CN115143075A - Vacuum energy-saving pump with good damping effect and high stability - Google Patents

Abstract

The invention discloses a vacuum energy-saving pump with good damping effect and high stability, and belongs to the field of vacuum energy-saving pumps. A vacuum energy-saving pump with good damping effect and high stability comprises a vacuum energy-saving pump main body, wherein the vacuum energy-saving pump main body is provided with a first buffering supporting piece and a second buffering supporting piece which are used for positioning the vacuum energy-saving pump main body; a supporting seat is arranged below the vacuum energy-saving pump main body, and the top of the supporting seat is clamped with the bottoms of the first buffer supporting piece and the second buffer supporting piece respectively; according to the invention, the vacuum energy-saving pump main body is fixed by matching the first buffer support piece and the second buffer support piece, when the vacuum energy-saving pump main body vibrates, the vibration amplitude is buffered by the first buffer support piece and the second buffer support piece, and the first buffer support piece and the second buffer support piece can provide effective and stable support while reducing the vibration of the pump body and providing certain buffer.

Description

Vacuum energy-saving pump with good damping effect and high stability

Technical Field

The invention relates to the technical field of vacuum energy-saving pumps, in particular to a vacuum energy-saving pump with good damping effect and high stability.

Background

The vacuum pump refers to a device or equipment for obtaining vacuum by pumping a pumped container by using a mechanical, physical, chemical or physicochemical method. Generally speaking, a vacuum pump is a device for improving, generating and maintaining vacuum in a certain closed space by various methods, and on the basis of the vacuum energy-saving pump, frequency conversion is carried out by using a frequency conversion technology according to the requirement in actual working, and active frequency reduction is carried out when strong power consumption is not needed so as to reduce efficiency and achieve low energy consumption, and active frequency increase is carried out when high power consumption is needed so as to achieve the effect of energy saving.

The existing vacuum pump is often provided with an installation frame, on a construction site, the vacuum pump provided with the installation frame and part of the vacuum pumps without the installation frame need to use additional installation frames to adapt to different installation environments, and after the additional installation frames are used, the pump body provided with the installation frame is too heavy and cannot be moved well.

The vibration amplitude of the pump body itself can not be considered when the existing pump body is installed, but when the pump body vibrates, not only the vibration can continuously damage the positioning frame body, instability of the frame body is caused, the frame body collapses or the pump body deflects easily, and when the integrated pump body is damaged, the assembly and disassembly are difficult, so that the vacuum energy-saving pump with good damping effect and high stability is provided to solve the problem provided by the method.

Disclosure of Invention

The invention aims to solve the problems of poor stability and large vibration amplitude of a pump body in the prior art, and provides a vacuum energy-saving pump with good damping effect and high stability.

In order to achieve the purpose, the invention adopts the following technical scheme:

a vacuum energy-saving pump with good damping effect and high stability comprises a vacuum energy-saving pump main body, wherein the vacuum energy-saving pump main body is provided with a first buffering support piece and a second buffering support piece which are used for positioning the vacuum energy-saving pump main body; a supporting seat is arranged below the vacuum energy-saving pump main body, and the top of the supporting seat is clamped with the bottoms of the first buffer supporting piece and the second buffer supporting piece respectively; the number of the first buffer supporting pieces is two, and the two first buffer supporting pieces are respectively arranged on the left side of the vacuum energy-saving pump main body and the middle part of the vacuum energy-saving pump main body.

In order to realize effective buffering and fixing on the left side and the middle part of the vacuum energy-saving pump main body, preferably, the first buffering support piece comprises a positioning frame, an external positioning ring, a supporting spring, an inner ring positioning ring, a purging air bag and a communicating air pipe; the supporting springs are uniformly arranged between the outer positioning ring and the inner ring positioning ring in an annular shape; the inner ring positioning ring is sleeved on the vacuum energy-saving pump main body, and the bottom of the outer positioning ring is fixedly connected with the positioning frame; sweep gasbag, intercommunication trachea and all have a plurality ofly, and a plurality ofly sweep the gasbag and be annular and evenly install between outside holding ring, inner circle holding ring, and a plurality of intercommunication tracheas all install on inner circle holding ring, and set up a plurality of blowing gas holes towards vacuum energy-saving pump main part surface on the inner circle holding ring, every the tracheal one end of intercommunication is linked together with adjacent blowing gas bag, and every tracheal other end of intercommunication all communicates with adjacent blowing gas hole.

In order to know whether the vacuum energy-saving pump main body works normally or not, the first buffer support further preferably comprises a signal receiver which is arranged on the front surface of the external positioning ring; the inner wall of outside holding ring is the annular and evenly installs a plurality of pressure sensor, and the equal input electric connection of adjacent outside holding ring of a plurality of pressure sensor's output.

In order to assist in buffering the side edge of the vacuum energy-saving pump main body and flexibly support the right side of the vacuum energy-saving pump main body, preferably, the second buffering support piece comprises a support frame, a contact plate and a support block, a first chute is formed in the contact plate, the support block is slidably connected with the contact plate through the first chute, one end of the support frame is fixedly connected with the support block, the other end of the support frame is fixedly connected with the support base, and four corners of the contact plate are fixedly connected with the vacuum energy-saving pump main body through screws.

In order to buffer the vacuum energy-saving pump main body, limit the vertical vibration amplitude of the whole vacuum energy-saving pump main body and improve the stability, preferably, a second sliding groove is formed in the contact plate, a plurality of limiting sliding blocks are connected to the inside of the second sliding groove in a sliding mode, and the limiting sliding blocks are fixedly connected with the adjacent supporting blocks.

In order to cooperate with the first buffer support piece and the second buffer support piece to support the vacuum energy-saving pump main body, preferably, the top and the bottom of the inner wall of the contact plate are fixedly provided with a buffer spring and a telescopic rod, and the other ends of the buffer springs and the telescopic rods are connected with adjacent support blocks.

In order to realize the fixing effect of the underframe and the ground-contacting seat, preferably, the support seat comprises a support plate, an underframe and a ground-contacting seat, the top of the support plate is respectively connected with the bottoms of the two first buffer support pieces in a clamping manner, and the top of the support plate is fixedly connected with the bottoms of the second buffer support pieces; a plurality of ground sticking seats are sequentially arranged at the bottom of the underframe in parallel from left to right; hollow grooves are formed in the plurality of ground sticking seats; every the equal sliding connection in inside of hollow groove has two inserted bars, and communicates the trachea and keep away from the one end and the hollow groove intercommunication that sweep the gasbag, the one end that the gasbag was swept away from in hollow groove is provided with the pressure release pipeline, the pressure release pipeline is linked together with the scavenging hole, and installs the relief valve in the pressure release pipeline.

For convenient scene to convenient fixed chassis and paste ground seat, preferably, the supporting seat still includes the connecting block, the connecting block has a plurality ofly, and a plurality of connecting blocks all with adjacent chassis fixed connection, and a plurality of chassis all through screw and paste ground seat fixed connection.

In order to facilitate the assembly and disassembly of the vacuum energy-saving pump main body, two solvent storage tanks for storing lubricating oil and cooling liquid are preferably mounted at the top of the supporting plate.

Compared with the prior art, the invention provides the vacuum energy-saving pump with good damping effect and high stability, and the vacuum energy-saving pump has the following beneficial effects:

1. this effectual and high vacuum energy-saving pump of stability of shock attenuation, through first buffering support piece, the cooperation of second buffering support piece fixes the energy-saving pump main part in vacuum, when energy-saving pump main part self vibrations, can cushion this vibration amplitude through first buffering support piece, second buffering support piece to when reducing the pump body vibrations, providing certain buffering, first buffering support piece, second buffering support piece can provide effective stable support.

2. This effectual and high vacuum energy-saving pump of stability of shock attenuation, first buffering support piece, second buffering support piece and supporting seat can be after vacuum energy-saving pump main part damages, pull down first buffering support piece, second buffering support piece, supporting seat from vacuum energy-saving pump main part one by one, and the dismouting is all comparatively convenient to it is comparatively stable to support.

3. This effectual and high vacuum energy-saving pump of stability of shock attenuation, the bottom of supporting seat can be according to actual demand, when meetting mud ground or soil ground, can prick root ground, and stable fixed can directly switch into the plane and place on the cement face, guarantees that it can select different bottom fixed modes according to the needs of difference.

Drawings

FIG. 1 is a schematic perspective view of a first perspective according to the present invention;

FIG. 2 is a schematic perspective view of a second viewing angle according to the present invention;

FIG. 3 is a schematic perspective view of a third viewing angle according to the present invention;

FIG. 4 is a side cross-sectional view of a second cushioning support member according to the present invention;

FIG. 5 is a schematic side view of a lateral connection structure of an outer retaining ring, a support spring and an inner retaining ring according to the present invention;

FIG. 6 is a schematic view of the structure of the floor base of the present invention after replacing the floor base with a flat plate;

fig. 7 is a schematic side sectional view of the floor base of the present invention.

In the figure: 1. a vacuum energy-saving pump main body; 2. a first cushioning support; 21. a signal receiver; 22. a positioning frame; 23. an outer positioning ring; 24. a support spring; 25. an inner ring positioning ring; 26. a pressure sensor; 27. purging the air bag; 28. is communicated with an air pipe; 29. blowing the air holes; 3. a second cushioning support; 31. a support frame; 32. a first chute; 33. a contact plate; 34. a second chute; 35. a limiting slide block; 36. a support block; 37. a buffer spring; 38. a telescopic rod; 4. a supporting seat; 41. a support plate; 42. a chassis; 43. sticking a ground seat; 44. connecting blocks; 45. a hollow groove; 46. a pressure relief duct; 47. a pressure relief valve; 48. a rod is inserted; 5. a solvent storage tank; 6. and (7) maintaining the tool box.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, 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 particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-7, a vacuum energy-saving pump with good damping effect and high stability comprises a vacuum energy-saving pump main body 1, wherein the vacuum energy-saving pump main body 1 is provided with a first buffer support member 2 and a second buffer support member 3 which are used for positioning the vacuum energy-saving pump main body 1; a supporting seat 4 is arranged below the vacuum energy-saving pump main body 1, and the top of the supporting seat 4 is clamped with the bottoms of the first buffer supporting piece 2 and the second buffer supporting piece 3 respectively; the number of the first buffer support pieces 2 is two, and the two first buffer support pieces 2 are respectively arranged at the left side of the vacuum energy-saving pump main body 1 and the middle part of the vacuum energy-saving pump main body 1.

In one embodiment, the first buffer supporting member 2 comprises a positioning frame 22, an outer positioning ring 23, a supporting spring 24, an inner positioning ring 25, a purging air bag 27 and a communication air pipe 28; the number of the supporting springs 24 is multiple, and the supporting springs 24 are uniformly arranged between the outer positioning ring 23 and the inner ring positioning ring 25 in an annular shape; the inner ring positioning ring 25 is sleeved on the vacuum energy-saving pump main body 1, and the bottom of the outer positioning ring 23 is fixedly connected with the positioning frame 22; sweep gasbag 27, intercommunication trachea 28 all have a plurality ofly, and a plurality ofly sweep the gasbag 27 and be annular evenly install between outside holding ring 23, inner circle holding ring 25, and a plurality of intercommunication tracheas 28 all install on inner circle holding ring 25, and set up a plurality of blowing gas holes 29 towards the surface of energy-conserving pump in vacuum main part 1 on the inner circle holding ring 25, the one end of every intercommunication trachea 28 is linked together with adjacent blowing gas bag 27, and the other end of every intercommunication trachea 28 all is linked together with adjacent blowing gas hole 29.

The first buffer support 2 can realize effective buffer fixation on the left side and the middle part of the vacuum energy-saving pump body 1, and the number of the support springs 24 on each external positioning ring 23 can be 8-16; and, still be provided with a plurality of gasbags 27 of blowing between outer holding ring 23, inner ring holding ring 25, when the energy-conserving pump main part 1 of vacuum produced vibrations, not only can compress corresponding supporting spring 24, still can compress corresponding gasbag 27 of blowing, when blowing gasbag 27 and being compressed, can blow the inside gas to the energy-conserving pump main part 1 surface of vacuum through communicating pipe 28, blow the gas pocket 29 and form a good dust removal effect, and what utilize is that the energy-conserving pump main part 1 of vacuum is vibrating force of itself reaches this effect, need not extra electric drive.

In one embodiment, the first cushioning support 2 further comprises a signal receiver 21, the signal receiver 21 being mounted to a front face of an external positioning ring 23; the inner wall of the external positioning ring 23 is annularly and uniformly provided with a plurality of pressure sensors 26, and the output ends of the pressure sensors 26 are electrically connected with the input end of the external positioning ring 23.

When the vacuum energy-saving pump main body 1 works, the vibration can enable the vacuum energy-saving pump main body 1 to move up and down, when the inner ring positioning ring 25 is touched with the pressure sensor 26 because the vibration amplitude of the vacuum energy-saving pump main body 1 is too large, the pressure sensor 26 can transmit data to the signal receiver 21 for recording, a worker can judge whether components are damaged inside the vacuum energy-saving pump main body 1 according to the number of times of impact recorded by the pressure sensor 26, when the vacuum energy-saving pump main body 1 is damaged by the components, but the vacuum energy-saving pump main body 1 can work, the vibration amplitude of the vacuum energy-saving pump main body 1 can be generally increased, when the inner ring positioning ring 25 touches the pressure sensors 26 in different directions for many times, whether the work of the vacuum energy-saving pump main body 1 is normal can be known, and the number of the pressure sensors 26 is matched with the number of the supporting springs 24.

In an embodiment, the second buffering support 3 includes a supporting frame 31, a contact plate 33 and a supporting block 36, the contact plate 33 is provided with a first sliding slot 32, the supporting block 36 is slidably connected to the contact plate 33 through the first sliding slot 32, one end of the supporting frame 31 is fixedly connected to the supporting block 36, the other end of the supporting frame 31 is fixedly connected to the supporting base 4, and four corners of the contact plate 33 are fixedly connected to the vacuum energy-saving pump main body 1 through screws.

The second buffer support 3 is arranged to assist the buffering for the side of the vacuum energy-saving pump main body 1 and to support the right side of the vacuum energy-saving pump main body 1.

In one embodiment, a second sliding slot 34 is formed in the contact plate 33, a plurality of limiting sliders 35 are slidably connected to the inside of the second sliding slot 34, and each of the limiting sliders 35 is fixedly connected to an adjacent supporting block 36.

The limiting slide blocks 35 are arranged and can be matched with the second sliding grooves 34 to limit the vertical vibration amplitude of the whole vacuum energy-saving pump main body 1, the stability is improved, and the number of the limiting slide blocks 35 is 2-4.

In one embodiment, the top and bottom of the inner wall of the contact plate 33 are fixedly mounted with a buffer spring 37 and an expansion link 38, and the other ends of the plurality of buffer springs 37 and the expansion link 38 are connected to the adjacent support block 36.

The buffer spring 37 and the telescopic rod 38 are arranged and can be matched with the supporting spring 24 to achieve the buffer effect on the vacuum energy-saving pump main body 1, and the number of the buffer spring 37 and the number of the telescopic rod 38 can be 4-8.

In one embodiment, the supporting seat 4 includes a supporting plate 41, a bottom frame 42 and a ground seat 43, the top of the supporting plate 41 is respectively connected with the bottoms of the two first buffer supports 2 in a clamping manner, and the top of the supporting plate 41 is fixedly connected with the bottom of the second buffer support 3; a plurality of ground sticking seats 43 are sequentially arranged in parallel at the bottom of the underframe 42 from left to right;

hollow grooves 45 are formed in the plurality of ground sticking seats 43; every the equal sliding connection in inside of hollow groove 45 has two inserted bars 48, and communicates trachea 28 and keep away from the one end and the hollow groove 45 of sweeping gasbag 27 and be linked together, the one end that hollow groove 45 kept away from sweeping gasbag 27 is provided with pressure release pipeline 46, pressure release pipeline 46 is linked together with blowing gas pocket 29, and installs relief valve 47 in the pressure release pipeline 46.

The supporting seat 4 is arranged to be matched with the first buffer supporting piece 2 and the second buffer supporting piece 3 to support the vacuum energy-saving pump main body 1, the number of the ground sticking seats 43 can be 4-6, when the ground sticking seats 43 are inserted into the ground, and in work, the vacuum energy-saving pump main body 1 vibrates, the air bag 27 is repeatedly extruded and swept, generated air enters the hollow groove 45 of the ground sticking seats 43, the air pressure in the hollow groove 45 is increased, the inserting rods 48 on the two sides are pushed to move outwards and are inserted into the soil, and the fixing effect is improved; meanwhile, as the hollow groove 45 and the purging air bag 27 are connected in series, and the air pressure in the hollow groove 45 is increased, the air pressure in the purging air bag 27 is also increased, the air bag is expanded, the movement of the inner ring positioning ring 25 is further limited, and the shaking of the vacuum energy-saving pump main body 1 is limited; when the air pressure in the hollow groove 45 continuously increases and reaches a critical value, the pressure release valve 47 is opened, the air is sprayed out through the blowing air hole 29 and sprayed to the vacuum energy-saving pump main body 1 to remove dust and cool, and when the pressure drops to the critical value, the pressure release valve 47 is automatically closed.

The air inlet pipe is further arranged on the blowing air bag 27, one-way valves are arranged in the air inlet pipe and the communicating air pipe 28, the one-way valves in the air inlet pipe enable air to enter the blowing air bag 27 only, the one-way valves in the communicating air pipe 28 enable air to enter the communicating air pipe 28 only through the blowing air bag 27.

In one embodiment, the supporting base 4 further includes a plurality of connecting blocks 44, the connecting blocks 44 are all fixedly connected to the adjacent bottom frame 42, and the bottom frames 42 are all fixedly connected to the ground seat 43 through screws.

The arrangement of the connecting blocks 44 facilitates the fixing effect of the bottom frame 42 and the ground adhering bases 43, and the number of the connecting blocks 44 can be 2 times that of the ground adhering bases 43.

In one embodiment, two solvent storage tanks 5 for storing lubricant and coolant are installed on the top of the support plate 41.

The solvent storage box 5 is arranged, so that lubricating oil, cooling liquid and other articles which can be used by the vacuum energy-saving pump main body 1 in time can be conveniently placed, and the vacuum energy-saving pump main body 1 can be conveniently maintained on site.

In one embodiment, a service tool box 6 is mounted on top of the support plate 41.

The maintenance tool box 6 is arranged, and a plurality of wrenches, screwdrivers and the like can be placed in the maintenance tool box, so that the vacuum energy-saving pump can be taken and used when the vacuum energy-saving pump main body 1 is assembled and disassembled, and is convenient.

Further, the ground-contacting seat 43 can be replaced according to the use scene, if the soil is soft, the mode in fig. 3 is used for inserting fixation, the stability is better, and if the soil is other ground such as cement, the mode in fig. 6 is used for horizontal fixation.

According to the invention, after the vacuum energy-saving pump main body 1 is transported to a target place, two first buffer supporting pieces 2 are sleeved on the vacuum energy-saving pump main body 1 from left to right, the vacuum energy-saving pump main body 1 is sleeved and then placed downwards, and finally the top of a supporting plate 41 is clamped and fixed with the bottoms of two positioning frames 22, at the moment, a contact plate 33 can be just attached to the vacuum energy-saving pump main body 1, if a threaded hole matched with the contact plate 33 is formed in the vacuum energy-saving pump main body 1, four corners of the contact plate 33 can be fixed with the right side face of the vacuum energy-saving pump main body 1 by using screws, and supporting springs 24 annularly distributed between an outer positioning ring 23 and an inner ring positioning ring 25 are arranged in the first buffer supporting pieces 2, so that the vacuum energy-saving pump main body 1 can be overhead, the vacuum energy-saving pump main body 1 and the structure of the outer positioning ring 23 fixed with the ground form soft connection, and under the condition of stable support, most of vibration amplitude of the vacuum energy-saving pump main body 1 can be consumed by the plurality of supporting springs 24, and an effective buffer effect is formed.

In the second buffer support member 3 on the right side, the telescopic rod 38 controls the vertical direction, so that the device can be adjusted from any direction vibration to the vertical vibration as much as possible, the stability of the device is further improved, and the buffer spring 37 cooperates with the support spring 24 to reduce the vibration amplitude of the vacuum energy-saving pump main body 1, thereby forming a buffer damping effect.

Even under the condition that does not paste ground seat 43, also can raise certain distance with backup pad 41 alone chassis 42, prevent ground ponding to the erosion of vacuum energy-saving pump main part 1 or cause other injuries, and can install through a plurality of connecting blocks 44 and screw between chassis 42 and the ground seat 43, paste ground seat 43 and can insert ground downwards, form a more stable support effect.

When the vacuum energy-saving pump main body 1 is disassembled, firstly, the screw on the contact plate 33 is removed, namely, the vacuum energy-saving pump main body 1 can be drawn upwards, the clamping relation between the supporting plate 41 and the positioning frame 22 is cancelled, and then, the first buffer supporting piece 2 can be removed by sliding from the left side of the vacuum energy-saving pump main body 1.

This effectual and high vacuum energy-saving pump of stability of shock attenuation, through first buffering support piece 2, the fixed vacuum energy-saving pump main part 1 of second buffering support piece 3 cooperation, when the vibrations of vacuum energy-saving pump main part 1 self, through first buffering support piece 2, this vibration range can be cushioned by second buffering support piece 3, and reduce the vibrations of the pump body, when providing certain buffering, first buffering support piece 2, second buffering support piece 3 can provide effective stable support, through first buffering support piece 2, second buffering support piece 3 and supporting seat 4 can be after vacuum energy-saving pump main part 1 damages, with first buffering support piece 2, second buffering support piece 3, supporting seat 4 pulls down one by one from vacuum energy-saving pump main part 1, the dismouting is all comparatively convenient, and it is comparatively stable to support, the bottom of supporting seat 4 can be according to actual demand, when meetting mud ground or soil ground, can prick root ground, it is stable fixed, can directly switch over to the plane on the cement face and place, guarantee that it can select different bottom fixing modes according to the needs.

All the used controllers and electronic elements can be installed in proper sizes and models according to actual conditions under the condition that the functions of the invention can be realized.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. A vacuum energy-saving pump with good damping effect and high stability comprises a vacuum energy-saving pump main body (1) and is characterized in that,

the vacuum energy-saving pump is characterized in that the vacuum energy-saving pump main body (1) is provided with a first buffer support piece (2) and a second buffer support piece (3) which are used for positioning the vacuum energy-saving pump main body (1);

a supporting seat (4) is arranged below the vacuum energy-saving pump main body (1), and the top of the supporting seat (4) is clamped with the bottoms of the first buffer supporting piece (2) and the second buffer supporting piece (3) respectively;

the number of the first buffer supporting pieces (2) is two, and the two first buffer supporting pieces (2) are respectively arranged on the left side of the vacuum energy-saving pump main body (1) and the middle part of the vacuum energy-saving pump main body (1).

2. The vacuum energy-saving pump with good shock absorption effect and high stability as claimed in claim 1, wherein the first buffer support member (2) comprises a positioning frame (22), an outer positioning ring (23), a support spring (24), an inner positioning ring (25), a purging air bag (27) and a communicating air pipe (28);

the number of the supporting springs (24) is multiple, and the supporting springs (24) are uniformly arranged between the outer positioning ring (23) and the inner positioning ring (25) in an annular shape;

the inner ring positioning ring (25) is sleeved on the vacuum energy-saving pump main body (1), and the bottom of the outer positioning ring (23) is fixedly connected with the positioning frame (22);

sweep gasbag (27), intercommunication trachea (28) and all have a plurality ofly, and a plurality ofly sweep gasbag (27) and be annular evenly to install between outside holding ring (23), inner circle holding ring (25), and a plurality of intercommunication tracheas (28) all install on inner circle holding ring (25), and set up a plurality of sweeping gas hole (29) towards vacuum energy-saving pump main part (1) surface on inner circle holding ring (25), every the one end and the adjacent gasbag (27) that sweep of intercommunication trachea (28) are linked together, and the other end of every intercommunication trachea (28) all is linked together with adjacent sweeping gas hole (29).

3. The vacuum energy-saving pump with good shock absorption effect and high stability as claimed in claim 2, wherein the first buffer support (2) further comprises a signal receiver (21), the signal receiver (21) is mounted on the front surface of the outer positioning ring (23);

the inner wall of outside holding ring (23) is that the annular evenly installs a plurality of pressure sensor (26), and the equal input electric connection of adjacent outside holding ring (23) of output of a plurality of pressure sensor (26).

4. The energy-saving vacuum pump with good shock absorption and high stability as claimed in claim 1, wherein the second buffer support (3) comprises a support frame (31), a contact plate (33) and a support block (36);

the contact plate (33) is provided with a first sliding groove (32), and the supporting block (36) is in sliding connection with the contact plate (33) through the first sliding groove (32);

one end of the support frame (31) is fixedly connected with the support block (36), and the other end of the support frame (31) is fixedly connected with the support seat (4);

four corners of the contact plate (33) are fixedly connected with the vacuum energy-saving pump main body (1) through screws.

5. The vacuum energy-saving pump with good shock absorption effect and high stability as claimed in claim 4, wherein a second sliding groove (34) is formed inside the contact plate (33);

the inside sliding connection of second spout (34) has limiting slide block (35), limiting slide block (35) have a plurality ofly, and a plurality of limiting slide block (35) all with adjacent supporting shoe (36) fixed connection.

6. The energy-saving vacuum pump with good damping effect and high stability as claimed in claim 4, wherein the top and bottom of the inner wall of the contact plate (33) are fixedly provided with a buffer spring (37) and a telescopic rod (38);

the other ends of the buffer springs (37) and the telescopic rods (38) are connected with the adjacent supporting blocks (36).

7. The vacuum energy-saving pump with good shock absorption effect and high stability as claimed in claim 2, wherein the supporting seat (4) comprises a supporting plate (41), a bottom frame (42) and a ground-contacting seat (43);

the top of the supporting plate (41) is respectively connected with the bottoms of the two first buffer supporting pieces (2) in a clamping manner, and the top of the supporting plate (41) is fixedly connected with the bottom of the second buffer supporting piece (3);

a plurality of ground sticking seats (43) are sequentially arranged at the bottom of the bottom frame (42) from left to right in parallel;

hollow grooves (45) are formed in the plurality of ground sticking seats (43); every the equal sliding connection in inside of hollow groove (45) has two inserted bars (48), and communicates trachea (28) and keep away from the one end and the hollow groove (45) of sweeping gasbag (27) and be linked together, the one end that the gasbag (27) were swept in keeping away from of hollow groove (45) is provided with pressure release pipeline (46), pressure release pipeline (46) are linked together with sweeping gas hole (29), and install relief valve (47) in pressure release pipeline (46).

8. The vacuum energy-saving pump with good damping effect and high stability as claimed in claim 7, wherein the supporting base (4) further comprises a connecting block (44);

the connecting blocks (44) are multiple, the connecting blocks (44) are fixedly connected with the adjacent underframe (42), and the underframe (42) is fixedly connected with the ground sticking seat (43) through screws.

9. The energy-saving vacuum pump with good shock absorption effect and high stability as claimed in claim 7, wherein two solvent storage tanks (5) for storing lubricating oil and cooling liquid are installed on the top of the supporting plate (41).

10. The vacuum energy-saving pump with good shock absorption effect and high stability as claimed in claim 7, wherein a maintenance tool box (6) is installed on the top of the supporting plate (41).

Images