CN113910076A

CN113910076A - Rotation type pipeline rust cleaning equipment that hydraulic engineering used

Info

Publication number: CN113910076A
Application number: CN202111186476.5A
Authority: CN
Inventors: 王勋江
Original assignee: Individual
Current assignee: Chunjing Construction Group Co ltd
Priority date: 2021-10-12
Filing date: 2021-10-12
Publication date: 2022-01-11
Anticipated expiration: 2041-10-12
Also published as: CN113910076B

Abstract

The invention discloses a rotary pipeline rust removing device for hydraulic engineering. The invention aims to provide a rotary pipeline rust removing device for hydraulic engineering, which can automatically rotate a pipeline to remove rust, automatically compress and fix the pipeline, automatically spray a rust remover on the pipeline and ensure that the pipeline can be sufficiently rust-removed. The technical scheme of the invention is that the rotary pipeline rust removing equipment for the hydraulic engineering comprises a base, wherein the upper part of the base is connected with a shell; one side of the lower part in the shell is connected with the supporting seat; the upper part of the supporting seat is rotatably connected with the rotating seat; the upper part of the rotating seat is connected with the fixed rod; the inside upside of casing is equipped with rust cleaning mechanism. The rotary pipeline rust removing equipment for the hydraulic engineering disclosed by the invention has the advantages that the pipeline is automatically rotated to complete rust removal, the pipeline is automatically pressed and fixed, and a rust remover is automatically sprayed onto the pipeline, so that the pipeline is sufficiently rust removed.

Description

Rotation type pipeline rust cleaning equipment that hydraulic engineering used

Technical Field

The invention relates to a rust removing device, in particular to a rotary pipeline rust removing device for hydraulic engineering.

Background

The hydraulic engineering refers to an engineering which is constructed for controlling and allocating surface water and underground water in the nature to achieve the purposes of removing harm and benefiting, when the hydraulic engineering is constructed, a pipeline is an indispensable material, however, the pipeline is rusted after being placed for a long time, and in order to reduce waste, the pipeline needs to be continuously used after being derusted.

The existing pipeline rust removing technology is basically that people hold a rust removing plate by hands, and the rust removing plate is used for wiping a pipeline to remove rust on the pipeline under the condition of stabilizing the pipeline.

Therefore, it is necessary to develop a rotary pipeline rust removal device for hydraulic engineering, which can automatically rotate a pipeline to remove rust, automatically compress the fixed pipeline, automatically spray a rust remover on the pipeline, and ensure sufficient rust removal for the pipeline.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the rotary pipeline rust removing equipment for the hydraulic engineering, which can automatically rotate a pipeline to complete rust removal, automatically compress and fix the pipeline, automatically spray a rust remover on the pipeline and ensure that the pipeline can be sufficiently rust removed.

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

in a first aspect, a rotary pipeline rust removing device for hydraulic engineering comprises: the upper part of the base is connected with a shell; one side of the lower part in the shell is connected with the supporting seat; the upper part of the supporting seat is rotatably connected with the rotating seat; the upper part of the rotating seat is connected with the fixed rod; the upper side in the shell is provided with a rust removing mechanism; a rotating mechanism is arranged between one side of the lower part in the shell and the lower side of the rotating seat.

Further, rust removing mechanism includes: the upper side and the lower side of the interior of the shell are symmetrically connected with sliding sleeves; the inner sides of the sliding sleeves are connected with the sliding rods in a sliding manner; the inner sides of the sliding rods on the two sides are connected with the derusting plate; the guide rails are connected between the outer sides of the sliding rods on the two sides; the compression springs are connected between the guide rails and the sliding sleeves and sleeved on the sliding rods; the electric push rod is arranged on one side of the upper part in the shell; the connecting rod, electric putter telescopic link upside are connected with the connecting rod, connecting rod and guide rail slidingtype cooperation.

Further, the rotary mechanism includes: the driving motor is arranged on one side of the lower part in the shell; a fixed seat is connected with one side of the lower part in the shell; one side of the fixed seat is rotatably connected with a rotating shaft, and the lower side of the rotating shaft is connected with an output shaft of the driving motor; the upper side of the rotating shaft and the lower side of the rotating seat are both connected with a driving wheel; the belt is connected between the driving wheels.

Further, still include clamping component, clamping component includes: the guide rod is connected with the upper side of the fixed rod; the outer sides of the guide rods are evenly connected with the clamping plates in a sliding mode at intervals; the tension springs are symmetrically connected between the clamping plate and the guide rod from top to bottom; the lower part of the guide rod is connected with a sliding sleeve in a sliding way; the connecting rods are rotatably connected between the outer sides of the sliding sleeves and the clamping plates.

Further, still including the linkage subassembly, the linkage subassembly includes: the middle of the lower part in the shell is rotatably connected with a screw; the lower part of the screw is connected with a threaded sleeve through threads; the upper part of the threaded sleeve is uniformly connected with four connecting shafts at intervals, the connecting shafts penetrate through the rotating seat, and the upper sides of the connecting shafts are connected with the sliding sleeve; the lower part of the screw is connected with a first gear; one side of the lower part in the shell is connected with a guide rod; the guide rod is connected with the bidirectional rack in a sliding manner; the middle of one side of the lower part in the shell is rotatably connected with the rotating rod; the two sides of the rotating rod are both connected with second gears, and the bidirectional rack is meshed with the first gear and the second gear on one side; and the rack rod is connected with the rack rod in a sliding manner on one side in the shell, the upper side of the rack rod is connected with the connecting rod, and the rack rod is meshed with the second gear on one side.

Further, still including storage component, storage component sets up between base and casing middle part one side.

Further, the magazine assembly includes: the connecting seat is connected between one sides of the middle parts of the bases; the supporting frame is connected between one side of the upper part of the connecting seat and one side of the middle part of the shell; the upper part of the support frame is connected with the mounting frame; the storage box is connected with the storage box on the inner side of the upper part of the mounting frame.

Further, still including spraying the subassembly, spraying the subassembly including: the spray heads are symmetrically connected with the two sides of the middle part in the shell from top to bottom; the two sides in the shell are both connected with the cylinder body in an up-down symmetrical manner; the inner sides of the cylinder bodies are connected with piston rods in a sliding manner; the return springs are connected between the piston rods and the cylinder body and sleeved on the piston rods; the outer sides of the piston rods are connected with contact rods, and the contact rods are matched with the guide rails; the water outlet pipes are connected between the cylinder body and the spray heads on the same side; the water pipe, all be connected with the inlet tube between cylinder body and the storage case.

The invention has the advantages that: (1) according to the invention, the connecting rod is driven to move downwards by the electric push rod telescopic rod, the guide rail, the slide rod and the rust removing plate are pushed to move inwards, so that the rust removing plate is attached to the pipeline, the driving motor is started to drive the rotating seat and the pipeline to rotate, and the effect of automatically rotating the pipeline to remove rust is achieved; (2) according to the invention, the connecting rod drives the rack rod to move downwards, and finally drives the screw rod to rotate, so that the threaded sleeve, the connecting shaft and the sliding sleeve are driven to move upwards, the clamping plate is driven to move outwards through the connecting rod, a pipeline is compressed and fixed, and the effect of automatically compressing and fixing the pipeline is achieved; (3) the guide rail moves inwards to push the contact rod and the piston rod to move inwards to push out the rust remover, the rust remover is sprayed out of the spray head to the pipeline, the guide rail moves outwards, the contact rod and the piston rod move outwards to reset, the rust remover is sucked into the cylinder body, the effect of automatically spraying the rust remover to the pipeline is achieved, and rust removal is fully performed on the pipeline.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is a schematic perspective view of a first rust removing mechanism of the present invention.

Fig. 5 is a schematic perspective view of a second rust removing mechanism of the present invention.

Fig. 6 is a schematic perspective view of the rotating mechanism of the present invention.

Fig. 7 is a schematic perspective view of a first clamping assembly according to the present invention.

Fig. 8 is a schematic perspective view of a second clamping assembly of the present invention.

Fig. 9 is a schematic view of a third perspective view of the clamping assembly of the present invention.

FIG. 10 is a first perspective view of the linkage assembly of the present invention.

FIG. 11 is a second perspective view of the linkage assembly of the present invention.

FIG. 12 is a schematic diagram of a third perspective structure of the linkage assembly of the present invention.

FIG. 13 is a schematic diagram of a fourth perspective structure of the linkage assembly of the present invention.

Fig. 14 is a schematic partial perspective view of a magazine assembly and a spray assembly according to the present invention.

Fig. 15 is a schematic perspective view of a first spray assembly of the present invention.

Fig. 16 is a schematic perspective view of a second spray assembly of the present invention.

Fig. 17 is a schematic view of a third perspective view of the spray assembly of the present invention.

The meaning of the reference symbols in the figures: 1. a base, 2, a shell, 3, a support seat, 4, a rotating seat, 5, a fixed rod, 6, a derusting mechanism, 61, a sliding sleeve, 62, a sliding rod, 63, a derusting plate, 64, a guide rail, 65, a compression spring, 66, a connecting rod, 67, an electric push rod, 7, a rotating mechanism, 71, a driving motor, 72, a fixed seat, 73, a rotating shaft, 74, a transmission wheel, 75, a belt, 8, a clamping component, 81, a guide rod, 82, a clamping plate, 83, a tension spring, 84, a sliding sleeve, 85, a connecting rod, 9, a linkage component, 91, a screw rod, 92, a threaded sleeve, 93, a connecting shaft, 94, a first gear, 95, a guide rod, 96, a bidirectional rack, 97, a rotating rod, 98, a second gear, 99, a rack rod, 10, a storage component, 101, a connecting seat, 102, a support frame, 103, a mounting frame, 104, a storage box, 11, a spraying component, 111, a spray head, 112, a cylinder body, 113. piston rod, 114, reset spring, 115, contact lever, 116, outlet pipe, 117, inlet tube.

Detailed Description

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

Example 1

As shown in fig. 1 to 6, the embodiment discloses a rotary pipeline rust removing device for hydraulic engineering, which comprises a base 1, a shell 2, a supporting seat 3, a rotating seat 4, a fixing rod 5, a rust removing mechanism 6 and a rotating mechanism 7, wherein the shell 2 is connected to the upper part of the base 1, the supporting seat 3 is connected to the right side of the inner lower part of the shell 2, the rotating seat 4 is connected to the upper part of the supporting seat 3 in a rotating manner, the fixing rod 5 is connected to the upper part of the rotating seat 4, the rust removing mechanism 6 is arranged on the upper side inside the shell 2, and the rotating mechanism 7 is arranged between the left side of the inner lower part of the shell 2 and the lower side of the rotating seat 4.

Derusting mechanism 6 is including sliding sleeve 61, slide bar 62, derusting board 63, guide rail 64, compression spring 65, connecting rod 66 and electric putter 67, the equal bilateral symmetry in both sides has sliding sleeve 61 about casing 2 is inside, the equal slidingtype connection of sliding sleeve 61 inboard has slide bar 62, all be connected with derusting board 63 between the slide bar 62 inboard of the left and right sides, all be connected with guide rail 64 between the slide bar 62 outside of the left and right sides, all be connected with compression spring 65 between guide rail 64 and the sliding sleeve 61, compression spring 65 overlaps on slide bar 62, electric putter 67 is installed to the upper portion rear side in the casing 2, electric putter 67 telescopic link upside is connected with connecting rod 66, connecting rod 66 and the slidingtype cooperation of guide rail 64.

The rotating mechanism 7 comprises a driving motor 71, a fixed seat 72, a rotating shaft 73, a driving wheel 74 and a belt 75, the driving motor 71 is installed on the left side of the inner lower portion of the shell 2, the fixed seat 72 is connected to the left side of the inner lower portion of the shell 2, the rotating shaft 73 is rotatably connected to the right side of the fixed seat 72, the lower side of the rotating shaft 73 is connected with an output shaft of the driving motor 71, the driving wheels 74 are connected to the upper side of the rotating shaft 73 and the lower side of the rotating seat 4, and the belt 75 is connected between the driving wheels 74.

When a user needs to remove rust from a pipeline, the pipeline is placed on the rotating seat 4 from top to bottom, the electric push rod 67 is started, the telescopic rod of the electric push rod 67 moves downwards to drive the connecting rod 66 to move downwards, the push guide rail 64 moves inwards to drive the sliding rod 62 and the rust removing plate 63 to move inwards, the compression spring 65 is compressed to enable the rust removing plate 63 to clamp and cling to the pipeline, the driving motor 71 is started to drive the rotating shaft 73 to rotate to drive the driving wheel 74 and the belt 75 to rotate, so that the rotating seat 4 and the pipeline are driven to rotate, iron rust on the outer wall of the pipeline is removed under the action of the rust removing plate 63, after the pipeline is completely removed, the driving motor 71 is closed, the rotating seat 4 and the pipeline stop rotating, the electric push rod 67 is started again, the telescopic rod of the electric push rod 67 moves upwards to drive the connecting rod 66 to move upwards, the guide rail 64 is pushed to move outwards to drive the sliding rod 62 and the rust removing plate 63 to move outwards, the compression spring 65 stretches back, the rust removing plate 63 is far away from the pipeline and returns to the original state, the electric push rod 67 is closed, the rust removing plate 63 stops moving, the pipeline can be taken down, and the operation is repeated in this way, so that the effect of automatically rotating the pipeline to remove rust is achieved.

Example 2

As shown in fig. 1 to 3 and 7 to 17, in some embodiments, the clamping assembly 8 further includes a guide rod 81, a clamping plate 82, an extension spring 83, a sliding sleeve 84 and a connecting rod 85, the guide rod 81 is connected to the upper side of the fixing rod 5, the clamping plate 82 is slidably connected to the outer side of the guide rod 81 at an even interval, the extension spring 83 is vertically symmetrically connected between the clamping plate 82 and the guide rod 81, the sliding sleeve 84 is slidably connected to the lower portion of the guide rod 81, and the connecting rod 85 is rotatably connected between the outer side of the sliding sleeve 84 and the clamping plate 82.

The device also comprises a linkage assembly 9, wherein the linkage assembly 9 comprises a screw 91, a threaded sleeve 92, a connecting shaft 93, a first gear 94, a guide rod 95, a bidirectional rack 96, a rotating rod 97, a second gear 98 and a rack rod 99, the screw 91 is rotatably connected in the middle of the lower part in the shell 2, the lower part of the screw 91 is connected with the threaded sleeve 92 through threads, the upper part of the threaded sleeve 92 is uniformly connected with four connecting shafts 93 at intervals, the connecting shafts 93 penetrate through the rotating seat 4, the upper sides of the connecting shafts 93 are connected with the sliding sleeve 84, the lower part of the screw 91 is connected with the first gear 94, the left rear side of the lower part in the shell 2 is connected with the guide rod 95, the guide rod 95 is slidably connected with the bidirectional rack 96, the rotating rod 97 is rotatably connected in the middle of the rear side of the lower part in the shell 2, the front and rear sides of the rotating rod 97 are connected with the second gears 98, and the bidirectional rack 96 is meshed with the first gear 94 and the second gear 98 on the front side, a rack bar 99 is slidably connected to the left side of the rear portion in the housing 2, the upper side of the rack bar 99 is connected to the connecting rod 66, and the rack bar 99 and the rear second gear 98 are engaged with each other.

When the connecting rod 66 moves downwards, the rack rod 99 is driven to move downwards, the second gear 98 and the rotating rod 97 are driven to rotate, the bidirectional rack 96 is driven to move rightwards, the first gear 94 and the screw rod 91 are driven to rotate, the threaded sleeve 92 is driven to move upwards, the connecting shaft 93 and the sliding sleeve 84 are driven to move upwards, the clamping plate 82 is driven to move outwards through the connecting rod 85, the stretching spring 83 is stretched, the clamping plate 82 is pressed and fixed on the pipeline, after the pipeline is derusted, the connecting rod 66 moves upwards, the rack rod 99 is driven to move upwards, the second gear 98 and the rotating rod 97 are driven to rotate reversely, the bidirectional rack 96 is driven to move leftwards, the first gear 94 and the screw rod 91 are driven to rotate reversely, the threaded sleeve 92 is driven to move downwards, the connecting shaft 93 and the sliding sleeve 84 are driven to move downwards, the clamping plate 82 is driven to move inwards to be away from the pipeline through the connecting rod 85, the extension spring 83 retracts, the pipeline can be taken down after the clamping plate 82 loosens the pipeline, and the reciprocating operation is carried out, so that the effect of automatically compressing and fixing the pipeline is achieved.

Still including storage assembly 10, storage assembly 10 is connected with connecting seat 101 between the base 1 middle part rear side including connecting seat 101, support frame 102, mounting bracket 103 and storage case 104, and connecting seat 101 is connected with between connecting seat 101 upper portion rear side and the 2 middle part rear sides of casing, and support frame 102 upper portion is connected with mounting bracket 103, and mounting bracket 103 upper portion inboard is connected with storage case 104.

Still including spraying subassembly 11, spraying subassembly 11 is including shower nozzle 111, cylinder body 112, piston rod 113, reset spring 114, contact bar 115, outlet pipe 116 and inlet tube 117, the equal longitudinal symmetry in middle part left and right sides has shower nozzle 111 in the casing 2, the equal longitudinal symmetry in left and right sides has cylinder body 112 in the casing 2, the equal sliding connection in cylinder body 112 inboard has piston rod 113, all be connected with reset spring 114 between piston rod 113 and the cylinder body 112, reset spring 114 overlaps on piston rod 113, the piston rod 113 outside all is connected with contact bar 115, contact bar 115 and guide rail 64 mutually support, all be connected with outlet pipe 116 between cylinder body 112 and the homonymy shower nozzle 111, all be connected with inlet tube 117 between cylinder body 112 and the storage case 104.

A large amount of rust remover is injected into the storage box 104, when the guide rail 64 moves inwards, the push contact rod 115 moves inwards to drive the piston rod 113 to move inwards, the reset spring 114 is compressed, then the guide rail 64 moves outwards to be far away from the contact rod 115, under the action of the reset spring 114, the piston rod 113 and the contact rod 115 are pushed outwards to suck the rust remover in the storage box 104 into the cylinder through the water inlet pipe 117, and after the guide rail 64 pushes the contact rod 115 and the piston rod 113 to move inwards next time, the rust remover is pushed out and flows into the spray head 111 through the water outlet pipe 116 and is sprayed on the outer wall of the pipeline through the spray head 111, so that the rust removing plate 63 is helped to better remove iron rust of the pipeline, and the reciprocating is achieved, the effect of automatically spraying the rust remover onto the pipeline is achieved, and the rust removal is fully performed on the pipeline.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. The utility model provides a rotation type pipeline rust cleaning equipment that hydraulic engineering used, characterized by: comprises the following steps: the upper part of the base (1) is connected with a shell (2); one side of the lower part in the shell (2) is connected with the supporting seat (3); the upper part of the supporting seat (3) is rotatably connected with the rotating seat (4); the upper part of the rotating seat (4) is connected with the fixed rod (5); the upper side in the shell (2) is provided with a rust removing mechanism (6); a rotating mechanism (7), and the rotating mechanism (7) is arranged between one side of the lower part in the shell (2) and the lower side of the rotating seat (4).

2. A rotary pipe rust removing apparatus for hydraulic engineering as claimed in claim 1, wherein: the rust removing mechanism (6) comprises: the upper side and the lower side of the interior of the shell (2) are symmetrically connected with the sliding sleeves (61); the sliding rods (62) are connected to the inner sides of the sliding sleeves (61) in a sliding manner; the inner sides of the sliding rods (62) on the two sides of the rust removing plate (63) are connected with the rust removing plate (63); the guide rail (64) is connected between the outer sides of the sliding rods (62) on the two sides; the compression springs (65) are connected between the guide rail (64) and the sliding sleeve (61), and the compression springs (65) are sleeved on the sliding rod (62); the electric push rod (67) is arranged on one side of the upper part in the shell (2); connecting rod (66), electric putter (67) telescopic link upside are connected with connecting rod (66), and connecting rod (66) and guide rail (64) sliding type fit.

3. A rotary pipe rust removing apparatus for hydraulic engineering as claimed in claim 2, wherein: the rotating mechanism (7) comprises: the driving motor (71), one side of the lower part in the shell (2) is provided with the driving motor (71); a fixed seat (72) is connected with one side of the lower part in the shell (2); the rotating shaft (73) is rotatably connected to one side of the fixed seat (72), and the lower side of the rotating shaft (73) is connected with an output shaft of the driving motor (71); the upper side of the rotating shaft (73) and the lower side of the rotating seat (4) are connected with a driving wheel (74); the belt (75) is connected between the belt (75) and the transmission wheel (74).

4. A rotary pipe rust removing apparatus for hydraulic engineering as claimed in claim 3, wherein: still including clamping component (8), clamping component (8) including: the upper side of the fixed rod (5) is connected with a guide rod (81); the clamping plates (82) are connected to the outer sides of the guide rods (81) at intervals in a sliding mode; the extension springs (83) are symmetrically connected between the clamping plate (82) and the guide rod (81) from top to bottom; the lower part of the guide rod (81) is connected with a sliding sleeve (84) in a sliding way; the connecting rods (85) are rotatably connected between the outer sides of the connecting rods (85) and the sliding sleeve (84) and the clamping plate (82).

5. A rotary pipe rust cleaning apparatus for hydraulic engineering as claimed in claim 4, wherein: still including linkage assembly (9), linkage assembly (9) including: the middle of the lower part in the shell (2) is rotatably connected with a screw (91); the lower part of the screw rod (91) is connected with the threaded sleeve (92) through threads; the upper part of the threaded sleeve (92) is uniformly connected with four connecting shafts (93) at intervals, the connecting shafts (93) penetrate through the rotating seat (4), and the upper sides of the connecting shafts (93) are connected with the sliding sleeve (84); the lower part of the screw (91) is connected with a first gear (94); a guide rod (95), wherein one side of the inner lower part of the shell (2) is connected with the guide rod (95); the guide rod (95) is connected with the bidirectional rack (96) in a sliding manner; a rotating rod (97) is rotatably connected to the middle of one side of the lower part in the shell (2); the two sides of the rotating rod (97) are both connected with second gears (98), and the bidirectional rack (96) is meshed with the first gear (94) and the second gear (98) on one side; the rack rod (99) is connected with the rack rod (99) on one side in the shell (2) in a sliding mode, the upper side of the rack rod (99) is connected with the connecting rod (66), and the rack rod (99) is meshed with the second gear (98) on one side.

6. A rotary pipe rust cleaning apparatus for hydraulic engineering as claimed in claim 5, wherein: still including storage component (10), storage component (10) set up between base (1) and casing (2) middle part one side.

7. A rotary pipe rust cleaning apparatus for hydraulic engineering as claimed in claim 6, wherein: the magazine assembly (10) comprises: the connecting seat (101) is connected between one sides of the middle parts of the bases (1); the supporting frame (102) is connected between one side of the upper part of the connecting seat (101) and one side of the middle part of the shell (2); the upper part of the support frame (102) is connected with the mounting frame (103); the storage box (104) is connected with the storage box (104) on the inner side of the upper part of the mounting rack (103).

8. A rotary pipe rust removing apparatus for hydraulic engineering as claimed in claim 7, wherein: still including spraying subassembly (11), spraying subassembly (11) including: the spray nozzles (111) are symmetrically connected to the upper and lower sides of the middle part in the shell (2); the cylinder body (112) is connected to the two sides in the shell (2) in an up-down symmetrical manner; the inner sides of the cylinder bodies (112) are all connected with the piston rods (113) in a sliding manner; the return spring (114) is connected between the piston rod (113) and the cylinder body (112), and the return spring (114) is sleeved on the piston rod (113); the outer sides of the piston rods (113) are connected with contact rods (115), and the contact rods (115) are matched with the guide rails (64); the water outlet pipes (116) are connected between the cylinder body (112) and the spray head (111) on the same side; the water pipe (117), the cylinder body (112) and the storage box (104) are connected with a water inlet pipe (117).