CN221588189U - High-efficiency energy-saving protein separator - Google Patents

Abstract

The high-efficiency energy-saving protein separator comprises a separator cylinder, wherein a water inlet pipeline is arranged on the side wall of the lower part of the separator cylinder, a water outlet pipeline is arranged on the side wall of the upper part of the separator cylinder, a sedimentation sewage pipe is connected to the bottom of the separator cylinder, a foam sewage pipe is connected to the top of the separator cylinder, and a fluid mixing jet pump device is arranged inside the separator cylinder; in summary, the present utility model relates to a water treatment apparatus, which utilizes micro-nano bubbles with negative ions in a gas-liquid mixture generated by a fluid mixing jet pump device in a separator cylinder to adsorb protein components dissolved in a culture water body or other water bodies to be treated and dirt such as particles suspended in the water body, and then air-floats to the top of a main cylinder of a protein separator, and is discharged through a foam drain pipe; compared with the traditional protein separator, the utility model has good quality of generated bubbles and greatly saves energy consumption.

Description

High-efficiency energy-saving protein separator

Technical Field

The utility model belongs to the technical field of protein separation treatment, and particularly relates to a high-efficiency energy-saving protein separator.

Background

Currently, the separation of proteins and contaminants in a body of water by air bubbles of a protein separator is an effective method of purifying a body of water. Since protein separators are mainly used in the sea water treatment and aquaculture, the majority of the treatments required are light suspended particles, such as: algae in lakes, reservoirs and portions of rivers; plant residues and fine colloidal impurities; biological excreta and the like contain a large amount of water using flocs which are poorly effective in a sedimentation manner. In order to treat the floccules, bubbles are artificially introduced into water, and particularly, the surface tension of the bubbles acts, so that the floccules adhere to the bubbles, the overall density of the floccules is greatly reduced, and the floccules are forced to float upwards by the rising speed of the bubbles, thereby realizing rapid solid-liquid separation. The protein separator needs to process most of light suspended particles and organic matters, and the existing protein separator often has the problems of overlarge bubble particle size, quicker crushing, less bubble quantity and the like, so that the water body purifying efficiency is low and the energy consumption is high.

Disclosure of utility model

The utility model aims to provide a high-efficiency energy-saving protein separator, which solves the technical problems of low water purification efficiency and high energy consumption of the existing protein separator.

In order to solve the technical problems, the utility model adopts the following technical scheme:

The high-efficiency energy-saving protein separator comprises a separator cylinder, wherein a water inlet pipeline is arranged on the side wall of the lower part of the separator cylinder, a water outlet pipeline is arranged on the side wall of the upper part of the separator cylinder, a sedimentation sewage pipe is connected to the bottom of the separator cylinder, a foam sewage pipe is connected to the top of the separator cylinder, and a fluid mixing jet pump device is arranged inside the separator cylinder;

The fluid mixing jet pump device comprises a base, wherein the base is arranged at the bottom in a separator cylinder, a bottom cover is fixedly arranged at the top of the base, an outer shell is fixedly arranged in the bottom cover, a multi-head pump cover is fixedly arranged at the top of the outer shell, four connectors are arranged outside the multi-head pump cover and are fixedly arranged at tangent lines of the multi-head pump cover, and the interval between the four connectors is ninety degrees; and each connecting head is provided with a negative pressure mixing nozzle.

Furthermore, the bottom of the inner cavity of the separator cylinder body is of a conical surface structure, and the sedimentation drain pipe is connected to the conical surface structure.

Further, a water level observing transparent tube is also installed on the upper side wall of the separator cylinder.

Further, the discharge direction of the foam sewage pipes is arranged in a horizontally downward inclined mode, and the included angle between the discharge direction and the horizontal plane is 5 degrees.

Further, the negative pressure mixing nozzle comprises a nozzle shell, the side part of the nozzle shell is connected with a liquid inlet connector, the nozzle shell is arranged on the connector through the liquid inlet connector, one end of the nozzle shell is provided with two spray holes, the other end of the nozzle shell is provided with an air inlet, the air inlet is connected with an air pipe, and the air pipe penetrates through the separator cylinder body to extend outwards;

The spray head shell is internally provided with a double-spherical inner cavity and a negative pressure cavity, a baffle is fixed in the middle of the double-spherical inner cavity, the baffle divides the double-spherical inner cavity into two mixing inner cavities, the two mixing inner cavities are arranged up and down side by side, two spray holes are respectively communicated with the two mixing inner cavities correspondingly, liquid inlet notches are formed in the side parts of the two mixing inner cavities, the baffle is positioned between the two liquid inlet notches, the liquid inlet direction of the liquid inlet notch is arranged along the tangential direction of the mixing inner cavity, and the liquid inlet connector is in butt joint with the two liquid inlet notches;

the negative pressure cavity is located the lateral part of two spherical inner chambers, and the lateral part of two mixed inner chambers all is provided with the negative pressure through-hole, and two mixed inner chambers are linked together with the negative pressure cavity through two negative pressure through-holes respectively, and the air inlet is linked together with the negative pressure cavity.

Further, the air pipe and a power line of the fluid mixing jet pump device are hermetically arranged on the separator cylinder body through a rubber plug and a flange cover.

Further, the water inlet pipeline, the water outlet pipeline and the water level observation transparent pipe are all arranged on the separator cylinder body through the quick insertion pipe joint.

Compared with the prior art, the utility model has the beneficial effects that: the utility model relates to water treatment equipment, which utilizes micro-nano bubbles with negative ions in a gas-liquid mixture generated by a fluid mixing jet pump device in a separator cylinder body to absorb protein components dissolved in a culture water body or other water bodies to be treated and dirt such as particles suspended in the water body and the like, and then air floats the top of a main cylinder of a protein separator to be discharged through a foam blow-down pipe; compared with the traditional protein separator, the air bubble produced by the utility model has good quality, the traditional protein separator is integrally connected with the circulating pump and the jet pump, so that the energy consumption is greatly increased during equipment maintenance, replacement and use, and the high-efficiency energy-saving protein separator is only designed with a water inlet interface, but does not comprise the circulating pump, can supply water through an independent circulating pump and can also utilize the gravitational potential energy of the water to avoid electric power water inlet, thereby providing various independently selected application scenes for users and greatly saving the energy consumption.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model. In the drawings:

FIG. 1 is an isometric view of a high efficiency energy saving protein separator of the present utility model;

FIG. 2 is a side view of an energy efficient protein separator of the present utility model;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 2;

FIG. 4 is a schematic diagram of a fluid mixing jet pump device;

FIG. 5 is an isometric view of a fluid mixing jet pump device;

FIG. 6 is a schematic diagram of the operation of a fluid mixing jet pump device;

FIG. 7 is a schematic view of the structure of the negative pressure mixing nozzle;

FIG. 8 is an exploded view of a negative pressure mixing head;

FIG. 9 is an exploded view of another view of the negative pressure mixing head;

Fig. 10 is a schematic operation of the negative pressure mixing nozzle.

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.

The present utility model is described in further detail below with reference to examples.

As shown in fig. 1-10, the present utility model provides a specific embodiment of a high-efficiency energy-saving protein separator:

The high-efficiency energy-saving protein separator comprises a separator cylinder body 1, wherein a water inlet pipeline 2 is arranged on the side wall of the lower part of the separator cylinder body 1, a water outlet pipeline 3 is arranged on the side wall of the upper part of the separator cylinder body 1, a sedimentation sewage pipe 4 is connected to the bottom of the separator cylinder body 1, a foam sewage pipe 5 is connected to the top of the separator cylinder body 1, and a fluid mixing jet pump device 6 is arranged inside the separator cylinder body 1;

The fluid mixing jet pump device 6 comprises a multi-outlet characteristic energy-efficient pump, wherein the multi-outlet characteristic energy-efficient pump is in the prior art, the specific structure refers to an utility model patent with a patent number ZL202222681863.2, the fluid mixing jet pump device comprises a base 7, the base 7 is arranged at the inner bottom of a separator cylinder 1, a bottom cover 8 is fixedly arranged at the top of the base 7, an outer shell 9 is fixedly arranged in the bottom cover 8, a multi-head pump cover 10 is fixedly arranged at the top of the outer shell 9, four connectors 11 are arranged outside the multi-head pump cover 10, the four connectors 11 are fixedly arranged at tangent lines of the multi-head pump cover 10, and the intervals among the four connectors 11 are ninety degrees; each of the connectors 11 is provided with a negative pressure mixing nozzle 12.

The negative pressure mixing nozzle 12 comprises a nozzle shell 13, a liquid inlet joint 14 is connected to the side part of the nozzle shell 13, the nozzle shell 13 is arranged on the joint 11 through the liquid inlet joint 14, two spray holes 15 are arranged at one end of the nozzle shell 13, an air inlet 16 is arranged at the other end of the nozzle shell 13, an air pipe 17 is connected to the air inlet 16, and the air pipe 17 extends outwards through the separator cylinder 1;

The spray head shell 13 is internally provided with a double-spherical inner cavity 18 and a negative pressure cavity 19, a baffle 20 is fixed in the middle of the double-spherical inner cavity 18, the baffle 20 divides the double-spherical inner cavity 18 into two mixing inner cavities 21, the two mixing inner cavities 21 are arranged side by side up and down, the two spray holes 15 are respectively correspondingly communicated with the two mixing inner cavities 21, liquid inlet notches 22 are arranged on the side parts of the two mixing inner cavities 21, the baffle 20 is positioned between the two liquid inlet notches 22, the liquid inlet direction of the liquid inlet notches 22 is arranged along the tangential direction of the mixing inner cavities 21, and the liquid inlet connector 14 is butted with the two liquid inlet notches 22;

The negative pressure cavity 19 is located the lateral part of double sphere inner chamber 18, and the lateral part of two mixture inner chambers 21 all is provided with negative pressure through-hole 23, and two mixture inner chambers 21 are linked together with negative pressure cavity 19 through two negative pressure through-holes 23 respectively, and air inlet 16 is linked together with negative pressure cavity 19.

When the high-efficiency energy-saving protein separator works, the potential energy of a water body or the water body to be treated is sent into the separator cylinder 1 through the water inlet pipeline 2 by using the circulating pump, then the high-efficiency energy-saving pump provides liquid power, the liquid is pumped into the four negative pressure mixing spray heads 12 at high speed, and the process of entering the liquid into each negative pressure mixing spray head 12 is as follows: liquid enters the mixing cavity 21 through the two liquid inlet notches 22 in the tangential direction of the mixing cavity 21, the liquid rotates at a high speed to generate negative pressure in the mixing cavity 21, air enters the negative pressure cavity 19 through the air pipe 17 and the air inlet 16 under the suction effect of the negative pressure, then enters the mixing cavity 21 through the negative pressure cavity 19, the liquid and the air simultaneously rotate at a high speed after entering, the gas is crushed into bubbles with micro-nano level and negative ions under the actions of venturi principle and high-speed friction shearing when the gas and the liquid are mixed, finally the gas and the liquid are sprayed outwards through the two spray holes 15, and the rotating micro-nano bubbles absorb protein components dissolved in a water body and dirt such as particles suspended in the water body and then air float to the top of the separator cylinder 1, and are discharged through the foam blow-off pipe 5.

In addition, the bottom of the inner cavity of the separator cylinder 1 is provided with a conical surface structure 24, the sedimentation drain pipe 4 is connected to the conical surface structure 24, and the conical surface structure 24 is convenient for centralized drain. The upper side wall of the separator cylinder 1 is also provided with a water level observation transparent pipe 25, and the water level observation transparent pipe 25 can observe the liquid level condition in the separator cylinder 1. The foam discharge pipeline at the top of the traditional protein separator mostly flows out horizontally or flows out horizontally after a dirt collecting cup is turned, the discharge direction of the foam blow-down pipe 5 of the embodiment is arranged in a horizontally downward inclined manner, and the included angle between the discharge direction and the horizontal plane is 5 degrees, so that perfect blow-down is realized.

The air pipe 17 and the power line of the fluid mixing jet pump device 6 are hermetically arranged on the separator cylinder 1 through a rubber plug and a flange cover 26. The water inlet pipeline 2, the water outlet pipeline 3 and the water level observation transparent pipe 25 are all installed on the separator cylinder 1 through quick-insertion pipe joints, and the quick-installation can be realized only by simple insertion pipes without welding or threaded connection.

It should be noted that in this document, terms such as "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. An efficient energy-saving protein separator, which is characterized in that: the separator comprises a separator cylinder, wherein a water inlet pipeline is arranged on the side wall of the lower part of the separator cylinder, a water outlet pipeline is arranged on the side wall of the upper part of the separator cylinder, a sedimentation sewage pipe is connected to the bottom of the separator cylinder, a foam sewage pipe is connected to the top of the separator cylinder, and a fluid mixing jet pump device is arranged inside the separator cylinder;

The fluid mixing jet pump device comprises a base, wherein the base is arranged at the bottom in a separator cylinder, a bottom cover is fixedly arranged at the top of the base, an outer shell is fixedly arranged in the bottom cover, a multi-head pump cover is fixedly arranged at the top of the outer shell, four connectors are arranged outside the multi-head pump cover and are fixedly arranged at tangent lines of the multi-head pump cover, and the interval between the four connectors is ninety degrees; and each connecting head is provided with a negative pressure mixing nozzle.

2. An energy efficient protein separator according to claim 1 wherein: the bottom of the inner cavity of the separator cylinder body is of a conical surface structure, and the sedimentation drain pipe is connected to the conical surface structure.

3. An energy efficient protein separator according to claim 2 wherein: the upper side wall of the separator cylinder is also provided with a water level observation transparent pipe.

4. A high efficiency energy saving protein separator as defined in claim 3 wherein: the discharge direction of the foam blow-off pipe is horizontally and downwards inclined, and the included angle between the discharge direction and the horizontal plane is 5 degrees.

5. The energy efficient protein separator according to claim 4 wherein: the negative pressure mixing spray head comprises a spray head shell, the side part of the spray head shell is connected with a liquid inlet connector, the spray head shell is arranged on the connecting head through the liquid inlet connector, one end of the spray head shell is provided with two spray holes, the other end of the spray head shell is provided with an air inlet, the air inlet is connected with an air pipe, and the air pipe penetrates through the separator cylinder body to extend outwards;

The spray head shell is internally provided with a double-spherical inner cavity and a negative pressure cavity, a baffle is fixed in the middle of the double-spherical inner cavity, the baffle divides the double-spherical inner cavity into two mixing inner cavities, the two mixing inner cavities are arranged up and down side by side, two spray holes are respectively communicated with the two mixing inner cavities correspondingly, liquid inlet notches are formed in the side parts of the two mixing inner cavities, the baffle is positioned between the two liquid inlet notches, the liquid inlet direction of the liquid inlet notch is arranged along the tangential direction of the mixing inner cavity, and the liquid inlet connector is in butt joint with the two liquid inlet notches;

the negative pressure cavity is located the lateral part of two spherical inner chambers, and the lateral part of two mixed inner chambers all is provided with the negative pressure through-hole, and two mixed inner chambers are linked together with the negative pressure cavity through two negative pressure through-holes respectively, and the air inlet is linked together with the negative pressure cavity.

6. An energy efficient protein separator according to claim 5 wherein: the power line of the air pipe and the fluid mixing jet pump device is arranged on the separator cylinder body in a sealing way through the rubber plug and the flange cover.

7. An energy efficient protein separator according to claim 6 wherein: the water inlet pipeline, the water outlet pipeline and the water level observation transparent pipe are all arranged on the separator cylinder body through the quick insertion pipe joint.