WO2018157553A1

WO2018157553A1 - Protein separation structure

Info

Publication number: WO2018157553A1
Application number: PCT/CN2017/096388
Authority: WO
Inventors: 章晓俊; 刘文学; 孙晓磊; 贾海松
Original assignee: 深圳市泓亚水族设备制造有限公司
Priority date: 2017-03-03
Filing date: 2017-08-08
Publication date: 2018-09-07
Also published as: CN206635070U; JP3224668U

Abstract

Disclosed is a protein separation structure comprising a reaction chamber (3) and a waste liquid collection cup (1) connected to an upper end of the reaction chamber (3), wherein a water pump (7) and a compression chamber (9) communicating with the water pump (7) are provided in the reaction chamber (3), the bottom of the compression chamber (9) is provided with a spiral channel (91), the top of the compression chamber (9) is provided with a sieve plate (8), the sieve plate (8) is provided with a spiral sieve hole (81) turning in the same direction as the spiral channel (91), and the water pump (7) pumps water through the spiral channel (91) to the compression chamber (9); and water strikes the sieve plate (8) and is sprayed into the reaction chamber (3) via the spiral sieve hole (81). The protein separation structure has a high foaming efficiency, improving the precision of water level control.

Description

Protein separation structure

Technical field

The present invention relates to a water purification apparatus, and more particularly to a protein separation structure.

Background technique

The existing protein separator, although functionally capable of satisfying protein separation to purify water quality, has many unsatisfactory performances, such as weak foaming performance, inconspicuous purification effect, and The noise generated during use is large, and the external muffler is used to affect the overall coordination of the device. In addition, most of the water level adjustment is regulated by a water valve, and the control precision is not high. Based on the current situation, it is necessary to propose an improved protein separation structure. .

Summary of the invention

The object of the present invention is to overcome the deficiencies of the prior art, and provide a protein separation structure with high foaming efficiency, obvious purification effect, and effectively integrating the noise elimination device into the body of the protein separation device, and further improving the accuracy of the water level control. , grasp the quality of purification of water.

In order to solve the above technical problem, a protein separation structure provided by an embodiment of the present invention is improved in that it comprises a reaction chamber and a waste liquid collection cup connected to an upper end of the reaction chamber, and a water pump and a water pump are arranged in the reaction chamber. a closed compression chamber, a bottom of the compression chamber is provided with a spiral passage, and a top of the compression chamber is provided with a sieve plate, and the sieve plate is provided with a spiral sieve hole that is turned in the same direction as the spiral passage, and the water pump pumps the water body through the spiral passage pump To the compression chamber; the water body impacts the sieve plate through the spiral sieve hole to spray into the reaction chamber.

In the above structure, the water inlet end of the water pump is connected to the water inlet provided outside the reaction chamber, and The radial side wall of the nozzle is provided with an air inlet communicating with the water inlet. When the water pump pumps water through the water inlet, the negative pressure generated at the water inlet is extracted from the air inlet and mixed into the water body.

In the above structure, the waste liquid collecting cup and the reaction chamber are connected by an annular muffler, and the annular muffler is provided with an air inlet hole, an air outlet port and a sound absorbing passage, and the air inlet hole and the air outlet port pass through the ring shape. The muffling passages inside the muffler are in communication with each other, and the outlet port exposes one end of the annular muffler and communicates with the intake port through an intake pipe.

In the above structure, one side of the reaction chamber is provided with a water level regulator that communicates with the bottom of the reaction chamber, and the water level regulator includes an outlet pipe provided with a water outlet, the outlet pipe has an adjustment rod built therein, and the adjustment rod The bottom of the adjusting rod is connected with a plug attached to the inner wall of the water outlet pipe. The top of the adjusting rod is engaged with a knob through a rack, and the rotating knob engages the driving rack. The adjusting rod drives the bottom plug to move up and down along the water outlet pipe to adjust the water outlet. The flow of water.

In the above structure, the quick release structure for fixing the bottom plate of the reaction chamber to the mounting plate is further included.

In the above structure, the quick release structure is a bolt adjusting hole disposed on the bottom plate, the bolt is fixed to the mounting plate through the screw adjusting hole, and the bottom plate is rotated relative to the mounting plate, and the bolt slides along the bolt adjusting hole, and the bolt adjusting hole has at least one The larger end of the bolt can be passed through.

In the above structure, the quick release structure includes a rotary tongue rotatable about a bolt, and a lower end of the rotary tongue is provided with a mouth for the bottom plate to be buckled, and the rotary tongue is mounted on the fixed plate by bolts.

In the above structure, the quick release structure includes a push block provided with a bolt adjusting hole, the bolt is connected to the mounting plate through the bolt adjusting hole, and the push block is pushed along the bolt adjusting hole, and the pressing plate on the side of the push block is pressed against the bottom plate. Surface, lock the bolts and secure the bottom plate to the mounting plate.

In the above structure, the quick release structure includes a fixing block fixed to the mounting plate by bolts and a movable block inserted into the fixing block, the latch of the movable block penetrating the side end of the fixing block, and pressing the bottom plate to be mounted On the board.

In the above structure, the side of the latch is provided with a gusset on the side end of the latch. When the latch is inserted into the fixed block, a gap is left between the gusset and the fixed block.

Embodiments of the present invention have the following beneficial effects:

In the embodiment of the present invention, the protein separation structure provided by the invention has high foaming efficiency, obvious purification effect, and effectively integrates the noise elimination device into the body of the protein separation device, and further improves the accuracy of the water level control and grasps the water body. Purify the quality.

DRAWINGS

1 is a perspective view of a protein separation structure in an embodiment of the present invention.

2 is a diagram showing the internal structure of a protein separation structure in an embodiment of the present invention.

3 is a schematic view showing the internal structure of a ring muffler according to an embodiment of the present invention.

4 is a schematic view showing the structure of a compression chamber and its connection with a water pump according to an embodiment of the present invention.

Figure 5 is a schematic view showing the working state of a protein separation structure in an embodiment of the present invention.

FIG. 6 is a schematic diagram of a quick release structure according to an embodiment of the present invention.

In the figure: 1, waste liquid collection cup; 2, ring muffler; 3, reaction chamber; 4, intake pipe; 5, water inlet; 6, water level adjuster; 7, water pump; 8, sieve plate; 10, compressed warehouse inlet pipe; 11, mounting plate; 12, rotating tongue; 13, push block; 14, fixed block; 15, movable block; 21, air intake hole; 22, air outlet; 23, noise elimination channel; , bottom plate; 41, air inlet; 61, outlet pipe; 62, adjusting rod; 63, knob; 64, plug; 81, spiral screen hole; 91, spiral passage; 611, water outlet; 621, rack; , mouth; 131, bolt adjustment hole; 132, pressure plate; 151, latch; 152, gusset.

detailed description

The present invention is further described below in conjunction with the accompanying drawings and specific embodiments.

Referring to Figures 1 to 6, the present invention discloses a protein separation structure comprising a reaction chamber 3 and a waste liquid collection cup 1 connected to the upper end of the reaction chamber 3, and a water pump 7 and a water pump 7 are disposed in the reaction chamber 3. The compression chamber 9 is connected, specifically, the compression chamber 9 can be connected to the water outlet of the water pump 7 through the compression tank inlet pipe 10; the bottom of the compression chamber 9 is provided with a spiral passage 91, and the top of the compression chamber 9 is provided with a sieve plate 8, The sieve plate 8 is provided with a spiral screen 81 which is turned in the same direction as the spiral passage 91. The water pump 7 pumps the water body through the spiral passage 91 to the compression chamber 9; the water body impact sieve plate 8 is sprayed to the reaction chamber 3 through the spiral sieve hole 81. The impact mode of the spiral can stimulate the generation of bubbles in the water body, thereby improving the foaming efficiency, and the purification effect is obvious. The spiral method can rotate the water body at high speed for centrifugal motion, and the kinetic energy generated is much higher than the direct type, and the amount of foam directly affects. Adsorption of proteins in water.

Further, the water inlet end of the water pump 7 is in communication with the water inlet 5 disposed outside the reaction chamber 3, the radial side wall of the water inlet 5 is provided with an air inlet 41 communicating with the water inlet 5, and the water pump 7 is connected to the water inlet 5 When pumping water, the negative pressure generated at the water inlet 5 is extracted from the air inlet 41 and mixed into the water body. At the same time of drawing the water body, the generated negative pressure is used to pump the air, so that the air is mixed into the water body and pumped to the compression chamber. 9, the amount of bubbles produced is significantly more, and this arrangement does not require special equipment to inject gas into the foaming process.

Further, the waste liquid collecting cup 1 and the reaction chamber 3 are connected by an annular muffler 2, and the annular muffler 2 is provided with an air inlet hole 21, an air outlet port 22, and a sound absorbing passage 23, between the air inlet hole 21 and the air outlet port 22. The air vent 22 is connected to the air venting passage 2 and the air venting passage 2 is connected to the air inlet 41 through the air inlet tube 4. The noise absorbing design integrated in the connecting member saves space for the device. Moreover, the overall feeling is good, thereby avoiding the bad effect that the sound absorbing device independently disposed on the outside of the device brings a sudden abruptness to the whole.

Further, one side of the reaction chamber 3 is provided with a water level regulator that communicates with the bottom of the reaction chamber 3. The water level regulator includes an outlet pipe 61 provided with a water outlet 611, and the outlet pipe 61 has an adjustment rod 62 built therein, and the bottom of the adjustment rod 62 The plug 64 is attached to the inner wall of the water outlet pipe 61. The top of the adjusting rod 62 is engaged with the knob 63 through the rack 621. The rotating knob 63 engages the driving rack 621. The adjusting rod 62 drives the bottom plug 64 along the water outlet pipe 61. Up and down movement to adjust the water flow rate of the water outlet 611, the engagement of the knob 63 and the rack 621 can effectively control the displacement of the plug 64 up and down movement, thereby achieving the blockage of the water outlet 611 by the plug 64, and the control precision is directly derived from the rack. 621 inter-tooth gap, easy to adjust adjustment, water level adjustment High degree.

Further, a quick release structure for fixing the bottom plate 31 of the reaction chamber 3 to the mounting plate 11 is further included, and the quick release structure effectively improves the installation and disassembly efficiency of the device.

Further, the quick release structure is a bolt adjusting hole 131 disposed on the bottom plate 31. The bolt is fixed to the mounting plate 11 through the screw adjusting hole, and the bottom plate 31 is rotated relative to the mounting plate 11, and the bolt slides along the bolt adjusting hole 131, and the bolt is adjusted. At least one hole 131 can be passed through the larger end of the bolt, so that the bottom plate 31 can be fixed on the mounting plate 11 only by loosening or tightening the bolt, and the hole alignment can be reduced by the bolt adjusting hole 131. Difficulty.

Further, the quick release structure includes a rotary tongue 12 rotatable around the bolt, and the lower end of the rotary tongue 12 is provided with a mouth 121 for the bottom plate 31 to be buckled, and the rotary tongue 12 is mounted on the fixed plate by bolts. The utility model can be flexibly applied. When the size of the base is not fixed, the height of the mouth 121 can be adjusted according to actual needs. When the rotating tongue 12 is rotated to be attached to the base, the mouth 121 can press the base against the fixed plate.

Further, the quick release structure includes a push block 13 provided with a bolt adjusting hole 131. The bolt is connected to the mounting plate 11 through the bolt adjusting hole 131, and the push block 13 is pushed along the bolt adjusting hole 131, and the pressing plate 132 on the side of the push block 13 is pushed. The upper surface of the bottom plate 31 is pressed against, the bolt is locked, and the bottom plate 31 is fixed to the mounting plate 11.

Further, the quick release structure includes a fixing block 14 fixed to the mounting plate 11 by bolts and a movable block 15 interposed with the fixing block 14, the pin 151 of the movable block 15 penetrating the side end of the fixing block 14, and the bottom plate 31 is Pressed on the mounting plate 11.

Further, a latching plate 152 is disposed on the side of the latching member 151. When the latching pin 151 is inserted into the latching block 151, a gap is left between the latching plate 152 and the fixing block 14 so as to facilitate the latching of the latching plate 152. The pin 151 of the movable block 15 is separated from the fixed block 14, and the detaching device can be removed, which is extremely easy to use.

The above description is only the preferred embodiment of the present invention, and the above specific embodiments are not intended to limit the present invention. Various variations and modifications can be made within the scope of the technical idea of the present invention. Modifications, modifications, or equivalent substitutions made by the skilled person in light of the above description are within the scope of the invention.

Claims

A protein separation structure, comprising: a reaction chamber and a waste collection cup connected to an upper end of the reaction chamber, wherein the reaction chamber is provided with a water pump and a compression chamber connected to the water pump, and the bottom of the compression chamber is provided with a spiral a channel, a top of the compression chamber is provided with a sieve plate, the sieve plate is provided with the same spiral sieve hole as the spiral passage, the water pump pumps the water body to the compression chamber through the spiral passage; the water body impacts the sieve plate through the spiral sieve hole Spray to the reaction chamber.
A protein separation structure according to claim 1, wherein the water inlet end of the water pump is in communication with a water inlet disposed outside the reaction chamber, and the radial side wall of the water inlet is provided to communicate with the water inlet. The air inlet, when the water pump pumps water through the water inlet, the negative pressure generated at the water inlet is extracted from the air inlet and mixed into the water body.
The protein separation structure according to claim 2, wherein the waste liquid collecting cup and the reaction chamber are connected by an annular muffler, and the annular muffler is provided with an air inlet hole, an air outlet, and a sound elimination passage. The air inlet hole and the air outlet port communicate with each other through a sound attenuating passage inside the annular muffler, and the air outlet port exposes one end of the annular muffler and communicates with the air inlet through an intake pipe.
A protein separation structure according to any one of claims 1 to 3, wherein one side of the reaction chamber is provided with a water level regulator communicating with the bottom of the reaction chamber, and the water level regulator includes The outlet pipe has a water outlet, the outlet pipe has an adjustment rod built therein, and the bottom of the adjustment rod is connected with a plug attached to the inner wall of the water outlet pipe, and the top of the adjustment rod is engaged with a knob through a rack, and the rotary knob is engaged The transmission rack and the adjusting rod drive the bottom plug to move up and down along the water outlet pipe to adjust the outlet flow of the water outlet.
A protein separation structure according to claim 4, further comprising a quick release structure for fixedly attaching the bottom plate of the reaction chamber to the mounting plate.
The protein separation structure according to claim 5, wherein the quick release structure is a bolt adjusting hole provided on the bottom plate, and the bolt is fixed to the mounting plate through the screw adjusting hole, and the bottom plate is rotated relative to the mounting plate. , the bolt slides along the bolt adjusting hole, and at least one bolt adjusting hole is available for the bolt The larger end passes through.
A protein separation structure according to claim 5, wherein said quick release structure comprises a rotary tongue rotatable about a bolt, and a lower end of said rotary tongue is provided with a mouth for the bottom plate to be snapped, said rotary tongue Mounted on the mounting plate by bolts.
A protein separation structure according to claim 5, wherein the quick release structure comprises a push block provided with a bolt adjusting hole, and the bolt is connected to the mounting plate through the bolt adjusting hole, and is pushed along the bolt adjusting hole. The block, the pressure plate on the side of the push block is pressed against the upper surface of the bottom plate, the bolt is locked, and the bottom plate is fixed on the mounting plate.
A protein separation structure according to claim 5, wherein said quick release structure comprises a fixing block fixed to the mounting plate by bolts and a movable block interposed with the fixing block, the pin of the movable block being worn Pass through the side end of the block and press the bottom plate against the mounting plate.
The protein separation structure according to claim 9, wherein the movable block is provided with a gusset plate at a side end of the plug, and when the plug is inserted into the fixed block, the gusset plate and the fixed block are left. There is a gap.