CN218681296U - Novel protein separator - Google Patents

Abstract

A novel protein separator relates to the technical field of seawater vat equipment. It comprises a reaction cabin body; the frequency conversion needle brushing water pump module is connected with the reaction cabin body; the gas injection module is arranged on the frequency conversion needle brushing water pump module; and a collecting cup arranged at the top end of the reaction bin body; the gas injection module is used for injecting gas into liquid entering the variable-frequency needle brushing water pump module to form bubbles, the variable-frequency needle brushing water pump module is used for pumping the liquid into the reaction cabin body and generating foams, an overflow opening is formed in the top end of the reaction cabin body, and the overflow opening is used for allowing the foams to overflow and enter the collection cup. By adopting the technical scheme, the energy consumption is saved, and the use cost is reduced.

Description

Novel protein separator

Technical Field

The utility model relates to a sea water jar equipment technical field, concretely relates to novel protein separator.

Background

In marine aquarium, the protein separator is almost indispensable equipment, and organic waste such as excrement and food residue in the aquarium affects the quality of water, and is decomposed into toxic substances for a long time, so that the protein separator is required to remove the organic waste. The existing protein separator adopts a Venturi jet negative pressure principle to mix water and air, and then utilizes water flow with air bubbles to attach organic waste to achieve the cleaning effect, but the existing protein separator has high energy consumption and improves the use cost.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a novel protein separator aiming at the defects and shortcomings of the prior art, which has the advantage of low energy consumption.

In order to achieve the above object, the utility model adopts the following technical scheme: a novel protein separator, comprising: a reaction cabin body; the frequency conversion needle brushing water pump module is connected with the reaction cabin body; the gas injection module is arranged on the frequency conversion needle brushing water pump module; and a collecting cup arranged at the top end of the reaction bin body; the gas injection module is used for injecting gas into liquid entering the variable-frequency needle brushing water pump module to form bubbles, the variable-frequency needle brushing water pump module is used for pumping the liquid into the reaction cabin body and generating foams, an overflow opening is formed in the top end of the reaction cabin body, and the overflow opening is used for allowing the foams to overflow and enter the collection cup.

The utility model discloses further set up, the internal bottom in reaction storehouse be equipped with the water conservancy diversion storehouse that the delivery port of frequency conversion needle brush water pump module is connected, open on the top in water conservancy diversion storehouse has a plurality of water conservancy diversion pores.

The utility model discloses further set up, frequency conversion needle brush water pump module includes: a liquid inlet pipe connected with the reaction bin body; the liquid outlet pipe is connected with the diversion bin; and a frequency conversion needle brush water pump arranged between the liquid inlet pipe and the liquid outlet pipe; the gas injection module is connected with the liquid inlet pipe and injects gas into liquid entering the liquid inlet pipe, the liquid inlet pipe is used for guiding the liquid into the frequency conversion needle brush water pump from the reaction bin body, the frequency conversion needle brush water pump is used for pumping out the liquid and generating foam, and the liquid outlet pipe is used for guiding the pumped liquid into the flow guide bin.

The utility model discloses further set up, the feed liquor pipe with be equipped with adjusting valve on the drain pipe.

The utility model discloses further set up, reaction storehouse body bottom is equipped with drinking-water pipe and drain pipe, the drinking-water pipe is used for leading-in pending liquid the reaction storehouse body, the drain pipe be used for with the internal liquid discharge in reaction storehouse.

The utility model discloses further set up, the inboard top of collection cup is equipped with the cleaning brush, the cleaning brush is used for sweeping the foam that overflows into collect the cup.

The utility model discloses further set up, be equipped with the drain on the collection cup, the drain is used for discharging collect the filth in the cup.

The utility model discloses further set up, the reaction storehouse body with it is the PP material to collect the cup

After adopting above-mentioned technical scheme, through the frequency conversion needle brush water pump module of the connection reaction storehouse body and the cooperation of locating the gas injection module on the frequency conversion needle brush water pump module, frequency conversion needle brush water pump module will be to the internal pump of reaction storehouse liquid that has a large amount of bubbles, the filth in the bubble attached liquid then gathers into the foam through the overflow opening on the top of the reaction storehouse and spills over to the collection cup, realize organic waste separation function, adopt the design of frequency conversion needle brush water pump, saved the energy consumption under the same circumstances of flow, the cost of use has been reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed 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 some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic side view of the present invention;

fig. 3 is a schematic cross-sectional view of the present invention;

fig. 4 is an exploded view of the structure of the present invention;

fig. 5 is an exploded view of another structure of the present invention.

Description of reference numerals: 1. a reaction cabin body; 11. an overflow opening; 2. a frequency conversion needle brushing water pump module; 21. a liquid inlet pipe; 22. a liquid outlet pipe; 23. a variable frequency needle brush water pump; 24. adjusting the valve; 3. a gas injection module; 31. an air inlet pipe; 32. an air valve; 4. a collection cup; 41. a cleaning brush; 42. a sewage draining outlet; 5. a diversion bin; 51. fine diversion holes; 61. a water pumping pipe; 62. and a water discharge pipe.

Detailed Description

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

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment as required without making a contribution, but all the embodiments are protected by the patent law within the scope of the claims of the present invention.

The present embodiment relates to a novel protein separator, as shown in fig. 1 and fig. 3, which comprises a reaction chamber body 1, a frequency conversion needle brush water pump module 2 connected to the reaction chamber body 1, a gas injection module 3 disposed on the frequency conversion needle brush water pump module 2, and a collecting cup 4 disposed on the top of the reaction chamber body 1. The gas injection module 3 is used for injecting gas into the liquid entering the frequency conversion needle brushing water pump module 2 so as to form bubbles by mixing water and gas. The frequency conversion needle brushing water pump module 2 is used for pumping liquid into the reaction cabin body 1 and generating a large amount of foam. The top end of the reaction bin body 1 is provided with an overflow opening 11, and the overflow opening 11 is used for overflowing foam into the collecting cup 4. In the process of floating foam, the foam can adsorb various granular dirt and soluble organic matters mixed in the liquid, the foam floats upwards and is concentrated to the liquid surface to be gathered, overflows from the overflow opening 11 and then enters the collection cup 4, and the separation of organic waste is realized. By adopting the frequency conversion needle brushing water pump 23, the energy consumption in the separation process is effectively reduced, and the use cost is reduced.

A diversion bin 5 is arranged at the bottom of the reaction bin body 1, the diversion bin 5 is connected with a water outlet of the variable frequency needle brushing pump module 2, and a plurality of diversion pores 51 are formed at the top end of the diversion bin 5, as shown in fig. 3 and 4. The frequency conversion needle brushing water pump module 2 pumps liquid with a large amount of foam into the diversion bin 5, and the foam can only flow out through the diversion pores 51 at the top end of the diversion bin 5, so that the diversion effect is achieved. And when the foam passes through the fine guide holes 51, the foam is divided into finer foam by the fine guide holes 51, so that the organic waste in the liquid can be quickly adsorbed.

Specifically, as shown in fig. 2, the frequency conversion needle brush water pump module 2 includes a liquid inlet pipe 21 connected to the reaction chamber 1, a liquid outlet pipe 22 connected to the diversion chamber 5, and a frequency conversion needle brush water pump 23 disposed between the liquid inlet pipe 21 and the liquid outlet pipe 22, and the gas injection module 3 is connected to the liquid inlet pipe 21 for injecting gas into the liquid entering the liquid inlet pipe 21. As shown in the figure, gas injection module 3 specifically includes intake pipe 31 and the pneumatic valve 32 of setting on intake pipe 31, intake pipe 31 is connected to between feed liquor pipe 21 and the frequency conversion needle brush water pump 23, after the liquid entering feed liquor pipe 21 of reaction storehouse body 1, can follow the gas that intake pipe 31 pours into feed liquor pipe 21 into and carry out the aqueous vapor mixture, and when brushing water pump 23 through the frequency conversion needle, the needle brush impeller high-speed rotation on the frequency conversion needle brush water pump 23, produce a large amount of little bubbles, then liquid pumps out drain pipe 22 with a large amount of foams, it is leading-in to in the guiding storehouse 5. The more the bubbles are, the more the organic waste is taken away by adsorption, the processing capacity of the variable frequency needle brush water pump 23 is strong, and the energy-saving effect can be achieved.

Be equipped with adjusting valve 24 on feed liquor pipe 21 and drain pipe 22 for the user manual regulation business turn over liquid flow, when liquid tension and protein separator's feed liquor air input did not match, the condition of exploding towards gas leakage bubble often can appear, and the user can pass through the flow of adjusting valve 24 manual regulation business turn over liquid this moment, alleviates the condition of exploding towards, improves the efficiency that protein separator and liquid break-in.

The bottom of the reaction cabin body 1 is provided with a water pumping pipe 61 and a water draining pipe 62, as shown in fig. 1, the water pumping pipe 61 is used for introducing the liquid to be treated into the reaction cabin body 1, and the water draining pipe 62 is used for draining the liquid in the reaction cabin body 1. In this embodiment, the water pumping pipe 61 and the water draining pipe 62 are connected to a seawater tank, seawater in the seawater tank enters the reaction chamber body 1 through the water pumping pipe 61, then enters the liquid inlet pipe 21 to be mixed with gas, is pumped out of the liquid outlet pipe 22 to the diversion chamber 5 through the frequency conversion needle brush water pump 23, and upwards passes through the diversion fine holes 51 to return to the reaction chamber body 1, a large amount of foam upwards floats from the diversion chamber 5, so that organic waste in the flowing seawater is adsorbed and taken away, thereby completing separation, and the seawater after protein separation returns to the seawater tank through the water draining pipe 62, thereby completing the process of cyclic purification.

The top of the inside of the collecting cup 4 is provided with a cleaning brush 41, as shown in fig. 3 and 5, the cleaning brush 41 serving to sweep the overflowing foam into the collecting cup 4. The sewage outlet 42 is formed in the collecting cup 4, protein sewage in the collecting cup 4 can be discharged, a user can insert the protein sewage outlet into a sewage discharge pipe, the automatic sewage discharge function is achieved, the frequency of manually cleaning the protein separator by the user can be reduced, and the use experience is improved.

In this embodiment, the reaction chamber body 1 and the collecting cup 4 are both made of a PP material, which is an environment-friendly material and is more environment-friendly.

The working principle of the utility model is as follows: through the frequency conversion needle brush water pump module 2 of the connection reaction storehouse body 1 and the cooperation of locating gas injection module 3 on the frequency conversion needle brush water pump module 2, frequency conversion needle brush water pump module 2 will have the liquid of a large amount of bubbles to the 1 interior pump-in of the reaction storehouse body, the filth in the bubble attached liquid then gathers into the foam through the opening 11 that overflows on the 1 top of the reaction storehouse body and spills over to collect in the cup 4, realize organic waste separation function, adopt the design of frequency conversion needle brush water pump 23, the energy consumption has been saved under the same circumstances of flow, the cost of using has been reduced.

The above description is only for the purpose of illustration and not limitation, and other modifications or equivalent replacements made by those skilled in the art to the technical solution of the present invention should be covered by the scope of the claims of the present invention as long as they do not depart from the spirit and scope of the technical solution of the present invention.

Claims (8)

1. A novel protein separator, comprising:

a reaction cabin body (1);

a frequency conversion needle brushing water pump module (2) connected with the reaction cabin body (1);

the gas injection module (3) is arranged on the frequency conversion needle brushing water pump module (2); and

the collecting cup (4) is arranged at the top end of the reaction cabin body (1);

the gas injection module (3) is used for injecting gas into the liquid entering the frequency conversion needle brushing water pump module (2) to form bubbles, the frequency conversion needle brushing water pump module (2) is used for pumping the liquid into the reaction cabin body (1) and generating foams, an overflow opening (11) is arranged at the top end of the reaction cabin body (1), and the overflow opening (11) is used for allowing the foams to overflow and enter the collection cup (4).

2. The novel protein separator as claimed in claim 1, wherein a diversion bin (5) connected with the water outlet of the frequency conversion needle brush water pump module (2) is arranged at the bottom inside the reaction bin body (1), and a plurality of diversion fine holes (51) are formed in the top end of the diversion bin (5).

3. The novel protein separator as claimed in claim 2, wherein said variable frequency needle brush water pump module (2) comprises:

a liquid inlet pipe (21) connected with the reaction bin body (1);

a liquid outlet pipe (22) connected with the diversion bin (5); and

a frequency conversion needle brush water pump (23) arranged between the liquid inlet pipe (21) and the liquid outlet pipe (22);

the gas injection module (3) is connected with the liquid inlet pipe (21) and injects gas into liquid entering the liquid inlet pipe (21), the liquid inlet pipe (21) is used for guiding liquid into the variable frequency needle brushing pump (23) from the reaction cabin body (1), the variable frequency needle brushing pump (23) is used for pumping out the liquid and generating foam, and the liquid outlet pipe (22) is used for guiding the pumped liquid into the diversion cabin (5).

4. The novel protein separator as claimed in claim 3, characterized in that the inlet pipe (21) and the outlet pipe (22) are provided with regulating valves (24).

5. The novel protein separator as claimed in claim 1, characterized in that a water suction pipe (61) and a water discharge pipe (62) are arranged at the bottom of the reaction chamber body (1), the water suction pipe (61) is used for introducing the liquid to be treated into the reaction chamber body (1), and the water discharge pipe (62) is used for discharging the liquid in the reaction chamber body (1).

6. The novel protein separator according to claim 1, characterized in that the top inside the collecting cup (4) is provided with a cleaning brush (41), the cleaning brush (41) being used to sweep the overflowing froth into the collecting cup (4).

7. The novel protein separator as claimed in claim 1, characterized in that a drain (42) is provided on the collecting cup (4), said drain (42) being used to drain the dirt in the collecting cup (4).

8. The novel protein separator as claimed in claim 1, characterized in that said reaction cartridge (1) and said collection cup (4) are both of PP material.

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