CN117569915B - High-stability energy-saving generator set - Google Patents

Abstract

The invention discloses a high-stability energy-saving generator set, which comprises: the engine unit main body comprises a power generation frame body, a power generation module and an inversion power supply processing module, wherein a plurality of blocking modules are arranged on a bottom cross beam of the power generation frame body and are propped against the power generation module, an oil tank body is positioned above the power generation module, the inversion power supply processing module is positioned on one side of the power generation module, so that the internal space of the power generation frame body is reasonably utilized, a control panel is arranged on the outer side of one end of the power generation frame body, the oil tank body can be communicated with the power generation module through an oil conveying pipe, gasoline in the oil tank body is conveyed to the power generation module, the power generation module converts chemical energy of the gasoline into electric energy, and output voltage and current which meet the use are obtained after the processing of the inversion power supply processing module.

Description

High-stability energy-saving generator set

Technical Field

The invention relates to the technical field of generator sets, in particular to a high-stability energy-saving generator set.

Background

The generator set is complete mechanical equipment for converting other forms of energy into electric energy, can be used as an emergency power supply for families or businesses, can provide power for outdoor exercises, and has wide application in daily life due to portability and portability.

In general, a generator set is often mounted by fixing an engine and a generator to a rigid base. The installation mode is simple, effective and cost-effective to implement, but can also cause strong vibration due to rigid installation of the unit, so that the service life of the unit is influenced. Therefore, there is a need for a high stability energy efficient generator set that at least partially addresses the problems of the prior art.

Disclosure of Invention

In the summary, a series of concepts in a simplified form are introduced, which will be further described in detail in the detailed description. The summary of the invention is not intended to define the key features and essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

To at least partially solve the above problems, the present invention provides a high-stability energy-saving generator set, including: the engine unit main body comprises a power generation frame body, a power generation module arranged in the power generation frame body, an inverter power supply processing module and an oil tank body, wherein a plurality of blocking modules are arranged on a bottom cross beam of the power generation frame body, the blocking modules are propped against the power generation module, the oil tank body is positioned above the power generation module, the inverter power supply processing module is positioned on one side of the power generation module, a control panel is arranged on the outer side of one end of the power generation frame body, the inverter power supply processing module is respectively electrically connected with the control panel and the power generation module, and the oil tank body is communicated with the power generation module.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the power generation module comprises an engine and a generator, the engine is arranged at the bottom of the power generation frame body and is positioned at the delivery of the oil tank body, the generator is arranged on the output shaft of the engine, and the output end of the generator is electrically connected with the inverter power supply processing module.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the blocking modules are propped against the engine, each blocking module comprises a first triangular inner support piece, a second triangular inner support piece and a middle telescopic mechanism, each second triangular inner support piece is arranged on the bottom cross beam, each middle telescopic mechanism is arranged between the corresponding first triangular inner support piece and each second triangular inner support piece, and each first triangular inner support piece is positioned above the corresponding middle telescopic mechanism and props against the engine.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the first triangular inner support piece is provided with the first outer blocking sleeve, the second triangular inner support piece is provided with the second outer blocking sleeve, the bottom of the second triangular inner support piece is provided with the plurality of bottom fixing blocks, the second outer blocking sleeve is provided with the bottom fixing grooves corresponding to the bottom fixing blocks, and the bottom of the second triangular inner support piece is connected with the bottom cross beam through the auxiliary mechanism.

According to the high-stability energy-saving generator set disclosed by the embodiment of the invention, the oil tank body is connected with the engine through the oil pipeline module, the oil pipeline module comprises an explosion-proof oil pipeline and two explosion-proof joints, the two explosion-proof joints are arranged at two ends of the explosion-proof oil pipeline, and the two explosion-proof joints are respectively connected with the oil tank body and the engine.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the explosion-proof connector comprises an explosion-proof connecting pipe, two outer cap bodies and an explosion-proof outer pipe, wherein the explosion-proof outer pipe is arranged on the explosion-proof connecting pipe, the two outer cap bodies are arranged at two ends of the explosion-proof connecting pipe, the explosion-proof outer pipe is inserted into the outer cap bodies, a plurality of first inner explosion-proof pieces and a plurality of second inner explosion-proof pieces are arranged in the explosion-proof connecting pipe, the second inner explosion-proof pieces are positioned between the inner sides of the adjacent two first inner explosion-proof pieces, and the plurality of first inner explosion-proof pieces and the second explosion-proof pieces are positioned in a waterproof hammer cabin between the explosion-proof outer pipe and the explosion-proof connecting pipe and are propped against the explosion-proof outer pipe.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the first inner explosion-proof piece comprises the first inner explosion-proof arc-shaped plate and two telescopic driving pieces, the two telescopic driving pieces are respectively arranged in the two driving holes of the waterproof hammer cabin, the telescopic driving pieces comprise a driving rod and a telescopic core rod, the first inner explosion-proof arc-shaped plate is movably connected with the driving rod through an inclined frame, the telescopic core rod is arranged in the driving rod in a penetrating way, the outer end of the telescopic core rod is provided with an outer driving part, the inner end of the driving rod is provided with a locking part, and the inner end of the telescopic core rod is provided with a driving release rod corresponding to the locking part.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the outer driving part comprises the telescopic spring and the outer baffle disc, the telescopic spring and the outer baffle disc are arranged at the outer end of the telescopic core rod, and the telescopic spring is propped between the outer baffle disc and the driving rod.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the locking part comprises the locking cap body and the locking rod, the locking cap body is rotatably arranged at the inner end of the driving rod, the driving rod is internally provided with the pre-tightening spring, the pre-tightening spring is connected with the locking cap body, the locking rod is arranged on the locking cap body, the locking rod is provided with the locking block, and the inner wall of the locking cap body is provided with the inclined slideway corresponding to the driving release rod.

According to the high-stability energy-saving generator set provided by the embodiment of the invention, the second inner explosion-proof part comprises the second inner explosion-proof arc-shaped plate, the inner wall of the second inner explosion-proof arc-shaped plate is connected with the explosion-proof connecting pipe through the two inner top springs and the guide rod, the bottom of the telescopic core rod is provided with the auxiliary locking ring, the auxiliary locking ring is provided with the auxiliary rod body and the locking rod body, the locking rod body is connected in the auxiliary rod body in a sliding manner through the inner auxiliary springs, and the locking rod body corresponds to the guide hole on the guide rod.

Compared with the prior art, the invention at least comprises the following beneficial effects:

The invention provides a high-stability energy-saving generator set, which comprises an engine set main body, wherein the engine set main body comprises a power generation frame body, a power generation module, an inverter power supply processing module and an oil tank body, the power generation module, the inverter power supply processing module and the oil tank body are arranged in the power generation frame body, a plurality of blocking modules are arranged on a bottom cross beam of the power generation frame body, the blocking modules are abutted against the power generation module, the oil tank body is positioned above the power generation module, the inverter power supply processing module is positioned at one side of the power generation module, so that the internal space of the power generation frame body is reasonably utilized, a control panel is arranged at the outer side of one end of the power generation frame body, the control panel is electrically connected with the internal inverter power supply processing module, the power generation module is electrically connected with the inverter power supply processing module, the oil tank body can be communicated with the power generation module through an oil delivery pipe, the gasoline in the oil tank body is transmitted to the power generation module, the power generation module converts chemical energy generated by gasoline combustion into electric energy, and obtains output voltage and current which meet the use after the processing of the inverter power supply processing module, the engine set main body is assisted by the blocking modules to block the power generation module, so that the whole power generation frame body can stably work in a stable state.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic view of a part of the internal structure of the present invention.

Fig. 3 is a schematic structural diagram of a simple fixing seat in the present invention.

Fig. 4 is a schematic structural diagram of a blocking module according to the present invention.

Fig. 5 is a bottom view of the blocking module according to the present invention.

Fig. 6 is a schematic view of a portion of a blocking module according to the present invention.

Fig. 7 is an enlarged schematic view of the portion a of fig. 6 according to the present invention.

Fig. 8 is a schematic view of the internal structure of the intermediate telescopic mechanism in the present invention.

Fig. 9 is a schematic view of a part of the auxiliary mechanism in the present invention.

Fig. 10 is an enlarged schematic view of the portion B of fig. 9 according to the present invention.

Fig. 11 is a schematic view of a part of the structure of the intermediate telescopic mechanism in the present invention.

Fig. 12 is a schematic structural view of an explosion-proof joint in the present invention.

Fig. 13 is a schematic view showing the internal structure of the explosion-proof joint in the present invention.

Fig. 14 is a schematic view of the structure of the waterproof hammer chamber in the present invention.

Fig. 15 is a schematic structural view of a first inner explosion-proof member according to the present invention.

Fig. 16 is a schematic view showing a part of the structure of the first inner explosion-proof member in the present invention.

Fig. 17 is a schematic view showing a part of the internal structure of the first inner explosion-proof member in the present invention.

Fig. 18 is a schematic view showing an internal structure of the locking portion in the present invention.

Fig. 19 is a schematic view showing a part of the structure of the locking portion in the present invention.

Fig. 20 is a schematic structural view of a second inner explosion-proof member according to the present invention.

Fig. 21 is a schematic structural view of the first inner explosion-proof member and the second inner explosion-proof member in an initial state in the present invention.

Fig. 22 is a schematic structural view of the first inner explosion-proof member and the second inner explosion-proof member in the working state in the present invention.

Detailed Description

The present invention is described in further detail below with reference to the drawings and examples to enable those skilled in the art to practice the invention by referring to the description.

It will be understood that terms, such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

As shown in fig. 1-2, the present invention provides a high-stability energy-saving generator set, comprising: the engine unit main body 100, this engine unit main body 100 includes power generation support body 1, power generation module 2, inverter power supply processing module 3, the oil tank body 4, here above-mentioned power generation module 2, inverter power supply processing module 3, the oil tank body 4 is installed in power generation support body 1, wherein, install a plurality of blocking module 6 on the bottom crossbeam 10 of power generation support body 1, here a plurality of blocking module 6 support power generation module 2, the oil tank body 4 is located power generation module 2's top, inverter power supply processing module 3 is located power generation module 2's one side, make the inside space of power generation support body 1 obtain the rational utilization, and install control panel 11 in the one end outside of power generation support body 1, control panel 11 and inside inverter power supply processing module 3 electricity are connected, and power generation module 2 and inverter power supply processing module 3 are also electric connection, here oil tank body 4 can be through defeated oil pipe and power generation module 2, power generation module 2 is given to the petrol in the power generation module 2 to the fuel tank body 4, power generation module 2 then turns into the chemical energy that petrol burns, and obtain the output voltage and the electric current that satisfy the use after the processing of inverter power supply processing module 3, this power generation support body 1 is located power generation module 2 and the steady state of energy-saving and make the whole engine unit can be in order to stabilize the steady state through power generation module 6, the power generation support body 1 vibration state is in order to make the steady state to make the whole vibration state to be in order to work.

Exemplary Power Generation Module

As shown in fig. 3, further, in some embodiments of the present invention, a specific structure of the power generation module 2 is provided, the power generation module 2 of the structure includes an engine 21 and a generator 22, where the engine 21 is installed at the bottom of the power generation frame 1 and is located at the bottom of the oil tank 4, so that the internal space of the power generation frame 1 is reasonably utilized; meanwhile, the blocking module 6 is located at the bottom of the engine 21, and the blocking module 6 assists in blocking the vibration transmission of the engine 21, so that the power generation frame 1 is in a stable state and the whole energy-saving engine unit can work with high stability.

The generator 22 is mounted on the output shaft of the engine 21, the output shaft of the engine 21 is connected with the rotor of the generator 22, so that the rotor of the generator 22 is driven to rotate to generate electricity after the engine 21 rotates, and the radiator fan 23 is mounted on the generator 22, so that the rotor of the generator 22 also drives the radiator fan 23 to rotate to perform heat dissipation treatment on the inverter power processing module 33 when rotating, and meanwhile, the output end of the generator 22 is electrically connected with the inverter power processing module 33, so that the inverter power processing module 3 rectifies and transforms the current to meet the requirement.

Exemplary blocking Module

As shown in fig. 3 to 11, in the prior art, the engine 21 is generally fixed in the power generation frame 1 by the simple fixing base 210, and the engine 21 generates vibration during operation, and since the simple fixing base 210 does not have a function of blocking transmission of vibration, the vibration of the engine 21 is transmitted to the power generation frame 1, and then is transmitted to other structural components through the power generation frame 1, so that the other structural components are easily damaged by vibration to affect normal operation thereof.

Therefore, the specific structure of the blocking module 6 is provided in some embodiments of the present invention, and the blocking module 6 is used to assist in blocking the vibration transmission based on the simple fixing base 210, so that the power generation frame 1 is in a stable state and the whole energy-saving engine unit can work with high stability.

Specifically, a plurality of blocking modules 6 are mounted on the inner wall of the above-described power generation frame body 1, where the plurality of blocking modules 6 are respectively located at the bottom of the engine 21 such that the plurality of blocking modules 6 are abutted against the engine 21. The blocking module 6 of the structure comprises a first triangular inner support piece 61, a second triangular inner support piece 62 and a middle telescopic mechanism 63, wherein a first outer blocking sleeve 611 is arranged on the whole outer part of the first triangular inner support piece 61 in a wrapping way, a second outer blocking sleeve 621 is arranged on the whole outer part of the second triangular inner support piece 62 in a wrapping way, and the wear resistance of the first triangular inner support piece 61 and the second triangular inner support piece 62 is increased through the first outer blocking sleeve 611 and the second outer blocking sleeve 621, and noise caused by friction between the first triangular inner support piece 61 and the engine 21 due to direct contact of the first triangular inner support piece 61 with the engine 21 is avoided;

Further, the length of the blocking module 6 can be increased according to actual needs, that is, two or more blocking modules 6 can be spliced together, and the first outer blocking sleeve 611 and the second outer blocking sleeve 621 are both provided with the heat dissipation cavity 600, so that the heat dissipation cavity 600 can be filled with heat dissipation cooling medium, and the heat dissipation of the engine 21 is facilitated after the first outer blocking sleeve 611 contacts the engine 21.

Specifically, two first splicing grooves 612 are formed at one end of the first outer blocking sleeve 611 (the second outer blocking sleeve 621), and two first splicing blocks 613 are mounted at the other end, so that the splicing of the two blocking modules 6 can be achieved after the first splicing blocks 613 are spliced to the first splicing stabilizing holes 612.

Further, a plurality of bottom fixing blocks 622 are further installed at the bottom of the second triangular inner support piece 62, a plurality of bottom fixing grooves 623 are formed in the second outer blocking sleeve 621, and then the bottom fixing blocks 622 can be inserted into the bottom fixing grooves 623, so that the direct connection firmness of the second triangular inner support piece 62 and the second outer blocking sleeve 621 is further improved;

the intermediate telescopic mechanism 63 is installed between the first inner triangle support 61 and the second inner triangle support 62, and the bottom of the second inner triangle support 62 is connected to the inner wall of the power generation frame 1 through the auxiliary mechanism 64. Therefore, after the blocking module 6 is mounted on the inner wall of the power generation frame body 1 through the auxiliary mechanism 64, the first triangular inner support piece 61 in the blocking module 6 props against the engine 21 through the first outer blocking sleeve 611, so that vibration generated in the working process of the engine 21 cannot be transmitted to the power generation frame body 1 to affect other structural components, and the service life of the whole energy-saving engine unit is prolonged.

Exemplary intermediate telescoping mechanism

Further, in some embodiments of the present invention, a specific structure of the intermediate telescopic mechanism 63 is provided, and the vibration transmitted to the first triangle inner stay 61 by the engine 21 is resisted by the intermediate telescopic mechanism 63; the middle telescopic mechanism 63 of the structure comprises an inner supporting block 631, a first telescopic sleeve 632, a second telescopic sleeve 633, a third telescopic sleeve 634 and a first inner spring 635, wherein the inner supporting block 631 is connected with a first triangular inner supporting piece 61, a first V-shaped groove 6311 is formed in the inner supporting block 631 and is fixedly connected with the first triangular inner supporting piece 61 through the first V-shaped groove 6311, a first telescopic sleeve 632 is arranged at the bottom of the inner supporting block 631, two opposite extension ear plates 636 are arranged on the second telescopic sleeve 633, when the second telescopic sleeve 633 stretches into the first telescopic sleeve 632, the extension ear plates 636 are rotatably connected with the first telescopic sleeve 632 through a rotary disc 637, further, shaking grooves 638 are formed in the extension ear plates 636, when the vibration amplitude of an engine 21 is large, the end parts of the first telescopic sleeve 632 can reciprocate in the shaking grooves 638 on the extension ear plates 636, meanwhile, the second telescopic sleeve 633 is connected in the third telescopic sleeve 634 in a sliding mode, the third telescopic sleeve 634 is connected with the second triangular inner supporting piece 62, and the whole telescopic sleeve 634 is in a telescopic manner of supporting the third telescopic sleeve 634, and is in a telescopic sleeve 634 is rotatably connected with the first telescopic sleeve 632 through the first telescopic sleeve 634, and the middle telescopic sleeve is rotatably arranged in the middle of the third telescopic sleeve 634; the bottom of the third telescopic sleeve 634 is provided with a second V-shaped groove 6341, and is fixedly connected with the second triangle inner support 62 through the second V-shaped groove 6341.

Exemplary auxiliary mechanisms

Further, in some embodiments of the present invention, a specific structure of the auxiliary mechanism 64 is provided, and the stability of the connection between the second triangular inner support 62 and the power generation frame body 1 is further increased by the auxiliary mechanism 64;

the auxiliary mechanism 64 with the structure comprises a fixed screw rod 641, a circumferential sleeve 642, a first spacer 643, a second spacer 644 and a plurality of second inner springs 645, wherein the second triangular inner support 62 is provided with an inverted convex groove 624 corresponding to the auxiliary mechanism 64, the auxiliary mechanism 64 is installed through the inverted convex groove 624, the circumferential sleeve 642 is arranged in the inverted convex groove 624 in a penetrating way, and a stabilizing ring 646 is arranged between the circumferential sleeve 642 and the inverted convex groove 624 to prevent the circumferential sleeve 642 from being deformed under force;

The fixed screw 641 is inserted into the circumferential sleeve 642 and connected to the inner wall of the power generation frame 1, where a first spacer 643 is installed on the fixed screw 641, a second spacer 644 is installed on the first spacer 643, a plurality of spring grooves are formed on the second spacer 644 to facilitate the installation of the second inner spring 645, a circumferential groove 647 is formed in the circumferential sleeve 642, one end of the second inner spring 645 is located in the spring groove, and the other end abuts against the circumferential groove 647. Therefore, even if the second triangular inner support 62 is vibrated by the vibration, the plurality of second inner springs 645 uniformly designed herein can impact the vibration due to the design of the auxiliary mechanism 64, so that the second triangular inner support 62 is restored to the original state after the vibration, and the connection stability between the second triangular inner support 62 and the power generation frame 1 is increased.

In general, an engine in a generator set is connected with an oil delivery pipe, an oil tank body supplies oil to the engine through the oil delivery pipe, and gasoline is required to be continuously injected into the engine. Therefore, when the oil delivery pipe is shut down when the electricity generation is stopped, and when the oil delivery pipe is shut down, the joint of the oil delivery pipe and the engine can bear the water hammer effect generated by the gasoline, so that burst and oil leakage easily occur, and once burst fails, the leaked gasoline splashes to the engine to possibly cause fire. Thus, in some embodiments of the present invention, a fuel delivery module is provided, wherein, when the fuel tank body 4 is connected to the engine 21 through the fuel delivery module, a fuel delivery pump (not shown) pumps out the fuel from the fuel tank body 4, and the fuel is supplied into the engine 21 through the fuel delivery module, so as to prevent the occurrence of fuel leakage.

The oil delivery pipe module comprises an explosion-proof oil delivery pipe and two explosion-proof joints 7, wherein the two explosion-proof joints 7 are arranged at two ends of the explosion-proof oil delivery pipe, and the two explosion-proof joints 7 are respectively connected with the oil tank body 4 and the engine 21. Through the structural design of explosion-proof joint 7 to play the effect of preventing the emergence oil leak.

Exemplary explosion-proof Joint

As shown in fig. 12-22, further, in some embodiments of the present invention, a specific structure of the explosion-proof joint 7 is provided, where the explosion-proof joint 7 includes an explosion-proof adapter tube 71, two outer caps 72, and an explosion-proof outer tube 73, where the explosion-proof outer tube 73 is mounted on the explosion-proof adapter tube 71, and the two outer caps 72 may be screwed on two ends of the explosion-proof adapter tube 71, and the explosion-proof outer tube 73 is inserted into the outer caps 72, and the outer caps 72 fixedly mount the explosion-proof outer tube 73 on the explosion-proof adapter tube 71, so that a space between the explosion-proof outer tube 73 and the explosion-proof adapter tube 71 is a space for a water hammer cabin 711 to temporarily store and release pressure for suddenly stopped gasoline, and damage of the water hammer effect of the gasoline to the explosion-proof adapter tube 71 is reduced;

Further, in order to increase the protection effect of the explosion-proof outer tube 73, a plurality of first inner explosion-proof pieces 74 and a plurality of second inner explosion-proof pieces 75 are installed in the explosion-proof connecting tube 71, wherein the plurality of first inner explosion-proof pieces 74 and the plurality of second inner explosion-proof pieces 75 are located in the explosion-proof hammer cabin 711, the second inner explosion-proof pieces 75 are located between the inner sides of two adjacent first inner explosion-proof pieces 74, in the initial state, the two first inner explosion-proof pieces 74 are close to the explosion-proof connecting tube 71, the second inner explosion-proof pieces 75 on the inner side are also close to the explosion-proof connecting tube 71, when the water hammer effect generated by gasoline needs to be processed, the gasoline enters into the waterproof hammer cabin 711 through two driving holes 712 of the waterproof hammer cabin 711, then the plurality of first inner explosion-proof pieces 74 are far away from the explosion-proof connecting tube 71 and are close to the explosion-proof outer tube 73, meanwhile the plurality of second inner explosion-proof pieces 75 are far away from the explosion-proof connecting tube 71 and are close to the explosion-proof outer tube 73, and are combined with the first inner explosion-proof pieces 74 to be combined to be attached to the whole inner wall of the explosion-proof hammer cabin 73, and the gasoline hammer cabin 73 can be prevented from entering into the waterproof cabin 711, and the inner tube 73 can be stored, and the waterproof cabin is prevented from entering into the explosion-proof cabin.

Exemplary first inner explosion proof piece

Further, in some embodiments of the present invention, a specific structure of the first inner explosion-proof member 74 is provided, the first inner explosion-proof member 74 of the structure includes a first inner explosion-proof arc plate 741 and two telescopic driving members 742, wherein the two telescopic driving members 742 are respectively installed in the two driving holes 712 of the waterproof hammer cabin 711, the telescopic driving members 742 include a driving rod 743 and a telescopic core rod 744, the first inner explosion-proof arc plate 741 is movably connected with the driving rod 743 through an inclined frame 745, and the first inner explosion-proof arc plate 741 faces the explosion-proof outer tube 73, the telescopic core rod 744 is penetrated in the driving rod 743, an outer driving part is installed at the outer end of the telescopic core rod 744, a locking part is installed at the inner end of the driving rod 743, and a driving release rod 746 is installed at the inner end of the telescopic core rod 744, so that when gasoline enters into the driving hole 712, the outer driving part moves the telescopic core rod 744 into the waterproof hammer cabin 711, and at the same time, the driving release rod 746 on the telescopic core rod 744 rotates the locking part, so that the two driving rods 743 move inwards to the waterproof hammer cabin 711, and the two driving rods 743 move inwards to the inner explosion-proof arc plate 743, and the inner explosion-proof arc plate 743 is fixed to the inner explosion-proof arc plate 743, and the explosion-proof protection member is fastened to the inner explosion-proof plate 743, and the explosion-proof device is moved by the inclined distance of the inner explosion-proof rod 743.

Exemplary external drive portion

Further, in some embodiments of the present invention, there is provided a specific structure of the outer driving part, where the outer driving part includes a telescopic spring 747 and an outer retainer 748, where the telescopic spring 747 and the outer retainer 748 are installed at the outer end of the telescopic core rod 744, and the telescopic spring 747 is abutted between the outer retainer 748 and the driving rod 743, so when the gasoline acts on the outer retainer 748, the outer retainer 748 is moved toward the waterproof hammer cabin 711, and then the outer retainer 748 is simultaneously abutted against the telescopic spring 747, so that the telescopic core rod 744 moves first in the driving rod 743, and the telescopic core rod 744 drives the locking part at the bottom to act; the telescopic spring 747 is contracted under the action of the outer baffle disc 748, so that the driving rod 743 also moves towards the inside of the waterproof hammer cabin 711, and the driving rod 743 drives the inclined frame 745 to act, so that the protection of the first inner explosion-proof piece 74 on the explosion-proof outer tube 73 is realized, the waterproof hammer cabin 711 is reserved for storing and releasing gasoline, and the water hammer effect is reduced.

Exemplary locking portion

Further, in some embodiments of the present invention, a specific structure of a locking portion is provided, through which the connection between the two driving rods 743 is achieved to drive the first inner explosion-proof arc plate 741 to be abutted against the explosion-proof outer tube 73, the locking portion of the structure includes a locking cap 749 and a locking rod 750, wherein the locking cap 749 is rotatably mounted at an inner end of the driving rod 743, and a pre-tightening spring 7431 is provided in the driving rod 743, one end of the pre-tightening spring 7431 is connected with the locking cap 749, and the other end is connected with the driving rod 743, so that when the driving release rod 746 moves in the inclined slide 7491 on an inner wall of the locking cap 749, the locking cap 749 is driven to perform circumferential rotation relative to the driving rod 743, and the other end of the internal pre-tightening spring 7431 is driven to also rotate, so that the pre-tightening spring 7431 is further tensioned, and the locking rod 750 on the locking cap 749 moves toward the other locking rod 750 until the locking blocks 7501 on the two locking rods are buckled to each other, thereby achieving the two driving rods to be fixed.

Exemplary second inner explosion proof piece

Further, in some embodiments of the present invention, a specific structure of the second inner explosion-proof member 75 is provided, where the second inner explosion-proof member 75 includes a second inner explosion-proof arc plate 751, where the second inner explosion-proof arc plate 751 is located between two adjacent first inner explosion-proof arc plates 741, so when the two first inner explosion-proof arc plates 741 are close to fit on the inner wall of the explosion-proof outer tube 73, the two first inner explosion-proof arc plates 741 no longer block the second inner explosion-proof arc plate 751, so the inner wall of the second inner explosion-proof arc plate 751 is connected with the explosion-proof adapter tube 71 through two inner top springs 752, and under the action of the two inner top springs 752, the second inner explosion-proof arc plate 751 is also close to fit on the inner wall of the explosion-proof outer tube 73, and is tightly connected with the two first inner explosion-proof arc plates 741;

In the above process, the telescopic core rod 744 moves, so that the telescopic core rod 744 drives the auxiliary locking ring 754 to move, and the auxiliary rod body 755 on the auxiliary locking ring 754 also moves towards the guide rod 753, and the locking rod 756 is slidably connected in the auxiliary rod body 755 through the inner auxiliary spring 757, so that the locking rod 756 enters the guide hole 758 on the guide rod 753 under the action of the inner auxiliary spring 757, and at this time, the second inner explosion-proof arc plate 751 is abutted under the action of the auxiliary locking ring 754, the auxiliary rod body 755, the locking rod 756 and other components, so that the second inner explosion-proof arc plate 751 is also close to be attached to the inner wall of the explosion-proof outer tube 73, and is tightly connected with the two first inner explosion-proof arc plates 741, so that the protection of the first inner explosion-proof member 74 on the explosion-proof outer tube 73 is realized, and the water hammer cabin 711 is left to store and release gasoline, and the water hammer effect is reduced.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

Although embodiments of the present invention have been disclosed above, it is not limited to the details and embodiments shown and described, it is well suited to various fields of use for which the invention would be readily apparent to those skilled in the art, and accordingly, the invention is not limited to the specific details and illustrations shown and described herein, without departing from the general concepts defined in the claims and their equivalents.

Claims (7)

1. A high stability energy efficient generator set, comprising:

The power generation system comprises an engine unit main body (100), wherein the engine unit main body (100) comprises a power generation frame body (1), a power generation module (2), an inverter power supply processing module (3) and an oil tank body (4), the power generation module (2) is arranged in the power generation frame body (1), a plurality of blocking modules (6) are arranged on a bottom cross beam (10) of the power generation frame body (1), the blocking modules (6) are abutted against the power generation module (2), the oil tank body (4) is positioned above the power generation module (2), the inverter power supply processing module (3) is positioned on one side of the power generation module (2), a control panel (11) is arranged on the outer side of one end of the power generation frame body (1), the inverter power supply processing module (3) is respectively electrically connected with the control panel (11) and the power generation module (2), and the oil tank body (4) is communicated with the power generation module (2).

The power generation module (2) comprises an engine (21) and a generator (22), the engine (21) is arranged at the bottom of the power generation frame body (1) and is positioned below the oil tank body (4), the generator (22) is arranged on an output shaft of the engine (21), and the output end of the generator (22) is electrically connected with the inverter power supply processing module (3);

the oil tank body (4) is connected with the engine (21) through the oil pipeline module, the oil pipeline module includes explosion-proof oil pipeline, two explosion-proof joint (7) set up in explosion-proof oil pipeline's both ends, two explosion-proof joint (7) are connected with oil tank body (4), engine (21) respectively, explosion-proof joint (7) are including explosion-proof takeover (71), two outer cap bodies (72), explosion-proof outer tube (73) set up on explosion-proof takeover (71), two outer cap bodies (72) set up the both ends at explosion-proof takeover (71) to explosion-proof outer tube (73) are pegged graft in outer cap body (72), explosion-proof takeover (71) are provided with a plurality of first interior explosion-proof pieces (74), a plurality of second interior explosion-proof pieces (75) in, explosion-proof piece (75) are located between two adjacent first interior explosion-proof pieces (74), a plurality of hammer in the first explosion-proof pieces (74), second explosion-proof pieces (73) are located explosion-proof cabin (73) and explosion-proof (73) and are located between explosion-proof outer tube (73).

2. The high-stability energy-saving generator set according to claim 1, wherein a plurality of blocking modules (6) are propped against the engine (21), the blocking modules (6) comprise a first triangular inner support (61), a second triangular inner support (62) and an intermediate telescopic mechanism (63), the second triangular inner support (62) is arranged on a bottom cross beam, the intermediate telescopic mechanism (63) is arranged between the first triangular inner support (61) and the second triangular inner support (62), and the first triangular inner support (61) is positioned above the intermediate telescopic mechanism (63) and is propped against the engine (21).

3. The high-stability energy-saving generator set according to claim 2, wherein a first outer blocking sleeve (611) is arranged on the first triangular inner support (61), a second outer blocking sleeve (621) is arranged on the second triangular inner support (62), a plurality of bottom fixing blocks (622) are arranged at the bottom of the second triangular inner support (62), bottom fixing grooves (623) corresponding to the bottom fixing blocks (622) are arranged on the second outer blocking sleeve (621), and the bottom of the second triangular inner support (62) is connected with a bottom cross beam through an auxiliary mechanism (64).

4. The high-stability energy-saving generator set according to claim 1, wherein the first inner explosion-proof member (74) comprises a first inner explosion-proof arc plate (741) and two telescopic driving members (742), the two telescopic driving members (742) are respectively arranged in two driving holes (712) of the waterproof hammer cabin (711), the telescopic driving members (742) comprise driving rods (743) and telescopic core rods (744), the first inner explosion-proof arc plate (741) is movably connected with the driving rods (743) through inclined frames (745), the telescopic core rods (744) are arranged in the driving rods (743) in a penetrating mode, outer driving parts are arranged at the outer ends of the telescopic core rods (744), locking parts are arranged at the inner ends of the driving rods (743), and driving release rods (746) corresponding to the locking parts are arranged at the inner ends of the telescopic core rods (744).

5. The high-stability energy-saving generator set according to claim 4, wherein the outer driving part comprises a telescopic spring (747) and an outer baffle disc (748), the telescopic spring (747) and the outer baffle disc (748) are arranged at the outer end of the telescopic core rod (744), and the telescopic spring (747) is propped between the outer baffle disc (748) and the driving rod (743).

6. The high-stability energy-saving generator set according to claim 4, wherein the locking part comprises a locking cap body (749) and a locking rod (750), the locking cap body (749) is rotatably arranged at the inner end of the driving rod (743), a pre-tightening spring is arranged in the driving rod (743), the pre-tightening spring is connected with the locking cap body (749), the locking rod (750) is arranged on the locking cap body (749), a locking block (7501) is arranged on the locking rod (750), and an inclined slideway (7491) corresponding to the driving release rod (746) is arranged on the inner wall of the locking cap body (749).

7. The high-stability energy-saving generator set according to claim 4, wherein the second inner explosion-proof part (75) comprises a second inner explosion-proof arc plate (751), the inner wall of the second inner explosion-proof arc plate (751) is connected with the explosion-proof connecting tube (71) through two inner top springs (752) and a guide rod (753), an auxiliary locking ring (754) is arranged at the bottom of the telescopic core rod (744), an auxiliary rod body (755) and a locking rod body (756) are arranged on the auxiliary locking ring (754), the locking rod body (756) is connected in the auxiliary rod body (755) in a sliding mode through the inner auxiliary springs (757), and the locking rod body (756) corresponds to a guide hole (758) in the guide rod (753).