CN114941629A - High-sealing impact-resistant double-shell energy-saving pump - Google Patents

Abstract

The invention discloses a high-sealing impact-resistant double-shell energy-saving pump, which belongs to the technical field of double-shell energy-saving pumps.

Description

High-sealing impact-resistant double-shell energy-saving pump

Technical Field

The invention relates to a double-shell energy-saving pump, in particular to a high-sealing impact-resistant double-shell energy-saving pump, and belongs to the technical field of double-shell energy-saving pumps.

Background

Compared with a common oil pump, the energy-saving pump has the advantages of high benefit, low noise, no vibration and long service life;

the energy-saving pump plays an important role in the drying process fields of textile printing and dyeing, chemical industry, wood construction, medicine, paper making and the like;

the energy-saving pump in the prior art has the following problems:

when the device is used, the outer shell of the device does not have a good protection function, so that the first problem is that relatively large noise is easily generated, and the second problem is that the device is very easy to damage when being impacted;

the energy-saving pump in the prior art cannot realize the function of heat exchange when in use, so that the energy in the process needing cooling cannot be fully utilized;

when the energy-saving pump in the prior art is used, the energy-saving pump is not fixed with good damping function and has comprehensive damping and fixing effects on different parts;

when the energy-saving pump in the prior art is used, the energy-saving pump has no good filtering function on the flow guide of different solutions;

a high-sealing and impact-resistant double-shell energy-saving pump is designed for improving the problems.

Disclosure of Invention

The invention mainly aims to provide a high-sealing impact-resistant double-shell energy-saving pump, wherein a first heat exchange tube is wound on the outer side of a liquid inlet tube, a second heat exchange tube is wound on the outer side of a liquid outlet tube, one end of the first heat exchange tube penetrates through a first clamping arc-shaped plate, one end of the second heat exchange tube penetrates through a second clamping arc-shaped plate, two groups of first clamping arc-shaped plates are fixed on the outer side of the liquid inlet tube through screws and clamp the first heat exchange tube, the second clamping arc-shaped plate is fixed on the outer side of the liquid outlet tube through screws and clamp the second heat exchange tube, when equipment is impacted, a first inner sliding plate or a second inner sliding plate is compressed through contact with a first side arc-shaped buffer plate or a second side arc-shaped buffer plate to adjust a third buffer spring or a second buffer spring to perform protection buffering and operation noise reduction, a first U-shaped clamping seat is sleeved on the outer side of the first clamping arc-shaped plate and fixes a first T-shaped motor seat on a bottom plate, the second U-shaped clamping seat is sleeved on the outer side of the second clamping arc-shaped plate and fixes the second T-shaped motor seat on the bottom plate, liquid passes through the liquid inlet pipe when the paddle is started to operate, the second U-shaped communicating pipe, the second inner cylinder when the first U-shaped connecting pipe and the liquid outlet pipe run, the second T-shaped motor seat, the fourth buffer spring and the first inner cylinder, the first T-shaped motor seat and the first buffer spring buffer and reduce noise, the liquid passes through the first detachable filter cylinder and the second detachable filter cylinder when the paddle runs, the liquid is filtered through the filter plates in the first detachable filter cylinder and the second detachable filter cylinder and then is led out, and when heat exchange is needed, cold water can be subjected to heat exchange with the liquid flowing in the liquid inlet pipe and the liquid outlet pipe through the first heat exchange pipe and the second heat exchange pipe.

The purpose of the invention can be achieved by adopting the following technical scheme:

a high-sealing impact-resistant double-shell energy-saving pump comprises a first U-shaped connecting pipe, wherein the bottom of the first U-shaped connecting pipe is communicated with a liquid guide driving bin assembly, the bottom of the liquid guide driving bin assembly is communicated with a second U-shaped communicating pipe, the bottom of the second U-shaped communicating pipe is communicated with a first detachable filter cylinder, the top of the first U-shaped connecting pipe is communicated with a second detachable filter cylinder, filter plate assemblies are arranged inside the second detachable filter cylinder and the first detachable filter cylinder, the other end of the first U-shaped connecting pipe is communicated with a liquid outlet pipe, the other end of the second U-shaped communicating pipe is communicated with a liquid inlet pipe, heat exchange pipe assemblies are wound on the outer sides of the liquid inlet pipe and the liquid outlet pipe, a first clamping arc-shaped plate and a second clamping arc-shaped plate are respectively mounted on the outer sides of the liquid inlet pipe and the liquid outlet pipe, and a first arc-shaped buffer plate assembly is mounted on the outer side of the first clamping arc-shaped plate, the motor base is characterized in that a second arc-shaped buffer plate assembly is installed on the outer side of the second clamping arc-shaped plate, a first motor base assembly is installed at the bottom of the first clamping arc-shaped plate, and a second motor base assembly is installed at the bottom of the second clamping arc-shaped plate.

Preferably, drain drive storehouse subassembly includes roof, paddle cover and paddle, the roof is installed to the bottom of first U type connecting pipe, just the paddle cover is installed to the bottom of roof, the interior middle part department of paddle cover is equipped with the paddle, the drive arrangement storehouse is installed to the bottom of paddle cover, just the inside in drive arrangement storehouse is equipped with driving motor, and this driving motor runs through the bottom middle part department of paddle cover and paddle and fixes.

Preferably, the filter subassembly includes filter, median septum and umbrella type roof, the filter is all installed at the inner bottom middle part that the cartridge filter can be dismantled with the second in the inner bottom middle part of first cartridge filter of dismantling, the median septum is installed to the top department of filter, the umbrella type roof is installed at the top of median septum, and the umbrella type roof that is located on the first cartridge filter of dismantling contradicts in the interior top department of second U type communicating pipe, and the umbrella type roof that is located on the cartridge filter can be dismantled to the second contradicts in the interior bottom department of first U type connecting pipe.

Preferably, the heat exchange tube assembly comprises a first heat exchange tube and a second heat exchange tube, the first heat exchange tube is wound on the outer side of the liquid inlet tube, the second heat exchange tube is wound on the outer side of the liquid outlet tube, one ends of the first heat exchange tube and the second heat exchange tube respectively penetrate through the first clamping arc-shaped plate and the second clamping arc-shaped plate, and the first heat exchange tube and the second heat exchange tube can be connected through a connecting tube.

Preferably, the first arc-shaped buffer plate component comprises a first outer sliding cylinder, a first inner sliding plate, a first side arc-shaped buffer plate and a third buffer spring, the first outer sliding cylinder is installed at the top and the bottom of the outer side of the first clamping arc-shaped plate, the third buffer spring is installed at the inner end part of the first outer sliding cylinder, the first inner sliding plate is installed at the outer end part of the third buffer spring, and the first inner sliding plate penetrates through the first outer sliding cylinder and is installed with the first side arc-shaped buffer plate.

Preferably, the second arc-shaped buffer plate assembly comprises a second buffer spring, a second inner sliding plate, a second outer sliding cylinder and a second side arc-shaped buffer plate, the second outer sliding cylinder is mounted at the top and the bottom of the outer side of the second clamping arc-shaped plate, the second buffer spring is mounted at the inner end of the second outer sliding cylinder, the second inner sliding plate is mounted at the outer end of the second buffer spring, the second inner sliding plate penetrates through the second outer sliding cylinder to be mounted on the second inner sliding plate, and the second side arc-shaped buffer plate is mounted at the other end of the second inner sliding plate.

Preferably, first motor support subassembly includes first U type grip slipper, first inner tube, first T type motor cabinet and first buffer spring, first U type grip slipper is installed through the screw rod in the outside bottom department of first centre gripping arc, first inner tube is installed in the bottom middle part department of first U type grip slipper, first buffer spring is installed in the interior top department of first inner tube, first T type motor cabinet is installed to first buffer spring's bottom.

Preferably, the second motor base assembly comprises a second U-shaped clamping base, a second inner tube, a second T-shaped motor base and a fourth buffer spring, the second U-shaped clamping base is installed at the bottom of the outer side of the second clamping arc plate through a screw rod, the second inner tube is installed at the middle of the bottom of the second U-shaped clamping base, the fourth buffer spring is installed at the top of the inner portion of the second inner tube, and the second T-shaped motor base is installed at the bottom of the fourth buffer spring.

Preferably, the anticorrosive coating has been paintd in the outside of first side arc buffer board, the tip of feed liquor pipe and the tip of drain pipe all set up the ring flange structure.

Preferably, the double-shell energy-saving pump further comprises a using method, and the using method comprises the following specific steps:

the method comprises the following steps: the first heat exchange tube is wound on the outer side of the liquid inlet tube, the second heat exchange tube is wound on the outer side of the liquid outlet tube, one end of the first heat exchange tube penetrates through the first clamping arc-shaped plate, and one end of the second heat exchange tube penetrates through the second clamping arc-shaped plate;

step two: two groups of first clamping arc-shaped plates are fixed on the outer side of the liquid inlet pipe through screws and clamp the first heat exchange pipe, and a second clamping arc-shaped plate is fixed on the outer side of the liquid outlet pipe through screws and clamp the second heat exchange pipe;

step three: when the equipment is impacted, the first inner sliding plate or the second inner sliding plate is compressed by contacting with the first side arc-shaped buffer plate or the second side arc-shaped buffer plate to adjust the third buffer spring or the second buffer spring to perform protection buffering and operation noise reduction;

step four: sleeving a first U-shaped clamping seat on the outer side of the first clamping arc-shaped plate and fixing a first T-shaped motor base on the bottom plate, sleeving a second U-shaped clamping seat on the outer side of the second clamping arc-shaped plate and fixing a second T-shaped motor base on the bottom plate;

step five: when the paddle is started to operate, liquid passes through the liquid inlet pipe, the second U-shaped communicating pipe, the first U-shaped connecting pipe and the liquid outlet pipe, and is buffered and denoised through the second inner cylinder, the second T-shaped motor base, the fourth buffer spring, the first inner cylinder, the first T-shaped motor base and the first buffer spring;

step six: when in operation, liquid passes through the first detachable filter cylinder and the second detachable filter cylinder, so that the liquid is filtered by the filter plates in the first detachable filter cylinder and the second detachable filter cylinder and then is led out;

step seven: when heat exchange is needed, cold water can exchange heat with liquid flowing in the liquid inlet pipe and the liquid outlet pipe through the first heat exchange pipe and the second heat exchange pipe.

The invention has the beneficial technical effects that:

the invention provides a high-sealing impact-resistant double-shell energy-saving pump, wherein a first heat exchange tube is wound on the outer side of a liquid inlet tube, a second heat exchange tube is wound on the outer side of a liquid outlet tube, one end of the first heat exchange tube penetrates through a first clamping arc-shaped plate, one end of the second heat exchange tube penetrates through a second clamping arc-shaped plate, two groups of first clamping arc-shaped plates are fixed on the outer side of the liquid inlet tube through screws and clamp the first heat exchange tube, the second clamping arc-shaped plate is fixed on the outer side of the liquid outlet tube through screws and clamp the second heat exchange tube, when equipment is impacted, a first inner sliding plate or a second inner sliding plate is compressed through contact with a first side arc-shaped buffer plate or a second side arc-shaped buffer plate to adjust a third buffer spring or a second buffer spring to perform protection, buffering and operation and noise reduction, a first U-shaped clamping seat is sleeved on the outer side of the first clamping arc-shaped plate and a first T-shaped motor seat is fixed on a bottom plate, the second U-shaped clamping seat is sleeved on the outer side of the second clamping arc-shaped plate and fixes the second T-shaped motor seat on the bottom plate, liquid passes through the liquid inlet pipe when the paddle is started to operate, the second U-shaped communicating pipe, the second inner cylinder when the first U-shaped connecting pipe and the liquid outlet pipe run, the second T-shaped motor seat, the fourth buffer spring and the first inner cylinder, the first T-shaped motor seat and the first buffer spring buffer and reduce noise, the liquid passes through the first detachable filter cylinder and the second detachable filter cylinder when the paddle runs, the liquid is filtered through the filter plates in the first detachable filter cylinder and the second detachable filter cylinder and then is led out, and when heat exchange is needed, cold water can be subjected to heat exchange with the liquid flowing in the liquid inlet pipe and the liquid outlet pipe through the first heat exchange pipe and the second heat exchange pipe.

Drawings

FIG. 1 is a schematic view of a first perspective view of an apparatus of a preferred embodiment of a high-sealing impact-resistant double-casing energy-saving pump according to the present invention;

FIG. 2 is a schematic perspective view of a second perspective view of an apparatus of a preferred embodiment of a high-sealing impact-resistant double-casing energy-saving pump according to the present invention;

FIG. 3 is a third perspective view of the apparatus of a preferred embodiment of a high seal impact resistant double hull energy efficient pump according to the present invention;

FIG. 4 is a fourth perspective view of the apparatus of a preferred embodiment of a high seal impact resistant double hull energy efficient pump according to the present invention;

FIG. 5 is a schematic perspective view of an outer baffle assembly of a preferred embodiment of a high seal impact resistant double hull economizer pump according to the present invention;

FIG. 6 is a first perspective view of the pump body structure of a preferred embodiment of the high-sealing impact-resistant double-casing energy-saving pump according to the present invention;

FIG. 7 is a second perspective view of the pump body structure of a preferred embodiment of a high-sealing impact-resistant dual-casing energy-saving pump according to the present invention;

FIG. 8 is a side cross-sectional view of the outer baffle assembly of a preferred embodiment of a high seal impact resistant double hull economized pump in accordance with the present invention;

FIG. 9 is a schematic structural view of a motor base of a preferred embodiment of a high-sealing impact-resistant double-shell energy-saving pump according to the present invention;

fig. 10 is a schematic view of a detachable filter cartridge assembly of a preferred embodiment of a high-sealing impact-resistant double-shell energy-saving pump according to the present invention.

In the figure: 1. a first side arc-shaped buffer plate; 2. a first outer sliding cylinder; 3. a first inner slide plate; 4. a first removable filter cartridge; 5. a first T-shaped motor base; 6. a first inner cylinder; 7. a first U-shaped clamping seat; 8. an umbrella-shaped top plate; 9. a liquid inlet pipe; 10. a first heat exchange tube; 11. a top plate; 12. a first U-shaped communicating pipe; 13. a second removable filter cartridge; 14. a filter plate; 15. a second side arc-shaped buffer plate; 16. a second clamping arc plate; 17. a second outer sliding barrel; 18. a second inner slide plate; 19. a second U-shaped clamping seat; 20. a second inner barrel; 21. a blade cover; 22. a second U-shaped communicating pipe; 23. a middle partition plate; 24. a driving device bin; 25. a second T-shaped motor base; 26. a liquid outlet pipe; 27. a second heat exchange tube; 28. a first buffer spring; 29. a paddle; 30. a second buffer spring; 31. a first clamping arc.

Detailed Description

In order to make the technical solutions of the present invention more clear and definite for those skilled in the art, the present invention is further described in detail below with reference to the examples and the accompanying drawings, but the embodiments of the present invention are not limited thereto.

As shown in fig. 1-10, the high-sealing and impact-resistant double-casing energy-saving pump provided in this embodiment includes a first U-shaped connecting pipe 12, a liquid guiding driving bin assembly is connected to the bottom of the first U-shaped connecting pipe 12, a second U-shaped communicating pipe 22 is connected to the bottom of the liquid guiding driving bin assembly, a first detachable filter cartridge 4 is connected to the bottom of the second U-shaped communicating pipe 22, a second detachable filter cartridge 13 is connected to the top of the first U-shaped connecting pipe 12, filter board assemblies are disposed inside the second detachable filter cartridge 13 and the first detachable filter cartridge 4, a liquid outlet pipe 26 is connected to the other end of the first U-shaped connecting pipe 12, a liquid inlet pipe 9 is connected to the other end of the second U-shaped communicating pipe 22, heat exchange pipe assemblies are wound around the outer sides of the liquid inlet pipe 9 and the liquid outlet pipe 26, a first clamping arc-shaped plate 31 and a second clamping arc-shaped plate 16 are respectively mounted on the outer sides of the liquid inlet pipe 9 and the liquid outlet pipe 26, first arc-shaped buffer plate component is installed in the outside of first centre gripping arc 31, and second arc-shaped buffer plate component is installed in the outside of second centre gripping arc 16, and first motor base subassembly is installed to the bottom of first centre gripping arc 31, and second motor base subassembly is installed to the bottom of second centre gripping arc 16.

The first heat exchange tube 10 is wound on the outer side of the liquid inlet tube 9, the second heat exchange tube 27 is wound on the outer side of the liquid outlet tube 26, one end of the first heat exchange tube 10 penetrates through the first clamping arc-shaped plate 31, one end of the second heat exchange tube 27 penetrates through the second clamping arc-shaped plate 16, two groups of first clamping arc-shaped plates 31 are fixed on the outer side of the liquid inlet tube 9 through screws and clamp the first heat exchange tube 10, the second clamping arc-shaped plate 16 is fixed on the outer side of the liquid outlet tube 26 through screws and clamp the second heat exchange tube 27, when the equipment is impacted, the first inner sliding plate 3 or the second inner sliding plate 18 is compressed through being in contact with the first side arc-shaped buffer plate 1 or the second side arc-shaped buffer plate 15 to adjust the third buffer spring or the second buffer spring 30 to perform protection buffering and operation noise reduction, the first U-shaped clamping seat 7 is sleeved on the outer side of the first clamping arc-shaped plate 31 and the first T-shaped motor seat 5 is fixed on the bottom plate, the second U-shaped clamping base 19 is sleeved on the outer side of the second clamping arc-shaped plate 16, the second T-shaped motor base 25 is fixed on the bottom plate, when the paddle 29 is started to operate to enable liquid to pass through the liquid inlet pipe 9, the second U-shaped communicating pipe 22, the first U-shaped connecting pipe 12 and the liquid outlet pipe 26, the buffering and noise reduction are carried out through the second inner cylinder 20, the second T-shaped motor base 25, the fourth buffer spring, the first inner cylinder 6, the first T-shaped motor base 5 and the first buffer spring 28, in operation, liquid passes through the first removable filter cartridge 4 and the second removable filter cartridge 13, the liquid is filtered by the filter plates 14 in the first removable filter cartridge 4 and the second removable filter cartridge 13 and then is led out, when heat exchange is required, cold water can exchange heat with the liquid flowing in the liquid inlet pipe 9 and the liquid outlet pipe 26 through the first heat exchange pipe 10 and the second heat exchange pipe 27.

In this embodiment, drain drive storehouse subassembly includes roof 11, blade cover 21 and paddle 29, and roof 11 is installed to the bottom of first U type connecting pipe 12, and blade cover 21 is installed to the bottom of roof 11, and the interior middle part department of blade cover 21 is equipped with paddle 29, and drive arrangement storehouse 24 is installed to the bottom of blade cover 21, and the inside in drive arrangement storehouse 24 is equipped with driving motor, and this driving motor runs through blade cover 21 and paddle 29's end middle part department fixed.

In this embodiment, the filter subassembly includes filter 14, median septum 23 and umbrella type roof 8, filter 14 is all installed at the inner bottom middle part that cartridge filter 13 can be dismantled with the second in the inner bottom middle part of first removable cartridge filter 4, median septum 23 is installed to the top department of filter 14, umbrella type roof 8 is installed at the top of median septum 23, the umbrella type roof 8 that is located on first removable cartridge filter 4 contradicts in the interior top department of second U type communicating pipe 22, the umbrella type roof 8 that is located on the second removable cartridge filter 13 contradicts in the interior bottom department of first U type connecting pipe 12.

In this embodiment, the heat exchange tube assembly comprises a first heat exchange tube 10 and a second heat exchange tube 27, the first heat exchange tube 10 is wound outside the liquid inlet tube 9, the second heat exchange tube 27 is wound outside the liquid outlet tube 26, one end of the first heat exchange tube 10 and one end of the second heat exchange tube 27 respectively penetrate through the first clamping arc 31 and the second clamping arc 16, and the first heat exchange tube 10 and the second heat exchange tube 27 can be connected through a connecting tube.

In this embodiment, the first arc-shaped buffer plate component includes a first outer sliding cylinder 2, a first inner sliding plate 3, a first side arc-shaped buffer plate 1 and a third buffer spring, the first outer sliding cylinder 2 is installed at the top and the bottom of the outer side of the first clamping arc-shaped plate 31, the third buffer spring is installed at the inner end of the first outer sliding cylinder 2, the first inner sliding plate 3 is installed at the outer end of the third buffer spring, and the first inner sliding plate 3 penetrates through the first outer sliding cylinder 2 and is installed with the first side arc-shaped buffer plate 1.

In this embodiment, the second arc-shaped buffer plate assembly includes a second buffer spring 30, a second inner sliding plate 18, a second outer sliding cylinder 17 and a second side arc-shaped buffer plate 15, the second outer sliding cylinder 17 is installed at the top and the bottom of the outer side of the second clamping arc-shaped plate 16, the second buffer spring 30 is installed at the inner end of the second outer sliding cylinder 17, the second inner sliding plate 18 is installed at the outer end of the second buffer spring 30, the second inner sliding plate 18 penetrates through the second outer sliding cylinder 17 to be installed with the second inner sliding plate 18, and the second side arc-shaped buffer plate 15 is installed at the other end of the second inner sliding plate 18.

In this embodiment, first motor holder subassembly includes first U type grip slipper 7, first inner tube 6, first T type motor cabinet 5 and first buffer spring 28, and first U type grip slipper 7 is installed through the screw rod in the outside bottom department of first centre gripping arc 31, and first inner tube 6 is installed in the bottom middle part department of first U type grip slipper 7, and first buffer spring 28 is installed in the interior top department of first inner tube 6, and first T type motor cabinet 5 is installed to the bottom of first buffer spring 28.

In this embodiment, the second motor base assembly includes second U-shaped holder 19, second inner tube 20, second T-shaped motor base 25 and fourth buffer spring, and second U-shaped holder 19 is installed through the screw rod in the outside bottom department of second centre gripping arc 16, and second inner tube 20 is installed in the bottom middle part department of second U-shaped holder 19, and fourth buffer spring is installed in the interior top department of second inner tube 20, and second T-shaped motor base 25 is installed to fourth buffer spring's bottom.

In this embodiment, the outer side of the first side arc-shaped buffer plate 1 is coated with an anti-corrosion coating, and the end portions of the liquid inlet pipe 9 and the liquid outlet pipe 26 are both provided with flange plate structures.

In this embodiment, the double-casing energy-saving pump further includes a use method, and the specific steps are as follows:

the method comprises the following steps: the first heat exchange tube 10 is wound on the outer side of the liquid inlet tube 9, the second heat exchange tube 27 is wound on the outer side of the liquid outlet tube 26, one end of the first heat exchange tube 10 penetrates through the first clamping arc-shaped plate 31, and one end of the second heat exchange tube 27 penetrates through the second clamping arc-shaped plate 16;

step two: two groups of first clamping arc-shaped plates 31 are fixed on the outer side of the liquid inlet pipe 9 through screws and clamp the first heat exchange pipe 10, and a second clamping arc-shaped plate 16 is fixed on the outer side of the liquid outlet pipe 26 through screws and clamp the second heat exchange pipe 27;

step three: when the equipment is impacted, the first inner sliding plate 3 or the second inner sliding plate 18 is compressed by contacting with the first side arc-shaped buffer plate 1 or the second side arc-shaped buffer plate 15 to adjust the third buffer spring or the second buffer spring 30 to perform protection buffer and operation noise reduction;

step four: sleeving a first U-shaped clamping seat 7 on the outer side of the first clamping arc-shaped plate 31, fixing a first T-shaped motor seat 5 on the bottom plate, sleeving a second U-shaped clamping seat 19 on the outer side of the second clamping arc-shaped plate 16, and fixing a second T-shaped motor seat 25 on the bottom plate;

step five: when the paddle 29 is started to operate to enable liquid to pass through the liquid inlet pipe 9, the second U-shaped communicating pipe 22, the first U-shaped connecting pipe 12 and the liquid outlet pipe 26, the buffering and noise reduction are carried out through the second inner cylinder 20, the second T-shaped motor base 25, the fourth buffer spring, the first inner cylinder 6, the first T-shaped motor base 5 and the first buffer spring 28;

step six: in operation, liquid passes through the first detachable filter cylinder 4 and the second detachable filter cylinder 13, so that the liquid is filtered by the filter plates 14 in the first detachable filter cylinder 4 and the second detachable filter cylinder 13 and then is led out;

step seven: when heat exchange is required, cold water can exchange heat with the liquid flowing in the liquid inlet pipe 9 and the liquid outlet pipe 26 through the first heat exchange pipe 10 and the second heat exchange pipe 27.

The above are only further embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can substitute or change the technical solution of the present invention and its idea within the scope of the present invention.

Claims (10)

1. The utility model provides a high sealed two shell energy-saving pump that shocks resistance which characterized in that: comprises a first U-shaped connecting pipe (12), the bottom of the first U-shaped connecting pipe (12) is communicated with a liquid guiding driving bin component, the bottom of the liquid guiding driving bin component is communicated with a second U-shaped communicating pipe (22), the bottom of the second U-shaped communicating pipe (22) is communicated with a first detachable filter cylinder (4), the top of the first U-shaped connecting pipe (12) is communicated with a second detachable filter cylinder (13), the insides of the second detachable filter cylinder (13) and the first detachable filter cylinder (4) are both provided with filter plate components, the other end of the first U-shaped connecting pipe (12) is communicated with a liquid outlet pipe (26), the other end of the second U-shaped communicating pipe (22) is communicated with a liquid inlet pipe (9), the outer sides of the liquid inlet pipe (9) and the liquid outlet pipe (26) are both wound with heat exchange pipe components, the outer sides of the liquid inlet pipe (9) and the liquid outlet pipe (26) are respectively provided with a first clamping arc plate (31) and a second clamping arc plate (16), first arc-shaped buffer plate component is installed in the outside of first centre gripping arc (31), second arc-shaped buffer plate component is installed in the outside of second centre gripping arc (16), first motor base component is installed to the bottom of first centre gripping arc (31), second motor base component is installed to the bottom of second centre gripping arc (16).

2. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 1, wherein: drain drive storehouse subassembly includes roof (11), paddle cover (21) and paddle (29), roof (11) are installed to the bottom of first U type connecting pipe (12), just paddle cover (21) are installed to the bottom of roof (11), the interior middle part department of paddle cover (21) is equipped with paddle (29), dirver storehouse (24) is installed to the bottom of paddle cover (21), just the inside in dirver storehouse (24) is equipped with driving motor, and this driving motor runs through paddle cover (21) and paddle (29) the end middle part department fixed.

3. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 2, wherein: the filter subassembly includes filter (14), median septum (23) and umbrella type roof (8), filter (14) are all installed at the inner bottom middle part that cartridge filter (13) can be dismantled with the second in the inner bottom middle part of first cartridge filter (4) of dismantling, median septum (23) are installed to the top department of filter (14), umbrella type roof (8) are installed at the top of median septum (23), and umbrella type roof (8) that are located on first cartridge filter (4) of dismantling contradict in the interior top department of second U type communicating pipe (22), and umbrella type roof (8) that are located on the second cartridge filter (13) of dismantling contradict in the interior bottom department of first U type connecting pipe (12).

4. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 3, wherein: the heat exchange tube assembly comprises a first heat exchange tube (10) and a second heat exchange tube (27), the outside of the liquid inlet tube (9) is wound with the first heat exchange tube (10), the outside of the liquid outlet tube (26) is wound with the second heat exchange tube (27), one end of the first heat exchange tube (10) and one end of the second heat exchange tube (27) respectively penetrate through the first clamping arc plate (31) and the second clamping arc plate (16), and the first heat exchange tube (10) and the second heat exchange tube (27) can be connected through a connecting tube.

5. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 4, wherein: the first arc-shaped buffer plate component comprises a first outer sliding cylinder (2), a first inner sliding plate (3), a first side arc-shaped buffer plate (1) and a third buffer spring, the first outer sliding cylinder (2) is installed at the top and the bottom of the outer side of the first clamping arc-shaped plate (31), the third buffer spring is installed at the inner end of the first outer sliding cylinder (2), the first inner sliding plate (3) is installed at the outer end of the third buffer spring, and the first side arc-shaped buffer plate (1) is installed by penetrating through the first outer sliding cylinder (2) by the first inner sliding plate (3).

6. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 5, characterized in that: the second arc-shaped buffer plate component comprises a second buffer spring (30), a second inner sliding plate (18), a second outer sliding cylinder (17) and a second side arc-shaped buffer plate (15), the second outer sliding cylinder (17) is arranged at the top and the bottom of the outer side of the second clamping arc-shaped plate (16), the second buffer spring (30) is arranged at the inner end of the second outer sliding cylinder (17), the second inner sliding plate (18) is arranged at the outer end of the second buffer spring (30), the second inner sliding plate (18) penetrates through the second outer sliding cylinder (17) to be arranged at the second inner sliding plate (18), and the second side arc-shaped buffer plate (15) is arranged at the other end of the second inner sliding plate (18).

7. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 6, wherein: first motor holder subassembly includes first U type grip slipper (7), first inner tube (6), first T type motor cabinet (5) and first buffer spring (28), first U type grip slipper (7) are installed through the screw rod in the outside bottom department of first centre gripping arc (31), first inner tube (6) are installed in the end middle part department of first U type grip slipper (7), first buffer spring (28) are installed in the interior top department of first inner tube (6), first T type motor cabinet (5) are installed to the bottom of first buffer spring (28).

8. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 7, wherein: the second motor support subassembly includes second U type grip slipper (19), second inner tube (20), second T type motor cabinet (25) and fourth buffer spring, second U type grip slipper (19) are installed through the screw rod in the outside bottom department of second centre gripping arc (16), second inner tube (20) are installed in the bottom middle part department of second U type grip slipper (19), the fourth buffer spring is installed in the interior top department of second inner tube (20), second T type motor cabinet (25) are installed to fourth buffer spring's bottom.

9. The high-sealing impact-resistant double-shell energy-saving pump according to claim 8, characterized in that: the outside of first side arc buffer board (1) is smeared with anticorrosive coating, the tip of feed liquor pipe (9) and the tip of drain pipe (26) all set up the ring flange structure.

10. The high-sealing impact-resistant double-shell energy-saving pump as claimed in claim 9, wherein: the double-shell energy-saving pump also comprises a using method, and the specific steps are as follows:

the method comprises the following steps: a first heat exchange tube (10) is wound on the outer side of the liquid inlet tube (9), a second heat exchange tube (27) is wound on the outer side of the liquid outlet tube (26), one end of the first heat exchange tube (10) penetrates through the first clamping arc-shaped plate (31), and one end of the second heat exchange tube (27) penetrates through the second clamping arc-shaped plate (16);

step two: two groups of first clamping arc-shaped plates (31) are fixed on the outer side of the liquid inlet pipe (9) through screws and clamp the first heat exchange pipe (10), and a second clamping arc-shaped plate (16) is fixed on the outer side of the liquid outlet pipe (26) through screws and clamp the second heat exchange pipe (27);

step three: when the equipment is impacted, the first side arc-shaped buffer plate (1) or the second side arc-shaped buffer plate (15) is contacted to compress the first inner sliding plate (3) or the second inner sliding plate (18) to adjust the third buffer spring or the second buffer spring (30) to carry out protection buffering and operation noise reduction;

step four: sleeving a first U-shaped clamping seat (7) on the outer side of the first clamping arc-shaped plate (31) and fixing a first T-shaped motor seat (5) on the bottom plate, sleeving a second U-shaped clamping seat (19) on the outer side of the second clamping arc-shaped plate (16) and fixing a second T-shaped motor seat (25) on the bottom plate;

step five: when the paddle (29) is started to operate and liquid passes through the liquid inlet pipe (9), the second U-shaped communicating pipe (22), the first U-shaped connecting pipe (12) and the liquid outlet pipe (26), buffering and noise reduction are carried out through the second inner cylinder (20), the second T-shaped motor base (25), the fourth buffer spring, the first inner cylinder (6), the first T-shaped motor base (5) and the first buffer spring (28);

step six: in operation, liquid passes through the first detachable filter cylinder (4) and the second detachable filter cylinder (13), and is filtered by the filter plates (14) in the first detachable filter cylinder (4) and the second detachable filter cylinder (13) and then is led out;

step seven: when heat exchange is needed, cold water can exchange heat with liquid flowing in the liquid inlet pipe (9) and the liquid outlet pipe (26) through the first heat exchange pipe (10) and the second heat exchange pipe (27).

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