JP2022517909A - Ultrasonic fuel exciter - Google Patents

Abstract

The present invention discloses an ultrasonic fuel excitation device. The ultrasonic fuel exciter includes a case, which comprises an outer layer metal case and an internal insulating layer, in which an internal cavity filled with insulating liquid fuel, at least one fuel inlet, and the like. It has at least one fuel outlet. The internal cavity of the case includes at least an ultrasonic energy conversion unit, a first electrode conductive connection block, a first conductive screw, a conductive spring, a second electrode conductive connection block, and a second conductive screw. The present invention improves fuel utilization, powers the device, saves fuel, reduces harmful gas emissions, protects the environment, reduces device operating noise, cleans oil channels, and carbon. Reduces deposition and facilitates installation and maintenance. The ultrasonic excitation device can be widely applied to various devices that acquire energy with fuel, and has strong adaptability. [Selection diagram] Fig. 1

Description

The present invention relates to an ultrasonic excitation device, specifically, an ultrasonic fuel excitation device.

An engine is a mechanical device that uses a fuel to generate power, that is, a machine that converts fuel from chemical energy to thermal energy and finally to mechanical energy.
Engine efficiency has two indicators: mechanical efficiency and thermal efficiency. Here, thermal efficiency refers to the ratio of the amount of heat to work after the fuel burns to the total amount of heat that can be generated. A part of the heat generated by the complete combustion of the fuel is taken away to the engine cooling system, a part is discharged together with the exhaust gas, and only a small amount of heat is used for work. The thermal efficiency of a conventional internal combustion engine is low, and the thermal efficiency of a 4-stroke gasoline engine is generally 20% to 25%, and even a high-performance engine has a thermal efficiency of less than 30%.

In order to solve the problems that the fuel heat loss of a conventional engine is large and the thermal efficiency is low, the present invention provides an ultrasonic fuel excitation device.

An ultrasonic fuel exciter comprising an insulating case, wherein the insulating case has an internal cavity filled with an insulating liquid fuel, at least one fuel inlet, and at least one fuel outlet.
The internal cavity of the insulating case includes at least an ultrasonic energy conversion unit, a first electrode conductive connection block, a first conductive connection member, a conductive spring, a second electrode conductive connection block, and a second conductive connection member. And have.
As a preferred embodiment thereof, the ultrasonic energy conversion unit includes an ultrasonic energy conversion element having a front surface facing the fuel outlet side and a back surface facing the fuel inlet side. The ultrasonic energy conversion element is installed in the internal cavity of the insulating case and is completely immersed in the liquid fuel. The ultrasonic energy conversion element is provided with one or a plurality of ultrasonic energy conversion element through holes penetrating the front surface and the back surface of the ultrasonic energy conversion element, and the first electrode conductive connection block and the second electrode conductive connection block are provided. Is provided with a fuel through hole, the ultrasonic energy conversion element through hole and the fuel through hole form a fuel passage that communicates the fuel inlet and the fuel outlet, and the insulating liquid fuel has a through hole from the back surface of the ultrasonic energy conversion element. It flows to the front through.

In a preferred embodiment thereof, the ultrasonic energy conversion unit includes two or more ultrasonic energy conversion elements. This has the effect of improving the effect. The front of each of the ultrasonic energy conversion elements faces the fuel outlet side, the back surface faces the fuel inlet side, and the two adjacent ultrasonic energy conversion elements are connected in series by a conductive connection assembly to convert each ultrasonic energy. Each element is provided with one or more ultrasonic energy conversion element through holes penetrating the front and back of the ultrasonic energy conversion element, and the first electrode conductive connection block and the second electrode conductive connection block penetrate fuel. Holes are provided, and the ultrasonic energy conversion element through holes of each ultrasonic energy conversion element communicate with each other to form a fuel passage that communicates the fuel through hole, the fuel inlet, and the fuel outlet, and the insulating liquid fuel is used as fuel. It flows in along the back surface of the ultrasonic energy conversion element on the inlet side and passes through each ultrasonic energy conversion element in order until it flows out from the front of the ultrasonic energy conversion element on the fuel outlet side.

The internal cavity of the insulating case includes at least one ultrasonic energy conversion element whose front surface faces the fuel outlet side and its back surface faces the fuel inlet side, and the ultrasonic energy conversion element is installed in the internal cavity of the insulating case. The ultrasonic energy conversion unit completely immersed in the insulating liquid fuel, the first electrode conductive connection block connected to the electrode of the ultrasonic energy conversion unit, and the first electrode conductive connection block are fixed to the insulating case. A first conductive connecting member, a conductive spring connected to another electrode of the ultrasonic energy conversion unit, a second electrode conductive connection block connected to the conductive spring, and the second electrode conductive connection block. The first conductive connecting member and the second conductive connecting member are connected to a power source, including a second conductive connecting member fixed to the insulating case.

The first electrode conductive connection block and the conductive spring are connected to both ends of the ultrasonic energy conversion unit, respectively. That is, when the ultrasonic energy conversion unit includes only one ultrasonic energy conversion element, the first electrode conductive connection block and the conductive spring are connected to the front surface and the back surface of the ultrasonic energy conversion element, respectively. When the ultrasonic energy conversion unit includes two or more ultrasonic energy conversion elements, the first electrode conductive connection block is connected to the front of the ultrasonic energy conversion element closest to the fuel outlet side, and the conductive spring is among them. It is connected to the back surface of the ultrasonic energy transformation element closest to the fuel inlet side.

The first conductive connection member fixes the first electrode conductive connection block to the case, and the first signal line is connected to the first conductive connection member. The second electrode conductive connection block and the conductive spring are electrically connected. The second conductive connecting member fixes the second electrode conductive connecting block to the case, and the second signal line is connected to the second conductive connecting member. The first signal line and the second signal line are connected to the inner and outer interface electrodes of the actuator, respectively. The first conductive connecting member and the second conductive connecting member have the functions of sealing and conductivity at the same time, avoid the problem that the conducting wire does not pass, the oil resistance due to the presence of the insulating layer is not obtained, and the aging is likely to occur, and the connection is made. The seal is durable and reliable.

As a preferred embodiment thereof, an outer layer metal case is provided outside the insulating case, the outer layer metal case includes an inlet metal seal head, an outlet metal seal head, and a metal housing, and the metal housing is provided with a housing screw. The inlet metal seal head and the outlet metal seal head are fixedly connected, and the first conductive connecting member and the second conductive connecting member are connected to a power source by a first signal line and a second signal line, respectively. The conductor shielding layer of the first signal line and the conductor shielding layer of the second signal line are each connected to the metal housing.
The conductor shielding layer can be connected to the metal housing of the actuator via a housing screw to shield and prevent interference.

As a preferred embodiment thereof, the insulating case includes at least an inlet insulating nozzle, an outlet insulating nozzle, and an insulating case. The inlet insulating nozzle is installed at the bottom end of the ultrasonic fuel exciter, the middle of which has the fuel inlet. The outlet insulating nozzle is installed at the top end of the ultrasonic fuel exciter, the middle of which has the fuel outlet. The insulating inner sleeve was fixedly connected to the inlet insulating nozzle and the outlet insulating nozzle by the first conductive connecting member and the second conductive connecting member, respectively.

In a preferred embodiment thereof, the conductive connection assembly includes a metal spring seat and a connecting conductive spring provided in the metal spring seat.

In a preferred embodiment thereof, the conductive spring is fitted in an internal metal oil guide nozzle, and the middle portion of the internal metal oil guide nozzle has an internal passage for communicating the fuel inlet and the fuel passage in the ultrasonic energy conversion element.

As a preferred embodiment thereof, the inlet and outlet insulating nozzles are each composed of a metal nozzle and an insulating sleeve, and the metal nozzles of the inlet and outlet insulating nozzles are a second electrode conductive connection block and a first electrode conductive connection, respectively. It is integrally connected to the block. The insulating sleeve is fitted to the outside of the metal nozzle to form an insulating layer.

As a preferred embodiment thereof, the outside of the first conductive connecting member and the second conductive connecting member is filled with an electrode sealant.

As a preferred embodiment thereof, an interface seal gasket is provided on the contact surface between the fuel inlet side and the inlet insulation nozzle of the insulation case, and an interface seal gasket is provided on the contact surface between the fuel outlet side of the insulation case and the outlet insulation nozzle. Be done.

As a preferred embodiment thereof, the first conductive connecting member and the second conductive connecting member are conductive screws.

As a preferred embodiment thereof, the ultrasonic energy conversion element is an ultrasonic transducer or an ultrasonic energy conversion sheet. The ultrasonic transducer, the ultrasonic energy conversion sheet, and the front and back surfaces thereof are all technical common sense in this field, and description thereof will be omitted here.

In the present invention, by exciting the fuel using ultrasonic energy, the fuel is more easily atomized after being excited by high-frequency ultrasonic waves in the present apparatus, and various components in the fuel are easily sufficiently burned. Use this device to improve fuel utilization, enhance the power of the device, save fuel, reduce harmful gas emissions, protect the environment, reduce the operating noise of the device, clean the oil passages. It reduces carbon deposits and is easy to install and maintain. The ultrasonic excitation device can be widely applied to a device that acquires energy with various fuels, and has strong adaptability. In addition, adding an actuator to the spare oil pipeline is highly compatible and does not affect the performance of the original device after the actuator device is stopped.

Is a structural schematic diagram of the ultrasonic fuel excitation device according to the first embodiment. Is a structural schematic diagram of the ultrasonic fuel excitation device according to the second embodiment.

The structure of the ultrasonic fuel excitation device of the present invention will be further described with reference to the following examples.
(Example 1)

FIG. 1 shows a standard ultrasonic fuel exciter. That is, the ultrasonic energy conversion unit includes only one ultrasonic energy conversion sheet 8.

The case of the ultrasonic fuel excitation device is composed of an outer layer metal case and an inner insulating layer, where the outer layer metal case is composed of an inlet metal seal head 21, an outlet metal seal head 22 and a metal housing 24. The inlet metal seal head 21 is fixed to the bottom of the metal housing 24 by two housing screws 20, and the outlet metal seal head 22 is fixed to the top of the metal housing 24 by the housing screws 20. The internal insulating layer is composed of an inlet insulating nozzle 2, an outlet insulating nozzle 1, and an insulating case. The inlet insulating nozzle 2 is hermetically installed in the inlet metal seal head 21 and has a fuel inlet inside thereof. The outlet insulating nozzle 1 is hermetically installed in the outlet metal seal head 22, and has a fuel outlet inside thereof. The insulating case 3 is fixedly connected to the inlet insulating nozzle 2 and the outlet insulating nozzle 1 by the first conductive screw 16 and the second conductive screw 17, respectively, and the interface seal gasket 13 is installed at the connection portion and sealed. It forms an insulating internal cavity and is filled with insulating liquid fuel. An interface seal O-type gasket 23 is installed between the metal housing 24 and the insulating case to seal the metal housing 24. The outside of the first conductive screw 16 and the second conductive screw 17 is filled with the electrode sealant 4.

The ultrasonic energy conversion sheet 8 is fixed to the insulating internal cavity by the energy conversion sheet fixing insulating nut 12. That is, the ultrasonic energy conversion sheet 8 is completely immersed in the insulating liquid fuel, and the front surface thereof faces the fuel outlet side and the back surface faces the fuel inlet side. The ultrasonic energy conversion sheet 8 is provided with two ultrasonic energy conversion sheet through holes 9 penetrating the front surface and the back surface thereof. The ultrasonic energy conversion sheet through hole 9 is a fuel passage that communicates the fuel inlet and the fuel outlet, and the insulating liquid fuel flows from the back surface of the ultrasonic energy conversion element to the front through the through hole.

The first electrode conductive connection block 5 is installed on the ultrasonic energy conversion sheet 8 and comes into contact with the front surface thereof. The first conductive screw 16 penetrates the inlet insulating nozzle 2 and the insulating inner sleeve 3 in order and is fixed to the first electrode conductive connection block 5, and crimps the first electrode conductive connection block 5 and the ultrasonic energy conversion sheet 8. A first metal conductive gasket 14 is installed on the contact surface between the first conductive screw 16 and the inlet insulating nozzle 2, and the first signal line 18 is locked to the first metal conductive gasket 14 by the first conductive screw 16. The front surface of the ultrasonic energy conversion sheet 8 is connected to one pole of the power supply by the first electrode conductive connection block 5, the first conductive screw 16, and the first signal line 18.

The conductive spring 11 is connected to the back surface of the ultrasonic energy conversion sheet 8. The conductive spring 11 is fitted in the internal metal oil guide nozzle 7, and the central portion of the internal metal oil guide nozzle 7 has an internal passage for communicating the fuel inlet and the ultrasonic energy conversion sheet through hole 9. The second electrode conductive connection block 6 is fixedly connected to the internal metal oil guide nozzle 7. The second conductive screw 17 passes through the inlet insulating nozzle 2 and the insulating inner sleeve 3 in order, and is fixed below the second electrode conductive connection block 6. A second metal conductive gasket 15 is installed on the contact surface between the second conductive screw 17 and the inlet insulating nozzle 2, and the second signal line 19 is locked to the second metal conductive gasket 15 by the second conductive screw 17. The back surface of the ultrasonic energy conversion sheet 8 is connected to the other pole of the power supply by the second electrode conductive connection block 6, the second conductive screw 17, and the second signal line 19.

The conductor shielding layer of the first signal line (not shown) and the conductor shielding layer of the second signal line 19 (not shown) are each connected to the metal housing 24 by the housing screw 20. The conductor shielding layer can be connected to the metal housing 24 of the actuator via the housing screw 20 to shield and prevent interference.

The flow direction of the liquid fuel flows from the fuel inlet through the internal passage of the internal metal oil guide nozzle 7, flows into the ultrasonic energy conversion sheet through hole 9 from the back surface and flows out from the front surface, and the energy is generated by the action of the ultrasonic energy conversion sheet 8. Complete the conversion and then drain from the fuel outlet.
(Example 2)

FIG. 2 shows an enhanced ultrasonic fuel exciter. That is, the ultrasonic energy conversion unit includes two ultrasonic energy conversion sheets connected in series, that is, a first ultrasonic energy conversion sheet 8a and a second ultrasonic energy conversion sheet 8b.

The case of the ultrasonic fuel excitation device is composed of an outer layer metal case and an inner insulating layer, where the outer layer metal case is composed of an inlet metal seal head 21, an outlet metal seal head 22 and a metal housing 24. The inlet metal seal head 21 is fixed to the bottom of the metal housing 24 by two housing screws 20, and the outlet metal seal head 22 is fixed to the top of the metal housing 24 by two housing screws 20. The internal insulating layer is composed of an inlet insulating nozzle 2, an outlet insulating nozzle 1, and an insulating case 3. The inlet insulating nozzle 2 is hermetically installed in the inlet metal seal head 21 and has a fuel inlet inside thereof. The outlet insulating nozzle 1 is hermetically installed in the outlet metal seal head 22, and has a fuel outlet inside thereof. The insulating case 3 is fixedly connected to the inlet insulating nozzle 2 and the outlet insulating nozzle 1 by the first conductive screw 16 and the second conductive screw 17, respectively, and the interface seal gasket 13 is installed at the connection portion and sealed. It forms an insulating internal cavity and is filled with insulating liquid fuel. An interface seal O-type gasket 23 is installed between the metal housing 24 and the insulating inner sleeve 3 to seal the metal housing 24.

The outside of the first conductive screw 16 and the second conductive screw 17 is filled with the electrode sealant 4.

The first and second ultrasonic energy conversion sheets 8a and 8b are both installed in the insulating internal cavity with the front facing the fuel outlet side and the back facing the fuel inlet side, and the first and second ultrasonic energy conversion sheets are converted. The sheets 8a and 8b are completely immersed in the insulating liquid fuel. Among them, the first ultrasonic energy conversion sheet 8a is installed directly above the second ultrasonic energy conversion sheet 8b, and the energy conversion sheet fixed insulating nut 12 and the insulating inner layer are fixedly connected by threads to obtain the second ultrasonic energy. The conversion sheet 8b is installed on the energy conversion sheet fixed insulating nut 12. A first ultrasonic energy conversion sheet through hole 9a penetrating the front surface and the back surface thereof is provided in the middle of the first ultrasonic energy conversion sheet 8a, and the two side portions of the second ultrasonic energy conversion sheet 8b are respectively provided with the first ultrasonic energy conversion sheet through hole 9a. A second ultrasonic energy conversion sheet through hole 9b that penetrates the front surface and the back surface is provided. A metal spring seat 26 is installed in front of the second ultrasonic energy conversion sheet 8b, the metal spring seat 26 is fixed in the insulating sleeve 25, and a metal spring seat through hole 27 is installed at the bottom of the metal spring seat 26. In addition, a support leg erected on the edge of the second ultrasonic energy conversion sheet 8b is installed on the outside of the bottom, a connecting conductive spring 10 is attached in the metal spring seat 26, and the connecting conductive spring 10 is the first ultrasonic wave. It is connected to the back surface of the energy conversion sheet 8a. The first and second ultrasonic energy conversion sheet through holes 9a and 9b, the metal spring seat through holes 27, and the connecting conductive spring 10 form a fuel passage that communicates the fuel inlet and the fuel outlet, and the insulating liquid fuel has ultrasonic energy. It flows from the back surface of the conversion element to the front surface through the through hole.

The first electrode conductive connection block 5 is connected to the front surface of the first ultrasonic energy conversion sheet 8a, and the conductive spring 11 is connected to the back surface of the second ultrasonic energy conversion sheet 8b. The first conductive screw 16 passes through the inlet insulating nozzle 2 and the insulating case in order and is fixed to the first electrode conductive connection block 5. A first metal conductive gasket 14 is installed on the contact surface between the first conductive screw 16 and the inlet insulating nozzle 2, and the first signal line 18 is locked to the first metal conductive gasket 14 by the first conductive screw 16. The front surface of the first ultrasonic energy conversion sheet 8a is connected to one pole of the power supply by the first electrode conductive connection block 5, the first conductive screw 16, and the first signal line 18.
The conductive spring 11 is connected to the back surface of the second ultrasonic energy conversion sheet 8b. The conductive spring 11 is fitted in the internal metal oil guide nozzle 7, and the central portion of the internal metal oil guide nozzle 7 has an internal passage for communicating the fuel inlet and the ultrasonic energy conversion sheet through hole. The second electrode conductive connection block 6 is fixedly connected to the internal metal oil guide nozzle 7. The second conductive screw 17 passes through the inlet insulating nozzle 2 and the insulating inner sleeve 3 in order, and is fixed below the second electrode conductive connection block 6. A second metal conductive gasket 15 is installed on the contact surface between the second conductive screw 17 and the inlet insulating nozzle 2, and the second signal line 19 is locked to the second metal conductive gasket 15 by the second conductive screw 17. The back surface of the second ultrasonic energy conversion sheet 8b is connected to the other pole of the power supply by the second electrode conductive connection block 6, the second conductive screw 17, and the second signal line 19.

The conductor shielding layer of the first signal line (not shown) and the conductor shielding layer of the second signal line (not shown) are each connected to the metal housing 24 by the housing screw 20. The conductor shielding layer can be connected to the metal housing 24 of the actuator via the housing screw 20 to shield and prevent interference.

The flow direction of the liquid fuel flows from the fuel inlet through the internal passage of the internal metal oil guide nozzle 7, flows into the second ultrasonic energy conversion sheet through hole 9b from the back surface, flows out from the front surface, and is connected through the metal spring seat through hole 27. It penetrates the center of the conductive spring 10, flows from the back surface to the first ultrasonic energy conversion sheet through hole 9a, flows out from the front surface, completes the energy conversion by the action of the ultrasonic energy conversion sheets 8a and 8b, and then completes the energy conversion, and then the fuel outlet. Outflow from.
The above will display and explain the basic principles and main features of the present invention and the advantages of the present invention. As will be appreciated by those skilled in the art, the present invention is not limited to the above embodiments, and those described in the above examples and the specification merely explain the principle of the present invention. The invention is further modified and improved on the premise that it does not deviate from the spirit and scope of the invention, all of which are within the scope of the claimed invention. The claims of the present invention are defined by the appended claims and their equivalents.

1-Outlet Insulation Nozzle, 2-Inlet Insulation Nozzle, 3-Insulation Case, 4-Electronic Sealant, 5-First Electrode Conductive Connection Block, 6-Second Electrode Conductive Connection Block, 7-Internal Metal Oil Guide Nozzle, 8- Ultrasonic energy conversion sheet, 8a-1st ultrasonic energy conversion sheet, 8b-2nd ultrasonic energy conversion sheet, 9-ultrasonic energy conversion sheet through hole, 9a-1st ultrasonic energy conversion sheet through hole, 9b- 2nd ultrasonic energy conversion sheet through hole, 10-connecting conductive spring, 11-conductive spring, 12-energy conversion sheet fixed insulating nut, 13-interfacial seal gasket, 14-1st metal conductive gasket, 15-2nd metal conductive Gasket, 16-1st conductive screw, 17-2nd conductive screw, 18-1st signal line, 19-2nd signal line, 20-housing screw, 21-inlet metal seal head, 22-outlet metal seal head, 23 -Interfacial seal O-shaped gasket, 24-metal housing, 25-insulating sleeve, 26-metal spring seat, 27-metal spring seat through hole

Claims (10)

An ultrasonic fuel exciter that includes an insulating case.
The insulating case has an internal cavity filled with insulating liquid fuel, at least one fuel inlet, and at least one fuel outlet.
The internal cavity of the insulating case is
It contains at least one ultrasonic energy conversion element with the front facing the fuel outlet side and the back facing the fuel inlet side, and the ultrasonic energy conversion element is installed in the internal cavity of the insulating case and completely immersed in the insulating liquid fuel. Ultrasonic energy conversion unit and
The first electrode conductive connection block connected to the electrode of the ultrasonic energy conversion unit,
A first conductive connection member for fixing the first electrode conductive connection block to the insulating case,
A conductive spring connected to the other electrodes of the ultrasonic energy conversion unit,
The second electrode conductive connection block connected to the conductive spring,
A second conductive connecting member for fixing the second electrode conductive connecting block to the insulating case is included.
An ultrasonic fuel excitation device, wherein the first conductive connecting member and the second conductive connecting member are connected to a power source. The ultrasonic fuel excitation device according to claim 1, wherein the ultrasonic energy conversion unit is provided with at least one through hole penetrating both sides as a fuel passage. The ultrasonic energy conversion unit includes two or more ultrasonic energy conversion elements, and each of the ultrasonic energy conversion elements has a front surface facing the fuel outlet side and a back surface facing the fuel inlet side, and two adjacent ultras. The ultrasonic fuel excitation device according to claim 1, wherein the sonic energy conversion elements are connected in series by a conductive connection assembly. An outer layer metal case is provided outside the insulating case, the outer layer metal case includes an inlet metal seal head, an outlet metal seal head, and a metal housing, and the metal housing includes the inlet metal seal head and the inlet metal seal head by means of housing screws. It is fixedly connected to the outlet metal seal head, and the first conductive connecting member and the second conductive connecting member are connected to the power supply by the first signal line and the second signal line, respectively, and shield the conductor of the first signal line. The ultrasonic fuel excitation device according to claim 1, wherein the layer and the conductor shielding layer of the second signal line are each connected to the metal housing. The insulating case is
An inlet insulating nozzle installed at the bottom end of the ultrasonic fuel exciter and having the fuel inlet in the middle thereof.
An outlet insulating nozzle installed at the top end of the ultrasonic fuel exciter, the middle of which has the fuel outlet, and
The ultrasonic according to claim 1 or 4, wherein the inlet insulating nozzle and the outlet insulating nozzle include an insulating case fixedly connected by a first conductive connecting member and a second conductive connecting member, respectively. Ultrasonic fuel exciter. The ultrasonic fuel excitation device according to claim 3, wherein the conductive connection assembly includes a metal spring seat and a connection conductive spring provided in the metal spring seat. The present invention is characterized in that the conductive spring is fitted in an internal metal oil guide nozzle, and the central portion of the internal metal oil guide nozzle has an internal passage for communicating the fuel inlet and the fuel passage in the ultrasonic energy conversion element. The ultrasonic fuel excitation device according to 1 or 3. The ultrasonic fuel excitation device according to claim 1 or 3, wherein the ultrasonic energy conversion element is an ultrasonic transducer or an ultrasonic energy conversion sheet. The inlet and outlet insulating nozzles are composed of a metal nozzle and an insulating sleeve fitted to the outside of the metal nozzle, respectively, and the metal nozzles of the inlet and outlet insulating nozzles are the second electrode conductive connection block and the first electrode, respectively. The ultrasonic fuel excitation device according to claim 1, wherein the ultrasonic fuel excitation device is integrally connected to a conductive connection block. An interface seal gasket is provided on the contact surface between the fuel inlet side and the inlet insulation nozzle of the insulation case, and the interface seal gasket is provided on the contact surface between the fuel outlet side and the outlet insulation nozzle of the insulation case. , The ultrasonic fuel excitation device according to claim 1 or 9.

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