CN106517450B - Wastewater separation device - Google Patents

Abstract

The invention discloses a wastewater separation device which is characterized by comprising a water inlet pipe, a water inlet valve, a flow meter I, a gouge separation pipe, a detection pipe, a water outlet valve and a flow meter II which are sequentially connected, wherein a circulating water pipe is also arranged between the detection pipe and the water outlet pipe, the other end of the circulating water pipe is positioned between the flow meter I and the gouge separation pipe, a circulating valve, a circulating pump and a flow meter III are sequentially arranged on the circulating water pipe, a detection device is arranged below the detection pipe and comprises a detection plate and a magnet, two ends of the detection plate are respectively hinged with a support, the magnet is arranged at the center of the upper surface of the detection plate, and a strain gauge is arranged at the center of the lower surface of the detection. The invention ensures that the discharged wastewater basically does not contain iron shavings and avoids the pollution to the environment by arranging the iron shavings separation pipe, the detection pipe and the circulating water pipe.

Description

Wastewater separation device

Technical Field

The invention relates to a wastewater separation device.

Background

Need a large amount of water to be used for cooling to the cutting portion during the cutting, consequently, can produce a large amount of waste water that contain the iron and cut, can get rid of a part iron through subsiding, but some tiny iron cuts can suspend in waste water, are difficult to get rid of through subsiding, if handle improper can cause the pollution to the environment.

Disclosure of Invention

In accordance with the above-mentioned technical problem, there is provided a wastewater separation apparatus. The technical means adopted by the invention are as follows:

a wastewater separation device is characterized by comprising a water inlet pipe, a water inlet valve, a flow meter I, a gouge separation pipe, a detection pipe, a water outlet valve and a flow meter II which are sequentially connected, wherein a circulating water pipe is further arranged between the detection pipe and the water outlet pipe, the other end of the circulating water pipe is positioned between the flow meter I and the gouge separation pipe, a circulating valve, a circulating pump and a flow meter III are sequentially arranged on the circulating water pipe,

a detection device is arranged below the detection tube and comprises a detection plate and a magnet, two ends of the detection plate are respectively hinged with the support, the magnet is arranged at the center of the upper surface of the detection plate, a strain gauge is arranged at the center of the lower surface of the detection plate,

the iron-cutting separating tube comprises an inlet section, a separating section and an outlet section,

the inlet section comprises a round pipeline I and a square pipeline I which are communicated in sequence,

the outlet section comprises a square pipeline II and a round pipeline II which are connected in sequence,

the separation section comprises a square pipe section III and a porous solid framework positioned in the square pipe section III,

the porous solid skeleton is formed by orthogonally stacking a plurality of composite balls, each composite ball comprises a spherical plastic porous shell and a magnet positioned in the spherical plastic porous shell,

when the device is in a working state, the water inlet valve and the water outlet valve are opened, wastewater sequentially passes through the water inlet pipe, the water inlet valve, the flowmeter I, the iron-cutting separation pipe, the detection pipe, the water outlet valve and the flowmeter II, when the strain gauge deforms, the water inlet valve and the water outlet valve are closed, the circulating valve and the circulating pump are sequentially opened, when the flow value of the flowmeter III is equal to the difference value of the flowmeter I and the flowmeter II, the circulating pump and the circulating valve are sequentially closed, the water outlet valve is opened, and when the flow value of the flowmeter II is equal to the flow value of the flowmeter I, the water inlet valve is opened.

The invention ensures that the discharged wastewater basically does not contain iron shavings and avoids the pollution to the environment by arranging the iron shavings separation pipe, the detection pipe and the circulating water pipe.

For the above reasons, the present invention can be widely applied to the fields of wastewater treatment, etc.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view showing a structure of a wastewater separation apparatus according to an embodiment of the present invention.

Fig. 2 is a top view of a detection device in an embodiment of the present invention.

Fig. 3 is a schematic structural view of a tapered separator tube according to an embodiment of the present invention.

Detailed Description

As shown in fig. 1-3, a wastewater separation device comprises a water inlet pipe 1, a water inlet valve 2, a flow meter i 3, a gouge separation pipe 4, a detection pipe 5, a water outlet pipe 6, a water outlet valve 7 and a flow meter ii 8 which are connected in sequence, a circulating water pipe 9 is further arranged between the detection pipe 5 and the water outlet pipe 6, the other end of the circulating water pipe 9 is positioned between the flow meter i 3 and the gouge separation pipe 4, a circulating valve 10, a circulating pump 11 and a flow meter iii 12 are sequentially arranged on the circulating water pipe 9,

a detection device 13 is arranged below the detection tube 5, the detection device 13 comprises a detection plate 14 and a magnet 15, two ends of the detection plate 14 are respectively hinged with a support 16, the magnet 15 is arranged at the center of the upper surface of the detection plate 14, a strain gauge 17 is arranged at the center of the lower surface of the detection plate 14,

the iron-cutting separator tube 4 comprises an inlet section 18, a separation section 19 and an outlet section 20,

the inlet section 18 comprises a round pipeline I21 and a square pipeline I22 which are communicated in sequence,

the outlet section 20 comprises a square pipeline II 23 and a round pipeline II 24 which are connected in sequence,

the separation section 19 comprises a square pipe section III 25 and a porous solid framework 26 positioned in the square pipe section III 25,

the porous solid skeleton 26 is formed by orthogonally stacking a plurality of composite balls, each of which comprises a spherical plastic porous shell and a magnet positioned in the spherical plastic porous shell,

during the operating condition, water inlet valve 2 with outlet valve 7 opens, and waste water passes through in proper order inlet tube 1, water inlet valve 2, flow table I3, iron scrap separator tube 4, detection tube 5, outlet pipe 6, outlet valve 7 with flow table II 8, when strain gauge 17 takes place to warp, water inlet valve 2 with outlet valve 7 closes, circulating valve 10 with circulating pump 11 opens in proper order, treats when the flow value of flow table III 12 equals flow table I3 with the difference of flow table II 8, circulating pump 11 with circulating valve 10 closes in proper order, outlet valve 7 opens, treats when the flow value of flow table II 8 equals the flow value of flow table I3, water inlet valve 2 opens.

The inlet section 18, the separation section 19 and the outlet section 20 are each connected by flanges.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (1)

1. A wastewater separation device is characterized by comprising a water inlet pipe, a water inlet valve, a flow meter I, a gouging separating pipe, a detection pipe, a water outlet valve and a flow meter II which are connected in sequence, wherein a circulating water pipe is further arranged between the detection pipe and the water outlet pipe, the other end of the circulating water pipe is positioned between the flow meter I and the gouging separating pipe, a circulating valve, a circulating pump and a flow meter III are sequentially arranged on the circulating water pipe, a detection device is arranged below the detection pipe and comprises a detection plate and a magnet, two ends of the detection plate are respectively hinged with a support, the magnet is arranged at the center of the upper surface of the detection plate, a strain gauge is arranged at the center of the lower surface of the detection plate, the gouging separating pipe comprises an inlet section, a separating section and an outlet section, the inlet section comprises a round pipeline I and a square pipeline, the outlet section comprises a square pipeline II and a circular pipeline II which are sequentially connected, the separation section comprises a square pipeline III and a porous solid framework positioned in the square pipeline III, the porous solid framework is formed by orthogonally stacking a plurality of composite balls, each composite ball comprises a spherical plastic porous shell and a magnet positioned in the spherical plastic porous shell, when the separation section is in a working state, the water inlet valve and the water outlet valve are opened, wastewater sequentially passes through the water inlet pipe, the water inlet valve, the flow meter I, the iron-cutting separation pipe, the detection pipe, the water outlet valve and the flow meter II, when the strain gauge deforms, the water inlet valve and the water outlet valve are closed, the circulating valve and the circulating pump are sequentially opened, and when the flow value of the flow meter III is equal to the difference value of the flow meter I and the flow meter II, and the circulating pump and the circulating valve are closed in sequence, the water outlet valve is opened, and the water inlet valve is opened when the flow value of the flow meter II is equal to that of the flow meter I.