CN218530868U - Combustion agent flow guide device based on pusher - Google Patents

Abstract

The utility model provides a propellant guiding device based on pusher, which comprises a mixing box, a discharging pipe, a feeding pipe, a pump body, a circulating stirring mechanism, a frame body, a material collecting pipe, a plurality of guide pipes, a vibration component, a heating device, a plurality of electromagnetic valves and a controller, wherein the circulating stirring device circularly stirs alcohol singlet oxygen molecules, water and catalyst in the mixing box, so that all raw materials are uniformly mixed; carry mixed liquid to a plurality of honeycomb duct department through the inlet pipe afterwards, shunt the transport via a plurality of honeycomb duct, flow the in-process in the mixed liquid honeycomb duct, the mixed liquid of vibration subassembly in to the honeycomb duct on the honeycomb duct disturbs, and cooperate heating device to heat the mixed liquid in the honeycomb duct, utilize methyl alcohol singlet oxygen molecule, water and catalyst under the multistage collision catalysis of vibration subassembly, realize the separation of oxyhydrogen in the thermal environment, cause the leading fracture of hydrogen atom bond chain, the energy consumption is low, the hydrogen manufacturing is efficient and practice thrift cost's advantage.

Description

Combustion agent flow guide device based on pusher

Technical Field

The utility model relates to a fuel auxiliary transportation technical field, concretely relates to burning agent guiding device based on impeller uses.

Background

Hydrogen energy is a recognized clean energy source that is emerging as a low carbon and zero carbon energy source. The hydrogen fuel has the advantages of no pollution, good combustion performance and wide sources, and the existing industrial hydrogen production method comprises the following steps: 1. the water vapor passes through scorching coke (called a carbon reduction method), and the hydrogen purification degree is about 75 percent; 2. the water vapor passes through the scorching iron to obtain hydrogen with the purity of less than or equal to 97 percent; 3. extracting hydrogen from the water gas to obtain hydrogen with lower purity; 4. the purity of the hydrogen prepared by the water electrolysis method can reach more than or equal to 99 percent, and can also be obtained by the electrolysis method from 2NaOH or KOH solution.

The production method has the problems of complex process, excessive energy consumption and excessive cost, is not beneficial to production and use, can use the alcohol singlet oxygen molecular to match the catalyst and the water to react to prepare the hydrogen under certain environment at present, but the preparation process has the defects that the alcohol singlet oxygen molecular solution is difficult to be uniformly mixed with the catalyst and the water, and the preparation effect of the hydrogen is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the weak point that exists among the above-mentioned technique, provide a fire agent guiding device based on impeller uses, aim at solving above-mentioned problem.

The utility model provides a fire agent guiding device based on impeller uses, include:

the mixing box is provided with a discharge pipe and a plurality of feed pipes for raw materials to flow into, and the discharge pipe is provided with a pump body for driving the raw materials to flow through the discharge pipe;

the circulating stirring mechanism is arranged on the mixing box and is used for stirring the raw materials in the mixing box;

the device comprises a frame body, wherein a material collecting pipe is arranged on the frame body and is communicated with a material inlet pipe, and a plurality of guide pipes are communicated and arranged on the material collecting pipe;

the vibration component is arranged on the flow guide pipe and can drive liquid flowing in the flow guide pipe to vibrate;

the heating device is positioned at the bottom of the frame body and can provide heat for the flow guide pipe;

the electromagnetic valves are arranged on the discharge pipe and the feed pipes;

and the controller is electrically connected with the pump body, the circulating stirring mechanism, the heating device and the plurality of electromagnetic valves respectively.

Preferably, circulation rabbling mechanism includes drive assembly, first barrel, first bull stick, second barrel and second bull stick, first barrel is respectively the second barrel with mixing box upper end intercommunication sets up, the second barrel with mixing box lower extreme intercommunication sets up, first bull stick rotates to be installed on the first barrel, the second bull stick rotates to be installed on the second barrel, be provided with first helical blade on the first bull stick, be provided with on the second bull stick with first helical blade revolves to opposite second helical blade, drive assembly respectively with first bull stick with the transmission of second bull stick is connected and can be ordered about first bull stick with the synchronous rotation of second bull stick.

Preferably, drive assembly includes servo motor, action wheel, belt and follows the driving wheel, servo motor with the action wheel transmission is connected and can be ordered about the action wheel rotates, the action wheel passes through the belt pulley with connect and can drive from the driving wheel transmission it rotates from the driving wheel, the action wheel sets up on the first bull stick and can drive first bull stick rotates, it is in from the driving wheel setting on the second bull stick and can drive the second bull stick rotates, the controller with servo motor electric connection can control servo motor's operating condition.

Preferably, the draft tube is a U-shaped tube.

Preferably, the vibration assembly comprises a plurality of elastic pieces and a plurality of bumps, the elastic pieces are arranged on the inner wall of the flow guide pipe in a comb-shaped array, and the bumps are arranged on the inner wall of the flow guide pipe.

Preferably, the material collecting pipe is an annular pipe, and the plurality of guide pipes are arranged in a circumferential array along the axis of the annular pipe.

Preferably, the heating device comprises a vortex-shaped electric heating pipe and a heat conducting disc, and the vortex-shaped electric heating pipe is arranged on the heat conducting disc.

Compared with the prior art, the utility model discloses following beneficial effect has:

circularly stirring the alcohol singlet oxygen molecules, the water and the catalyst in the mixing tank by a circular stirring device to uniformly mix the raw materials; carry mixed liquid to a plurality of honeycomb duct department through the inlet pipe afterwards, shunt the transport via a plurality of honeycomb duct, flow the in-process in the mixed liquid honeycomb duct, the mixed liquid of vibration subassembly in to the honeycomb duct on the honeycomb duct disturbs, and cooperate heating device to heat the mixed liquid in the honeycomb duct, utilize methyl alcohol singlet oxygen molecule, water and catalyst under the multistage collision catalysis of vibration subassembly, realize the separation of oxyhydrogen in the thermal environment, cause the leading fracture of hydrogen atom bond chain, the energy consumption is low, the hydrogen manufacturing is efficient and practice thrift cost's advantage.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only preferred embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without inventive effort.

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

fig. 2 is a schematic structural view of a circulating stirring mechanism according to an embodiment of the present invention;

fig. 3 is a schematic structural view of the vibration assembly and the heating device according to an embodiment of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 3;

fig. 5 is an enlarged view at B in fig. 3.

In the figure, 10-mixing box; 11-a discharge pipe; 12-a feed pipe; 13-a pump body; 20-a circulating stirring mechanism; 21-a drive assembly; 211-a servo motor; 212-a capstan; 213-a belt; 214-a driven wheel; 22-a first cylinder; 23-a first rotating bar; 231-first helical blades; 24-a second cylinder; 25-a second rotating rod; 251-a second helical blade; 30-a frame body; 31-a material collecting pipe; 32-a draft tube; 40-a vibration assembly; 41-an elastic sheet; 42-a bump; 50-a heating device; 51-vortex electric heating tube; 52-heat conducting disc; 60-electromagnetic valve; and 70, a controller.

Detailed Description

Reference will now be made in detail to the present embodiments of the present invention, preferred embodiments of which are illustrated in the accompanying drawings, wherein the drawings are provided to supplement the description of the text of the specification with figures, so that the present invention can be visually and vividly understood as to each technical feature and the whole technical solution of the present invention, but the present invention should not be construed as limiting the scope of the present invention.

Example 1:

referring to fig. 1 to 5, the present invention provides a fuel guiding device based on a pusher, including:

the mixing box 10 is provided with a discharge pipe 11 and a plurality of feed pipes 12 for raw materials to flow into, and the discharge pipe 11 is provided with a pump body 13 for driving the raw materials to flow through the discharge pipe 11;

the circulating stirring mechanism 20 is arranged on the mixing box 10, and is used for stirring the raw materials in the mixing box 10;

the device comprises a frame body 30, wherein a material collecting pipe 31 is arranged on the frame body 30, the material collecting pipe 31 is communicated with a material inlet pipe 12, and a plurality of guide pipes 32 are communicated on the material collecting pipe 31;

the vibration assembly 40 is arranged on the flow guide pipe 32 and can drive the liquid flowing in the flow guide pipe 32 to vibrate;

a heating device 50, wherein the heating device 50 is positioned at the bottom of the frame body 30 and can provide heat for the guide pipe 32;

the electromagnetic valves 60 are arranged on the plurality of electromagnetic valves 60, the discharge pipe 11 and the plurality of feed pipes 12;

and the controller 70, wherein the controller 70 is respectively electrically connected with the pump body 13, the circulating stirring mechanism 20, the heating device 50 and the plurality of electromagnetic valves 60.

Circularly stirring the alcohol singlet oxygen molecules, the water and the catalyst in the mixing box 10 by a circular stirring device to uniformly mix all the raw materials; then carry mixed liquid to a plurality of honeycomb duct 32 department through inlet pipe 12, shunt the transport through a plurality of honeycomb duct 32, flow the in-process in the mixed liquid honeycomb duct 32, the mixed liquid in honeycomb duct 32 is disturbed to the vibration subassembly 40 on the honeycomb duct 32, and cooperate heating device 50 to heat the mixed liquid in honeycomb duct 32, utilize methyl alcohol singlet oxygen molecule, water and catalyst under the multistage collision catalysis of vibration subassembly 40, realize the separation of oxyhydrogen in the thermal environment, cause the leading fracture of hydrogen atom bond chain, have the energy consumption low, the hydrogen manufacturing is efficient and cost-effective advantage. Wherein the controller 70 is a PLC controller 70.

Specifically, the circulating stirring mechanism 20 includes a driving assembly 21, a first cylinder 22, a first rotating rod 23, a second cylinder 24 and a second rotating rod 25, the first cylinder 22 is respectively communicated with the upper ends of the second cylinder 24 and the mixing box 10, the second cylinder 24 is communicated with the lower end of the mixing box 10, the first rotating rod 23 is rotatably installed on the first cylinder 22, the second rotating rod 25 is rotatably installed on the second cylinder 24, the first rotating rod 23 is provided with a first helical blade 231, the second rotating rod 25 is provided with a second helical blade 251 which is opposite to the first helical blade 231 in rotation direction, the driving assembly 21 is respectively in transmission connection with the first rotating rod 23 and the second rotating rod 25 and can drive the first rotating rod 23 and the second rotating rod 25 to synchronously rotate.

Specifically, the driving assembly 21 includes a servo motor 211, a driving wheel 212, a belt 213 and a driven wheel 214, the servo motor 211 is in transmission connection with the driving wheel 212 and can drive the driving wheel 212 to rotate, the driving wheel 212 is in transmission connection with the driven wheel 214 through the belt 213 and can drive the driven wheel 214 to rotate, the driving wheel 212 is disposed on the first rotating rod 23 and can drive the first rotating rod 23 to rotate, the driven wheel 214 is disposed on the second rotating rod 25 and can drive the second rotating rod 25 to rotate, and the controller 70 is electrically connected with the servo motor 211 and can control the working state of the servo motor 211.

The driving wheel 212 is driven by the servo motor 211 to rotate, the driving wheel 212 drives the first rotating rod 23 to rotate and drives the second rotating rod 25 to rotate through the belt 213 and the driven wheel 214, the first rotating rod 23 and the second rotating rod 25 rotate synchronously, the first helical blade 231 rotates along with the first rotating rod 23, the second helical blade 251 rotates along with the second rotating rod 25, and because the rotating direction of the first helical blade 231 is opposite to that of the second helical blade 251, under the action of the rotation and matching of the second helical blade 251 of the first helical blade 231, the raw materials in the mixing box 10 circularly flow among the mixing box 10, the first cylinder 22 and the second cylinder 24, and are stirred by the first helical blade 231 and the second helical blade 251 in the flowing process, so that the raw materials in the mixing box 10 are mixed more uniformly.

Specifically, the flow guide pipe 32 is a U-shaped pipe. Set up the honeycomb duct 32 into the U-shaped pipe so that order about the solution and constantly pile up in honeycomb duct 32 and rise, realize that methyl alcohol singlet oxygen molecule, water and catalyst realize the separation of oxyhydrogen under vibration subassembly 40 multistage collision catalysis in the adverse current state of thermal environment, improve the hydrogen manufacturing effect.

Example 2:

referring to fig. 1 to 5, in combination with the technical solution of embodiment 1, in this embodiment, the flow guide pipe 32 is a U-shaped pipe. The flow guide pipe 32 is set to be a U-shaped pipe, so that the separation of hydrogen and oxygen can be realized under the condition of multistage collision catalysis of the vibration assembly 40 in a thermal environment countercurrent state, and the hydrogen production effect is improved.

Specifically, the vibration assembly 40 includes a plurality of elastic sheets 41 and a plurality of protrusions 42, the plurality of elastic sheets 41 are arranged on the inner wall of the flow guide tube 32 in a comb-shaped array, and the plurality of protrusions 42 are disposed on the inner wall of the flow guide tube 32. The solution flowing in the flow guide pipe 32 is disturbed by matching the bumps 42 with the elastic sheets 41, so that the uniformity of solution mixing is further improved. The elastic sheet 41 is a platinum sheet, and the bump 42 is an inverted tooth-shaped nickel metal bump 42.

Specifically, the material collecting pipe 31 is an annular pipe, and a plurality of flow guide pipes 32 are arranged in a circumferential array along the axis of the annular pipe.

Specifically, the heating device 50 includes a vortex electric heating tube 51 and a heat conducting disc 52, and the vortex electric heating tube 51 is disposed on the heat conducting disc 52.

The foregoing is merely a preferred embodiment of the invention and is not intended to limit the invention in any manner. The technical solution of the present invention can be used by anyone skilled in the art to make many possible variations and modifications, or to modify equivalent embodiments, without departing from the scope of the technical solution of the present invention. Therefore, any modification, equivalent change and modification of the above embodiments according to the present invention are all within the protection scope of the present invention.

Claims (7)

1. A fuel flow directing apparatus for use with an impeller, comprising:

the mixing box is provided with a discharge pipe and a plurality of feed pipes for raw materials to flow into, and the discharge pipe is provided with a pump body for driving the raw materials to flow through the discharge pipe;

the circulating stirring mechanism is arranged on the mixing box and is used for stirring the raw materials in the mixing box;

the device comprises a frame body, wherein a material collecting pipe is arranged on the frame body and is communicated with a material inlet pipe, and a plurality of guide pipes are communicated and arranged on the material collecting pipe;

the vibration assembly is arranged on the flow guide pipe and can drive liquid flowing in the flow guide pipe to vibrate;

the heating device is positioned at the bottom of the frame body and can provide heat for the flow guide pipe;

the electromagnetic valves are arranged on the discharge pipe and the feed pipes;

and the controller is electrically connected with the pump body, the circulating stirring mechanism, the heating device and the plurality of electromagnetic valves respectively.

2. The fuel flow guide device used based on the pusher as claimed in claim 1, wherein:

circulation rabbling mechanism includes drive assembly, first barrel, first bull stick, second barrel and second bull stick, first barrel is respectively the second barrel with mixing box upper end intercommunication sets up, the second barrel with mixing box lower extreme intercommunication sets up, first bull stick rotates to be installed on the first barrel, the second bull stick rotates to be installed on the second barrel, be provided with first helical blade on the first bull stick, be provided with on the second bull stick with first helical blade revolves to opposite second helical blade, drive assembly respectively with first bull stick with the transmission of second bull stick is connected and can be ordered about first bull stick with the second bull stick rotates in step.

3. The fuel guiding device used based on the pusher is characterized in that:

drive assembly includes servo motor, action wheel, belt and follows the driving wheel, servo motor with the action wheel transmission is connected and can be ordered about the action wheel rotates, the action wheel passes through the belt pulley with connect and can drive from the driving wheel transmission from the driving wheel rotation, the action wheel sets up on the first bull stick and can drive first bull stick rotates, from the driving wheel setting on the second bull stick and can drive the second bull stick rotates, the controller with servo motor electric connection can control servo motor's operating condition.

4. The fuel guiding device used based on the pusher is characterized in that:

the honeycomb duct is a U-shaped pipe.

5. The fuel flow guide device used based on the pusher as claimed in claim 1, wherein:

the vibration component comprises a plurality of elastic pieces and a plurality of convex blocks, the elastic pieces are arranged on the inner wall of the flow guide pipe in a comb-shaped array, and the convex blocks are arranged on the inner wall of the flow guide pipe.

6. The fuel guiding device used based on the pusher is characterized in that:

the material collecting pipe is an annular pipe, and the guide pipes are arranged in a circumferential array along the axis of the annular pipe.

7. The fuel flow guide device used based on the pusher as claimed in claim 1, wherein:

the heating device comprises a vortex-shaped electric heating pipe and a heat conducting disc, and the vortex-shaped electric heating pipe is arranged on the heat conducting disc.

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