CN114759733B - Intelligent generator set - Google Patents

Abstract

The invention provides an intelligent generator set, which comprises a generator body, a prime motor and an air cooling mechanism, wherein the generator body is provided with a power supply; the air cooling mechanism comprises a cover body, a cooling fan and a self-cleaning air inlet assembly; the cover body covers the cooling fan; the cover body is provided with an installation opening suitable for installing the self-cleaning air inlet assembly; the cooling fan is suitable for being driven by the prime mover to rotate, so that external cold air is sucked into the generator body from the self-cleaning air inlet assembly for cooling; the self-cleaning type air inlet assembly is suitable for filtering sucked external cold air and cleaning filtered dust. The self-cleaning air inlet assembly filters air entering the generator body, dust after filtering is cleaned simultaneously, the durability of the self-cleaning air inlet assembly on dust filtering is improved, dust is prevented from blocking a filter screen, and the cooling effect on the generator body is improved.

Description

Intelligent generator set

Technical Field

The invention relates to the field of generators, in particular to an intelligent generator set.

Background

The generator is used as a standby power supply, is often arranged in a factory and is used as an emergency power supply device, the generator is in a standing state for a long time, and the environment and the machine can have a lot of accumulated dust.

Air-cooled structure among the prior art is when cooling off the generator, can inhale between a large amount of dirt enters into the rotor and the stator of generator, cause the hidden danger to the electricity generation process, the solution commonly used at present, adopt the filter screen to filter dust at the air inlet, prevent that it from entering into between the rotor and the stator of generator, however, when the accumulational dust of filter screen is too much, can lead to the cooling effect of air-cooled structure to reduce, thereby make the high temperature of generator during operation, also can cause the potential safety hazard equally.

The above problems are currently urgently needed.

Disclosure of Invention

The invention aims to provide an intelligent generator set.

In order to solve the above technical problem, the present invention provides an intelligent generator set, including:

the generator comprises a generator body, a prime motor and an air cooling mechanism;

the air cooling mechanism is connected to a rotor shaft of the generator body and is suitable for being driven by a prime mover so as to cool the generator body;

the air cooling mechanism comprises a cover body, a cooling fan and a self-cleaning air inlet assembly

The cover body covers the cooling fan;

the cover body is provided with an installation opening suitable for installing the self-cleaning air inlet assembly;

the cooling fan is suitable for being driven by the prime mover to rotate, so that external cold air is sucked into the generator body from the self-cleaning air inlet assembly for cooling;

the self-cleaning type air inlet assembly is suitable for filtering sucked external cold air and cleaning filtered dust.

Further, the self-cleaning air intake assembly includes: a mounting plate and a cleaning plate;

the mounting plate is provided with an air inlet, and a filter cavity is arranged behind the air inlet;

the side wall of the filter cavity is provided with a plurality of filter holes;

the cleaning plate is rotationally connected to the air inlet through a torsional spring;

the cleaning plate is suitable for opening the air inlet under the driving of negative pressure generated by the rotation of the cooling fan when the cooling fan rotates, rotates inwards along the side wall of the filter cavity and cleans the side wall of the filter cavity when the cleaning plate rotates;

the cleaning plate is further suitable for cleaning the side wall of the filter cavity when the cooling fan stops rotating and moves back outwards along the side wall of the filter cavity under the action of the torsion spring.

Furthermore, when the side wall of the filter cavity is blocked, the suction force of the negative pressure generated by the rotation of the cooling fan on the cleaning plate is reduced, at the moment, the cleaning plate is suitable for retreating outwards along the side wall of the filter cavity so as to clean the side wall of the filter cavity, and then the suction force of the negative pressure generated by the rotation of the cooling fan on the cleaning plate is increased and continues to rotate inwards along the side wall of the filter cavity so as to clean the side wall of the filter cavity again.

Further, the cleaning plate comprises a rotating part and a telescopic part;

the telescopic part is sleeved at one end of the rotating part close to the side wall of the filter cavity and is elastically connected to the rotating part;

the tail end of the telescopic part is abutted against the side wall of the filter cavity.

Further, the rotating part is provided with a first plug and a second plug;

the first plug and the second plug are oppositely arranged and are arranged at one end of the rotating part close to the side wall of the filter cavity;

a spacing groove is formed between the first plug and the second plug;

a first insertion cavity is formed in the position, opposite to the first plug, of the telescopic part;

a second insertion cavity is formed in the position, opposite to the second plug, of the telescopic part;

a propping block is arranged between the first inserting cavity and the second inserting cavity;

the top of the abutting block is elastically connected to the top of the spacing groove through a first spring;

the cross section of the tail end of the abutting block is arc-shaped and abuts against the side wall of the filter cavity.

Further, a dust accommodating groove is formed in the bottom of the air inlet of the mounting plate;

the cleaning plate is further suitable for scraping dust filtered out from the side wall of the filter cavity into the dust accommodating groove when the cooling fan stops rotating and retreats outwards along the side wall of the filter cavity.

Further, the dust containing groove set up the position with the clearance board returns to maximum position adaptation.

Further, the dust accommodating groove comprises a first accommodating groove, a second accommodating groove and a connecting block;

the first accommodating groove and the second accommodating groove are formed in two sides of the connecting block;

the surface of the connecting block is wrapped with a first sponge layer after water absorption;

the surface of the abutting block comprises a second sponge layer;

the second sponge layer is suitable for contacting with the first sponge layer when the cleaning plate is retreated to the maximum position, so that the moisture in the first sponge layer is transferred to the second sponge layer;

the butting block is provided with a plurality of vent holes for communicating the first insertion cavity with the second insertion cavity;

the second sponge layer is suitable for adsorbing dust cleaned by the abutting block when the cooling fan rotates;

the first plug and the second plug are suitable for scraping off dust adhered to the second sponge layer when the cleaning plate retreats outwards along the side wall of the filter cavity.

Furthermore, the number of the air inlets of the mounting plate is multiple, and the number of the cleaning plates is the same as that of the air inlets.

Further, the number of the self-cleaning air inlet assemblies is two;

the two self-cleaning air inlet assemblies are respectively arranged on the mounting openings at the two sides of the cover body.

The intelligent generator set has the beneficial effects that the intelligent generator set comprises a generator body, a prime motor and an air cooling mechanism; the air cooling mechanism is connected to a rotor shaft of the generator body and is suitable for being driven by a prime mover so as to cool the generator body; the air cooling mechanism comprises a cover body, a cooling fan and a self-cleaning air inlet assembly; the cover body covers the cooling fan; the cover body is provided with an installation opening suitable for installing the self-cleaning air inlet assembly; the cooling fan is suitable for being driven by the prime mover to rotate, so that external cold air is sucked into the generator body from the self-cleaning air inlet assembly for cooling; the self-cleaning air inlet assembly is suitable for filtering sucked external cold air and cleaning filtered dust. The self-cleaning air inlet assembly is used for filtering air entering the generator body, and meanwhile, the filtered dust is cleaned, so that the durability of the self-cleaning air inlet assembly on dust filtration is improved, the filter screen is prevented from being blocked by the dust, and the cooling effect on the generator body is improved.

Drawings

The invention is further illustrated by the following examples in conjunction with the drawings.

Fig. 1 is a schematic structural diagram of an intelligent generator set provided by the invention.

Fig. 2 is a schematic structural diagram of the intelligent generator set provided by the invention after the cover body is hidden.

Fig. 3 is a schematic structural diagram of the self-cleaning air intake assembly provided by the invention.

Fig. 4 is a cross-sectional view of a self-cleaning air induction assembly provided by the present invention.

Fig. 5 is an enlarged view at a in fig. 4.

Fig. 6 is a schematic structural view of the telescopic part provided by the present invention.

Fig. 7 is a schematic view of a cleaning plate when the cooling fan provided by the present invention is not rotating.

Fig. 8 is a schematic view showing a state of the cleaning plate when the cooling fan provided by the present invention is rotated.

FIG. 9 is a schematic view of the cleaning plate when the cooling fan provided by the present invention is rotating and the filter chamber is clogged.

In the figure: 100. a generator body; 200. a prime mover; 300. an air cooling mechanism; 310. a cover body; 320. a cooling fan; 330. a self-cleaning air intake assembly; 331. mounting a plate; 332. an air inlet; 333. cleaning the plate; 3331. a rotating part; 3331a, a first plug; 3331b, a second plug; 3331c, spacer grooves; 3331d, a first spring; 3332. a telescopic part; 3332a, a first insertion cavity; 3332b, a second insertion cavity; 3332c, a sustaining block; 3332c 1-vent; 334. a filter chamber; 3341. a side wall; 335. a dust accommodating groove; 3351. a first accommodating groove; 3352. a second accommodating groove; 3353. and (4) connecting the blocks.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

Example 1

Referring to fig. 1 to 9, embodiment 1 provides an intelligent generator set, including: a generator body 100, a prime mover 200, and an air-cooling mechanism 300; the air cooling mechanism 300 is connected to a rotor shaft of the generator body 100 and is adapted to be driven by a prime mover 200 to cool the generator body 100; the air cooling mechanism 300 comprises a housing 310, a cooling fan 320 and a self-cleaning air intake assembly 330; the cover 310 covers the cooling fan 320; the cover body 310 is provided with a mounting opening suitable for mounting the self-cleaning air intake assembly 330; the cooling fan 320 is adapted to rotate under the driving of the prime mover 200, thereby drawing external cold air from the self-cleaning air intake assembly 330 into the generator body 100 for cooling; the self-cleaning type air intake assembly 330 is adapted to filter the sucked external cool air and clean the filtered dust. Air entering the generator body 100 is filtered through the self-cleaning air inlet assembly 330, and filtered dust is cleaned, so that the durability of the self-cleaning air inlet assembly 330 on dust filtration is improved, the filter screen is prevented from being blocked by the dust, and the cooling effect on the generator body 100 is improved.

In this embodiment, the self-cleaning intake assembly 330 includes: mounting plate 331 and cleaning plate 333; the mounting plate 331 is provided with an air inlet 332, and a filter cavity 334 is arranged behind the air inlet 332; the side wall 3341 of the filter cavity 334 is provided with a plurality of filter holes; the cleaning plate 333 is rotatably connected to the air inlet 332 through a torsion spring; the cleaning plate 333 is adapted to be driven by the negative pressure generated by the rotation of the cooling fan 320 to open the air inlet 332 and rotate inwards along the side wall 3341 of the filter cavity 334 when the cooling fan 320 rotates, and to clean the side wall 3341 of the filter cavity 334 when the cleaning plate rotates; the cleaning plate 333 is further adapted to retreat along the side wall 3341 of the filter chamber 334 by the torsion spring when the cooling fan 320 stops rotating, and to clean the side wall 3341 of the filter chamber 334 when retreating. The cleaning plate 333 cleans the filter cavity 334 to prevent dust from blocking the filter holes in the filter cavity 334, thereby ensuring the efficiency of air entering the generator body 100, greatly prolonging the service life of the air cooling mechanism 300, and reducing the occurrence of safety accidents caused by untimely heat dissipation.

In this embodiment, when the side wall 3341 of the filter cavity 334 is blocked, the suction force of the negative pressure generated by the rotation of the cooling fan to the cleaning plate 333 is reduced, and at this time, the cleaning plate 333 is further adapted to retreat outward along the side wall 3341 of the filter cavity 334 to clean the side wall 3341 of the filter cavity 334, and then, the suction force of the negative pressure generated by the rotation of the cooling fan 320 to the cleaning plate 333 is increased and continues to rotate inward along the side wall 3341 of the filter cavity 334 to clean the side wall 3341 of the filter cavity 334 again. In the power generation process of the generator, if the filter holes on the side wall 3341 of the filter cavity 334 are blocked, the cleaning plate 333 can perform self-adaptive cleaning on the side wall 3341 of the filter cavity 334, so that the heat dissipation effect on the generator body 100 is ensured.

In this embodiment, the cleaning plate 333 includes a rotating part 3331 and a telescopic part 3332; the telescopic part 3332 is sleeved at one end of the rotating part 3331 close to the side wall 3341 of the filter cavity 334 and is elastically connected to the rotating part 3331; the end of the telescoping portion 3332 abuts the side wall 3341 of the filter cavity 334.

Wherein the rotating part 3331 is provided with a first plug and a second plug; the first plug and the second plug are oppositely arranged and are arranged at one end of the rotating part 3331 close to the side wall 3341 of the filter cavity 334; a spacer 3331c is provided between the first plug 3331a and the second plug 3331 b; a first insertion cavity 3332a is formed in the telescopic part 3332 opposite to the first plug; a second insertion cavity 3332b is formed in the position of the telescopic part 3332 opposite to the second plug; a butting block 3332c is arranged between the first insertion cavity 3332a and the second insertion cavity 3332 b; the top of the abutting block 3332c is elastically connected to the top of the spacing groove 3331c through a first spring 3331 d; the cross section of the end of the supporting block 3332c is circular arc and supports against the side wall 3341 of the filter cavity 334.

In this embodiment, the bottom of the air inlet 332 of the mounting plate 331 is provided with a dust accommodating groove 335; the cleaning plate 333 is further adapted to scrape the dust filtered from the side wall 3341 of the filter chamber 334 into the dust accommodating groove 335 when the cooling fan 320 stops rotating and retreats outwardly along the side wall 3341 of the filter chamber 334. It should be noted that a person is required to periodically dispose of the dust accumulated in the dust accommodating tank 335.

In this embodiment, the setting position of the dust accommodating groove 335 is adapted to the position where the cleaning plate 333 is retracted to the maximum.

In this embodiment, the dust accommodating groove 335 includes a first accommodating groove 3351, a second accommodating groove 3352, and a connection block 3353; the first receiving groove 3351 and the second receiving groove 3352 are disposed at both sides of the connection block 3353; the surface of the connecting block 3353 is wrapped with a first sponge layer after water absorption; the surface of the supporting block 3332c comprises a second sponge layer; the second sponge layer is suitable for contacting with the first sponge layer when the cleaning plate 333 is retreated to the maximum position, so that the moisture in the first sponge layer is transferred to the second sponge layer; the supporting block 3332c is opened with a plurality of vent holes 3332c1 for communicating the first insertion cavity 3332a with the second insertion cavity 3332 b; the second sponge layer is suitable for adsorbing dust cleaned by the abutting block 3332c when the cooling fan 320 rotates; the first and second plugs are adapted to scrape off dust adhering to the second sponge layer when the cleaning plate 333 is retracted outwardly along the side wall 3341 of the filter chamber 334. When the filter holes on the side wall 3341 of the filter cavity 334 are blocked, the cleaning plate 333 retracts, at this time, the contact part of the second sponge layer on the abutting block 3332c and the side wall 3341 of the filter cavity 334 cleans the filter screen, meanwhile, because the abutting block 3332c is provided with a plurality of vent holes 3332c1, the negative pressure generated by the cooling fan 320 can suck air from the vent holes, the moving direction of the airflow of the air sucked from the vent holes is shown as the airflow moving direction of F2 in FIG. 9, at this time, the dust cleaned by the second sponge layer is driven by the air sucked from the vent holes 3332c1, and is attached to the part of the second sponge layer, which is not in contact with the side wall 3341 of the filter cavity 334; after the second sponge layer is wetted, the attaching effect on dust is greatly improved, the attaching effect on dust is improved, and the moving direction of the airflow of the air directly sucked from the filter cavity is shown as the airflow moving direction of F1 in fig. 9.

In this embodiment, the number of the air inlets 332 of the mounting plate 331 is multiple, and the number of the cleaning plates 333 is the same as that of the air inlets 332. By providing a plurality of air inlets 332 and a cleaning plate 333, the space required for rotation of the cleaning plate 333 is reduced, thereby reducing the overall volume of the self-cleaning air inlet assembly 330.

In this embodiment, the number of the self-cleaning air intake assemblies 330 is two; the two self-cleaning air intake assemblies 330 are respectively disposed on the mounting openings of the two sides of the housing 310.

In summary, the present invention provides an intelligent generator set, which includes a generator body 100, a prime mover 200 and an air cooling mechanism 300; the air cooling mechanism 300 is connected to a rotor shaft of the generator body 100 and is adapted to be driven by a prime mover 200 to cool the generator body 100; the air cooling mechanism 300 comprises a housing 310, a cooling fan 320 and a self-cleaning air intake assembly 330; the cover 310 covers the cooling fan 320; the cover body 310 is provided with a mounting opening suitable for mounting the self-cleaning air intake assembly 330; the cooling fan 320 is adapted to rotate under the driving of the prime mover 200, thereby drawing external cold air from the self-cleaning air intake assembly 330 into the generator body 100 for cooling; the self-cleaning type air intake assembly 330 is adapted to filter the sucked external cold air and clean the filtered dust. Air entering the generator body 100 is filtered through the self-cleaning air inlet assembly 330, and filtered dust is cleaned, so that the durability of the self-cleaning air inlet assembly 330 on dust filtration is improved, the filter screen is prevented from being blocked by the dust, and the cooling effect on the generator body 100 is improved.

The components selected for use in the present application (components not illustrated for specific structures) are all common standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experimentation. Moreover, the software programs referred to in the present application are all prior art, and the present application does not relate to any improvement of the software programs.

In the description of the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. The above-described apparatus embodiments are merely illustrative, and for example, the division of the units into only one type of logical function may be implemented in other ways, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not implemented. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of devices or units through some communication interfaces, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one position, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (7)

1. An intelligent generator set, comprising:

the generator comprises a generator body, a prime motor and an air cooling mechanism;

the air cooling mechanism is connected to a rotor shaft of the generator body and is suitable for being driven by a prime mover so as to cool the generator body;

the air cooling mechanism comprises a cover body, a cooling fan and a self-cleaning air inlet assembly;

the cover body covers the cooling fan;

the cover body is provided with an installation opening suitable for installing the self-cleaning air inlet assembly;

the cooling fan is suitable for being driven by the prime mover to rotate, so that external cold air is sucked into the generator body from the self-cleaning air inlet assembly for cooling;

the self-cleaning air inlet assembly is suitable for filtering sucked external cold air and cleaning the filtered dust;

the self-cleaning air intake assembly includes: a mounting plate and a cleaning plate;

the mounting plate is provided with an air inlet, and a filter cavity is arranged behind the air inlet;

the side wall of the filter cavity is provided with a plurality of filter holes;

the cleaning plate is rotatably connected to the air inlet through a torsion spring;

the cleaning plate is suitable for opening the air inlet under the driving of negative pressure generated by the rotation of the cooling fan when the cooling fan rotates, rotates inwards along the side wall of the filter cavity and cleans the side wall of the filter cavity when the cleaning plate rotates;

the cleaning plate is also suitable for retreating outwards along the side wall of the filter cavity under the action of the torsion spring when the cooling fan stops rotating, and cleaning the side wall of the filter cavity when retreating;

the cleaning plate comprises a rotating part and a telescopic part;

the telescopic part is sleeved at one end of the rotating part close to the side wall of the filter cavity and is elastically connected to the rotating part;

the tail end of the telescopic part is abutted against the side wall of the filter cavity;

the rotating part is provided with a first plug and a second plug;

the first plug and the second plug are oppositely arranged and are arranged at one end of the rotating part close to the side wall of the filter cavity;

a spacing groove is formed between the first plug and the second plug;

a first insertion cavity is formed in the position, opposite to the first plug, of the telescopic part;

a second insertion cavity is formed in the position, opposite to the second plug, of the telescopic part;

a butting block is arranged between the first inserting cavity and the second inserting cavity;

the top of the abutting block is elastically connected to the top of the spacing groove through a first spring;

the cross section of the tail end of the abutting block is arc-shaped and abuts against the side wall of the filter cavity.

2. The intelligent power generation set of claim 1,

when the side wall of the filter cavity is blocked, the suction force of the negative pressure generated by the rotation of the cooling fan on the cleaning plate is reduced, at the moment, the cleaning plate is suitable for retreating outwards along the side wall of the filter cavity so as to clean the side wall of the filter cavity, and then the suction force of the negative pressure generated by the rotation of the cooling fan on the cleaning plate is increased and continues to rotate inwards along the side wall of the filter cavity so as to clean the side wall of the filter cavity again.

3. The intelligent power generation set of claim 1,

the bottom of the air inlet of the mounting plate is provided with a dust accommodating groove;

the cleaning plate is further suitable for scraping dust filtered out from the side wall of the filter cavity into the dust accommodating groove when the cooling fan stops rotating and retreats outwards along the side wall of the filter cavity.

4. The intelligent power generation unit of claim 3,

the dust containing groove is arranged at a position matched with the maximum position of the cleaning plate in a retreating mode.

5. The intelligent power generation unit of claim 4,

the dust accommodating groove comprises a first accommodating groove, a second accommodating groove and a connecting block;

the first accommodating groove and the second accommodating groove are arranged on two sides of the connecting block;

the surface of the connecting block is wrapped with a first sponge layer after water absorption;

the surface of the abutting block comprises a second sponge layer;

the second sponge layer is suitable for contacting with the first sponge layer when the cleaning plate is retracted to the maximum position, so that moisture in the first sponge layer is transferred to the second sponge layer;

the supporting block is provided with a plurality of vent holes for communicating the first inserting cavity with the second inserting cavity;

the second sponge layer is suitable for adsorbing dust cleaned by the abutting block when the cooling fan rotates;

the first plug and the second plug are suitable for scraping off dust adhered to the second sponge layer when the cleaning plate retreats outwards along the side wall of the filter cavity.

6. The intelligent power generation set of claim 1,

the quantity of the air inlet of mounting panel is a plurality of, the quantity of cleaning plate with the quantity of air inlet is the same.

7. The intelligent power generation unit of claim 1,

the number of the self-cleaning air inlet assemblies is two;

the two self-cleaning air inlet assemblies are respectively arranged on the mounting openings at the two sides of the cover body.

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