CN112032017A

CN112032017A - Compression device for electromagnetic compressor

Info

Publication number: CN112032017A
Application number: CN202010963540.5A
Authority: CN
Inventors: 鞠文兵
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-14
Filing date: 2020-09-14
Publication date: 2020-12-04

Abstract

The invention discloses a compression device for an electromagnetic compressor, which comprises a bottom supporting base plate, wherein two opposite main vertical plates are arranged on the upper surface of the bottom supporting base plate, a main first rotating shaft is arranged in the top end of one main vertical plate through a main bearing, a main shaft sleeve is arranged at the top of the other main vertical plate, a main second rotating shaft is arranged in the main shaft sleeve through the main bearing, and a main third rotating shaft is arranged at the end part, opposite to the main second rotating shaft, of the main first rotating shaft. The invention utilizes the electromagnetic principle, when the electric power is switched on, the permanent magnet can generate the expansion trend under the action of the magnetic field and the magnetic pole, so that the parts do not generate the friction contact with larger range and strength, thereby reducing the friction loss and prolonging the service life of the parts.

Description

Compression device for electromagnetic compressor

Technical Field

The invention relates to the technical field of compression devices, in particular to a compression device for an electromagnetic compressor.

Background

At present, most of compression devices compress air through curved bars, but the curved bars are connected during working, so that abrasion of parts at movable parts is large, and the service lives of the parts are short.

Disclosure of Invention

The present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide a compression device for an electromagnetic compressor.

In order to achieve the purpose, the invention provides the following technical scheme: a compression device for an electromagnetic compressor comprises a bottom supporting base plate, wherein two opposite main vertical plates are arranged on the upper surface of the bottom supporting base plate, a main first rotating shaft is arranged in the top end of one main vertical plate through a main bearing, a main shaft sleeve is arranged on the top of the other main vertical plate, a main second rotating shaft is arranged in the main shaft sleeve through the main bearing, a main third rotating shaft is arranged at the end opposite to the main second rotating shaft on the main first rotating shaft, a cylindrical hollow shell is arranged at the end opposite to the main first rotating shaft through a main first connecting plate, a component rotating space is arranged in the center of the cylindrical hollow shell, the main third rotating shaft extends into the center in the component rotating space, an auxiliary wire guide hole is arranged in the center of the main third rotating shaft, and a main wire guide hole communicated with the auxiliary wire guide hole is arranged in the center of the main first rotating shaft, the outer side of the main first rotating shaft is provided with two parallel annular clamping grooves, annular lead copper sheets are respectively embedded in the two annular clamping grooves, the outer ring of each annular lead copper sheet is provided with a wiring conflict groove, the inner ring of each annular lead copper sheet is provided with an auxiliary binding post extending into the main lead hole, the upper surface of the bottom supporting substrate is provided with a main supporting rod, the top of the main supporting rod is provided with a wiring shell, the upper surface of the wiring shell is provided with two main binding posts, each main binding post is correspondingly inserted into the wiring conflict groove, two main guide wires respectively communicated with the two main binding posts are arranged in the wiring shell, the circumferential side surface of the main third rotating shaft is provided with three annular array type component mounting columns, each component mounting column is internally provided with a component mounting hole, and an iron core of which one side surface is sleeved with a coil is arranged in each component mounting hole, the part mounting hole and the auxiliary wire hole are communicated through a wire through hole, the side face of the cylindrical hollow shell is provided with a plurality of annular array type main hollow shells, each main hollow shell is internally provided with a main hollow structure, each main hollow structure is provided with a main air inlet hole and a main air exhaust hole on the end face towards the outer side, a piston is arranged inside each main hollow structure, a main telescopic rod is arranged on one end face towards the inner side of the piston, each main spiral spring in a stretching state is arranged on the rod body of the main telescopic rod, each permanent magnet is arranged on the end portion of the main telescopic rod, the main hollow shell is penetrated through the end portion of the main telescopic rod, and a main shaft body mounting flange plate is arranged on the other end of the main first rotating shaft.

Furthermore, the positive and negative connecting ends of each coil are respectively connected with the two auxiliary binding posts through conducting wires.

Further, the axis of the component mounting post and the axis of the main hollow housing are offset from the axis of the main third rotating shaft.

Further, the deviation direction of the axis of the component mounting post and the axis of the main hollow shell is opposite.

Further, the component mounting post does not contact the permanent magnet during rotational movement.

Furthermore, an air one-way valve is respectively arranged inside the main air inlet hole and the main exhaust hole.

Furthermore, the air exhaust direction and the air intake direction of the air one-way valves positioned in the main air inlet hole and the main air outlet hole face to the air compression space.

Compared with the prior art, the invention has the beneficial effects that: the invention utilizes the electromagnetic principle, when the electric power is switched on, the permanent magnet can generate the expansion trend under the action of the magnetic field and the magnetic pole, so that the parts do not generate the friction contact with larger range and strength, thereby reducing the friction loss and prolonging the service life of the parts.

Drawings

Fig. 1 is a schematic view of a compression device for an electromagnetic compressor according to the present invention;

FIG. 2 is a schematic structural view of a compression device for an electromagnetic compressor of the present invention in the A-A direction;

in the figure: 1, a bottom supporting substrate, 2, a main vertical plate, 3, a main shaft sleeve, 4, a main first rotating shaft, 5, a main shaft body mounting flange plate, 6, a main wire hole, 7, a main third rotating shaft, 8, a cylindrical hollow shell, 9, a main first connecting plate, 10, a main second rotating shaft, 11, an annular clamping groove, 12, an annular wire copper sheet, 13, a wire connection interference groove, 14, an auxiliary wiring terminal, 15, a main wiring terminal, 16, a wiring shell, 17, a main third rotating shaft, 18, a main supporting rod, 19, a component rotating space, 20, an auxiliary wire hole, 21, a main hollow shell, 22, a main hollow structure, 23, a main air inlet hole, 24, a main air outlet hole, 25, a piston, 26, a main telescopic rod, 27, a main spiral spring, 28, a permanent magnet, 29, a component mounting column, 30, a wire through hole, 31, a component mounting hole, 32, an iron core, 33 and a coil.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 and fig. 2, an embodiment of the present invention: the bottom support base plate comprises a bottom support base plate 1, wherein two opposite main vertical plates 2 are arranged on the upper surface of the bottom support base plate 1, a main first rotating shaft 4 is arranged in the top end of one main vertical plate 2 through a main bearing, a main shaft sleeve 3 is arranged on the top of the other main vertical plate 2, a main second rotating shaft 10 is arranged in the main shaft sleeve 3 through a main bearing, a main third rotating shaft 7 is arranged at the end part opposite to the main second rotating shaft 10 of the main first rotating shaft 4, a cylindrical hollow shell 8 is arranged at the end part opposite to the main first rotating shaft 4 through a main first connecting plate 9, a component rotating space 19 is arranged at the center of the cylindrical hollow shell 8, the main third rotating shaft 7 extends into the center in the component rotating space 19, an auxiliary wire guide hole 20 is arranged at the center of the main third rotating shaft 7, and a main wire guide hole 6 communicated with the auxiliary wire guide hole 20 is arranged at the center of the main first rotating shaft 4, the outer side of the main first rotating shaft 4 is provided with two parallel annular clamping grooves 11, annular lead copper sheets 12 are respectively embedded in the two annular clamping grooves 11, the outer ring of each annular lead copper sheet 12 is provided with a wiring interference groove 13, the inner ring of each annular lead copper sheet 12 is provided with an auxiliary binding post 14 extending into the main lead hole 6, the upper surface of the bottom supporting substrate 1 is provided with a main supporting rod 18, the top of the main supporting rod 18 is provided with a wiring shell 16, the upper surface of the wiring shell 16 is provided with two main binding posts 15, each main binding post 15 is correspondingly inserted into one wiring interference groove 13, two main conducting wires 17 respectively communicated with the two main binding posts 15 are arranged in the wiring shell 16, the circumferential side surface of the main third rotating shaft 7 is provided with three annular array type component mounting posts 29, and each component mounting post 29 is internally provided with a component mounting hole 31, an iron core 32 with a coil 33 sleeved on one side is arranged in each component mounting hole 31, the component mounting holes 31 are communicated with the auxiliary wire holes 20 through the wire through holes 30, the side surface of the cylindrical hollow shell 8 is provided with a plurality of main hollow shells 21 in an annular array manner, the inside of each main hollow shell 21 is provided with a main hollow structure 22, the end surface of each main hollow structure 22 facing to the outside is provided with a main air inlet 23 and a main air outlet 24, a piston 25 is arranged in each main hollow structure 22, a main telescopic rod 26 is arranged on one end face of each piston 25 facing inwards, a main spiral spring 27 in a stretching state is arranged on the rod body of each main telescopic rod 26, the end part of each main telescopic rod 26 penetrates through the main hollow shell 21 and is provided with a permanent magnet 28, and a main shaft body mounting flange 5 is arranged at the other end of the main first rotating shaft 4; the positive and negative connecting ends of each coil 33 are respectively connected with the two auxiliary binding posts 14 through conducting wires, and the axial line of the component mounting post 29 and the axial line of the main hollow shell 21 are deviated from the axial line of the main third rotating shaft 7; the deviation direction of the shaft axis of the component mounting post 29 and the shaft axis of the main hollow shell 21 is opposite; the component mounting post 29 does not contact the permanent magnet 28 during rotational movement; an air one-way valve is respectively arranged inside the main air inlet hole 23 and the main exhaust hole 24; the air check valves located inside the main air intake holes 23 and the main air exhaust holes 24 have both the air exhaust direction and the air intake direction directed toward the air compression space 22.

The specific use mode is as follows: in the working process of the invention, a rotating shaft connecting flange 5 is fixedly connected with the end part of a rotating main shaft of a driving motor, then a main exhaust hole 24 is respectively connected with an air inlet hole for storing high-pressure air, and two leads 17 are respectively communicated with the positive pole and the negative pole of a power supply, so that the outer end of an iron core 32 generates a magnetic pole which is repellent to a permanent magnet 28, when the motor works, the iron core 32 can rotate under the linkage action of components, when the motor rotates to be close to the permanent magnet 28 each time, the permanent magnet 28 moves due to the action of the magnetic pole, and a main piston 25 is driven to move, so that the air is compressed, and after the air is compressed, the components reset under the action of a main spiral spring 27, and the reciprocating operation is carried out, so that the compression function of the components.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A compression device for an electromagnetic compressor, comprising a base support plate (1), characterized in that: the upper surface of the bottom supporting base plate (1) is provided with two opposite main vertical plates (2), a main first rotating shaft (4) is arranged in the top end of one main vertical plate (2) through a main bearing, a main shaft sleeve (3) is arranged at the top of the other main vertical plate (2), a main second rotating shaft (10) is arranged in the main shaft sleeve (3) through a main bearing, a main third rotating shaft (7) is arranged at the end part of the main first rotating shaft (4) opposite to the main second rotating shaft (10), a cylindrical hollow shell (8) is arranged at the end part of the main second rotating shaft (10) opposite to the main first rotating shaft (4) through a main first connecting plate (9), a component rotating space (19) is arranged in the center of the cylindrical hollow shell (8), the main third rotating shaft (7) extends into the center in the component rotating space (19), and an auxiliary wire guiding hole (20) is arranged in the center of the main third rotating shaft (7), the center of the main first rotating shaft (4) is provided with a main wire hole (6) communicated with an auxiliary wire hole (20), the outer side of the main first rotating shaft (4) is provided with two parallel annular clamping grooves (11), an annular wire copper sheet (12) is respectively embedded in the two annular clamping grooves (11), each outer ring of the annular wire copper sheet (12) is provided with a wiring interference groove (13), the inner ring of the annular wire copper sheet (12) is provided with an auxiliary binding post (14) extending into the main wire hole (6), the upper surface of the bottom supporting substrate (1) is provided with a main supporting rod (18), the top of the main supporting rod (18) is provided with a wiring shell (16), the upper surface of the wiring shell (16) is provided with two main binding posts (15), each main binding post (15) is correspondingly inserted into the wiring groove (13), two main binding posts (17) respectively communicated with the two main binding posts (15) are arranged in the wiring shell (16), the side surface of the circumference of the main third rotating shaft (7) is provided with three annular array type component mounting columns (29), each component mounting column (29) is internally provided with a component mounting hole (31), one side surface of each component mounting hole (31) is internally provided with an iron core (32) sleeved with a coil (33), the component mounting holes (31) are communicated with the auxiliary wire holes (20) through wire through holes (30), the side surface of the cylindrical hollow shell (8) is provided with a plurality of annular array type main hollow shells (21), a main hollow structure (22) is arranged inside each main hollow shell (21), each main hollow structure (22) is provided with a main air inlet hole (23) and a main exhaust hole (24) on the end surface facing to the outer side, a piston (25) is arranged inside each main hollow structure (22), and a main telescopic rod (26) is arranged on one end surface facing to the inner side of the piston (25), every the body of rod of main telescopic link (26) all installs one and is in tensile state main coil spring (27), every the tip of main telescopic link (26) all runs through main hollow shell (21) and installs a permanent magnet (28), main shaft body installation ring flange (5) are installed to the other end of main first rotation axis (4).

2. The compression device for an electromagnetic compressor according to claim 1, wherein: the positive and negative connecting ends of each coil (33) are respectively connected with the two auxiliary binding posts (14) through conducting wires.

3. The compression device for an electromagnetic compressor according to claim 1, wherein: the axial lead of the component mounting column (29) and the axial lead of the main hollow shell (21) are deviated from the axial lead of the main third rotating shaft (7).

4. A compression device for an electromagnetic compressor according to claim 3, wherein: the deviation direction of the axis of the component mounting column (29) and the axis of the main hollow shell (21) is opposite.

5. The compression device for an electromagnetic compressor according to claim 1, wherein: the component mounting post (29) does not contact the permanent magnet (28) during rotational movement.

6. The compression device for an electromagnetic compressor according to claim 1, wherein: and an air one-way valve is respectively arranged inside the main air inlet hole (23) and the main exhaust hole (24).

7. The compression device for an electromagnetic compressor according to claim 6, wherein: the air exhaust direction and the air intake direction of the air check valve positioned inside the main air inlet hole (23) and the main air exhaust hole (24) face the air compression space (22).