DE212007000094U1 - River propeller, water stirrer and protein separator with the propeller - Google Patents

Abstract

A flow propeller in which an impeller is driven by an electric motor via a rotor and continuously expels the water in a tangential direction and a radial direction while driving the water to rotate about an axis of rotation, characterized in that:
the impeller is provided with a guide cylinder at the circumference thereof, the cylinder prevents the water from flowing out, and allows the water to rotate therein, and generates an axial flow due to the accumulation of water, a rear baffle at the The rear end of the impeller is arranged in the axial direction to prevent the ejected water from flowing from the high pressure zone at the outer edge of the impeller to the low pressure zone at the center of the impeller via the rear end of the impeller, a front baffle at the outer End of the impeller is arranged in the axial direction to prevent the ejected water ...

Description

Field of the invention

The The present invention relates to a flow propeller, the used in water, and a device that controls the flow, the generated by the propeller, used to stir the water or to separate the protein from it. More specifically, it refers the present invention to a flow propeller, wherein a Impeller driven by an electric motor via a rotor and drives water to flow forward and around an axis to turn, and a device for stirring water or separating a protein by means of the vortex flow caused by such River propeller is generated.

Background of the invention

In the conventional one Technology uses a water pump an electric motor to drive an impeller to turn, and in turn drives the rotary motion of the impeller the water flow to turn around an axis. A half-closed pump housing is arranged around the impeller, the pump housing has a water inlet port open on the front of the impeller in the axial direction is to lead Water in the same, the water outlet is usually on the pump housing at the outer edge of the impeller and along the tangential or radial direction arranged the impeller.

Of the Water flow generated by such a conventional water pump , has a single flow direction, meaning that it is the same not for Situations suitable where a rotary flow is required is. If a person tries this kind of conventional Pump to use to stir water to a fluctuation in the water or to separate protein from water, wherein the same as a propulsion mechanism of a filtering, separating Device serves, causes the only water flow direction that the foreign substances in the water are pushed into a corner and difficult to filter or to be separated. In the meantime, a reactor tends to separate of protein the previously mentioned River in a single direction, a straight on-and-off river to form, which has a short flow path and a reduced Reaction time leads, so that the protein separation effect deteriorates. If the same serves as a propelling mechanism of a stirrer tends this conventional Water pump also to the driving grass in the water to a single direction and inclined to blow to the same, which is obvious unnatural looks.

Further is at a conventional Protein separator the foam collection slot a removable open structure. To ensure that water is on the outside do not flow into the foam collection slot and separate the foam back into the water, the foam collecting slot must during a Use to get out of the water. After elapse of a period of time In addition, the foam collecting slot must be removed to the To remove foam, before the same for re-attached for reuse; otherwise, the Foam that is continuous during of use is accumulated in the foam collecting slot and finally overflow and enter the water in the aquarium. Consequently, the conventional Protein separation device a problem in a joining and maintenance. Because the opening the foam collection slot over the water surface must come the protein separator at the top section of the aquarium, however, the present aquarium has at the upper portion generally on a lid, usually a electrical system is incorporated in the same, the protein separator probably disturbs the system. Furthermore, the enlarged Maintenance work of removing the foams in the collecting slot, what often required is, the burden of the people.

Summary of the invention

Of the The first purpose of the present invention is to provide a flow propeller to create, which can produce an eddy current, which is about an axis turns and forwards flows.

Of the second purpose of the present invention is to provide a protein separator to create, which has the propeller, by guiding the Eddy current generated by the propeller into a protein separation mechanism, the protein separator offers an extended route and a longer reaction time for the Water-air mixture or a mixture of water and another Gas in the reaction chamber, with less energy lost, why the protein separation effect is improved.

at The second purpose of the present invention is another improved protein separation device provided the device takes advantage of the air flow caused by the bursting of the bubbles is produced, best to continue the foam through an exit tube lead out, to ensure that the foam does not return to the aquarium.

Further, in the second purpose of the present invention, a structure is further In this structure, the other parts except for an upper tube of the separator may be immersed in the water, and therefore, the problem that the protein separator separates a partial space of the lid of the aquarium is solved occupies and obstructs the movement of the lid.

Of the The third purpose of the present invention is to add a water stirrer create, which has the river propeller, wherein the water stirrer the Vortex flow, which is generated by the propeller, uses to stir the water and about the stirring effect to increase.

at the third purpose of the present invention further provides a water stirrer, which generates a simulated wave with a swirling flow while the Water is stirred with the same.

The above purposes are achieved by the following solutions:
A flow propeller in which an impeller is driven by an electric motor via a rotor and continuously expels the water in a tangential direction and a radial direction while driving the water to rotate about an axis of rotation, the characteristic of the propeller being therein in that the impeller is provided with a guide cylinder at the periphery thereof, the cylinder preventing the water from flowing outwardly, allowing the water to rotate therein, and generating an axial flow due to the accumulation of water; a rear baffle is disposed at the rear end of the impeller in the axial direction to prevent the ejected water from flowing from the high pressure zone at the outer edge of the impeller to the low pressure zone at the center of the impeller via the rear end of the impeller; a front baffle is disposed at the outer end of the impeller in the axial direction to prevent the ejected water from flowing from the high pressure zone at the outer edge of the impeller to the low pressure zone at the center of the impeller via the front end surface of the impeller Water inlet is arranged at the central region of the rear baffle plate, the front end of the guide cylinder is used as the water outlet.

Under the effect of the guide cylinder, the rear baffle and the front baffle can be the river propeller create a vortex flow, the forward flows.

at the above solution are preferably the guide cylinder and the impeller at corresponding positions at the same level arranged. Furthermore, it is a management structure provided, the cross-section of which increases from back to front, for To lead of the rotating flow to an outlet at the axially outer end. The management structure can the centrifugal force of the expelled water on a thrust towards the larger opening efficiently transmitted in the axial direction and use the thrust to the effect of forcing the vortex flow forward to enforce.

at the above solution is preferably along the circumference of the part of the guide structure, whose cross-section increases from back to front, a plurality of Partition baffles distributing the rotating flow in a plurality of rivers divide and the same to the outlet at the other end in the axial Lead direction. The partition baffles divide the initial swirling flow that forms uniformly distributed in 360 degrees, in a plurality of rivers and send them forward, at the same time, the partition baffles have an effect of transmitting the partial energy that is contained in the water flow that is rotates about the axis of rotation, in a forward thrust in the axial direction on to the forward flow of the water flow to increase.

The protein separation device according to the present invention is carried out by the following solution:
A protein separation device comprising a water inlet mechanism for supplying the water, a gas entry mechanism in communication with the atmosphere, a protein separation reactor that allows a gas-water mixture therein to react and form foams, a foam collection slot for collecting foams, a water discharge mechanism for retuming of the water from which the protein was separated, characterized in that
the protein separation device further comprises a flow propeller for receiving the water from the water inlet mechanism and the gas from the gas inlet mechanism and mixing the water and the gas and forcing the mixture forward to enter an internal reaction chamber of the protein separation reactor.

In the above solution, when the river propeller runs, it continuously generates a vortex flow containing a large amount of bubbles and flows forward, and sends the vortex flow into an inner reaction chamber of the protein separation device. At that time, the surfaces of the bubbles absorb the macromolecule substance, such as protein, and form foams, with the foams spiraling upward along with the flow of water and floating up to the surface of the water. With the help or the guiding effect of the air flow caused by the bursting When the bubbles are generated, the foams enter and collect in the collection slot. Subsequently, the vortex flow moves down into an outer reaction chamber, a part of the bubbles still forms foams after absorbing protein, then drives up to the upper end of the water, lastly the water flows back to the water via the water outflow mechanism at the lower section of the outer reaction chamber.

at such device undergoes the vortex flow passing through the river propeller is generated, no longer connection line and the vortex flow experiences no changes a flow direction through a manifold, but enters the inner reaction chamber directly in an upward direction, so that the Energy loss is lower. Furthermore, the flow of the water-and-gas mixture, which enters the inner reaction chamber, spirally forward along the axial direction of the impeller, which is the path of the vortex flow longer as a straight path, indicating the reaction time, during which the water-and-gas mixture in the reaction chamber stays longer is what enhances the effect of protein separation.

There in such a device, the surface tension is greater, could not just the protein in the water, but also the organic salt and other high molecular substances in the water through the protein separation device be separated from the water.

at the above solution could the foam collection slot is modified to a collection tower, its larger opening too the region is exposed, in which the protein separation reactor gas and water supplies, to foams to form, and there is a tube for leading out the foams above the larger opening of the Foam collecting tower provided.

at such devices as above drive the foams during operation up to the top of the reactor and then collect at the larger opening of the Collection tower. With the help of the air flow caused by the bursting of the Bubbles is generated, the foams enter the outlet pipe and flow from the aquarium and the water in which the protein is separated, flows after down into the outer reaction chamber after passing through the top of the region, then enters the water outflow mechanism from the lower part of the outer reaction chamber from and flows over the Water discharge mechanism back to the aquarium.

at above devices can the led out foams be unloaded directly from the aquarium by the outlet pipe, even be discharged directly to the sewer, therefore it is beneficial that the discharged foams can not return to the water in the aquarium.

at the above solution More preferably, the foam collection tower may be enclosed in a device shell be. Thus could the entire device except the pipe in the upper part, to be submerged in the water so taking a part of the space of the lid of the aquarium and to avoid obstruction of movement of the cover of the aquarium. Further, since the foam collecting tower does not need to be cleaned frequently, is another problem of arduous work due to the Eliminated process of removing the device from the water.

Preferably makes up the device shell, on the water inlet mechanism, the gas inlet mechanism, the protein separation reactor and the Wasserausflussmechanismus attached are an enclosed structure with a housing of foam collecting tower.

Compared with the conventional Technology assigns the protein separation device, which is the river propeller uses, benefits of a simple structure, a good fit, high efficiency and convenient installation and adjustment.

The water stirrer according to the present invention is carried out by the following solution:
A Wasserrührer having a water inlet mechanism for supplying water, a water discharge mechanism for discharging water, characterized, in that
the water stirrer further comprises a flow propeller which receives the water from the water inlet mechanism and drives the water forward, the water outflow mechanism being connected to the flow propeller at the outlet thereof.

at such a water stirrer the river propeller creates a vortex flow that flows forward and over Water outflow mechanism emerges, and the water is through the Rotational movement of the vortex flow stirred. Consequently, the problem is that foreign matter in the water is pushed into a corner or that driving Grass in the water blown and inclined to a single direction etc., which is conventional Pumps due to the flow consisted of a single direction, overcome.

In the above solution, the water stirrer preferably has an electric circuit control for controlling the electric motor, so that the Electric motor in modes of turning, stopping, changing the direction of rotation, accelerating or slowing down could run. Thus, by utilizing a directional electric motor whose direction of rotation can be changed or a non-directional electric motor in cooperation with the electric circuit control, the operating mode of the electric motor can be switched, thus changing the direction of the swirling flow.

at such stirrers could the electric motor are operated to turn, to stop, to change the direction of rotation, to accelerate or slow down, so that the vortex flow, which is generated, larger or could be smaller flow in a clockwise or counterclockwise direction and could disappear and produce the effect equal to a sea wave at the water surface could or could be divided into a plurality of sub-flows, the to flow under the water.

The present invention has the following advantages and effects:
The flow propeller according to the present invention could generate a flow which makes a rotational movement in a plane perpendicular to the forward direction as it flows forward, and thus such a flow propeller has a characteristic of being able to generate a swirling flow. It could better adapt to the flow drive mechanism of any device used in water and meet the requirements of stirring, filtering, wave-making and protein separation.

Because the impeller of the flow propeller of the present invention directly acts on the water flow, the water flow has a rotary motion around the axis, and under the guidance of the guide cylinder and the action the rear baffle is flowing the water flow forward and becomes a vortex flow. When the turning energy of the water flow is sufficiently used, is the efficiency of the river propeller higher overall and the energy loss is lower.

There the propeller according to the present Invention with a guide structure and / or front baffle plate and rear baffle plate, It helps to turn the spinning river to the water outlet to lead the front, and / or to prevent the flow of water back to the central region the impeller flows, to form a local circulation, whereby the latter is particularly suitable for generating a swirling flow with low buoyancy.

Because the flow propeller also uses a partition baffle, to divide the water flow into a plurality of spiral flows, if the majority of spiral rivers forward moves and the guide cylinder leaves, same an involute-like one spiraling river could and could be reflected several times through the wall of the aquarium and form a more complicated water flow with different flow directions.

Of the Wasserrührer, using such a flow propeller produces an excellent stirring action, and when combined with a control circuit for the electric motor is, the stirrer can used to simulate a wave or a wave to create a river.

Brief description of the drawings

1 shows a schematic view of a flow propeller according to an embodiment of the present invention.

2 shows a schematic view of a Flußpropellers according to another embodiment of the present invention.

3 shows a schematic structural view of the river propeller in 2 with the rotor, impeller, front baffle and rear baffle joined together.

4 shows a schematic view of a protein separation device according to an embodiment of the present invention.

5 shows a schematic, exploded view of the protein separation device in 4 ,

6 shows a schematic sectional view of the protein separation device in 4 ,

7 shows a schematic, exploded view of the propeller of the protein separation device in 4 ,

8th shows a schematic, bottom view of the propeller base of the protein separation device in 4 ,

9 shows a schematic view of a protein separation device according to another embodiment of the present invention.

10 shows a schematic view of a water stirrer according to an embodiment of the present invention.

11 shows a schematic, exploded view of the water stirrer in 10 ,

12 shows a schematic sectional view of the water stirrer in 10 ,

13 shows a schematic, bottom view of the water stirrer in 10 ,

14 shows a schematic view of the installation base and the dome of the water stirrer in 10 ,

Detailed description the preferred embodiments

It It should be noted that in the following description, like reference numerals, in a same embodiment used to refer to the same components, but the same Reference numerals used in different embodiments be able to refer to different components.

The embodiment The present invention will be described with reference to the accompanying drawings described as follows.

embodiment 1

The embodiment 1 is the first embodiment the river propeller according to the present Invention.

With reference to 1 The flow propeller of the present embodiment has a housing 1 , an electric motor 2 , a rotor 3 , a rotor shaft 4 , an impeller 5 , a cylinder 6 , a truncated cone 7 , a front baffle 8th , a rear baffle 9 , a front shaft seat 10 , a rear shaft seat 11 and a partition baffle 12 on. The rotor shaft 4 at the impeller 5 is attached, is between the front shaft seat 10 and the rear shaft seat 11 arranged, the truncated cone 7 and the cylinder 6 form a hollow body that covers the circumference of the impeller 5 surrounds and serves as a guide cylinder. The hollow body has a gate for allowing the rotor shaft 4 passing through it, the truncated cone 7 acts as a leadership structure. The rear baffle 9 is at the rear end of the truncated cone 7 formed and extends to the central axis of the truncated cone and the gap between the rear baffle 9 and the rotor shaft 4 is formed, acts as a water inlet. The partition baffle plate 12 is uniformly distributed in the hollow body, by the truncated cone 7 and the cylinder 6 combined, the part of the partition baffle plate 12 at the front of the impeller 5 is positioned, extends radially to the center and joins at a certain point at which the front shaft seat 10 for fixing the rotor shaft 4 is arranged, the front shaft seat 10 extends radially outwardly from the edge thereof, so as to the front baffle 8th to build.

embodiment 2

The embodiment 2 is the second embodiment the river propeller according to the present Invention.

With reference to 2 and 3 the flow propeller of the embodiment has a housing 1 , an electric motor 2 , a rotor 3 , a rotor shaft 4 , an impeller 5 , a cylinder 6 , a truncated cone 7 , a front baffle 8th , a rear baffle 9 , a front shaft seat 10 , a rear shaft seat 11 and a partition baffle 12 on. The front baffle 8th is at the front end of the impeller 5 fixed while the rear baffle 9 at the rear end surface of the impeller 5 is fixed, the end surface of the truncated cone 7 does not extend to the central axis as in Embodiment 1, but becomes an entire opening as the water inlet.

embodiment 3

The embodiment 3 is the first embodiment the protein separation device according to the present invention Invention.

With reference to 4 - 8th For example, the protein separation device of the present embodiment has a water entry mechanism 1 , a gas inlet mechanism 2 , a propeller 3 , a protein separation reactor 4 , a collection mechanism 5 and a water outflow mechanism 6 on. The propeller 3 has an electric motor 31 , a rotor-and-impeller arrangement 32 , a front baffle 33 , a river guide 34 , a propeller base 35 on.

The river guidance 34 extends from the lower portion of a guide cylinder 342 down and forms a truncated cone 341 which contracts inwardly from the upper end to the lower end to serve as a guide structure. A rear baffle 345 that extends to the center, and a mounting base 343 which extends downwards are at the lower end of the truncated cone 341 formed, a plurality of partition baffles 344 from the inner wall of the truncated cone 341 protrude, continue to extend upward along the inner wall of the guide cylinder 342 , The rotor-and-impeller arrangement 32 is in a rotor chamber at the propeller base 35 attached, the electric motor 31 is in an Elek tromotor base below the propeller base 35 attached. At the propeller base 35 are a water inlet 351 and a gas inlet 352 educated. The front baffle 33 is at the front end of the impeller of the rotor-and-impeller assembly 32 attached and the river guidance 34 is at the propeller base 35 over the attachment base 343 the same attached. The rear baffle 345 , the propeller base 35 and the attachment base 343 form a water-gas mixing chamber 36 between them. The gas inlet mechanism 2 is with the gas inlet 352 the propeller base 35 of the propeller 3 connected via a pipe. The water to be separated enters the water inlet 351 the propeller base 35 over the water inlet 12 at a base 11 the water inlet mechanism 1 one.

The protein separation reactor 4 includes an inner reactor 41 and an outer reactor 42 , The outer reactor 42 is a part of the shell and forms the reaction chamber with the propeller base 35 and the foam collection slot 51 ; the lower portion of the inner reactor 41 forms a step that protrudes outward through which the inner reactor 41 to the guide cylinder 342 the river guidance 34 of the propeller 3 is appropriate. The propeller base 35 has a water outlet 353 on that with the water outflow mechanism 6 connected is. The water discharge mechanism 6 includes a throttle 51 for adjusting the flow rate of the water being discharged and a connecting pipe 52 ,

When water and gas enter the water-gas mixing chamber 36 over the water inlet 351 and the gas inlet 352 enter, the water and the gas are under the action of the impeller of the rotor-and-impeller arrangement 32 sufficiently mixed and form a vortex flow. Then the vortex flow through the flow guide 34 led and converted to flow upwards while the front baffle 33 and the rear baffle 345 prevent the water from forming a local reflux at the front and rear ends of the impeller. When the impeller forces to flow the water to the front, creating a high pressure zone at the outer edge of the impeller, and a low pressure zone is created in the center. The water and the gas in the water-gas mixing chamber 36 are sucked in by the low pressure in the middle, causing the water and gas to supplement through the water inlet 12 the water inlet mechanism 1 or the gas inlet mechanism 2 incessantly enter into it.

Thereafter, the water flow spirals up and enters the inner reactor 41 of the protein separation reactor 4 and continues to spiral upward in the inner reactor 41 , Here small bubbles absorb the macromolecule materials, such as protein, under the action of surface tension and form foams. Then the foams move together with the water flow helically upwards and contact the same with the help of which is generated by the bursting of the bubbles of the air flow, into the collection slot 51 the collection mechanism 5 and collect in the same or be through the outlet line 52 out of the aquarium. The water entering the outer reaction chamber is still spiraling and sinking and some bubbles react with the water in the outer reactor, these bubbles absorb the protein in the water and form foams leading to the collection mechanism 5 float. After entering the lower part of the outer reactor, the water flow flows downwards and over the water outlet 353 the propeller base into the water outflow mechanism 6 a, then the water flow flows back to the aquarium over the connecting line 61 and the throttle 62 , The throttle 62 can be used to len einzustel the level of the water surface in the reactor and to control the amount and rate at which enter the foams into the collecting mechanism.

embodiment 4

The embodiment 4 is the second embodiment the protein separation device according to the present invention Invention.

With reference to 9 the protein separation device of an aquarium is characterized in that: the inlet of the foam collection slot 6 is formed as an inverted funnel, exposing its downwardly larger opening to the region to which the protein separation reactor supplies gas and water to form foams, and an exit tube 8th is provided for leading out the foams over the foam collecting slot. Further, the device shell forms 9 in which the water inlet mechanism 1 , the gas entry mechanism 2 , the propeller, the protein separation reactor 5 and the water outflow mechanism 7 attached, an enclosed structure in cooperation with the sheath of the foam collecting slot 6 ,

In this way, the foams reaching the collection slot are discharged via a conduit through the larger opening of the collection slot. In addition, the water in the aquarium can not enter the foam collecting slot through side walls of the device shell, which would allow the whole device, except for the upper portion of the tube, to be submerged for use in the water. By adjusting the height of the foam outlet in the pipe, moreover, the entire apparatus can be adapted to different heights be adapted in the water.

at the present embodiment are the omitted content similar this embodiment Third

embodiment 5

The embodiment 5 is an embodiment of the water stirrer according to the present Invention.

With reference to 10 - 14 For example, the water stirrer of the present invention has a housing 1 , an electric motor 2 , a rotor 3 , a rotor shaft 4 , an impeller 5 , a cylinder 6 , a truncated cone 7 , a front baffle 8th , a rear baffle 9 , a front shaft seat 10 , a rear shaft seat 11 , a partition baffle 12 , a mounting frame 13 and a dome 14 on. The rotor shaft 4 at which the rotor 3 and the impeller 5 are fixed, after they are connected together, is between the front shaft seat 10 and the rear shaft seat 11 arranged. The truncated cone 7 and the cylinder 6 form a hollow body, which is the impeller 5 surrounds and serves as a guide cylinder. The hollow body has a gate for allowing the rotor shaft 4 passing through it, the truncated cone 7 acts as a leadership structure. The rear baffle 9 is formed at the rear end of the truncated cone and extends to the central axis of the truncated cone, the intermediate space between the rear deflector plate 9 and the rotor shaft 4 is formed, acts as a water inlet. The partition baffle plate 12 is uniformly distributed in the hollow body, by the truncated cone 7 and the cylinder 6 combined, the part of the partition baffle plate 12 at the front end of the impeller 5 is positioned, extends radially to the center and joins at a certain point at which the front shaft seat 10 for fixing the rotor shaft 4 is arranged, the front baffle plate 8th is designed to extend from the edge of the front shaft seat 10 extend radially outward.

The housing 1 includes a front cover 1a , a back cover 1b , a housing base 1c that have a convex arch 1f forms at the lower end. The mounting frame 13 is in the middle of it with a concave arch 141 designed to match the bow, the concave bow 141 has a sliding slot 142 in the form of a strip. The housing 1 is on the mounting frame 13 through a screw 1d and a mother 1e through the base 1c attached and is by the screw 1d slidable in the sliding slot 142 moved and is due to the fit between the concave arch 141 and the convex arch 1f slidable along the sliding slot 142 adjustable. Because the screw 1d in the sliding slot 142 can slide and turn and the dome 14 allows the sliding slot 142 of the mounting frame 13 could be attached at any angle, could the housing 1 be set in an angular range to a certain extent, so that the orientation of the water outlet of the front cover could be set arbitrarily. The dome 14 could be fixed to the inner wall of the aquarium.

Claims (13)

A flow propeller in which an impeller is driven by an electric motor via a rotor and continuously discharges the water in a tangential direction and a radial direction while driving the water to rotate about an axis of rotation, characterized in that: the impeller at the periphery thereof is provided with a guide cylinder, the cylinder prevents the water from flowing outwardly, and allows the water to rotate therein, and generates an axial flow due to the accumulation of water, a rear baffle at the rear end of the impeller in the axial direction to prevent the ejected water from flowing from the high pressure zone at the outer edge of the impeller to the low pressure zone at the center of the impeller via the rear end of the impeller, a front baffle at the outer end of the impeller Impellers arranged in the axial direction to prevent the ejected water from the high pressure zone at the outer edge of the impeller to the low pressure zone at the center of the impeller flows over the front end surface of the impeller, a water inlet is disposed at the central region of the rear baffle, and the leading end of the guide cylinder is used as the water outlet. The flow propeller according to claim 1, characterized that the guide cylinder and the impeller at corresponding positions at an equal level are arranged, the flow propeller further has a guide structure for further guidance of the rotating flow to a water outlet at the outer end in the axial direction and the cross section of a part the management structure gets bigger from back to front. The river propeller according to claim 2, characterized that along the circumference of the part of the guide structure whose cross section is from getting bigger in the back, a plurality of partition baffles is distributed, the to divide the rotating river into a plurality of rivers and to feed them the outlet at the outer end in lead the axial direction. The flow propeller according to claim 3, characterized that part of the partition baffle that is at the front end of the impeller is positioned radially to the center and united at a certain place, at the front Wellensitz is arranged, wherein the front shaft seat radially from the edge of the same to the outside extends to form the front baffle. The flow propeller according to claim 3, characterized that the front baffle is attached to the impeller and can rotate together with the impeller. The flow propeller according to any one of claims 2-5, characterized characterized in that the leadership structure extends to the central axis at the rear end so as to to form the rear baffle. A protein separation device that has a water entry mechanism for feeding the water, a gas inlet mechanism in communication with the atmosphere, a protein separation reactor that allows a gas-water mixture in the same reacts and foams forms, a foam collection slot for collecting foams, a Water discharge mechanism for returning the water, from the the protein has been separated, characterized in that the protein separation device further comprises a flow propeller according to the claims 1-6 to Picking up the water from the water inlet mechanism and the Gas from the gas inlet mechanism and mixing the water and the gas and forcing the mixture forward to into an inner Reaction chamber of the protein separation reactor enter has. The protein separation device according to claim 7, characterized in that that the inlet of the foam collection slot as a reverse funnel is shaped, the downwardly larger opening of the same is exposed to the region to which the protein separation reactor Supplying gas and water, to foams to form, and an outlet pipe for leading out the foams above the foam collecting slot is provided. The protein separation device according to claim 8, characterized in that the foam collection slot is enclosed in a device shell. The protein separation device according to claim 9, characterized in that that the device shell, in which the water inlet mechanism, the gas inlet mechanism, the river propeller, the protein separation reactor and the Wasserausflussme mechanism are fixed, with a housing Foam collection slot forms a trapped structure. A water stirrer, a water inlet mechanism for supplying water, a Wasserausflussmechanismus for discharging water, characterized in that the Wasserrührer Further, a flow propeller according to a the claims 1-6, which absorbs the water from the water inlet mechanism and the water forward drives, wherein the Wasserausflussmechanismus at the outlet thereof connected to the river propeller. The water stirrer according to claim 11, characterized in that the water stirrer further comprises an electrical circuit control for controlling the electric motor of the river propeller to itself to turn, to stop, to change the direction of rotation, to accelerate or to slow down. The water stirrer according to claim 11 or 12, characterized in that the water stirrer further a housing and a mounting frame, a convex arc on the lower end of the housing is formed and the mounting frame with a concave arc is formed, which corresponds to the convex arc in the middle, the concave arc has a sliding slot in the form of a strip, the housing on the mounting frame through the fit between the concave Bow and the convex bow is attached.