CN211038818U - Rebound reinforcing section framework and framework substrate structure thereof - Google Patents
Rebound reinforcing section framework and framework substrate structure thereof Download PDFInfo
- Publication number
- CN211038818U CN211038818U CN201921955624.3U CN201921955624U CN211038818U CN 211038818 U CN211038818 U CN 211038818U CN 201921955624 U CN201921955624 U CN 201921955624U CN 211038818 U CN211038818 U CN 211038818U
- Authority
- CN
- China
- Prior art keywords
- framework
- blade
- section
- gill
- rebounding
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
- 230000003014 reinforcing effect Effects 0.000 title claims abstract description 42
- 239000000758 substrate Substances 0.000 title claims description 79
- 238000005520 cutting process Methods 0.000 claims abstract description 32
- 238000005452 bending Methods 0.000 claims abstract description 30
- 238000004891 communication Methods 0.000 claims abstract description 4
- 230000035939 shock Effects 0.000 claims description 149
- 239000011664 nicotinic acid Substances 0.000 claims description 69
- 230000002787 reinforcement Effects 0.000 claims description 69
- 238000000034 method Methods 0.000 claims description 43
- 238000004080 punching Methods 0.000 claims description 6
- 238000003698 laser cutting Methods 0.000 claims description 5
- 239000002184 metal Substances 0.000 claims description 5
- 238000013459 approach Methods 0.000 claims description 4
- 238000004519 manufacturing process Methods 0.000 abstract description 15
- 230000008901 benefit Effects 0.000 abstract description 9
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 97
- 229910052757 nitrogen Inorganic materials 0.000 description 45
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 40
- 238000002485 combustion reaction Methods 0.000 description 40
- 239000001301 oxygen Substances 0.000 description 40
- 229910052760 oxygen Inorganic materials 0.000 description 40
- 238000000926 separation method Methods 0.000 description 30
- 230000006835 compression Effects 0.000 description 28
- 238000007906 compression Methods 0.000 description 28
- 230000000694 effects Effects 0.000 description 28
- 238000007493 shaping process Methods 0.000 description 27
- 238000012545 processing Methods 0.000 description 24
- 239000007789 gas Substances 0.000 description 19
- 230000008569 process Effects 0.000 description 17
- 238000005516 engineering process Methods 0.000 description 14
- 238000003466 welding Methods 0.000 description 12
- 230000008859 change Effects 0.000 description 11
- MYMOFIZGZYHOMD-UHFFFAOYSA-N Dioxygen Chemical compound O=O MYMOFIZGZYHOMD-UHFFFAOYSA-N 0.000 description 7
- 229910001873 dinitrogen Inorganic materials 0.000 description 6
- 238000007689 inspection Methods 0.000 description 6
- 230000009286 beneficial effect Effects 0.000 description 5
- 238000013461 design Methods 0.000 description 5
- 238000010586 diagram Methods 0.000 description 5
- 239000000446 fuel Substances 0.000 description 5
- 230000005291 magnetic effect Effects 0.000 description 5
- 229920005597 polymer membrane Polymers 0.000 description 5
- 230000002349 favourable effect Effects 0.000 description 4
- 238000009434 installation Methods 0.000 description 4
- 238000005728 strengthening Methods 0.000 description 4
- 241000251468 Actinopterygii Species 0.000 description 3
- 230000009471 action Effects 0.000 description 3
- 238000001914 filtration Methods 0.000 description 3
- 230000005484 gravity Effects 0.000 description 3
- 239000000463 material Substances 0.000 description 3
- DOTMOQHOJINYBL-UHFFFAOYSA-N molecular nitrogen;molecular oxygen Chemical compound N#N.O=O DOTMOQHOJINYBL-UHFFFAOYSA-N 0.000 description 3
- 238000002360 preparation method Methods 0.000 description 3
- 238000003672 processing method Methods 0.000 description 3
- 238000011160 research Methods 0.000 description 3
- 238000001514 detection method Methods 0.000 description 2
- 238000009826 distribution Methods 0.000 description 2
- 239000000203 mixture Substances 0.000 description 2
- 238000013021 overheating Methods 0.000 description 2
- 230000009467 reduction Effects 0.000 description 2
- 230000007704 transition Effects 0.000 description 2
- 238000007514 turning Methods 0.000 description 2
- RNFJDJUURJAICM-UHFFFAOYSA-N 2,2,4,4,6,6-hexaphenoxy-1,3,5-triaza-2$l^{5},4$l^{5},6$l^{5}-triphosphacyclohexa-1,3,5-triene Chemical group N=1P(OC=2C=CC=CC=2)(OC=2C=CC=CC=2)=NP(OC=2C=CC=CC=2)(OC=2C=CC=CC=2)=NP=1(OC=1C=CC=CC=1)OC1=CC=CC=C1 RNFJDJUURJAICM-UHFFFAOYSA-N 0.000 description 1
- OLBVUFHMDRJKTK-UHFFFAOYSA-N [N].[O] Chemical compound [N].[O] OLBVUFHMDRJKTK-UHFFFAOYSA-N 0.000 description 1
- 238000006243 chemical reaction Methods 0.000 description 1
- 239000002131 composite material Substances 0.000 description 1
- 239000000470 constituent Substances 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 230000005292 diamagnetic effect Effects 0.000 description 1
- 238000009792 diffusion process Methods 0.000 description 1
- 239000000428 dust Substances 0.000 description 1
- 238000004134 energy conservation Methods 0.000 description 1
- 238000003912 environmental pollution Methods 0.000 description 1
- 239000002360 explosive Substances 0.000 description 1
- 239000003063 flame retardant Substances 0.000 description 1
- 230000017525 heat dissipation Effects 0.000 description 1
- 230000003116 impacting effect Effects 0.000 description 1
- 230000007774 longterm Effects 0.000 description 1
- 238000003754 machining Methods 0.000 description 1
- 238000013178 mathematical model Methods 0.000 description 1
- 238000004806 packaging method and process Methods 0.000 description 1
- 230000005298 paramagnetic effect Effects 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- 238000005192 partition Methods 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 239000003208 petroleum Substances 0.000 description 1
- 230000002265 prevention Effects 0.000 description 1
- 238000007789 sealing Methods 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- 230000003068 static effect Effects 0.000 description 1
- 239000000126 substance Substances 0.000 description 1
- 208000024891 symptom Diseases 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
Images
Classifications
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/10—Internal combustion engine [ICE] based vehicles
- Y02T10/12—Improving ICE efficiencies
Landscapes
- Exhaust Gas After Treatment (AREA)
Abstract
The utility model discloses a bounce-back reinforcing section skeleton, a serial communication port, including wholly being annular fixed basic component, still include the bionical blade of multiunit gill, the bionical blade of each group gill is fixed on fixed basic component along circumference evenly distributed, the bionical blade of gill wholly is quadrangle and one side inside the place ahead bending and stretches out and make the monolithic wholly be the camber, and the distance that the bionical blade of every gill stretches out one side and the angle of bending is increased gradually along the air current direction of advance, and the bionical blade of every gill stretches out a side edge and transversely is provided with the multichannel joint-cutting, and partial blade between the adjacent joint-cutting is because the bending angle is different and stagger gradually. The utility model also discloses a section skeleton base plate structure is strengthened in bounce-back for preparing the section skeleton is strengthened in bounce-back. The utility model discloses can conveniently obtain the rebound enhancement section in the engine intake pipe, have simple structure, support reliable and stable, make advantages such as simple to operate swift and low in production cost are honest and clean.
Description
Technical Field
The utility model discloses engine air intake control technical field, concretely relates to bounce-back enhancement section skeleton and skeleton base plate structure of mainly used engine intake pipe.
Background
In the world, energy shortage and environmental pollution become world problems, and in order to save petroleum resources and protect the environment, green water in Qingshan mountain is used in human living space, and the world is in consensus on improving the automobile emission standard so as to reduce the exhaust emission pollution. China also prepares to implement the six emission standards of China recently so as to reduce the emission pollution of automobile exhaust.
The pollution of automobile tail gas is mainly caused by insufficient combustion of an automobile engine combustion chamber. At present, the emission standard of an automobile is improved, and two modes of front-end treatment and rear-end treatment of an engine are generally available. The most used is the rear-end treatment mode, namely the harmful components of the tail gas are treated between the exhaust of a combustion chamber and the emission of the tail gas of an automobile. The mode of this kind of rear end treatment addresses the symptoms and does not address the root cause, and the tail gas is produced the posttreatment and is got up comparatively troublesome, and the cost is higher, and the treatment effect is limited, and is hard not favorable, can not fundamentally solve the problem.
In the prior art, there are some methods for treating the front end of the intake air of the engine, and the general idea is to separate the nitrogen and the oxygen in the intake air, and then filter the nitrogen, or control the ratio of the nitrogen and the oxygen entering the combustion chamber of the engine, so that the nitrogen and the oxygen are beneficial to combustion. For example, a double-effect air intake system of an engine disclosed in CN102383982A, an air intake control system and a control method of an engine disclosed in CN201210301668, an air supply control method and a device of an engine disclosed in CN201811013782, and the like, which adopt technologies with similar concepts.
However, the prior patents of the front end processing technology of the engine all have the following defects: 1. the idea of the existing front-end processing technology of the engine is to consider how to realize the separation of nitrogen and oxygen components in the intake air of the engine and adjust and control the proportion of the nitrogen and oxygen components. However, the existing engine and the whole set of air intake and exhaust system of the automobile are designed according to the existing air component air intake combustion condition, and if the proportion of the air components in the combustion chamber of the engine is changed, the problems of the combustion of the automobile engine and the unmatched situation of the exhaust emission working condition and the existing air intake and exhaust system of the automobile are easily caused. For example, in general, an automobile exhaust system needs to consider not only exhaust but also heat dissipation, during exhaust emission, a sufficient proportion of nitrogen is needed to carry away excessive heat, and if the proportion of nitrogen is reduced or nitrogen intake is eliminated, damage to an engine and the exhaust system due to overheating is easily caused. 2. In the existing front-end processing technology of the engine, when nitrogen and oxygen are separated, most of working principles are that the nitrogen and oxygen are separated by means of a polymer membrane technology. The technology of realizing gas separation by means of the polymer membrane has no problem theoretically, but when the technology is applied to an automobile engine in actual use, a large amount of dust is involved into an engine air inlet pipe due to the fact that air components are complex and the automobile runs close to the ground. The air filter has limited filtering effect, can only meet the filtering requirement of combustion air intake of an engine, and cannot meet the air intake filtering requirement of long-term use of the polymer membrane, so that micro solid particles mixed in the air can cause the polymer membrane to generate blockage and pollution in a short time to cause the loss of the separation effect. The technology for realizing the separation of the nitrogen and the oxygen by the polymer membrane not only has very high cost, but also is difficult to be suitable for the actual use of automobile running. At present, the nitrogen-oxygen separation air intake control technology of the air intake end of the automobile basically stays in the theoretical research stage. And the research direction of the prior engine air inlet front end treatment is felt to go into the thinking misdistricts, so that the research technology is difficult to be suitable for practical application, and no automobile product using the automobile air inlet nitrogen-oxygen separation technology is seen in the market.
Therefore, the applicant changes the idea and designs the engine air inlet pipe which can carry out front-end treatment on the inlet air of the engine combustion chamber so as to be beneficial to combustion, generate the effects of energy conservation and emission reduction, reduce emission pollution, improve the emission standard, greatly reduce the treatment cost and enable the treatment cost to be suitable for practical application. The structure is as follows: an engine air inlet pipe comprises an air passage pipe body, wherein one end of the air passage pipe body is an engine connecting end, the other end of the air passage pipe body is an air filter connecting end, an air inlet structure framework is installed in the air passage pipe body, and a vortex airflow forming section, a shock wave airflow forming section and a rebound reinforcing section which are sequentially connected along the air inlet direction are formed in the air passage pipe body by the air inlet structure framework to form an air inlet separation structure; the vortex airflow forming section is used for guiding air to enter to generate vortex airflow, the shock wave airflow forming section is used for generating local compression and changing the direction on the vortex airflow to form oblique shock wave airflow, and the rebound reinforcing section is used for forming secondary rebound on the oblique shock wave airflow.
Specifically, a plurality of vortex airflow forming blades are arranged in the vortex airflow forming section, each vortex airflow forming blade is uniformly distributed and fixed on the inner cavity wall of the air passage pipe body along the circumferential direction, one side of each vortex airflow forming blade extends towards the inner front in a bending mode to enable a single piece to be in a bent arc shape integrally, the extending distance and the bending angle of each vortex airflow forming blade are gradually increased along the airflow advancing direction, the bent arc directions of the vortex airflow forming blades are arranged in a consistent mode, and vortex airflow can be integrally formed after the airflow passes through;
in the shock wave airflow forming section, a plurality of groups of shock wave airflow forming structures are uniformly distributed along the circumferential direction of the inner cavity wall of the air passage pipe body, each shock wave airflow forming structure comprises a shock wave forming blade which obliquely bends and extends out of the inner cavity wall of the air passage pipe body, the inner side surface of each shock wave forming blade is obliquely arranged facing the vortex rotation direction, the front end of the inner side of each shock wave forming blade bends and extends towards the front in the inner cavity of the air passage pipe body, each group of shock wave airflow forming structures also comprises a shock wave compression blade which is adjacent to the shock wave forming blade, the inner side of each shock wave compression blade bends and extends inwards and forwards and gradually approaches the front end in the shock wave forming blade, and a semi-surrounding space structure with the whole space gradually narrowed along the air inlet direction is formed between the shock wave compression blade and the shock wave;
in the rebound strengthening section, a plurality of groups of gill bionic blades are uniformly distributed along the circumferential direction of the inner cavity wall of the gas channel pipe body, the whole gill bionic blades are quadrilateral, one side of each gill bionic blade extends towards the inner front in a bending mode to enable a single plate to be in a bent arc shape, the extending distance and the bending angle of each gill bionic blade extending out of one side of each gill bionic blade are gradually increased along the airflow advancing direction, a plurality of cutting seams are transversely arranged on the edge of each gill bionic blade extending out of one side of each gill bionic blade, and part of blades between adjacent cutting seams are gradually staggered due to different bending.
Thus, the air inlet flow is impacted by the air inlet separation structures of the three sections, the flow state of the air inlet flow and the speed distribution condition of each component substance are changed, and oxygen molecules and nitrogen molecules with different specific gravities are enriched respectively due to the change of the impacted speed and angle. Thereby making it advantageous for combustion.
Then, in this engine air inlet structure skeleton, how to design an solitary bounce-back enhancement section skeleton for can obtain the structure of bounce-back enhancement section after the skeleton is installed in the engine air inlet pipe and skeleton self has simple structure, supports reliable and stable, makes simple to operate swift characteristics. Becomes a problem to be further solved.
SUMMERY OF THE UTILITY MODEL
To the not enough of above-mentioned prior art, the utility model aims to solve the technical problem that: how to provide a rebound reinforcing section skeleton and skeleton base plate structure that can install and can obtain the rebound reinforcing section after the engine intake pipe and self has simple structure, supports reliable and stable, make simple to operate swift characteristics. The front-rear direction in this application is defined as the direction forward with the airflow being the front, and the opposite direction being the rear, and the orientation description is made based on this.
In order to solve the technical problem, the utility model discloses a following technical scheme:
the utility model provides a bounce-back enhancement section skeleton, a serial communication port, including wholly being annular fixed base component, still include the bionical blade of multiunit gill, the bionical blade of each group gill is fixed on fixed base component along circumference evenly distributed, the bionical blade of gill wholly is quadrangle and one side inside the place ahead bending and stretches out and make the monolithic wholly be the camber, and the bionical blade of every gill stretches out the distance that one side stretches out and crooked angle along the air current direction of advance crescent, and the bionical blade of every gill stretches out a side edge and transversely is provided with the multichannel joint-cutting, and partial blade between the adjacent joint-cutting staggers gradually because the bending angle is different.
Thus, the utility model discloses a skeleton can prepare alone, then can obtain the rebound enhancement section in the intake pipe in the gas channel pipe body of direct mount engine intake pipe, makes its convenient manufacturing, reduces the processing cost.
Furthermore, the two fish gill bionic blades are arranged in pairs, and the front ends of the extending sides of each pair of fish gill bionic blades in the advancing direction of the airflow gradually approach each other, so that a semi-enclosed space structure with the whole cross section of the space gradually narrowed forwards in the air inlet direction is enclosed between each pair of fish gill bionic blades.
Therefore, the airflow flowing through each pair of gill bionic blades is further compressed under the action of a narrow effect to improve the flow speed, so that the airflow generates positive rebound through the gill bionic blades and flows through the edges of the blades to be folded to achieve equivalent flow state change, and the flow state change is more violent, thereby being more beneficial to further separation and enrichment of oxygen molecules and nitrogen molecules.
Furthermore, the rear ends of two adjacent gill bionic blades in two adjacent pairs of gill bionic blades are connected into a whole by an inclined transverse connecting part.
Thus, the production and the manufacture are more convenient.
Further, bounce-back reinforcement section skeleton is including the annular bounce-back reinforcement section skeleton base ring that is located the rear end, and the basis component is fixed promptly to bounce-back reinforcement section skeleton base ring, and bounce-back reinforcement section skeleton base ring rear end is used for with shock wave air forming section skeleton connecting strip front end fixed connection, and bounce-back reinforcement section skeleton base ring front end extends forward and is formed with a plurality of bounce-back reinforcement section skeleton connecting strips, and bounce-back reinforcement section skeleton connecting strip rear end one side is fixed with bounce-back reinforcement section skeleton base ring, and bounce-back reinforcement section skeleton connecting strip rear end opposite side relies on oblique horizontal connecting portion to connect as an organic wholely with two gill bionic blade rear ends in proper order.
Thus the utility model discloses an in the bounce-back reinforcement section skeleton, set up bounce-back reinforcement section skeleton base ring as supporting the basis, connecting elements around rethread bounce-back reinforcement section skeleton connecting strip is done, so whole has simple structure, supports reliable and stable, makes the advantage of the swift characteristics of simple to operate. And this bounce-back reinforcing segment skeleton can make alone, then with the welding of other two part skeletons constitution air intake structure skeleton of engine intake pipe, improve the convenient degree and the efficiency of air intake structure skeleton whole preparation.
Preferably, the front end of the framework of the rebound reinforcement section is also provided with a front end reinforcing ring of an annular structure, and the front end of the connecting strip of the framework of the rebound reinforcement section and the front end reinforcing ring are welded into a whole.
This may further improve the integrity and structural strength of the air intake structural skeleton.
The utility model also discloses a section skeleton base plate structure is strengthened in bounce-back that is used for preparing above-mentioned bounce-back enhancement section skeleton fast, a serial communication port, bounce-back enhancement section skeleton base plate is whole to be rectangle and the rear edge reason has a bounce-back enhancement section skeleton ring strip of rectangular shape, the equal partition interval in front side of bounce-back enhancement section skeleton base ring strip is provided with a plurality of the same unit structures, every unit structure includes that the rear end slant is parallel to be an integrative bounce-back enhancement section skeleton connecting strip and two gill bionic blade substrates, leave the clearance between bounce-back enhancement section skeleton connecting strip and the gill bionic blade substrate and between two adjacent gill bionic blade substrates, every gill bionic blade substrate deviates from bounce-back enhancement section skeleton connecting strip one side and has transversely seted up the multichannel joint-cutting.
Thus, by adopting the framework substrate structure of the rebound reinforcing section, only two ends of the framework substrate ring strip of the rebound reinforcing section in the length direction are required to be bent, welded and fixed into a ring shape to obtain the framework substrate ring of the rebound reinforcing section, and then the front ends of the two gill bionic blade substrates, which are respectively provided with the cutting seams, are bent inwards and forwards, so that the cutting seams at the edges of the gill bionic blade substrates are sequentially staggered in the bending process to obtain the gill bionic blades, and the inner front ends of the two adjacent gill bionic blade substrates in the two adjacent unit structures are mutually close to form a pair; thereby obtaining the framework of the rebound strengthening section. Thus, the framework of the rebound reinforcing section is manufactured, and the framework has the advantages of convenience and rapidness in processing, low cost and the like.
Furthermore, one side of the framework connecting strip of the rebound reinforcing section, which is far away from the gill bionic blade substrate, is perpendicular to the framework base ring strip of the rebound reinforcing section, so that the plate cutting space is saved.
Furthermore, the outer side edge of the gill bionic blade substrate at the outermost side is perpendicular to the ring strip of the rebound reinforcing framework base, so that the plate cutting space is saved.
Furthermore, the base plate of the framework of the rebound reinforcement section is obtained by punching, laser cutting or linear cutting a rectangular metal plate for preparing the framework of the rebound reinforcement section.
Therefore, the processing is simple, convenient, efficient and low in cost.
Furthermore, an alignment groove gap is formed in the middle position corresponding to each unit structure on the side edge of the rear end of the framework base ring strip of the rebound reinforcing section, so that in the process of bending the gill bionic blade substrate, whether the gill bionic blade substrate is bent in place can be better judged by taking the alignment groove gap as a reference. Meanwhile, in the process of welding and connecting the shock wave airflow forming section framework and the rebounding reinforcing section framework, the welding angle requirement on the circumferential direction can be conveniently ensured by means of aligning the groove notch for aligning.
To sum up, the utility model discloses can conveniently obtain vortex air-flow forming section in the intake pipe, have simple structure, support reliable and stable, make advantages such as simple to operate is swift and low in production cost are honest and clean.
Drawings
FIG. 1 is a schematic structural view of an intake pipe of an engine to which the present invention is applied; (the figure is a schematic view of the air inlet structure framework arranged in the air channel pipe body).
Fig. 2 is a schematic structural view of the air intake structure skeleton in fig. 1.
Fig. 3 is a schematic top view of fig. 2.
FIG. 4 is a schematic structural view of the skeleton of the swirling air-flow forming section of FIG. 2.
Fig. 5 is a top view of fig. 4.
Fig. 6 is a schematic structural diagram of the skeleton of the shock wave airflow shaping section in fig. 2.
Fig. 7 is a top view of fig. 6.
Fig. 8 is a schematic structural diagram of the framework of the rebound reinforcement section in fig. 2.
Fig. 9 is a top view of fig. 8.
Fig. 10 is a structural view of the front end reinforcing ring of fig. 2.
Fig. 11 is a top view of fig. 10.
FIG. 12 is a schematic structural diagram of a skeleton base plate of the vortex gas flow forming section.
Fig. 13 is a schematic structural diagram of a skeleton substrate of a shock wave airflow shaping section.
Fig. 14 is a schematic structural diagram of a skeleton base plate of the bounce reinforcement section.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.
In the specific implementation: as shown in fig. 1 to 14, an adopted the utility model discloses the engine intake pipe of structure, including air flue body 1, air flue body one end is the engine link, and the other end is the air cleaner link, be provided with the separation structure 2 that admits air in the air flue body (this admits air the separation structure promptly the utility model discloses a structure), the separation structure that admits air is including lieing in the inside bellied blade structure of engine admission line inner chamber, the blade structure can strike the air current that admits air, changes the flow state and each composition material velocity distribution condition of air current that admits air for the oxygen molecule and the nitrogen molecule that the proportion is different are because of receiving speed and the angle after the striking to produce the change and accomplish respective enrichment.
Therefore, due to the law of conservation of momentum, when air of an air inlet pipeline of the engine is fed, nitrogen molecules and oxygen molecules entering the inner cavity of the air inlet pipeline at the same air inlet speed collide with blades in the inner cavity of the air inlet pipeline, and under the same collision effect, different speeds and angles can be generated in the process of changing directions due to the collision of the blades due to the fact that the specific gravity and the mass of the nitrogen molecules and the oxygen molecules are different, and then the respective enrichment of the oxygen molecules and the nitrogen molecules is completed. Thereby making it advantageous for combustion.
Specifically, the working principle of the engine intake pipe is that air before entering the engine combustion chamber is processed by means of physical separation, so that before entering the engine, the air is enriched with unfavorable combustion components represented by nitrogen molecules and favorable combustion components represented by oxygen molecules, and the two components enter the engine combustion chamber in respective enriched states for combustion.
Thus, the engine intake pipe belongs to the engine intake front-end processing technology, but compared with the prior art, the engine intake pipe does not attempt to completely separate the nitrogen and oxygen components in the air and control and adjust the proportion of the nitrogen and oxygen components, but only completes the respective enrichment. So that the air can be sent into a combustion chamber of the engine to be combusted under the condition that the integral component proportion of the air is not changed and only the respective enrichment of two major components is completed. The processing mode after the thought conversion greatly reduces the difficulty of air processing and the difficulty of technical application, so that the air processing device is low in cost and is suitable for practical use. Meanwhile, the proportion of nitrogen in the intake air is not changed, so that enough nitrogen can take away the redundant heat generated by the engine during exhaust emission, the whole technology can be better matched with the existing mature engine and exhaust system, and the damage of the engine and the exhaust system caused by overheating is avoided.
More specifically describing the principle of the engine intake pipe, the two main components of air are oxygen and nitrogen, but due to the diffusion effect caused by the large gaps between gas molecules and the thermal movement of the molecules, the oxygen and the nitrogen are mixed together in a molecular-level ratio. Since the proportion of nitrogen in air is approximately four times higher than that of oxygen and both are in a mixed and mixed state at the molecular level, one oxygen molecule will surround approximately eight nitrogen molecules in the periphery from the viewpoint of the static micro-space structure between molecules. The applicant considers that in this state, if the air enters the combustion chamber directly, it is a flame-retardant gas because the nitrogen is not combustible and does not support combustion. Meanwhile, the combustion working condition of the engine combustion chamber needs to be changed into the instantaneous combustion after fuel molecules are injected in a high-temperature and high-pressure environment. Under the requirement of such instantaneous explosive combustion conditions, when each oxygen molecule entering the combustion chamber is surrounded by a plurality of nitrogen molecules, the combination of the oxygen molecules and the fuel molecules is greatly hindered, and the combustion is not facilitated. The utility model discloses the principle enters into the engine after enriching nitrogen gas molecule and oxygen molecule separately in with the air, makes the oxygen molecule periphery no longer or when no longer surrounding the nitrogen gas molecule as far as possible (the meaning of two major constituents enrichment separately lies in the nitrogen gas molecule quantity that reduces as far as possible around the oxygen molecule), just can shield as far as possible the interference effect that the nitrogen gas molecule combines the burning to oxygen molecule and fuel. Thereby greatly facilitating the oxygen molecules to fully participate in the combustion, and further improving the combustion quality and efficiency. After fuel molecules are fully combusted, the exhaust emission pollution is reduced, and the emission standard of an engine is improved.
In addition, when the method and the principle of the engine air inlet pipe are partially implemented, other technical means and modes can be adopted to realize the enrichment of oxygen molecules and nitrogen molecules in the air inlet. For example, the magnetic effect law of gas motion is utilized, a magnetic field with certain conditions is arranged in the gas inlet pipeline, and different magnetic properties of oxygen and nitrogen are utilized to realize the separation of the oxygen and the nitrogen. Because oxygen is a paramagnetic medium and nitrogen is a diamagnetic medium, the oxygen and the nitrogen tend to be separated from each other due to different magnetic field forces in the inhomogeneous magnetic field, and further the respective enrichment of the oxygen and the nitrogen can be completed. Since the applicant filed patent protection on the same day as the present invention for the principles of the method, it would still fall into infringement if others could adopt such means to achieve respective enrichment of oxygen and nitrogen molecules in the intake air to improve the combustion effect of the combustion chamber.
In the embodiment, the air inlet separation structure 2 comprises a vortex airflow forming section 3 and a shock wave airflow forming section 4 which are sequentially connected forward along the air inlet direction, wherein the vortex airflow forming section is used for guiding air to enter to generate vortex airflow, and the shock wave airflow forming section is used for generating local compression and changing the direction to the vortex airflow to form oblique shock wave airflow.
Therefore, air entering an air inlet pipe of the engine can generate vortex air flow, the whole air inlet pipe moves forward in a vortex mode, then the shock wave forming blades arranged in the shock wave airflow forming section are used for obliquely impacting and changing the direction of local vortex, the vortex air flow generates oblique shock wave airflow in an oblique forward direction, and nitrogen molecules and oxygen molecules generate different speeds and angles along with the process that the oblique shock wave airflow changes the direction under the strong impact effect of the oblique shock wave airflow, so that separation is realized, and respective enrichment is completed.
So adopt above-mentioned structure, produce the vortex air current to admitting air earlier, rely on the vortex air current, under the effect of centrifugal force for the great oxygen of proportion can produce the trend of outwards assembling, and the less nitrogen gas of proportion can inwards assemble, and then makes the two produce preliminary separation enrichment effect. Meanwhile, the vortex airflow accelerates the flowing speed of the inlet air, so that conditions are created for the generation of subsequent oblique shock wave airflow. The vortex airflow rotating at a high speed collides with shock wave forming blades arranged at a certain angle, the vortex airflow is forced to change direction under strong impact to generate oblique shock waves, and separation trends are promoted to be generated in the process that nitrogen molecules and oxygen molecules advance along with the oblique shock wave airflow, so that respective enrichment is completed. And the two parts of components enter the engine combustion chamber along with the engine air inlet pipe in respective enriched states to be combusted. And further, the combustion quality and efficiency are improved, the tail gas emission pollution is reduced after fuel molecules are fully combusted, and the engine emission standard is improved.
In this embodiment, the air intake separation structure 2 further includes a bounce reinforcement section 5 connected in front of the shock wave airflow shaping section, and the bounce reinforcement section is used for forming secondary bounce to oblique shock wave airflow.
Therefore, the shock wave airflow is rebounded again by the rebounding blade after the shock wave airflow, so that nitrogen molecules and oxygen molecules which move forward at different speeds generate different rebounding angles by virtue of rebounding, the separation effect is further enhanced, and the enrichment of the nitrogen molecules and the oxygen molecules is better realized.
Wherein, the distance between the air inlet separation structure 2 and the engine connecting end is 5-8 cm. The distance can ensure that two major components in the air inlet are rebounded and thrown out again through the rebounding reinforcing section to stagger the distance to finish enrichment and reserve enough space; meanwhile, the components in the air can not be merged again and mixed into a whole due to the distance process, so that the two components in the air can be kept in respective enriched states and enter the combustion chamber of the engine.
Wherein, be provided with a plurality of vortex air forming blades 6 in vortex air forming section 3, each vortex air forming blade is fixed on the inner chamber wall of air flue body along circumference evenly distributed, 6 one side of vortex air forming blade is crooked to be stretched out to the inside the place ahead and makes the monolithic whole be the camber, and every vortex air forming blade (single vortex air forming blade can include along the superimposed multi-disc vortex air forming blade of length direction) stretches out the distance that one side stretches out and crooked angle along the air current direction of advance and increases gradually, and the camber direction of each vortex air forming blade arranges unanimously for can form vortex air current after the air current crosses wholly.
Like this, adopt the mode that sets up vortex air current shaping blade to produce the vortex air current, have simple structure, set up easily, low cost to can guide better and admit air and produce required vortex, improve advantages such as vortex velocity of flow. However, in the specific implementation, if the vortex is generated by arranging a spiral drainage groove in the inner cavity of the pipeline or directly installing a fan blade in the middle of the inner cavity, the vortex shall be regarded as still falling into the protection scope of the present application.
In the swirl flow shaping section, a better option is to use four or six swirl flow shaping vanes (4 in this embodiment). Too few in number would make it difficult to create a swirl effect, too many would result in increased costs, while too many or a single number would make it difficult to create a mathematical model of the air flow, making it difficult to calculate and optimize the blade setting parameters through the model.
In this specific embodiment, in the shock wave airflow shaping section 4, a plurality of groups of shock wave airflow shaping structures 7 are uniformly distributed along the circumferential direction of the inner cavity wall of the air passage pipe body, each shock wave airflow shaping structure comprises a shock wave shaping blade 8 which obliquely bends and extends out of the inner cavity wall of the air passage pipe body, the inner side surface of each shock wave shaping blade obliquely faces the vortex rotation direction and the inner front end of each shock wave shaping blade bends and extends towards the front of the inner cavity of the air passage pipe body, each group of shock wave airflow shaping structures 7 further comprises a shock wave compression blade 9 which is adjacent to the shock wave shaping blade 8, the inner side of each shock wave compression blade bends and extends inwards and forwards and gradually approaches towards the inner front end of each shock wave shaping blade, and a semi-surrounding space structure that the whole cross section of the space between each shock wave compression blade and each shock wave shaping blade gradually narrows along the air inlet direction.
Therefore, the vortex formed after the vortex airflow forming section enters from the rear end (large section end) of the space enclosed between the shock wave compression blade and the shock wave forming blade, then is extruded by the shock wave compression blade, the space section is gradually reduced to generate a narrow effect, the wind speed is further gradually increased, so that oblique shock waves can be better formed after the vortex airflow forming section passes through the shock wave forming blade, mutual separation caused by different impact effects due to different specific gravities of oxygen molecules and nitrogen molecules in air can be better completed under the strong impact effect of the oblique shock waves, and the enrichment effect of the oxygen molecules and the nitrogen molecules in the air is improved.
In the present embodiment, the shock wave shaping blade 8 is formed in a triangular shape (here, the shape is a triangular shape after being flattened, and the shape is a curved surface shape in an actual space) with a sharp corner at the outer end as a whole. The shape of the blade can be better utilized to generate oblique shock waves.
In this embodiment, the shock wave compression blade 9 is a quadrilateral (here, the quadrilateral is a quadrilateral after being flattened, and the curved surface shape in the actual space) as a whole, and a plurality of slits are transversely arranged on the side edge of the extension part, and part of the blades between adjacent slits are gradually staggered due to different bending angles.
Therefore, a small part of the air flow entering the space between the shock wave compression blade and the shock wave forming blade can be discharged from the cutting seam, and more abrupt transitions of the air flow channel are generated by the transition change of the edge of the cutting seam, so that a small effect of enriching different air components is formed in a local space. Meanwhile, more wind flows are compressed towards the direction of the shock wave forming blades by depending on the partial blades with different bending angles between the cutting seams, and then a multi-level compression and superposition effect is generated, so that the wind flow flowing out from the shock wave forming blades can be better ensured to generate an oblique shock wave effect.
In this embodiment, the number of groups of the shock wave airflow shaping structures 7 is the same as the number of the vortex airflow shaping blades 6 (which refers to the number of a single blade, and a single blade may include multiple blades), and the shock wave airflow shaping structures are located on the forward channel of the single-strand vortex airflow guided by the vortex airflow shaping blades correspondingly.
Thus, single-stranded vortex airflow guided by the vortex airflow shaping blade can enter between the shock wave shaping blade and the shock wave compression blade from the upper end of the shock wave airflow shaping structure. The structure of the shock wave airflow forming section can be better correspondingly connected with the vortex airflow forming section, and the vortex generated by the vortex airflow forming section can generate oblique shock waves in the shock wave airflow forming section.
In this embodiment, in the rebound reinforcing section 5, a plurality of groups of gill bionic blades 10 are uniformly distributed along the circumferential direction of the inner cavity wall of the airway tube, the whole gill bionic blade is quadrilateral (quadrilateral after being flattened), and one side of the gill bionic blade extends towards the inner front in a bending manner, so that the whole single plate is in a curved arc shape, the extending distance and the bending angle of one side of each gill bionic blade 10 are gradually increased along the airflow advancing direction, a plurality of cutting seams are transversely arranged on the side edge of each gill bionic blade extending out, and part of blades between adjacent cutting seams are gradually staggered due to different bending angles.
Therefore, the gill bionic blade can realize multi-angle gradual rebound of oxygen molecules and nitrogen molecules which are separated and enriched under the action of oblique shock waves in the air, further improve the separation effect of the oxygen molecules and the nitrogen molecules by depending on different rebound angles, and is more favorable for respective enrichment of two major components.
In this embodiment, two pairs of the gill bionic blades 10 are arranged in pairs, the total number of pairs of the total pairs of the gill bionic blades is consistent with the total number of the total pairs of the gill bionic blades, and the front ends of the extended sides of the pair of the gill bionic blades, which extend.
Therefore, the airflow flowing through each pair of gill bionic blades is further compressed under the action of a narrow effect to improve the flow speed, so that the airflow generates positive rebound through the gill bionic blades and flows through the edges of the blades to be folded to achieve equivalent flow state change, and the flow state change is more violent, thereby being more beneficial to further separation and enrichment of oxygen molecules and nitrogen molecules.
In this embodiment, the rear ends of two adjacent gill bionic blades in two adjacent pairs of gill bionic blades 10 are connected into a whole by an oblique and transverse connecting part.
Thus, the production and the manufacture are more convenient.
Specifically, the engine intake pipe is provided with three passage sections to form an intake separation structure, wherein the first passage section (vortex airflow forming section) of the three passage sections is used for generating vortex, and the design of four or six curved arc-shaped blades is adopted, so that the air generates turning energy and vortex core speed energy when passing through, and the vortex turbulence with vortex cores is coiled at the tail end of a vortex layer to pass through, thereby providing basic conditions for the air to enter the second passage section to generate shock wave airflow. The second channel section (shock wave airflow forming section) acts on the vortex to generate shock wave airflow in the section, the wave front of a triangular wing arc-shaped blade (namely, a vortex airflow forming blade) generating oblique shock wave flow and a half-crosscut multilayer notch corresponding to the included angle position of the incoming flow are adopted and bent into an arc surface and a half-sector blade (namely, a shock wave compression blade), and the design utilizes the characteristics of sudden change and turning change of the shock wave airflow density to ensure that the generated oblique shock wave multilayer airflow is compressed, superposed and enters a third channel. The third channel section (the rebound strengthening section) utilizes the design of a curved arc-shaped semi-sector blade (namely the gill bionic blade) with a plurality of layers of notches of the gill bionic principle, and further completes the respective enrichment of oxygen molecules and nitrogen molecules in the air by utilizing the difference characteristics of the mass and the volume of air molecules.
The engine air inlet pipe is preferably prepared by the following processing method during production, and the processing method comprises the following steps:
a, independently preparing an air inlet structure framework 21, and arranging the air inlet separation structure 2 in the air inlet structure framework;
b, independently producing and preparing the air flue pipe body 1, and installing the air inlet structure framework 21 in the air flue pipe body 1.
Therefore, compared with the method of directly processing the internal air inlet separation structure in the air passage pipe body production and processing process, the method adopts the mode that the air inlet separation structure and the air passage pipe body are processed respectively and then assembled, so that the processing is simpler and more reliable, and the cost is lower.
The step B has two specific following installation methods, one is to complete the independent production preparation of the gas pipeline 1 (namely, rely on the gas channel pipe body of the engine intake pipe processed and completed by the traditional processing method), then to set up the peripheral diameter of the gas inlet structure skeleton 21 and match the inner diameter of the gas channel pipe body (the matching means the same or slightly less than to make it realize the clamping as the standard), and then to plug the gas inlet structure skeleton into the clamping in the gas channel pipe body.
The installation mode is convenient and quick, is particularly suitable for the automobile engine which is produced or sold, and is installed and used when being modified and upgraded.
The second installation mode of the step B is to realize the packaging of the air inlet structure framework in the process of producing and preparing the air flue pipe body, namely, a mould is firstly adopted to prepare a half body structure of two symmetrical half-groove-shaped air flue pipe bodies; and then, the two half body structures are butted and buckled, the air inlet structure framework is packaged in the air inlet structure framework, the periphery of the air inlet structure framework is attached to the inner wall of the half body structure, and then the two half body structures are hermetically connected in a heat sealing mode to obtain the air flue pipe body packaged with the air inlet structure framework.
The installation mode is simple and easy, the air inlet structure framework and the air passage pipe body can be attached more, and no gap is reserved to improve the air inlet separation and enrichment treatment effect of the device on air. Is particularly suitable for being implemented and used in the production process of new vehicle engines.
Wherein, when the air inlet structure skeleton is independently prepared in the step A, the following preparation method can be adopted: a, dividing an air inlet structure framework 21 into a vortex airflow forming section framework 22, a shock wave airflow forming section framework 23 and a rebound reinforcement section framework 24, wherein the vortex airflow forming section 3 is formed in the vortex airflow forming section framework 22, the shock wave airflow forming section 4 is formed in the shock wave airflow forming section framework 23, and the rebound reinforcement section 5 is formed in the rebound reinforcement section framework 24; and respectively processing and manufacturing the three parts of frameworks independently;
and b, sequentially welding and fixing the frameworks of the three parts into a whole to obtain the air inlet structure framework.
Specifically, the air inlet structure framework 21 comprises a vortex airflow forming section framework 22, a shock wave airflow forming section framework 23 and a rebound reinforcement section framework 24 which are sequentially connected;
the vortex airflow forming section framework 22 comprises a circular vortex airflow forming section framework base ring 25 positioned at the rear end, the front side of the vortex airflow forming section framework base ring extends forwards along the axial direction to form a plurality of vortex airflow forming section framework connecting strips 26, the number of the vortex airflow forming section framework connecting strips is correspondingly matched with vortex airflow forming blades 6 (one blade can be arranged on a single vortex airflow forming section framework connecting strip or a plurality of blades are overlapped along the length direction) and are uniformly distributed along the circumferential direction, the rear end of the vortex airflow forming section framework connecting strip, the vortex airflow forming section framework base ring and one side of the rear end of the corresponding vortex airflow forming blade are connected into a whole, and the front end of the vortex airflow forming section framework connecting strip 26 is connected with the shock wave airflow forming section framework 23 and welded into a whole;
the shock wave airflow forming section framework 23 comprises a circular shock wave airflow forming section framework base ring 27 and a shock wave airflow forming section framework connecting strip 28 which are positioned at the rear end, the rear end of the shock wave airflow forming section framework base ring 27 is fixedly connected with the front end of a vortex airflow forming section framework connecting strip 26, the number of the shock wave airflow forming section framework connecting strips 28 is consistent with the number of vortex airflow forming blades 6, one side of the rear end of each shock wave airflow forming blade is obliquely connected with the front end of the shock wave airflow forming section framework base ring 27, the other side of the rear end of each shock wave airflow forming blade 8 is integrally connected with one side of the rear end of each shock wave compression blade 9 through the rear end of the shock wave airflow forming section framework connecting strip 28, and the front ends of the shock wave airflow forming section framework connecting strips 28 extend obliquely forwards and are integrally connected with the rebound reinforcing section framework 24 in a welding mode;
bounce reinforcement section skeleton 24 is including being located the annular bounce reinforcement section skeleton base ring 29 of the ring shape of being of rear end, bounce reinforcement section skeleton base ring 29 rear end and the 28 front end fixed connections of shock wave air forming section skeleton connecting strip, bounce reinforcement section skeleton base ring front end extends forward and is formed with a plurality of bounce reinforcement section skeleton connecting strips 30, 30 rear end one side of bounce reinforcement section skeleton connecting strip and bounce reinforcement section skeleton base ring 29 are fixed, bounce reinforcement section skeleton connecting strip rear end opposite side relies on oblique horizontal connecting portion to connect as an organic wholely with two gill bionic blade 10 rear ends in proper order.
Like this, because the inside blade structure of three partial skeleton is totally different, so weld as an organic whole again after manufacturing alone respectively, reduce the processing degree of difficulty, improve machining efficiency for processing is simple more feasible. Meanwhile, the three part frameworks have the advantages of simple structure, reliable connection, convenient processing, no occupation of redundant flow channel space, capability of well finishing the function of corresponding channel sections, and the like.
Wherein, still be provided with the front end reinforcing ring 31 of an annular structure at bounce reinforcement section skeleton front end, bounce reinforcement section skeleton connecting strip front end and front end reinforcing ring in the bounce reinforcement section skeleton are welded as an organic whole. This may further improve the integrity and structural strength of the air intake structural skeleton.
The following method can be preferably adopted to process and manufacture the vortex airflow forming section framework: 1) firstly, preparing a vortex airflow forming section framework substrate 41, wherein the vortex airflow forming section framework substrate is integrally rectangular and is provided with a strip-shaped vortex airflow forming section framework annular strip 42 at the rear side edge, the front side of the vortex airflow forming section framework annular strip is divided into a plurality of units, and each unit comprises a vortex airflow forming section framework connecting strip 26 extending forwards along the vortex airflow forming section framework annular strip (the better choice is that the vortex airflow forming section framework connecting strip is vertically connected with the vortex airflow forming section framework annular strip so as to be more beneficial to punching forming and save materials); the vortex airflow forming section framework connecting strip side is connected with a vortex airflow forming blade substrate 43 (the better choice is that the vortex airflow forming blade substrate is parallelogram to fully utilize the plate material and improve the guiding effect of the formed blade to the airflow), the vortex airflow forming blade substrate 43 is inclined from one side far away from the vortex airflow forming section framework connecting strip to the direction far away from the vortex airflow forming section framework base ring strip 42, so that a triangular gap is formed between the vortex airflow forming blade substrate and the adjacent side of the vortex airflow forming section framework base ring strip in a separated mode, a cutting seam is arranged on the joint side of the vortex airflow forming blade substrate 43 and the vortex airflow forming section framework connecting strip 26 in the direction departing from the vortex airflow forming section framework base ring strip 42, the vortex airflow forming blade substrate is connected with the vortex airflow forming section framework connecting strip 26 only at a position close to one corner end part of the vortex airflow forming section framework base ring strip;
2) bending two ends of the vortex airflow forming section framework base ring strip 42 along the length direction, welding and fixing the two ends into a circular shape to obtain a vortex airflow forming section framework base ring 25, and then bending one end of the vortex airflow forming blade substrate 43 far away from the vortex airflow forming section framework base ring inwards and forwards to obtain a vortex airflow forming blade 6; and further obtaining the vortex airflow forming section framework.
The vortex airflow forming section framework manufactured in the method has the advantages of convenience and rapidness in processing, low cost and the like.
When the vortex airflow forming section framework substrate 41 is prepared, a rectangular metal plate for preparing the vortex airflow forming section framework is obtained, and then the vortex airflow forming section framework substrate structure is prepared by adopting a punching method, a laser cutting method or a linear cutting method. The processing is simple, convenient, efficient and low in cost.
Wherein, at vortex airflow shaping section skeleton base ring strip 42 rear end side limit, be formed with an alignment in the middle part position of the unit that corresponds every vortex airflow shaping section skeleton connecting strip and use recess breach 44 for the in-process that bends vortex airflow shaping blade substrate relies on this alignment to use the recess breach as the benchmark, can judge better whether bend to the position.
Wherein, the following method can be preferably adopted to process and manufacture the shock wave airflow forming section framework: 1) firstly, preparing a shock wave airflow forming section framework substrate 51, wherein the whole shock wave airflow forming section framework substrate is rectangular, the back side of the shock wave airflow forming section framework substrate is provided with a strip-shaped shock wave airflow forming section framework base ring strip 52, the front side of the shock wave airflow forming section framework base ring strip is provided with a plurality of same structural units at equal intervals, each structural unit comprises a shock wave airflow forming blade substrate 53, a shock wave airflow forming framework connecting strip 54 and a shock wave compression blade substrate 55, the shock wave airflow forming blade substrate is triangular (one side of the preferred triangle is perpendicular to the shock wave airflow forming section framework base ring strip to save plates), one end of the bottom edge of the triangle is connected with the shock wave airflow forming section framework base ring strip into a whole, the other end of the bottom edge of the triangle is sequentially connected with the back end of the shock wave airflow forming framework connecting strip and the back end of the shock wave compression blade into a whole in an inclined mode, the front end of the shock wave airflow forming framework connecting strip 54 extends forwards in an inclined manner, and two sides of the shock wave airflow forming framework connecting strip respectively form intervals with the shock wave airflow forming blade substrate 53 and the shock wave compression blade substrate 55, (as an optimized shock wave compression blade substrate, the whole shock wave compression blade substrate is quadrilateral, the rear end edge of the shock wave airflow forming framework connecting strip and the bottom edge of the shock wave airflow forming blade substrate form the same straight line, so that a plate material is utilized to the maximum extent), and a plurality of cutting seams are transversely formed on the side edge of the shock wave compression blade substrate 55 departing from the direction of the shock wave airflow forming framework connecting strip (as an optimized side edge of the shock wave compression blade substrate departing from the direction of the shock wave airflow forming framework;
2) bending two ends of a framework base ring strip 52 in the length direction of a shock wave airflow forming section, welding and fixing the two ends into a circular shape to obtain a framework base ring 27 of the shock wave airflow forming section, then bending the front end of a shock wave airflow forming blade substrate 53 inwards and forwards to obtain a shock wave airflow forming blade 8, bending the end angle position of the shock wave compression blade substrate 55 far away from the direction of the shock wave airflow forming blade substrate inwards and forwards and drawing the end angle position towards the front end of the shock wave airflow forming blade, so that cutting seams on the edge of the shock wave compression blade substrate in the bending process are sequentially staggered to obtain a shock wave compression blade 9, and in the process of bending the shock wave airflow forming blade substrate and the shock wave compression blade substrate, keeping a shock wave airflow forming framework connecting strip in the circumferential range where the framework base ring of the shock wave airflow forming section is located; thereby obtaining the shock wave airflow forming section framework.
Thus, the shock wave airflow forming section framework is manufactured, and the shock wave airflow forming section framework has the advantages of convenience and rapidness in processing, low cost and the like.
When the shock wave airflow forming section framework substrate 51 is prepared, a rectangular metal plate for preparing the shock wave airflow forming section framework is obtained, and then the shock wave airflow forming section framework substrate structure is prepared by adopting a punching method, a laser cutting method or a linear cutting method. The processing is simple, convenient, efficient and low in cost.
The rear end side of the framework base ring strip of the shock wave airflow forming section is provided with an alignment groove notch at the middle position of the structural unit corresponding to each shock wave airflow forming section framework connecting strip, so that in the process of bending the shock wave airflow forming blade substrate and shock wave compression blade substrate, whether the blade substrate is bent in place can be better judged by taking the alignment groove notch as a reference. Meanwhile, in the process of welding and connecting the vortex airflow forming section framework and the shock wave airflow forming section framework, the requirement of welding angles in the circumferential direction can be conveniently met by means of aligning the notch of the alignment groove.
The rebound reinforcement section framework can be processed and manufactured by the following method preferably: 1) firstly, preparing a bounce reinforcement section framework base plate 61, wherein the bounce reinforcement section framework base plate is rectangular as a whole, the rear side edge of the bounce reinforcement section framework base plate is provided with a strip-shaped bounce reinforcement section framework base ring strip 62, the front side of the bounce reinforcement section framework base ring strip is provided with a plurality of same unit structures at equal intervals, each unit structure comprises a bounce reinforcement section framework connecting strip 30 and two gill bionic blade substrates 63, the rear ends of the bounce reinforcement section framework connecting strips are obliquely and integrally arranged in parallel, preferably, one side of the bounce reinforcement section framework connecting strip, which is far away from the gill bionic blade substrates, is vertical to the bounce reinforcement section framework base ring strip so as to save plate cutting space, gaps are reserved between the bounce reinforcement section framework connecting strip 30 and the gill bionic blade substrates 63 and between two adjacent gill bionic blade substrates, (preferably, the outer side edge of the gill bionic blade substrate at the outermost side is vertical to the bounce reinforcement section framework base ring strip 62, to save the cutting space of the plate) a plurality of cutting seams are transversely arranged on the side edge of one side of each gill bionic blade substrate, which is far away from the framework connecting strip of the rebound reinforcing section;
2) bending two ends of the framework base ring strip 62 in the length direction of the rebound reinforcing section, welding and fixing the two ends into a ring shape to obtain a framework base ring 29 of the rebound reinforcing section, then bending the front ends of the two gill bionic blade substrates, which are respectively provided with the cutting seams, inwards and forwards, so that the cutting seams on the edges of the gill bionic blade substrates are staggered in sequence in the bending process to obtain the gill bionic blades, and the inner front ends of the two adjacent gill bionic blade substrates in the two adjacent unit structures are close to each other to form a pair; thereby obtaining the framework of the rebound strengthening section.
Thus, the framework of the rebound reinforcing section is manufactured, and the framework has the advantages of convenience and rapidness in processing, low cost and the like.
When the framework substrate 61 of the rebound reinforcement section is prepared, a rectangular metal plate for preparing the framework of the rebound reinforcement section is obtained, and then the framework substrate structure of the rebound reinforcement section is prepared by adopting a punching method, a laser cutting method or a linear cutting method. The processing is simple, convenient, efficient and low in cost.
Wherein, at the side of bounce-back enhancement section skeleton base ring back end side, be formed with a recess breach for alignment in the middle part position that corresponds every unit structure for at the in-process of crooked gill bionic blade substrate, rely on this to aim at with the recess breach as the benchmark, can judge better whether crooked target in place. Meanwhile, in the process of welding and connecting the shock wave airflow forming section framework and the rebounding reinforcing section framework, the welding angle requirement on the circumferential direction can be conveniently ensured by means of aligning the groove notch for aligning.
To sum up, the adoption is provided with the utility model discloses the engine intake pipe of structure, when carrying out front end processing to the combustion chamber air inlet, with prior art to the air in the nitrogen oxygen control thinking of the component proportion that admits air of control after separating, change for need not realize the thorough separation of oxygen nitrogen composition and only make it keep the state of two big compositions enrichment separately of nitrogen gas and oxygen and enter into the combustion chamber, and then make it be favorable to the combustion chamber abundant combustion, produce energy saving and emission reduction effect, reduce emission pollution, improve emission standard, just so greatly reduce treatment cost and make it be suitable for practical application.
In order to further verify the exhaust emission pollution prevention effect of the engine provided with the structure of the utility model, the applicant carries out vehicle inspection at a ten-weir. The inspection vehicle is the car, and the vehicle model is hippocampi tablet/HMC 7168E5S0, and check-up date is 20190904, and the inspection institution name is ten weir as leading to motor vehicle safety technology and detects limited company, and detection method is steady state operating mode method, adopts not installing during the detection the utility model discloses the automobile inspection of the engine intake pipe of structure, the inspection report serial number is 420303191909041034500108, under steady state operating mode method detects, NO content NO 10-6Is 259. Adopt again and installed the utility model discloses automobile inspection behind the engine intake pipe of structure detects the report serial number and is 420303191909040957010106, detects its NO content and reduces to NO 10-6Is 15. The event can further assist the demonstration the utility model discloses can greatly improve combustion chamber combustion efficiency to and reduce the effect that pollutes and discharges the discarded object.
Claims (10)
1. The utility model provides a bounce-back enhancement section skeleton, a serial communication port, including wholly being annular fixed base component, still include the bionical blade of multiunit gill, the bionical blade of each group gill is fixed on fixed base component along circumference evenly distributed, the bionical blade of gill wholly is quadrangle and one side inside the place ahead bending and stretches out and make the monolithic wholly be the camber, and the bionical blade of every gill stretches out the distance that one side stretches out and crooked angle along the air current direction of advance crescent, and the bionical blade of every gill stretches out a side edge and transversely is provided with the multichannel joint-cutting, and partial blade between the adjacent joint-cutting staggers gradually because the bending angle is different.
2. The framework of claim 1, wherein the gill bionic blades are arranged in pairs, and the front ends of each pair of gill bionic blades, which extend out of one side of the gill bionic blades and move forward along the airflow direction, gradually approach each other, so that a semi-enclosed space structure is formed between each pair of gill bionic blades, wherein the cross section of the space integral structure gradually narrows forward along the air inlet direction.
3. The framework of claim 1, wherein the back ends of two adjacent gill bionic blades of two adjacent pairs of gill bionic blades are connected into a whole by an inclined transverse connecting part.
4. The rebounding reinforcement section skeleton according to claim 1, wherein the rebounding reinforcement section skeleton comprises a circular rebounding reinforcement section skeleton base ring located at a rear end, the rebounding reinforcement section skeleton base ring is used for fixing a base component, a rear end of the rebounding reinforcement section skeleton base ring is used for being fixedly connected with a front end of a shock wave airforming section skeleton connecting strip, a plurality of rebounding reinforcement section skeleton connecting strips are formed by forward extending of the front end of the rebounding reinforcement section skeleton base ring, one side of the rear end of each rebounding reinforcement section skeleton connecting strip is fixed with the rebounding reinforcement section skeleton base ring, and the other side of the rear end of each rebounding reinforcement section skeleton connecting strip is sequentially connected with the rear ends of the two gill bionic blades into a whole by virtue of an oblique and transverse connecting part.
5. The framework of the rebound reinforcement section as set forth in claim 4, wherein a front end reinforcing ring of a ring structure is further provided at the front end of the framework of the rebound reinforcement section, and the front end of the connecting strip of the framework of the rebound reinforcement section and the front end reinforcing ring are welded together.
6. A rebounding reinforcing section framework substrate structure for preparing the rebounding reinforcing section framework of claim 5 is characterized in that the rebounding reinforcing section framework substrate is rectangular in whole, the rear side edge of the rebounding reinforcing section framework substrate is provided with a long-strip-shaped rebounding reinforcing section framework base ring strip, a plurality of identical unit structures are arranged on the front side of the rebounding reinforcing section framework base ring strip at equal intervals, each unit structure comprises a rebounding reinforcing section framework connecting strip and two gill bionic blade substrates, the rear ends of the rebounding reinforcing section framework connecting strip and the gill bionic blade substrates are obliquely and integrally arranged, gaps are reserved between the rebounding reinforcing section framework connecting strip and the gill bionic blade substrates and between the two adjacent gill bionic blade substrates, and a plurality of cutting seams are transversely formed in one side edge of each gill bionic blade substrate, which deviates from the rebounding reinforcing section framework connecting strip.
7. The structure of claim 6, wherein the side of the connecting strip of the framework of the rebound reinforcement section facing away from the gill bionic blade substrate is perpendicular to the ring strip of the framework of the rebound reinforcement section.
8. The framework substrate structure of claim 6, wherein the outer side of the gill bionic blade substrate at the outermost side is perpendicular to the ring strips of the framework substrate.
9. The structure of the framework substrate of the rebound reinforcement section as set forth in claim 6, wherein the framework substrate of the rebound reinforcement section is made of a metal plate for preparing the rectangular framework of the rebound reinforcement section by a method of punching, laser cutting or wire cutting.
10. The framework slab structure of claim 6, wherein an alignment notch is formed at the rear end side of the framework base ring strip of the rebound reinforcement section at a position corresponding to the middle of each unit structure.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921955624.3U CN211038818U (en) | 2019-11-13 | 2019-11-13 | Rebound reinforcing section framework and framework substrate structure thereof |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921955624.3U CN211038818U (en) | 2019-11-13 | 2019-11-13 | Rebound reinforcing section framework and framework substrate structure thereof |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN211038818U true CN211038818U (en) | 2020-07-17 |
Family
ID=71564723
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201921955624.3U Expired - Fee Related CN211038818U (en) | 2019-11-13 | 2019-11-13 | Rebound reinforcing section framework and framework substrate structure thereof |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN211038818U (en) |
-
2019
- 2019-11-13 CN CN201921955624.3U patent/CN211038818U/en not_active Expired - Fee Related
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN107620653B (en) | A kind of disturbing flow device for solid-rocket combustion gas scramjet engine | |
| CN205279155U (en) | Ran shao shi cui puts out pore structure | |
| CN105026697A (en) | Radial diffuser exhaust system | |
| CN211038818U (en) | Rebound reinforcing section framework and framework substrate structure thereof | |
| CN110671240A (en) | Combustion chamber air intake control method | |
| CN110966620B (en) | Single-tube flameless combustion chamber of ground gas turbine | |
| CN211038817U (en) | Vortex airflow forming section framework and framework substrate structure thereof | |
| CN110805510A (en) | Engine air inlet pipe machining method | |
| CN110757104A (en) | Preparation method of air inlet structure framework for combustion supporting of engine air inlet pipe | |
| CN211038819U (en) | Shock wave airflow channel section framework and framework substrate structure thereof | |
| CN211038820U (en) | Air inlet structure of engine combustion chamber | |
| CN102278232A (en) | Modified scramjet combustion chamber and design method of swirler thereof | |
| CN207365055U (en) | A kind of eddy flow microring array combustor | |
| CN110671243A (en) | Air inlet pipe of engine | |
| CN206753696U (en) | One kind burning blender burning mixed structure | |
| CN106524159A (en) | Swirling piece, swirling burner and manufacturing method of swirling burner | |
| CN214660392U (en) | Improve exhaust gas turbocharger turbine case of engine exhaust pulse pressure | |
| CN206320747U (en) | Spinning disk, turbulent burner | |
| CN205876438U (en) | Automobile exhaust secondary purifier | |
| CN114123654A (en) | Split type air cooling device for large-scale vehicle-mounted generator | |
| CN208967842U (en) | A kind of advanced standing vortex burning chamber of built-in flow spoiler | |
| CN206944136U (en) | Boiler separates burning device | |
| CN2216147Y (en) | Improved rotation induction device for IC engine | |
| CN104153871A (en) | Automobile emission-reduction accelerating device | |
| CN109630328A (en) | A kind of composite air intake road for using gasoline ignition engine instead on the basis of diesel engine |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| GR01 | Patent grant | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20200717 |