

Drawings

FIG. 1 is a system diagram of the present invention;

the water tank comprises a water tank 1, a first main pipeline 2, a second main pipeline 3, an auxiliary pipeline 4, a first waterway pipeline 5, a second waterway pipeline 6, a 1# pump 7, a 2# pump 8, a 3# pump 9, a T-shaped tee joint 10, an F-shaped tee joint 11, a 1# valve 12, a 2# valve 13, a 3# valve 14 and a 4# valve 15.

Detailed Description

The present invention will be further illustrated with reference to the accompanying drawings and specific embodiments, which are to be understood as merely illustrative of the invention and not as limiting the scope of the invention.

The water supply system is rectified and improved by the permanent record group on the concrete production site, as shown in fig. 1, the pipeline system comprises a water pool 1, a first main pipeline 2, a second main pipeline 3, an auxiliary pipeline 4, a first water channel pipeline 5 and a second water channel pipeline 6; a 1# pump 7 is arranged on the first main pipeline, a 2# pump 8 is arranged on the second main pipeline, and a 3# pump 9 is arranged on the auxiliary pipeline; the pond is all connected to the one end of first trunk line, second trunk line, auxiliary conduit, and first water route pipeline is all connected through T type tee bend 10 to the other end of first trunk line, auxiliary conduit, and first water route pipeline and second water route pipeline are connected through F type tee bend 11 to the second trunk line.

A1 # valve 12 is arranged on the first main pipe, and a 2# valve 13 is arranged on the second main pipe. The valves on the first main pipeline and the second main pipeline are arranged between the water supply pump and the first waterway pipeline.

On the first water route pipeline, be equipped with 3# valve 14 between first main pipeline and auxiliary line, be equipped with 4# valve 15 between second main pipeline and auxiliary line.

The valve is one of a ball valve, a check valve and a stop valve.

The method for reasonably regulating and controlling water supply by adopting the system comprises the following steps:

opening a 1# valve of the first main pipeline and a 2# valve of the second main pipeline, and opening a 1# pump of the first main pipeline and a 3# pump of the second main pipeline; closing the 3# valve and the 4# valve on the first waterway pipeline; the first main pipeline is communicated to the first waterway pipeline, and the second main pipeline is communicated to the second waterway pipeline; the first water channel pipeline and the second water channel pipeline respectively supply water;

if the 1# pump on the first main pipeline fails, closing the 1# valve on the first main pipeline; and opening the 2# pump of the auxiliary pipeline and the 3# pump of the second main pipeline; opening a 3# valve positioned between the first main pipeline and the auxiliary pipeline on the first waterway pipeline, and closing a 4# valve between the second main pipeline and the auxiliary pipeline; the auxiliary pipeline is communicated to the first waterway pipeline, the second main pipeline is communicated to the second waterway pipeline, and the first waterway pipeline and the second waterway pipeline respectively supply water;

if the 3# pump on the second main pipeline fails, closing the 2# valve on the second main pipeline; and opening the 1# pump of the first main pipeline and the 2# pump of the auxiliary pipeline; opening a No. 4 valve on the first waterway pipeline between the second main pipeline and the auxiliary pipeline; close the 3# valve that is located between first trunk line and the accessory line on the first waterway pipeline for first trunk line circulation is to first waterway pipeline, and accessory line circulation is to second waterway pipeline, and first waterway pipeline and second waterway pipeline supply water respectively.

The working principle is as follows: for the sake of clarity, reference is made to fig. 1. The water supply pipeline is networked, so that the water supply pipeline can be manually switched to the No. 2 pump no matter the No. 1 pump or the No. 3 pump fails, the continuous production is ensured, and sufficient time is provided for the maintenance of the water suction pump. During normal production, the 1# pump and the 3# pump work, and the 3# valve and the 4# valve are closed. When the No. 1 pump fails, the No. 1 valve is closed, the No. 2 pump is started, the No. 3 valve is opened, and the closed state of the No. 4 valve is kept, so that the No. 1 water path continues to work. When the No. 3 pump fails, the No. 2 valve is closed, the No. 2 pump is started, the No. 4 valve is opened, and the closed state of the No. 3 valve is kept, so that the No. 2 water path continues to work.

The improved process has the advantages of 1, powerfully ensuring the continuous production and reducing mistiming. 2. Sufficient time is left for the maintenance of the feed pump. 3. Greatly reducing the concrete quality problem caused by untimely water supply, the waste of materials and the like.

The technical means disclosed in the invention scheme are not limited to the technical means disclosed in the above embodiments, but also include the technical scheme formed by any combination of the above technical features. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of the present invention, and such improvements and modifications are also considered to be within the scope of the present invention.

Claims

1. A water supply pipeline system in a concrete production line is characterized in that: the pipeline system comprises a water pool, a first main pipeline, a second main pipeline, an auxiliary pipeline, a first waterway pipeline and a second waterway pipeline; the first main pipeline, the second main pipeline and the auxiliary pipeline are all provided with a water supply pump; the pond is all connected to the one end of first trunk line, second trunk line, auxiliary conduit, first water route pipeline is connected to the other end of first trunk line, auxiliary conduit, first water route pipeline and second water route pipeline are connected to the other end of second trunk line.

2. A water supply pipe system in a concrete production line as claimed in claim 1, wherein: valves are arranged on the first main pipeline and the second main pipeline.

3. A water supply pipe system in a concrete production line as set forth in claim 2, wherein: and a valve is arranged on the first water path pipeline between the first main pipeline and the auxiliary pipeline, and a valve is arranged between the second main pipeline and the auxiliary pipeline.

4. A water supply piping system in a concrete production line as claimed in claim 2 or 3, wherein: the valves are all one of ball valves, check valves and stop valves.

5. A water supply pipe system in a concrete production line as set forth in claim 3, wherein: the valves on the first main pipeline and the second main pipeline are arranged between the water supply pump and the first waterway pipeline.

6. A water supply pipe system in a concrete production line as claimed in claim 1, wherein: the other ends of the first main pipeline and the auxiliary pipeline are connected with a first water pipeline through T-shaped tee joints, and the other end of the second main pipeline is connected with the first water pipeline and a second water pipeline through F-shaped tee joints.