CN114688316A

CN114688316A - Energy-saving vacuum suction mechanism

Info

Publication number: CN114688316A
Application number: CN202011635573.3A
Authority: CN
Inventors: 陈晓峰; 杨春雨
Original assignee: Suzhou Zhuozhao Dispensing Co Ltd
Current assignee: Suzhou Zhuozhao Dispensing Co Ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2022-07-01
Anticipated expiration: 2040-12-31
Also published as: CN114688316B

Abstract

The invention discloses an energy-saving vacuum suction mechanism, which is arranged on a vacuum chamber body, wherein the outer surface of one side of the vacuum chamber body is provided with an air suction opening and two air inlets, a connecting seat is arranged on the air extraction opening, one end surface of the connecting seat is connected with the vacuum chamber body, the first cylinder is arranged on the other end face of the connecting seat, a piston rod of the first cylinder is connected with the first flange plate through a first core shaft, a first through hole communicated with the air suction port is formed in the connecting seat along the direction of the first mandrel, the first mandrel is telescopically arranged in the first through hole, the connecting seat is also provided with an air exhaust hole communicated with the first through hole, the first mandrel is sleeved with an elastic piece, be provided with a cushion between first cylinder and the connecting seat, it is two to imbed respectively the external diameter ratio between 2 second ring flanges in the air inlet is 5: 2 to 3. The invention realizes the accurate adjustment of the air pressure in the vacuum chamber body and can also realize the gradual pressure relief in the vacuum breaking process.

Description

Energy-saving vacuum suction mechanism

Technical Field

The invention relates to the technical field of vacuum cavity sealing, in particular to an energy-saving vacuum pumping mechanism.

Background

The vacuum cavity is mainly applied to the product point and glues and the encapsulation field, utilizes the effort of negative pressure, takes away the air in the vacuum box earlier at the in-process that fills, carries out the product again and fills, can permeate glue inside the product fast, fills and assaults and glue and also can take away fast with the bubble that the product contact produced under the negative pressure to guarantee the high performance of product. In the prior art, when the cavity is vacuumized, the vacuum value in the cavity is unstable due to the fact that the pressure difference between the air pressure in the cavity and the external air pressure is large and the valve is delayed when being closed. And the adsorption force generated by the larger internal and external pressure difference has higher output power requirement on the closing mechanism of the valve, and the valve opening and closing mechanism with larger kinetic energy can impact the cavity, so that the service life of the valve is shortened.

Disclosure of Invention

The invention aims to provide an energy-saving vacuum suction mechanism which realizes accurate adjustment of air pressure in a vacuum chamber body and can realize gradual pressure relief in a vacuum breaking process.

In order to achieve the purpose, the invention adopts the technical scheme that: an energy-saving vacuum suction mechanism is arranged on a vacuum chamber body, an air suction opening and two air inlets are formed in the outer surface of one side of the vacuum chamber body, the inner walls of the air suction opening and the air inlets, which are close to one end inside the vacuum chamber body, are respectively provided with a flange part extending inwards in the radial direction, a first flange plate is embedded into the air suction opening, a second flange plate is embedded into the air inlets, the end surfaces of one end of each of the first flange plate and the second flange plate are in surface contact with the end surfaces of the corresponding flange part, and the other end of each of the first flange plate and the second flange plate is connected with a piston rod of a first air cylinder and a piston rod of a second air cylinder which are correspondingly arranged;

the vacuum pump is characterized in that a connecting seat is mounted on the air exhaust opening, one end face of the connecting seat is connected with the vacuum chamber body, a first air cylinder is mounted on the other end face of the connecting seat, a piston rod of the first air cylinder is connected with a first flange plate through a first spindle, a first through hole communicated with the air exhaust opening is formed in the connecting seat along the direction of the first spindle, the first spindle is telescopically arranged in the first through hole, an air exhaust hole communicated with the first through hole is further formed in the connecting seat, and the air exhaust hole is used for being connected with a vacuum pump;

the first mandrel is sleeved with an elastic piece, one end of the elastic piece, close to the first flange plate, is in contact with an outer flange part positioned at the tail end of the first mandrel, and the other end of the elastic piece is connected with a shell of the first cylinder in an extrusion manner;

a cushion block is arranged between the first air cylinder and the connecting seat, the other end of the elastic piece is connected with the cushion block in an extrusion manner, a second through hole through which a piston rod and a first mandrel of the first air cylinder can penetrate is formed in the center of the cushion block, and an air outlet hole communicated with the second through hole is formed in the outer end face of the cushion block;

the inner diameter of one end, close to the elastic part, of the second through hole is smaller than that of one end, close to the first cylinder, of the second through hole;

the ratio of the outer diameters of the 2 second flange plates respectively embedded into the two air inlets is 5: 2-3, when the vacuum cabin body is in the pressure release state, the second flange plate with the small outer diameter is pulled out from the corresponding air inlet through the second air cylinder, and then the second flange plate with the large outer diameter is pulled out from the corresponding air inlet.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, an air inlet is provided with a supporting seat for mounting the second air cylinder.

2. In the above scheme, the second flange plate is connected with the piston rod of the second cylinder through a connecting block.

3. In the above scheme, the elastic member is a bellows-shaped elastic member.

4. In the scheme, a supporting gasket is arranged between the shell of the first cylinder and the elastic piece, and the supporting gasket is sleeved on the first mandrel and is in extrusion contact with the end face of the elastic piece.

5. In the above scheme, the support gasket is fixedly arranged in the air exhaust port.

6. In the above scheme, the cushion block comprises a main body part close to the first cylinder and a protruding part embedded into the air exhaust port.

7. In the above scheme, the extraction holes are arranged along a direction perpendicular to the first through hole.

Due to the application of the technical scheme, compared with the prior art, the invention has the following advantages:

1. the piston rod of the air cylinder of the energy-saving vacuum pumping mechanism is connected with the first flange plate through a mandrel, a through hole communicated with the air exhaust port is formed in the connecting seat along the direction of the mandrel, the mandrel is telescopically arranged in the through hole, an elastic piece is sleeved on the mandrel, one end of the elastic piece, close to the first flange plate, is in contact with an outer flange part positioned on the tail end of the mandrel, the other end of the elastic piece is in extrusion connection with a shell of the air cylinder, force can be applied to the first flange plate in a superposed mode when the first flange plate is closed through the arrangement of the elastic piece, the sealing performance of the first flange plate on the air exhaust port in the long-term use process is improved, impact caused by too fast contraction can be prevented in the opening process of the first flange plate, and the service life of the mechanism is prolonged.

2. The invention relates to an energy-saving vacuum pumping mechanism, wherein the ratio of the outer diameters of 2 second flange plates respectively embedded into two air inlets is 5: 2~3, when the vacuum storehouse body is in the pressure release state, pull out the second ring flange that the external diameter is little from the air inlet that corresponds through the second cylinder, pull out the second ring flange that the external diameter is big from the air inlet that corresponds again, set up through the cooperation between 2 second ring flanges that first ring flange and size are different, on the basis of realizing carrying out the evacuation to the vacuum storehouse body, further realized the accurate regulation to the internal gas pressure of vacuum storehouse, can also be at broken vacuum in-process step by step pressure release, both avoid the internal gas pressure shock of vacuum storehouse to damage product or equipment part, can avoid again because of the cylinder output power not enough the condition that can not pull open the second ring flange, both reduced the requirement to cylinder output power, consumption reduction and energy saving, can reduce the impact load to the vacuum storehouse body again, extension equipment life.

3. According to the energy-saving vacuum pumping mechanism, the cushion block is arranged between the first air cylinder and the connecting seat, the other end of the elastic piece is connected with the cushion block in an extruding manner, the center of the cushion block is provided with the second through hole for the piston rod of the first air cylinder and the first mandrel to penetrate through, and the outer end surface of the cushion block is provided with the air outlet hole communicated with the second through hole, so that the piston rod of the air cylinder can be ensured to always keep constant driving force in the long-term reciprocating motion process, and the condition that the flange plate cannot be driven to tightly seal the air suction opening due to air blocking is avoided; furthermore, the inner diameter of one end, close to the elastic piece, of the second through hole is smaller than that of one end, close to the first air cylinder, of the second through hole, so that the air cylinder and the cushion block can be assembled more tightly, smooth exhaust of the air outlet can be kept, the situation that the piston rod of the air cylinder is not smooth in movement due to air blocking is further prevented, and smooth and stable operation of a vacuumizing process in a long-term use process is guaranteed.

Drawings

FIG. 1 is a schematic structural view of an energy-saving vacuum pumping mechanism according to the present invention;

FIG. 2 is a schematic cross-sectional view of the energy-saving vacuum pumping mechanism of the present invention;

FIG. 3 is a first schematic structural diagram of a cushion block in the energy-saving vacuum pumping mechanism of the present invention;

FIG. 4 is a schematic structural diagram II of a cushion block in the energy-saving vacuum pumping mechanism of the invention.

In the above drawings: 1. a vacuum bin body; 2. an air extraction opening; 3. an air inlet; 4. a flange portion; 5. a first flange plate; 6. a second flange plate; 7. a first cylinder; 8. a second cylinder; 9. a connecting seat; 10. a first mandrel; 101. an outer flange portion; 11. a first through hole; 12. an air exhaust hole; 13. an air exhaust seat; 14. an elastic member; 15. a support washer; 16. a cushion block; 161. a main body portion; 162. a boss portion; 17. a second through hole; 18. and an air outlet.

Detailed Description

In the description of this patent, it is 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 in describing the present invention and simplifying the description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; 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 meaning of the above terms in this patent may be specifically understood by those of ordinary skill in the art.

Example 1: an energy-saving vacuum suction mechanism is arranged on a vacuum cabin body 1, an air suction opening 2 and two air inlet 3 are arranged on the outer surface of one side of the vacuum cabin body 1, the inner walls of the air suction opening 2 and the air inlet 3 close to one end inside the vacuum cabin body 1 respectively are provided with a flange part 4 extending inwards in the radial direction, a first flange plate 5 is embedded into the air suction opening 2, a second flange plate 6 is embedded into the air inlet 3, the end surfaces of one end of each of the first flange plate 5 and the second flange plate 6 are in surface contact with the end surfaces of the corresponding flange part 4, and the other end of each of the first flange plate 5 and the second flange plate 6 is connected with the piston rods of a first air cylinder 7 and a second air cylinder 8 which are correspondingly arranged;

a connecting seat 9 is installed on the air suction port 2, one end face of the connecting seat 9 is connected with the vacuum chamber body 1, the first air cylinder 7 is installed on the other end face of the connecting seat 9, a piston rod of the first air cylinder 7 is connected with the first flange 5 through a first mandrel 10, a first through hole 11 communicated with the air suction port 2 is formed in the connecting seat 9 along the direction of the first mandrel 10, the first mandrel 10 is telescopically arranged in the first through hole 11, an air suction hole 12 communicated with the first through hole 11 is further formed in the connecting seat 9, and the air suction hole 12 is used for being connected with a vacuum pump;

an elastic part 14 is sleeved on the first mandrel 10, one end of the elastic part 14 close to the first flange plate 5 is in contact with an outer flange part 101 positioned on the tail end of the first mandrel 10, and the other end of the elastic part 14 is connected with the shell of the first cylinder 7 in a squeezing mode;

a cushion block 16 is arranged between the first cylinder 7 and the connecting seat 9, the other end of the elastic part 14 is connected with the cushion block 16 in an extruding manner, a second through hole 17 for a piston rod of the first cylinder 7 and the first mandrel 10 to penetrate is formed in the center of the cushion block 16, and an air outlet hole 18 communicated with the second through hole 17 is formed in the outer end face of the cushion block 16;

the inner diameter of the second through hole 17 close to one end of the elastic piece 14 is smaller than that of the second through hole close to one end of the first cylinder 7;

the ratio of the outer diameters of the 2 second flange plates 6 respectively embedded into the two air inlets 3 is 5: 2, when the vacuum chamber body 1 is in a pressure relief state, the second flange 6 with small outer diameter is pulled out from the corresponding air inlet 3 through the second air cylinder 8, and then the second flange 6 with large outer diameter is pulled out from the corresponding air inlet 3.

A support seat for mounting the second cylinder 8 is mounted on the intake port 3.

The second flange 6 is connected with the piston rod of the second cylinder 8 through a connecting block.

The elastic member 14 is a bellows-shaped elastic member.

The support washer 15 is fixedly installed in the suction port 2.

The suction hole 12 is provided in a direction perpendicular to the first through hole 11.

Example 2: an energy-saving vacuum suction mechanism is arranged on a vacuum cabin body 1, an air suction opening 2 and two air inlet 3 are arranged on the outer surface of one side of the vacuum cabin body 1, the inner walls of the air suction opening 2 and the air inlet 3 close to one end inside the vacuum cabin body 1 respectively are provided with a flange part 4 extending inwards in the radial direction, a first flange plate 5 is embedded into the air suction opening 2, a second flange plate 6 is embedded into the air inlet 3, the end surfaces of one end of each of the first flange plate 5 and the second flange plate 6 are in surface contact with the end surfaces of the corresponding flange part 4, and the other end of each of the first flange plate 5 and the second flange plate 6 is connected with the piston rods of a first air cylinder 7 and a second air cylinder 8 which are correspondingly arranged;

the ratio of the outer diameters of the 2 second flange plates 6 respectively embedded into the two air inlets 3 is 5: 3, when the vacuum chamber body 1 is in a pressure relief state, the second flange 6 with small outer diameter is pulled out from the corresponding air inlet 3 through the second air cylinder 8, and then the second flange 6 with large outer diameter is pulled out from the corresponding air inlet 3.

A support gasket 15 is arranged between the shell of the first cylinder 7 and the elastic element 14, and the support gasket 15 is sleeved on the first mandrel 10 and is in pressing contact with the end face of the elastic element 14.

The pad 16 includes a main body 161 close to the first cylinder 7 and a boss 162 fitted into the suction port 2.

The working principle is as follows:

the first cylinder drives the first flange plate to stretch so as to control the opening and closing of the air exhaust channel, thereby controlling the on-off of the vacuumizing operation in the vacuum chamber body;

the opening and closing of the air inlet flow channel are controlled by driving the second flange plate to stretch by 2 second cylinders, and the air pressure change and the air pressure micro-change in the vacuum bin body are respectively controlled;

when the first flange plate is pulled away from the air pumping hole by the first air cylinder, the external part is connected with an air pump to start working, and air is pumped from the vacuum chamber body;

when the air pressure in the vacuum bin is larger than a preset value of an air pressure sensor arranged on the vacuum bin, the first air cylinder pushes the first flange plate into the air exhaust port;

pulling the second flange plate with the smaller outer diameter away from the air inlet, and finely adjusting the air pressure in the vacuum chamber body until the air pressure reaches a preset value;

after the operation in the vacuum cabin is finished, the second flange plate with the smaller outer diameter is pulled away from the air inlet, the pressure is slowly released, and when the air pressure in the vacuum cabin reaches a preset value, the second flange plate with the larger outer diameter is pulled away from the air inlet, and the pressure is completely released.

When the air suction mechanism is adopted, due to the arrangement of the elastic piece, the first flange plate can be superposed and applied with force when the first flange plate is closed, the sealing performance of the first flange plate on the air suction opening in the long-term use process is improved, the impact caused by too fast contraction can be prevented in the opening process of the first flange plate, and the service life of the mechanism is prolonged;

in addition, through the matching arrangement of the first flange plate and the 2 second flange plates with different sizes, on the basis of realizing the vacuumizing of the vacuum chamber body, the accurate adjustment of the air pressure in the vacuum chamber body is further realized, and the pressure can be gradually released in the vacuum breaking process, so that the damage to products or equipment parts caused by the sudden change of the air pressure in the vacuum chamber body is avoided, the condition that the second flange plate cannot be pulled open due to insufficient output power of the air cylinder is avoided, the requirements on the output power of the air cylinder are reduced, the consumption and the energy are reduced, the impact load on the vacuum chamber body can be reduced, and the service life of the equipment is prolonged;

in addition, the constant driving force of the piston rod of the air cylinder can be ensured to be always kept in the long-term reciprocating motion process, and the condition that the flange plate cannot be driven to tightly seal the air suction opening due to air holding is avoided;

furthermore, the assembly between the air cylinder and the cushion block can be more compact, smooth exhaust of the air outlet can be kept, the unsmooth movement of the piston rod of the air cylinder caused by air blocking is further prevented, and smooth and stable operation of the vacuumizing process in the long-term use process is guaranteed.

The above embodiments are only for illustrating the technical idea and features of the present invention, and the purpose of the present invention is to enable those skilled in the art to understand the content of the present invention and implement the present invention, and not to limit the protection scope of the present invention by this means. All equivalent changes and modifications made according to the spirit of the present invention should be covered in the protection scope of the present invention.

Claims

1. An energy-saving vacuum suction mechanism which is characterized in that: the device is characterized in that the device is arranged on a vacuum cabin body (1), an air suction opening (2) and two air inlets (3) are formed in the outer surface of one side of the vacuum cabin body (1), a flange part (4) extending inwards in the radial direction is formed in each of the inner walls of one ends, close to the inside of the vacuum cabin body (1), of the air suction opening (2) and the air inlets (3), a first flange plate (5) is embedded into the air suction opening (2), a second flange plate (6) is embedded into the air inlets (3), the end faces of one ends of the first flange plate (5) and one end face of one end of the second flange plate (6) are in surface contact with the end face of the corresponding flange part (4), and the other ends of the first flange plate (5) and the second flange plate (6) are connected with piston rods of a first air cylinder (7) and a second air cylinder (8) which are correspondingly arranged;

a connecting seat (9) is installed on the air suction opening (2), one end face of the connecting seat (9) is connected with the vacuum cabin body (1), the first air cylinder (7) is installed on the other end face of the connecting seat (9), a piston rod of the first air cylinder (7) is connected with the first flange plate (5) through a first mandrel (10), a first through hole (11) communicated with the air suction opening (2) is formed in the connecting seat (9) along the direction of the first mandrel (10), the first mandrel (10) is telescopically arranged in the first through hole (11), an air suction hole (12) communicated with the first through hole (11) is further formed in the connecting seat (9), and the air suction hole (12) is used for being connected with a vacuum pump;

an elastic piece (14) is sleeved on the first mandrel (10), one end, close to the first flange plate (5), of the elastic piece (14) is in contact with an outer flange portion (101) located at the tail end of the first mandrel (10), and the other end of the elastic piece (14) is connected with a shell of the first air cylinder (7) in an extrusion mode;

a cushion block (16) is arranged between the first air cylinder (7) and the connecting seat (9), the other end of the elastic part (14) is connected with the cushion block (16) in an extrusion manner, a second through hole (17) through which a piston rod of the first air cylinder (7) and the first mandrel (10) can penetrate is formed in the center of the cushion block (16), and an air outlet hole (18) communicated with the second through hole (17) is formed in the outer end face of the cushion block (16);

the inner diameter of one end, close to the elastic piece (14), of the second through hole (17) is smaller than that of one end, close to the first air cylinder (7), of the second through hole;

the ratio of the outer diameters of 2 second flange plates (6) respectively embedded into the two air inlets (3) is 5: 2~3, when the vacuum cabin body (1) is in the pressure release state, pull out the second ring flange (6) that the external diameter is little from air inlet (3) that correspond through second cylinder (8), pull out the second ring flange (6) that the external diameter is big from air inlet (3) that correspond again.

2. The energy efficient vacuum pumping mechanism of claim 1, wherein: and a support seat for mounting a second cylinder (8) is mounted on the air inlet (3).

3. The energy efficient vacuum pumping mechanism of claim 1, wherein: the second flange plate (6) is connected with a piston rod of the second cylinder (8) through a connecting block.

4. The energy efficient vacuum pumping mechanism of claim 1, wherein: the elastic member (14) is a bellows-shaped elastic member.

5. The energy efficient vacuum pumping mechanism of claim 1, wherein: a supporting gasket (15) is arranged between the shell of the first air cylinder (7) and the elastic part (14), and the supporting gasket (15) is sleeved on the first mandrel (10) and is in extrusion contact with the end face of the elastic part (14).

6. The energy efficient vacuum pumping mechanism of claim 5, wherein: the supporting gasket (15) is fixedly arranged in the air suction port (2).

7. The energy efficient vacuum pumping mechanism of claim 1, wherein: the cushion block (16) comprises a main body part (161) close to the first air cylinder (7) and a convex part (162) embedded in the air suction port (2).

8. The energy efficient vacuum pumping mechanism of claim 1, wherein: the air exhaust hole (12) is arranged along the direction perpendicular to the first through hole (11).