CN114656049A - A energy-saving suspension aeration machine for water environment is administered - Google Patents

Abstract

The invention is suitable for the technical field of water environment treatment, and particularly relates to an energy-saving suspension aerator for water environment treatment, which comprises a shell and a floating ball arranged outside the shell, wherein a gas inlet mechanism is arranged inside the shell and is connected with a gas inlet pipe and a gas outlet pipe, the gas inlet pipe and the gas outlet pipe both penetrate through the shell, a first hollow pipe is arranged outside the gas outlet pipe and penetrates through the shell, one end of the first hollow pipe penetrating through the shell is provided with a stirring blade, the gas outlet pipe penetrates through two ends of the first hollow pipe, and the first hollow pipe is connected with a rotating mechanism and a lifting mechanism; the device drives the stirring blades to rotate and reciprocate up and down through the rotating mechanism and the lifting mechanism, thereby playing a role in cleaning impurities around the air outlet pipe, avoiding the phenomenon that the air outlet pipe mouth is blocked by the impurities and improving the aeration efficiency.

Description

A energy-saving suspension aeration machine for water environment is administered

Technical Field

The invention relates to the technical field of water environment treatment, in particular to an energy-saving suspension aerator for water environment treatment.

Background

In the water treatment process, an aeration device is a key device for the pretreatment of water supply organisms and the biological treatment of sewage, and oxygen in air is transferred into liquid in an aeration tank through the aeration device so as to supply oxygen required by metabolism of aerobic organisms, thereby achieving the aim of biological treatment.

Aeration machine generally floats on the surface of water when using, and wherein aeration machine is connected with the trachea, and the trachea extends to the aquatic, and under aeration machine's effect, oxygen in the air enters into tracheal inside, then enters into the aquatic to reach the biological treatment purpose.

However, when the aeration machine in the prior art is used for treating water environment, various impurities often exist in water, and the air pipe is blocked by the impurities in the water in the air conveying process, so that the aeration effect is influenced.

Disclosure of Invention

The invention aims to provide an energy-saving suspension aerator for water environment treatment, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an energy-saving suspension aerator for water environment treatment comprises a shell and a floating ball arranged outside the shell, wherein an air inlet mechanism is arranged inside the shell and is connected with an air inlet pipe and an air outlet pipe, the air inlet pipe and the air outlet pipe both penetrate through the shell, a first hollow pipe is arranged outside the air outlet pipe and penetrates through the shell, one end of the first hollow pipe penetrating through the shell is provided with a stirring blade, the air outlet pipe penetrates through two ends of the first hollow pipe, and the first hollow pipe is connected with a rotating mechanism and a lifting mechanism;

the air inlet mechanism is used for conveying oxygen in the air to water and driving the rotating mechanism and the lifting mechanism to operate;

the rotating mechanism is used for driving the first hollow pipe to rotate so as to rotate the stirring blade;

the lifting mechanism is used for driving the first hollow pipe to reciprocate, so that the stirring blade reciprocates.

Further: the air inlet mechanism comprises a piston cylinder, a piston is arranged in the piston cylinder, the piston is connected with a telescopic assembly, the telescopic assembly is used for driving the piston to reciprocate, the air inlet pipe and the air outlet pipe are communicated with the piston cylinder and located on one side, close to the telescopic assembly, of the piston, and one-way valves are arranged on the air inlet pipe and the air outlet pipe.

Further: the piston cylinder is characterized in that a first shunt pipe and a second shunt pipe are arranged on the side wall of the piston cylinder, the first shunt pipe and the second shunt pipe are both located on one side, away from the telescopic assembly, of the piston, one-way valves are arranged on the first shunt pipe and the second shunt pipe, the first shunt pipe is communicated with the air inlet pipe through a three-way joint, and the second shunt pipe is communicated with the air outlet pipe through a three-way joint.

Further: the telescopic assembly comprises a motor, the motor is installed on a supporting plate, the supporting plate is fixedly connected with the inner wall of the shell, a first gear is arranged at the output end of the motor, one side, far away from the motor, of the first gear is movably connected with a first connecting rod in an eccentric arrangement, the first connecting rod is movably connected with a second connecting rod, and the second connecting rod penetrates through the supporting plate and the piston cylinder and is connected with the piston.

Further: the slewing mechanism includes the second hollow tube, the outside of second hollow tube is equipped with the second gear, the second gear is provided power by air inlet mechanism, the both ends of second hollow tube are run through to the outlet duct, the second hollow tube runs through the one end that first hollow tube is located the shell inside, be equipped with spacing subassembly between first hollow tube and the second hollow tube, spacing subassembly is used for spacing first hollow tube to make the second hollow tube can drive first hollow tube and rotate.

Further: the limiting assembly comprises a limiting block which is arranged inside the first hollow pipe and is fixedly connected with the second hollow pipe, a limiting groove is formed in the inner wall of the second hollow pipe, and the limiting block is located inside the limiting groove and is in sliding connection with the limiting groove.

Further: the lifting mechanism comprises a bearing, the bearing is sleeved outside the first hollow pipe, a supporting rod is arranged outside the bearing, a reset component is arranged on one side of the supporting rod, an extrusion component is arranged on the other side of the supporting rod, and the reset component and the extrusion component are used for driving the supporting rod to reciprocate.

Further: the extrusion assembly comprises a moving block arranged inside the shell, the moving block is movably connected with a third connecting rod, the other end of the third connecting rod is provided with a cam for extruding the supporting rod, a rotating rod penetrates through the inside of the cam, and the rotating rod is fixedly connected with the inner wall of the shell.

Further: one end of the support rod, which is close to the cam, is rotatably connected with a roller, and the roller is attached to the side face of the cam.

Compared with the prior art, the invention has the beneficial effects that: the utility model provides an energy-saving suspension aeration machine for water environment is administered, this device is under the effect of air inlet mechanism, oxygen in the air loops through the intake pipe, air inlet mechanism, the outlet duct enters into the aquatic, thereby reach the purpose of aeration, wherein the outlet duct runs through there is first hollow tube, be equipped with the stirring leaf on the first hollow tube, drive the stirring leaf through slewing mechanism and elevating system and rotate and up-and-down reciprocating motion, thereby the effect of a clearance has been played to impurity around the outlet duct, thereby the phenomenon that impurity will give vent to anger the mouth of pipe and stop up has been avoided, aeration efficiency has been improved, in addition rabbling mechanism and elevating system provide power by air inlet mechanism, the multi-purpose function of air inlet mechanism has been realized, the energy has been practiced thrift.

Drawings

Fig. 1 is a front view of the overall structure of an energy-saving suspension aerator for water environment treatment.

Fig. 2 is a front view of an air inlet mechanism of an energy-saving suspension aerator for water environment treatment.

Fig. 3 is a front view of an energy-saving suspension aerator telescopic assembly for water environment treatment.

Fig. 4 is a front view of a rotating mechanism of an energy-saving suspension aerator for water environment treatment.

Fig. 5 is a front view of an energy-saving suspension aerator lifting mechanism for water environment treatment.

Fig. 6 is a schematic diagram of an energy-saving suspension aerator limiting assembly for water environment treatment.

In the figure: 1-shell, 2-floating ball, 3-air inlet pipe, 4-air outlet pipe, 5-first hollow pipe, 6-stirring blade, 7-air inlet mechanism, 71-telescopic component, 711-second connecting rod, 712-first connecting rod, 713-first gear, 714-motor, 715-supporting plate, 72-piston cylinder, 73-piston, 74-first shunt pipe, 75-second shunt pipe, 76-one-way valve, 8-lifting mechanism, 81-extrusion component, 811-moving block, 812-third connecting rod, 813-rotating rod, 814-cam, 815-roller, 82-resetting component, 83-supporting rod, 84-bearing, 9-rotating mechanism, 91-limiting component, 911-limiting block, 912-a limit groove, 92-a second gear and 93-a second hollow tube.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

In this embodiment, please refer to fig. 1, an energy-saving suspension aerator for water environment treatment includes a housing 1 and a floating ball 2 disposed outside the housing 1, wherein an air inlet mechanism 7 is disposed inside the housing 1, the air inlet mechanism 7 is connected to an air inlet pipe 3 and an air outlet pipe 4, the air inlet pipe 3 and the air outlet pipe 4 both penetrate through the housing 1, a first hollow pipe 5 is disposed outside the air outlet pipe 4, the first hollow pipe 5 penetrates through the housing 1, one end of the first hollow pipe 5 penetrating through the housing 1 is provided with a stirring blade, the air outlet pipe 4 penetrates through two ends of the first hollow pipe 5, and the first hollow pipe 5 is connected to a rotating mechanism 9 and a lifting mechanism 8;

the air inlet mechanism 7 is used for conveying oxygen in the air to water and driving the rotating mechanism 9 and the lifting mechanism 8 to operate;

the rotating mechanism 9 is used for driving the first hollow pipe 5 to rotate, so that the stirring blade 6 rotates;

the lifting mechanism 8 is used for driving the first hollow pipe 5 to reciprocate, so that the stirring blade 6 reciprocates.

In the embodiment, when the device is used, the shell 1 floats on the water surface under the action of the floating ball 2, the air outlet pipe 4 is inserted into the water, the air inlet pipe 3 is positioned above the water surface, and oxygen in the air sequentially passes through the air inlet pipe 3, the air inlet mechanism 7 and the air outlet pipe 4 to enter the water under the action of the air inlet mechanism 7, so that the aeration purpose is achieved; in addition outlet duct 4 runs through there is first hollow tube 5, be equipped with stirring vane 6 on the first hollow tube 5, drive stirring vane 6 through slewing mechanism 9 and elevating system 8 and rotate and up-and-down motion, thereby impurity to 4 peripheries of outlet duct has played the effect of a clearance, thereby the phenomenon that 4 mouths of outlet duct were plugged up to impurity has been avoided, aeration efficiency has been improved, in addition rabbling mechanism and elevating system 8 provide power by air inlet mechanism 7, 7 multi-purpose functions of mechanism 7 have been realized admitting air, the energy has been practiced thrift.

In another embodiment, referring to fig. 1-2, the air inlet mechanism 7 includes a piston cylinder 72, a piston 73 is disposed inside the piston cylinder 72, the piston 73 is connected to a telescopic assembly 71, the telescopic assembly 71 is configured to drive the piston 73 to reciprocate, the air inlet pipe 3 and the air outlet pipe 4 are both communicated with the piston cylinder 72 and are located on one side of the piston 73 close to the telescopic assembly 71, and the air inlet pipe 3 and the air outlet pipe 4 are both provided with a check valve 76.

In this embodiment, this device is when carrying out the aeration, drive piston 73 up-and-down reciprocating motion through telescopic component 71, when piston 73 downstream, a negative pressure can be formed to the top of piston 73, the inside that the air entered piston cylinder 72 through intake pipe 3 under the effect of check valve 76 this moment, when piston 73 upward movement, the air of its top is extruded to piston 73, the air enters the inside of outlet duct 4 under the effect of check valve 76 this moment, enter into aquatic at last and aerate, wherein the gas reflux phenomenon has been avoided in the setting of check valve 76, air inlet mechanism 7 can also be replaced with the air pump in addition, the air pump is connected with outlet duct 4 and intake pipe 3.

In another embodiment, referring to fig. 2, a first shunt pipe 74 and a second shunt pipe 75 are disposed on a side wall of the piston cylinder 72, the first shunt pipe 74 and the second shunt pipe 75 are both located on a side of the piston 73 away from the telescopic assembly 71, a check valve 76 is disposed on each of the first shunt pipe 74 and the second shunt pipe 75, the first shunt pipe 74 is communicated with the air inlet pipe 3 through a three-way joint, and the second shunt pipe 75 is communicated with the air outlet pipe 4 through a three-way joint.

In this embodiment, when the piston 73 moves upward, a negative pressure is formed below the piston 73, at this time, air enters the inside of the piston cylinder 72 through the air inlet pipe 3, the three-way joint and the first shunt pipe 74 under the action of the check valve 76, when the piston 73 moves downward, the piston 73 extrudes the air below the piston, at this time, the air enters water through the second shunt pipe 75, the three-way joint and the air outlet pipe 4 under the action of the check valve 76, and thus, the rate of the air entering the water is increased, and the aeration efficiency is increased.

In another embodiment, referring to fig. 3, the telescopic assembly 71 includes a motor 714, the motor 714 is mounted on a support plate 715, the support plate 715 is fixedly connected to an inner wall of the housing 1, an output end of the motor 714 is provided with a first gear 713, one side of the first gear 713 away from the motor 714 is movably connected to an eccentrically arranged first connecting rod 712, the first connecting rod 712 is movably connected to a second connecting rod 711, and the second connecting rod 711 penetrates through the support plate 715 and the piston cylinder 72 and is connected to the piston 73.

In this embodiment, during aeration, the motor 714 drives the first gear 713 to rotate, the first gear 713 drives the first link 712 to swing while rotating, the first link 712 drives the second link 711 to move while swinging, the second link 711 only reciprocates up and down under the limit of the support plate 715, and further drives the piston 73 to reciprocate up and down, wherein the telescopic component 71 can also be replaced by a telescopic rod driving the piston 73 to reciprocate.

In another embodiment, referring to fig. 5, the rotating mechanism 9 includes a second hollow tube 93, a second gear 92 is disposed outside the second hollow tube 93, the second gear 92 is powered by the air intake mechanism 7, the air outlet tube 4 penetrates through two ends of the second hollow tube 93, the second hollow tube 93 penetrates through one end of the first hollow tube 5 located inside the housing 1, a limiting component 91 is disposed between the first hollow tube 5 and the second hollow tube 93, and the limiting component 91 is configured to limit the first hollow tube 5, so that the second hollow tube 93 can drive the first hollow tube 5 to rotate.

In this embodiment, this device is when carrying out the aeration, first gear 713 can with second gear 92 intermeshing, it rotates to drive second gear 92 by first gear 713, second gear 92 drives second hollow tube 93 and rotates, second hollow tube 93 drives first hollow tube 5 and rotates under spacing subassembly 91's effect, and then drive stirring vane 6 and rotate, it moves slewing mechanism 9 operation to drive by mechanism 7 that admits air, the dual-purpose function of motor 714 has been realized, the energy has been practiced thrift, in addition through the setting of first gear 713 and second gear 92, the inside of second hollow tube 93 is inserted to outlet duct 4 of being convenient for, the interference to outlet duct 4 when having avoided second hollow tube 93 to rotate, slewing mechanism 9 still can directly drive second hollow tube 93 with another motor 714 and rotate and replace in addition.

In another embodiment, referring to fig. 6, the limiting component 91 includes a limiting block 911 disposed inside the first hollow tube 5 and fixedly connected to the second hollow tube 93, a limiting groove 912 is disposed on an inner wall of the second hollow tube 93, and the limiting block 911 is disposed inside the limiting groove 912 and slidably connected thereto.

In this embodiment, the second hollow tube 93 rotates while driving the limiting block 911 to rotate, the limiting block 911 drives the first hollow tube 5 to rotate under the action of the limiting groove 912, and further drives the stirring blade 6 to rotate, in addition, the limiting block 911 can also slide inside the limiting groove 912, so that the first hollow tube 5 can also move up and down under the action of the lifting mechanism 8 while rotating, the interference brought to the lifting mechanism 8 in the rotating process of the first hollow tube 5 is avoided, in addition, the limiting assembly 91 can also be replaced by a spring and a fixing plate, wherein the fixing plate is arranged below the second hollow tube 93 and is fixedly connected with the inner wall of the first hollow tube 5, and two ends of the spring are respectively connected with the fixing plate and the bottom of the second hollow tube 93.

In another embodiment, referring to fig. 5, the lifting mechanism 8 includes a bearing 84 sleeved outside the first hollow tube 5, a supporting rod 83 is disposed outside the bearing 84, a reset component 82 is disposed on one side of the supporting rod 83, an extruding component 81 is disposed on the other side of the supporting rod 83, and the reset component 82 and the extruding component 81 are used for driving the supporting rod 83 to reciprocate.

In this embodiment, this device is when carrying out the aeration, drive branch 83 reciprocating up and down through reset subassembly 82 and extrusion subassembly 81, branch 83 drives second hollow tube 93 reciprocating up and down through bearing 84 while moving up and down, and then drive stirring vane 6 reciprocating up and down, the clearance effect to impurity has been improved, wherein bearing 84 sets up on the one hand to can drive second hollow tube 93 reciprocating up and down, on the other hand does not produce the interference to the rotation of second hollow tube 93, reset subassembly 82 can be the spring, the both ends of spring are connected with branch 83 and backup pad 715 respectively, elevating system 8 still can be replaced with telescopic link and carousel in addition, the carousel rotates with the bottom of shell 1 to be connected, the telescopic link sets up the upper surface at the carousel, the other end of telescopic link is connected with bearing 84.

In another embodiment, referring to fig. 5, the pressing assembly 81 includes a moving block 811 disposed inside the housing 1, the moving block 811 is movably connected to a third connecting rod 812, a cam 814 for pressing the supporting rod 83 is disposed at the other end of the third connecting rod 812, a rotating rod 813 penetrates through the cam 814, and the rotating rod 813 is fixedly connected to the inner wall of the housing 1.

In this embodiment, during aeration, the up-and-down movement of the moving block 811 drives the third connecting rod 812 to swing back and forth, while the third connecting rod 812 swings back and forth, the cam 814 swings back and forth around the rotating rod 813, while the cam 814 swings up, the supporting rod 83 is pressed, thereby the supporting rod 83 moves downwards, when the cam 814 swings downwards, the supporting rod 83 automatically moves downwards under the action of the reset component 82, thereby the up-and-down reciprocating motion of the first hollow pipe 5 is realized, the moving block 811 can be fixedly connected with the second connecting rod 711, the second connecting rod 711 can drive the moving block 811 to reciprocate up and down while reciprocating up and down, the air inlet mechanism 7 drives the lifting mechanism 8 to move, the three-purpose function of the motor 714 is realized, energy is saved, the extrusion assembly 81 can be replaced by a telescopic rod, and the telescopic rod drives the supporting rod 83 to reciprocate up and down.

In another embodiment, referring to fig. 5, a roller 815 is rotatably connected to one end of the rod 83 near the cam 814, and the roller 815 is engaged with a side surface of the cam 814.

In the embodiment, when the cam 814 presses the rod 83, the roller 815 is firstly pressed, the roller 815 slides on the side surface of the cam 814, and the rod 83 is pressed by the roller 815, so that friction between the rod 83 and the cam 814 is reduced, and the pressing effect of the cam 814 on the rod 83 is improved.

The implementation principle is as follows: when the device is used, under the action of the floating ball 2, the shell 1 floats on the water surface, the air outlet pipe 4 is inserted into the water, the air inlet pipe 3 is positioned above the water surface, then the first gear 713 is driven to rotate through the motor 714, the first gear 713 drives the first connecting rod 712 to swing while rotating, the first connecting rod 712 drives the second connecting rod 711 to move while swinging, the second connecting rod 711 can only do up-and-down reciprocating motion under the limit of the supporting plate 715, so as to drive the piston 73 to do up-and-down reciprocating motion, at the moment, air pressure is formed on two sides of the piston 73, at the moment, air enters the interior of the piston cylinder 72 through the air inlet pipe 3, then enters the interior of the air outlet pipe 4, and finally enters the water for aeration; the second connecting rod 711 drives the third connecting rod 812 to swing back and forth through the moving block 811 in the process of moving up and down, the third connecting rod 812 drives the cam 814 to swing back and forth with the rotating rod 813 as a circle center while swinging back and forth, the support rod 83 is driven to move up and down through the back and forth swing of the cam 814 and the matching of the reset component 82, and the support rod 83 drives the stirring blade 6 to move up and down through the bearing 84 and the first hollow tube 5; first gear 713 drives second gear 92 and rotates when pivoted, and second gear 92 drives second hollow tube 93 and rotates, and second hollow tube 93 drives stopper 911 and rotates when pivoted, and stopper 911 drives second hollow tube 93 and rotates under the effect of spacing groove 912, and then drives stirring vane 6 and rotate.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (9)

1. An energy-saving suspension aerator for water environment treatment comprises a shell and a floating ball arranged outside the shell; the device is characterized in that an air inlet mechanism is arranged inside the shell, the air inlet mechanism is connected with an air inlet pipe and an air outlet pipe, the air inlet pipe and the air outlet pipe both penetrate through the shell, a first hollow pipe is arranged outside the air outlet pipe, the first hollow pipe penetrates through the shell, one end of the first hollow pipe, penetrating through the shell, is provided with a stirring blade, the air outlet pipe penetrates through two ends of the first hollow pipe, and the first hollow pipe is connected with a rotating mechanism and a lifting mechanism;

the air inlet mechanism is used for conveying oxygen in the air to water and driving the rotating mechanism and the lifting mechanism to operate;

the rotating mechanism is used for driving the first hollow pipe to rotate so as to rotate the stirring blade;

the lifting mechanism is used for driving the first hollow pipe to reciprocate, so that the stirring blade reciprocates.

2. The energy-saving suspension aerator for water environment treatment according to claim 1, wherein the air inlet mechanism comprises a piston cylinder, a piston is arranged inside the piston cylinder, the piston is connected with a telescopic component, the telescopic component is used for driving the piston to reciprocate, the air inlet pipe and the air outlet pipe are both communicated with the piston cylinder and are positioned at one side of the piston close to the telescopic component, and the air inlet pipe and the air outlet pipe are both provided with one-way valves.

3. The energy-saving suspension aerator for water environmental remediation of claim 2, wherein the side wall of the piston cylinder is provided with a first shunt pipe and a second shunt pipe, the first shunt pipe and the second shunt pipe are both located on one side of the piston away from the telescopic assembly, the first shunt pipe and the second shunt pipe are both provided with one-way valves, the first shunt pipe is communicated with the air inlet pipe through a three-way joint, and the second shunt pipe is communicated with the air outlet pipe through a three-way joint.

4. The energy-saving suspension aerator for water environmental remediation of claim 2, wherein the telescopic assembly comprises a motor, the motor is mounted on a support plate, the support plate is fixedly connected with the inner wall of the housing, the output end of the motor is provided with a first gear, one side of the first gear, which is far away from the motor, is movably connected with a first connecting rod which is eccentrically arranged, the first connecting rod is movably connected with a second connecting rod, and the second connecting rod penetrates through the support plate and the piston cylinder and is connected with the piston.

5. The energy-saving suspension aerator for aquatic environment treatment according to claim 1, wherein the rotating mechanism comprises a second hollow pipe, a second gear is arranged outside the second hollow pipe and powered by the air inlet mechanism, the air outlet pipe penetrates through two ends of the second hollow pipe, the second hollow pipe penetrates through one end of the first hollow pipe inside the housing, a limiting component is arranged between the first hollow pipe and the second hollow pipe and is used for limiting the first hollow pipe, so that the second hollow pipe can drive the first hollow pipe to rotate.

6. The energy-saving suspension aerator for water environmental remediation of claim 5, wherein the limiting assembly comprises a limiting block disposed inside the first hollow pipe and fixedly connected to the second hollow pipe, the inner wall of the second hollow pipe is provided with a limiting groove, and the limiting block is disposed inside the limiting groove and slidably connected thereto.

7. The energy-saving suspension aerator for water environment treatment according to claim 1, wherein the lifting mechanism comprises a bearing sleeved outside the first hollow pipe, a support rod is arranged outside the bearing, a reset component is arranged on one side of the support rod, an extrusion component is arranged on the other side of the support rod, and the reset component and the extrusion component are used for driving the support rod to reciprocate.

8. The energy-saving suspension aerator for water environmental remediation of claim 7, wherein the extrusion assembly comprises a moving block disposed inside the housing, the moving block is movably connected with a third connecting rod, the other end of the third connecting rod is provided with a cam for extruding the support rod, a rotating rod penetrates through the cam, and the rotating rod is fixedly connected with the inner wall of the housing.

9. The energy-saving suspension aerator for water environmental remediation of claim 8, wherein the end of the support rod near the cam is rotatably connected with a roller, and the roller is attached to the side of the cam.

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