CN212494410U - Full-automatic integrated gas cylinder cleaning and inversion discharge device and system - Google Patents

Abstract

The application provides a full-automatic integrated gas cylinder washs and inverts discharging equipment and system. The full-automatic integrated gas cylinder cleaning and inverting discharge device comprises a base support and a rotary support; the base support comprises a base pillar, a rotating motor and two motor frame bodies, and the base pillar comprises a fixed base and a telescopic assembly; the rotating bracket comprises a rotating frame body, a clamping assembly, a valve rotating assembly and two rotating shafts, wherein the rotating frame body is positioned between the two motor frame bodies; the clamping assembly comprises a plurality of groups of clamping pieces, each group of clamping pieces comprises two clamping piece units which are oppositely arranged, and one end of each clamping piece unit is connected with the rotating frame body; the valve rotating assembly is connected with the motor frame body. Through the gas cylinder of two relative holders centre gripping gas cylinders that set up, the gas cylinder valve is turned round to the valve rotating assembly, and the rotating electrical machines rotates rotatory framework for the gas cylinder upset is convenient for discharge residual gas and impurity in a plurality of gas cylinders, later can also be through the rotating electrical machines upset for the original position, has improved the cleaning efficiency to the gas cylinder.

Description

Full-automatic integrated gas cylinder cleaning and inversion discharge device and system

Technical Field

The utility model relates to a gas cylinder washs technical field, especially relates to a full-automatic integrated gas cylinder washs and inverts discharging equipment and system.

Background

Along with the increase of chemical gas use amount, more and more kinds of gas cylinders are used for storing different gases, and for the use of gas cylinder, the tradition is through the gaseous circulation of the on-off control of valve.

However, gas in the gas cylinder still can remain some gas after using to exhaust, impurity such as water stain and granule rust slag, before the gas cylinder adorns gas again, need clear up the gas cylinder, in order to get rid of above-mentioned gas, impurity such as water stain and granule rust slag, traditional mode is to invert the gas cylinder through the manpower and discharges the clearance, and the gas cylinder is mostly the steel material, weight is great, overturn through the manpower, not only the degree of difficulty is great, moreover, can only overturn one by one, cleaning efficiency is lower, can not keep up with the increasing demand volume of using the gas cylinder.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, provide a discharge means and system are invertd in washing of full-automatic integrated gas cylinder of solving above-mentioned technical problem.

The purpose of the utility model is realized through the following technical scheme:

a full-automatic integrated gas cylinder washs and inverts eduction gear, includes: base support and runing rest. The base support comprises a base pillar, a rotating motor and two motor frames, wherein the motor frames are connected with one end of the base pillar, the rotating motor is arranged in the motor frames, the base pillar comprises a fixed base and a telescopic assembly, one end of the telescopic assembly is connected with the fixed base, and the other end of the telescopic assembly is connected with the motor frames; the rotating bracket comprises a rotating frame body, a clamping assembly, a valve rotating assembly and two rotating shafts, the rotating frame body is of a hollow structure and is positioned between the two motor frame bodies, and two ends of the rotating frame body are respectively in rotating connection with the rotating motor through one rotating shaft; the clamping assembly comprises a plurality of groups of clamping pieces, each group of clamping pieces comprises two clamping piece units which are oppositely arranged, one end of each clamping piece unit is connected with the rotating frame body, and the two clamping piece units which are oppositely arranged are used for clamping the gas cylinder; the valve rotating assembly is connected with the motor frame body and close to the clamping assembly, and the valve rotating assembly is used for rotating a valve of the gas cylinder.

In one embodiment, a rotating hole is formed in one surface of the motor frame body, which is close to the rotating frame body, the rotating shaft penetrates through the rotating hole, one end of the rotating shaft is connected with the rotating frame body, and the other end of the rotating shaft is connected with the rotating motor.

In one embodiment, the clamping member unit comprises a driving part and a clamping part, the driving part is connected with the rotating frame, and the telescopic end of the driving part is connected with the clamping part.

In one embodiment, the clamping portions are provided with clamping grooves, and the opening directions of the clamping grooves of the two oppositely-arranged clamping portions are oppositely arranged.

In one embodiment, the rotating bracket further includes a supporting plate, the supporting plate is connected to the rotating frame, and the driving part is connected to one surface of the supporting plate.

In one embodiment, the motor frame body is provided with a mounting opening, and the rotating motor is arranged in the motor frame body through the mounting opening.

In one embodiment, the base bracket further comprises a buffer assembly, the buffer assembly is arranged between the motor frame and the rotating frame, one surface of the buffer assembly is abutted against the motor frame, and the other surface of the buffer assembly is abutted against the rotating frame.

In one embodiment, the buffer assembly comprises a buffer plate and a buffer pad, one surface of the buffer plate is abutted with the rotating frame body, and the other surface of the buffer plate is abutted with the motor frame body through the buffer pad.

In one embodiment, the fully-automatic integrated gas cylinder cleaning and inverted discharging device further comprises two parallel conveying belts, the conveying belts are arranged on one side of the rotating frame body close to the base support, the conveying belts are arranged opposite to the valve rotating assemblies, and a lifting gap is formed between the two conveying belts.

A full-automatic integrated gas cylinder cleaning inverted discharge system, comprising: the full-automatic integrated gas cylinder cleaning inverted discharging device comprises a protection device and the full-automatic integrated gas cylinder cleaning inverted discharging device according to any one embodiment; the protection device comprises a protection support, a protection box and a touch panel, the full-automatic integrated gas cylinder cleaning and inversion discharge device is contained in the protection box, the protection box is arranged in the protection support, the touch panel is connected with the outer surface of the protection box, and the touch panel is further electrically connected with the rotating motor.

Compared with the prior art, the utility model discloses at least, following advantage has:

through the gas cylinder of two relative holder unit centre gripping gas cylinders that set up, the gas cylinder valve is turned round to the valve rotating assembly, and the rotating electrical machines rotates rotatory framework for the gas cylinder upset is convenient for discharge residual gas and impurity in a plurality of gas cylinders simultaneously, later can also overturn for the original position through the rotating electrical machines, has improved the cleaning efficiency to the gas cylinder, thereby improves the abluent automation performance of gas cylinder, is convenient for carry out full self-cleaning to the gas cylinder.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic diagram of a fully automated integrated cylinder cleaning inverted drain apparatus in one embodiment;

FIG. 2 is a schematic view from another perspective of the fully automated integrated cylinder purging inverted drain shown in FIG. 1;

FIG. 3 is a schematic view of yet another perspective of the fully automated integrated cylinder purging inverted drain shown in FIG. 1;

FIG. 4 is a schematic view of yet another perspective of the fully automated integrated cylinder purging inverted drain shown in FIG. 1;

FIG. 5 is a schematic view of an embodiment of an oil cleaning assembly;

fig. 6 is an enlarged schematic view at a1 of the oil cleaning assembly shown in fig. 5.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The utility model relates to a full-automatic integrated gas cylinder washs and inverts discharging equipment. In one embodiment, the fully automatic integrated cylinder cleaning inverted discharge device comprises a base bracket and a rotating bracket. The base support comprises a base pillar, a rotating motor and two motor frame bodies. The motor frame with the one end of base pillar is connected, the rotating electrical machines set up in the motor frame. The base pillar comprises a fixed base and a telescopic assembly. One end of the telescopic assembly is connected with the fixed base, and the other end of the telescopic assembly is connected with the motor frame body. The rotating support comprises a rotating frame body, a clamping assembly, a valve rotating assembly and two rotating shafts. The rotating frame body is provided with a hollow structure. The rotating frame bodies are positioned between the two motor frame bodies, and two ends of each rotating frame body are respectively connected with the rotating motor in a rotating mode through the rotating shaft. The clamping assembly comprises a plurality of groups of clamping pieces, and each group of clamping pieces comprises two clamping piece units which are oppositely arranged. One end of each clamping piece unit is connected with the rotating frame body. The two oppositely arranged clamping piece units are used for clamping the gas cylinder. The valve rotating assembly is connected with the motor frame body and is close to the clamping assembly. The valve rotating assembly is used for rotating a valve of the gas cylinder. Through the gas cylinder of two relative holder unit centre gripping gas cylinders that set up, the gas cylinder valve is turned round to the valve rotating assembly, and the rotating electrical machines rotates rotatory framework for the gas cylinder upset is convenient for discharge residual gas and impurity in a plurality of gas cylinders, later can also be through the rotating electrical machines upset for the original position, has improved the cleaning efficiency to the gas cylinder, thereby improves the abluent automation performance of gas cylinder, is convenient for carry out full self-cleaning to the gas cylinder.

Please refer to fig. 1, which is a schematic perspective view of an inverted discharging device for cleaning a fully-automatic integrated gas cylinder according to an embodiment of the present invention.

The fully automated integrated cylinder purging inverted drain apparatus 10 of an embodiment includes a base frame 100 and a swivel frame 200 of the fully automated integrated cylinder purging inverted drain apparatus 10. The base bracket 100 includes a base support 110, a rotating motor 120, and two motor frames 130. The motor frame 130 is connected to one end of the base support column 110, and the rotating motor 120 is disposed in the motor frame 130. The base support 110 includes a stationary base 112 and a telescoping assembly 114. One end of the telescopic assembly 114 is connected to the fixed base 112, and the other end of the telescopic assembly 114 is connected to the motor frame 130. The rotating bracket 200 includes a rotating frame 210, a clamping assembly 220, a valve rotating assembly 230, and two rotating shafts 240. The rotating frame 210 has a hollow structure. The rotating frame 210 is located between the two motor frames 130, and two ends of the rotating frame 210 are respectively rotatably connected to the rotating motor 120 through the rotating shaft 240. The clamping assembly 220 includes a plurality of sets of clamping members, each set of clamping members including two clamping member units 222 disposed opposite to each other. One end of each of the clamping member units 222 is connected to the rotating frame 210. The two clamp units 222 arranged oppositely are used for clamping the gas cylinder. The valve rotating assembly 230 is connected to the motor frame 130, and the valve rotating assembly 230 is disposed near the clamping assembly 220. The valve rotating assembly 230 is used to rotate the valve of the gas cylinder. In one embodiment, each set of the clamping members is two clamping member units 222 arranged oppositely, that is, the two clamping member units 222 together form one set of the clamping members, that is, each set of the clamping members is formed by two clamping members 222.

Through the gas cylinder of two relative holder units 222 centre gripping of setting, the gas cylinder valve is turned round to valve rotating assembly 230, rotating electrical machines 120 rotates rotatory framework 210 for the gas cylinder upset is convenient for discharge the residual gas and the impurity in a plurality of gas cylinders simultaneously, later can also be through the upset of rotating electrical machines 120 for the home position, has improved the cleaning efficiency to the gas cylinder, thereby improve the abluent automation performance of gas cylinder, be convenient for carry out full self-cleaning to the gas cylinder.

In one embodiment, referring to fig. 1, a rotating hole 132 is formed on a surface of the motor frame 130 close to the rotating frame 210, the rotating shaft 240 is inserted into the rotating hole 132, one end of the rotating shaft 240 is connected to the rotating frame 210, and the other end of the rotating shaft 240 is connected to the rotating motor 120. In this embodiment, the rotation hole 132 is used for the rotation shaft 240 to be disposed, so that the rotation shaft 240 rotates in the rotation hole 132, and the rotation motor 120 rotates the rotation frame 210 through the rotation shaft 240, thereby facilitating the control of the rotation frame 210.

In one embodiment, referring to fig. 1 to 3, each of the clamping unit 222 includes a driving portion 224 and a clamping portion 226, the driving portion 224 is connected to the rotating frame 210, and the telescopic end of the driving portion 224 is connected to the clamping portion 226. In this embodiment, the driving unit 224 is disposed on the rotating housing 210, and the driving unit 224 rotates along with the rotation of the rotating housing 210. The clamping portion 226 protrudes from the rotating frame 210, the clamping portion 226 protrudes toward the inside of the rotating frame 210, a gap is formed between the clamping portions 226 of the clamping member units 222, the gap is used for the gas cylinder to enter and exit, the gas cylinder is clamped by the two clamping portions 226, and therefore the gas cylinder is fixed between the two clamping portions 226. Like this, because the drive division 224 with clamping part 226 is connected, the drive division 224 along with rotatory framework 210 rotates, after two clamping part 226 that set up relatively held the gas cylinder, rotatory framework 210 upset drives the gas cylinder upset to be convenient for invert the gas cylinder, and then be convenient for invert the clearance to a plurality of gas cylinders, improved the cleaning efficiency to the gas cylinder.

Furthermore, the clamping portions 226 are provided with clamping grooves 2262, and the opening directions of the clamping grooves 2262 of the two clamping portions 226 which are oppositely arranged are opposite to each other. Because most of gas cylinders are cylindrical structures, namely the surface of the gas cylinder is a curved surface, namely the surface of the gas cylinder is a plane with radian. The middle of the clamp groove 2262 is concave, and the opening directions of the two clamp grooves 2262 which are oppositely arranged are opposite, so that the clamping portion 226 generates at least two acting forces on the gas cylinder, wherein two of the acting forces are oppositely arranged. Also, the clamp groove 2262 accommodates a portion of the gas cylinder. In this way, the clamping portion 226 clamps the gas cylinder, and generates opposite acting forces in two perpendicular directions, so that the clamping force applied to the gas cylinder is increased, the stability of clamping the gas cylinder by the clamping member units 222 is improved, and the probability of the gas cylinder escaping from between the two clamping member units 222 arranged oppositely due to the curved surface structure of the gas cylinder is reduced.

Further, the rotating bracket 200 further includes a supporting plate 250, the supporting plate 250 is connected to the rotating frame 210, and the driving part 224 is connected to one surface of the supporting plate 250. Since the clamp unit 222 is required to clamp the gas cylinder, which is heavy in weight, the weight is greatest when the gas cylinder is initially cleaned by inversion, and then is reduced as it is inverted. However, even if impurities such as residual gas, water stains, and granular rust in the gas cylinder are cleaned, the gas cylinder is heavy. The supporting plate 250 is used for supporting the driving portion 224, that is, the supporting plate 250 is used for supporting the clamping unit 222, so that when the clamping unit 222 clamps the gas cylinder, the supporting plate 250 provides a supporting force in a direction opposite to the gravity of the gas cylinder for the clamping unit 222, the probability that the clamping unit 222 presses and deforms the rotating frame 210 when clamping the gas cylinder is reduced, and the mechanical strength of the rotating frame 210 is improved.

In one embodiment, referring to fig. 1, the motor frame 130 is provided with a mounting opening 134, and the rotating electrical machine 120 is disposed in the motor frame 130 through the mounting opening 134. In this embodiment, the mounting opening 134 is opened at least one of a side edge and an end portion of the motor housing 130, and the mounting opening 134 is not provided at a position close to the rotating housing 210, that is, the mounting opening 134 may be opened at a position other than a position close to the rotating housing 210. The mounting opening 134 is used for mounting the rotating electrical machine 120 in the motor frame 130, so that the rotating electrical machine 120 can conveniently enter and exit the motor frame 130, and the rotating electrical machine 120 can be conveniently mounted and dismounted.

In one embodiment, referring to fig. 1 and fig. 2, the base bracket 100 further includes a buffer assembly 140, the buffer assembly 140 is disposed between the motor frame 130 and the rotating frame 210, one surface of the buffer assembly 140 abuts against the motor frame 130, and the other surface of the buffer assembly 140 abuts against the rotating frame 210. In this embodiment, the buffer assembly 140 is located between the motor housing 130 and the rotating housing 210, and the buffer assembly 140 serves as a buffer between the motor housing 130 and the rotating housing 210. Since the torque generated by the rotating frame 210 acts on the rotating shaft 240 during the rotation of the rotating frame 210, the distance between the motor frame 130 and the rotating frame 210 is reduced, and since the rotating speed of the rotating frame 210 is high, if the motor frame 130 and the rotating frame 210 are too small during the rotation of the rotating frame 210, the motor frame 130 and the rotating frame 210 may collide with each other, and the motor frame 130 and the rotating frame 210 may be damaged. In order to reduce the collision probability between the motor frame 130 and the rotating frame 210, the buffer assembly 140 is adopted to separate the motor frame 130 from the rotating frame 210, so as to protect the motor frame 130 and the rotating frame 210, prolong the service life of the motor frame 130 and the rotating frame 210, and further prolong the service life of the fully-automatic integrated gas cylinder cleaning inverted discharge device.

Further, the buffer assembly 140 includes a buffer plate 142 and a buffer pad 144, one surface of the buffer plate 142 abuts against the rotating frame 210, and the other surface of the buffer plate 142 abuts against the motor frame 130 through the buffer pad 144. The buffer plate 142 is in surface contact with the rotating frame 210, that is, the buffer plate 142 is in contact with a side surface of the rotating frame 210, that is, the buffer plate 142 is in surface-to-surface contact with the rotating frame 210, so that a contact area between the buffer plate 142 and the rotating frame 210 is increased. Thus, when the rotating frame 210 rotates, the rotating impact force generated by the rotating frame 210 is dispersed by the buffer plate 142, so that the compression pressure between the rotating frame 210 and the buffer plate 142 is reduced, and the possibility of damage to the rotating frame 210 is further reduced.

In addition, the buffer pads 144 and the buffer plates 142 are self-restoring buffer structures, and after being pressed by the outside, the self-restoring force is automatically generated, so that when the rotating frame 210 is shifted with respect to the base bracket 100, the buffer pads 144 and the buffer plates 142 push the rotating frame 210 to a home position.

In one embodiment, referring to fig. 1, the fully automatic integrated gas cylinder cleaning inverted discharging apparatus 10 further includes two parallel conveyer belts 300, the conveyer belts 300 are disposed on one side of the rotating frame 210 close to the base pillar 110, the conveyer belts 300 are disposed opposite to the valve rotating assembly 230, and a lifting gap is formed between the two conveyer belts 300. In this embodiment, the number of the base support columns 110 is four, that is, two base support columns 110 are disposed oppositely, the conveyer belt 300 is located between the two base support columns 110, and the conveyer belt 300 corresponds to the rotating frame 210, that is, the conveyer belt 300 is located below the rotating frame 210, so that the conveyer belt 300 can convey the gas cylinder to the lower side of the rotating frame 210, and the gas cylinder can be clamped by the clamping unit 222. Moreover, after the gas cylinder is cleaned, the conveying belt 300 sends the gas cylinder out of the full-automatic integrated gas cylinder cleaning inverted discharge device 10, so that full automation of cleaning and transportation of the gas cylinder is realized.

Further, the fully-automatic integrated gas cylinder cleaning and inverting discharging device 10 further includes a lifter 400, the lifter 400 is disposed on a side of the conveying belt 300 away from the rotating frame 210, a telescopic end of the lifter 400 moves in the lifting gap, and the telescopic end of the lifter 400 moves from a start end to an end of the lifter, so that the gas cylinder moves between the conveying belt 300 and the rotating frame 210. Thus, the gas cylinder is fed into the rotating frame 210 by the lift 400 for upside down cleaning, and after the cleaning is completed, the lift 400 removes the gas cylinder from the rotating frame 210.

Furthermore, the full-automatic integrated gas cylinder cleaning and inverting discharge device further comprises a material arranging device, wherein the material arranging device is arranged on the conveying belt and is arranged at a position close to the starting end of the conveying belt. The material arranging device is used for adjusting the positions of the plurality of gas cylinders on the conveying belt, so that the plurality of gas cylinders are arranged in order, the plurality of gas cylinders are aligned with the clamping unit in the subsequent cleaning process, and the cleaning efficiency of the gas cylinders is improved.

In one embodiment, referring to fig. 1, the base support 110 includes a fixed base 112 and a telescopic assembly 114, one end of the telescopic assembly 114 is connected to the fixed base 112, and the other end of the telescopic assembly 114 is connected to the motor frame 130. In this embodiment, the base support 110 remains horizontally stable when the fully automated integrated cylinder cleaning inverted drain is placed on a flat ground surface. However, when the floor on which the fully automatic integrated cylinder cleaning inverted discharge device is placed is uneven, the clamping assembly 220 cannot clamp all cylinders. To reduce the entrapment rate of holding a gas cylinder over uneven ground, the telescoping assembly 114 is mounted on the stationary base 112. The number of the fixed bases 112 is four, that is, the fixed bases 112 are four supporting legs of the fully automatic integrated gas cylinder cleaning inverted discharge device, and the telescopic assembly 114 moves telescopically on the fixed bases 112, so that the distance between the motor frame 130 and the fixed bases 112 is variable, and the distance between the rotating frame 210 and the ground is variable. Moreover, according to the sunken situation of the ground, the telescopic heights of the telescopic assemblies 114 on the four fixed bases 112 are adjusted, so that the rotating frame 210 is kept to be horizontally arranged, the rotating frame 210 is kept parallel to the conveying belt 300, and all the gas cylinders are conveniently grabbed.

Further, in order to facilitate grasping the valves of all the gas cylinders, the valve rotating assembly 230 includes an opening valve rod 232, a valve opening clamping jaw 234, a valve opening motor 236 and a valve opening rotating shaft 238, both ends of the opening valve rod 232 are respectively connected to the rotating frame 210, the opening valve rod 232 has an arc-shaped bent structure, the valve opening rotating shaft 238 is connected to the middle portion of the opening valve rod 232, one end of the valve opening motor 236 is rotatably connected to the rotating shaft 240, and the other end of the valve opening motor 236 is connected to the valve opening clamping jaw 234. The valve-opening motor 236 controls the rotation of the valve-opening clamping jaw 234, so that the valve of the gas cylinder is twisted at the valve-opening clamping jaw 234. The valve-opening motor 236 rotates about the valve-opening rotating shaft 238 so that the angle between the valve-opening clamping jaw 234 and the holder unit 222 is variable, and various other inclination angles are available in addition to the case where the valve-opening clamping jaw 234 is perpendicular to the holder unit 222. Thus, when the ground on which the fully-automatic integrated gas cylinder cleaning inverted discharge device is placed is uneven, the valve-opening clamping jaw 234 rotates through the valve-opening rotating shaft 238, so that the obliquely-placed gas cylinder is clamped by the valve-opening clamping jaw 234, the angle for the valve of the gas cylinder to be grabbed by the valve-opening clamping jaw 234 is larger, and the valve-opening clamping jaw 234 is convenient to grab all the gas cylinder valves.

Further, the valve rotating assembly 230 further includes a valve opening extension rod 231, one end of the valve opening extension rod 231 is connected to the valve opening rotating shaft 238, and the other end of the valve opening extension rod 231 is connected to the valve opening motor 236. In this embodiment, the telescopic valve-opening lever 231 has a telescopic function for adjusting the distance between the valve-opening motor 236 and the valve-opening rotating shaft 238, thereby facilitating adjustment of the distance between the valve-opening clamping jaw 234 and the valve-opening stem 232, and further facilitating adjustment of the distance between the valve-opening clamping jaw 234 and the rotating frame 210. Thus, when the full-automatic integrated gas cylinder cleaning inverted discharge device is placed on an uneven ground, the distance between the gas cylinder and the valve opening clamping jaw 234 is different, and the valve opening telescopic rod 231 enables the distance between the valve opening clamping jaw 234 and the valve of the gas cylinder to be adjustable through the self telescopic performance, so that the valve opening clamping jaw 234 can conveniently grab the valve of the gas cylinder, and the gas cylinder cleaning efficiency is improved.

Still further, the valve-opening jaw is a three-jaw clamp, i.e. the valve-opening jaw has three different jaw structures. The outer side surface of the valve of the gas cylinder is a continuous concave-convex curved surface, namely the surface of the valve-opening clamping jaw, which is contacted with the outer side surface of the valve of the gas cylinder, is a continuous concave-convex curved surface, so that the valve can be conveniently and well grasped, but the outer side surface of the valve of the gas cylinder is a continuous curved surface, namely a circular ring surface, and the valve-opening clamping jaw can slip when being grasped, namely the valve-opening clamping jaw slides on the valve of the gas cylinder relative to the valve of the gas cylinder, so that the valve of the gas cylinder cannot be opened, and the inside of the gas cylinder cannot be cleaned. Moreover, greasy dirt substances, including dust, rust or various types of grease, may adhere to the surface of the valve of the gas cylinder during daily use, so that the valve of the gas cylinder cannot be unscrewed by the valve-opening clamping jaw.

In order to reduce the probability of skidding of the valve opening clamping jaw when grabbing the gas cylinder, please refer to fig. 1 and 5 together, the fully-automatic integrated gas cylinder cleaning inverted discharging device 10 further comprises an oil stain cleaning assembly 500, the oil stain cleaning assembly 500 comprises a cleaning agent spray ring 510, a fixing rod 520, a liquid conveying pipe 530 and a pressure pump 540, the cleaning agent spray ring 510 surrounds the valve opening clamping jaw 234, one end of the fixing rod 520 is connected with the valve opening motor 236, the other end of the fixing rod 520 is connected with the cleaning agent spray ring 510, the liquid conveying pipe 530 is communicated with the inside of the cleaning agent spray ring 510, and one end of the liquid conveying pipe 530, which is far away from the cleaning agent spray ring 510, is connected with the pressure pump 540. The pressure pump 540 is used for pushing the cleaning agent into the infusion tube 530 in a pressurized manner, and the infusion tube 530 guides the cleaning agent to the cleaning agent spray ring 510. Liquid outlet 514 has been seted up to the one side that cleaner spray ring 510 is close to open valve clamping jaw 234 before open valve clamping jaw 234 snatchs the valve of gas cylinder, the valve of cleaner spout to the gas cylinder is spouted to the cleaner in the cleaner spray ring 510. The valve of gas cylinder is washd to the cleaner for greasy dirt material on the valve of gas cylinder is dissolved by the cleaner, and breaks away from the valve, has reduced the attached to of greasy dirt material on the valve of gas cylinder, thereby has reduced the probability of skidding of open valve clamping jaw 234 when snatching the valve of gas cylinder. And, under the pressurization of the pressurization pump 540, the cleaning agent in a high-pressure state cleans the valve of the gas cylinder, so that the cleaning agent washes away oil stain substances on the valve of the gas cylinder at a high pressure, and the slip probability of the valve-opening clamping jaw 234 when grabbing the valve of the gas cylinder is further reduced.

Further, the cleaning agent spray ring 510 includes two opposite spray ring halves 512, two spray ring halves 512 are close to the valve opening clamping jaw 234, and one side of spray ring halves 512 close to the valve opening clamping jaw 234 is parallel to the surface of the valve opening motor 236. Each of the spray ring halves 512 is correspondingly connected with a fixing rod 520, that is, each of the spray ring halves 512 is connected with the valve opening motor 236 through one of the fixing rods 520. The two opposite spray-washing half rings 512 surround the valve-opening clamping jaws 234, so that the valve of the gas cylinder is cleaned in multiple directions by using a cleaning agent, oil stain on the valve of the gas cylinder is further removed, and the slip probability of the valve-opening clamping jaws 234 when the valve of the gas cylinder is grabbed is reduced.

Further, please refer to fig. 1, fig. 5 and fig. 6 together, the oil cleaning assembly 500 further includes a spray guide plate 550, the spray guide plate 550 is accommodated in the liquid outlet hole 514, one end of the spray guide plate 550 is rotatably connected to the sidewall of the liquid outlet hole 514, and the other end of the spray guide plate 550 protrudes from the cleaning agent spray ring 510 and is close to the valve opening clamping jaw 234. The spray rinsing guide plate 550 is located in the liquid outlet hole 514, and the spray rinsing guide plate 550 is used for adjusting the spraying direction of the cleaning agent in the cleaning agent spray rinsing ring 510. Spray rinsing guide plate 550 with go out the lateral wall rotation of liquid hole 514 and connect, make spray rinsing guide plate 550 with there is inclination in the lateral wall of liquid hole 514, thereby makes spray rinsing guide plate 550 changes the play liquid direction of cleaner spray rinsing ring 510, and then makes cleaner spray rinsing ring 510 washs the valve of gas cylinder multi-angle ground, further with the greasy dirt material sanitization on the valve of gas cylinder, is convenient for open the valve of valve clamping jaw 234 stable centre gripping gas cylinder, further reduce the probability of skidding of opening valve clamping jaw 234 when snatching the valve of gas cylinder.

The utility model also provides a full-automatic integrated gas cylinder cleaning and inversion discharge system, which comprises a protective device and the full-automatic integrated gas cylinder cleaning and inversion discharge device of any one of the above embodiments; the protection device comprises a protection support, a protection box and a touch panel, the full-automatic integrated gas cylinder cleaning and inversion discharge device is contained in the protection box, the protection box is arranged in the protection support, the touch panel is connected with the outer surface of the protection box, and the touch panel is further electrically connected with the rotating motor. The full-automatic integrated gas cylinder cleaning and inverting discharge device comprises a base support and a rotary support. The base support comprises a base pillar, a rotating motor and two motor frame bodies. The motor frame with the one end of base pillar is connected, the rotating electrical machines set up in the motor frame. The base pillar comprises a fixed base and a telescopic assembly. One end of the telescopic assembly is connected with the fixed base, and the other end of the telescopic assembly is connected with the motor frame body. The rotating support comprises a rotating frame body, a clamping assembly, a valve rotating assembly and two rotating shafts. The rotating frame body is provided with a hollow structure. The rotating frame bodies are positioned between the two motor frame bodies, and two ends of each rotating frame body are respectively connected with the rotating motor in a rotating mode through the rotating shaft. The clamping assembly comprises a plurality of groups of clamping pieces, and each group of clamping pieces comprises two clamping piece units which are oppositely arranged. One end of each clamping piece unit is connected with the rotating frame body. The two oppositely arranged clamping piece units are used for clamping the gas cylinder. The valve rotating assembly is connected with the motor frame body and is close to the clamping assembly. The valve rotating assembly is used for rotating a valve of the gas cylinder. Through the gas cylinder of two relative holder unit centre gripping gas cylinders that set up, the gas cylinder valve is turned round to the valve rotating assembly, and the rotating electrical machines rotates rotatory framework for the gas cylinder upset is convenient for discharge the residual gas and the impurity in a plurality of gas cylinders simultaneously, later can also overturn for the original position through the rotating electrical machines, has improved the cleaning efficiency to the gas cylinder.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides a full-automatic integrated gas cylinder washs and inverts discharging equipment which characterized in that includes:

the base support comprises a base pillar, a rotating motor and two motor frames, wherein the motor frames are connected with one end of the base pillar, the rotating motor is arranged in the motor frames, the base pillar comprises a fixed base and a telescopic assembly, one end of the telescopic assembly is connected with the fixed base, and the other end of the telescopic assembly is connected with the motor frames;

the rotary support comprises a rotary frame body, a clamping assembly, a valve rotary assembly and two rotating shafts, the rotary frame body is of a hollow structure and is positioned between the two motor frame bodies, and two ends of the rotary frame body are respectively in rotary connection with the rotary motor through one rotating shaft; the clamping assembly comprises a plurality of groups of clamping pieces, each group of clamping pieces comprises two clamping piece units which are oppositely arranged, one end of each clamping piece unit is connected with the rotating frame body, and the two clamping piece units which are oppositely arranged are used for clamping the gas cylinder; the valve rotating assembly is connected with the motor frame body and close to the clamping assembly, and the valve rotating assembly is used for rotating a valve of the gas cylinder.

2. The full-automatic integrated gas cylinder cleaning and inverted discharging device according to claim 1, wherein a rotary hole is formed in one surface of the motor frame body, which is close to the rotary frame body, the rotary shaft penetrates through the rotary hole, one end of the rotary shaft is connected with the rotary frame body, and the other end of the rotary shaft is connected with the rotary motor.

3. The fully automatic integrated gas cylinder cleaning inverted discharge device according to claim 1, wherein each of the clamp units comprises a driving portion and a clamping portion, the driving portion is connected with the rotating frame, and a telescopic end of the driving portion is connected with the clamping portion.

4. The full-automatic integrated gas cylinder cleaning and inverted discharging device according to claim 3, wherein the clamping portions are provided with clamping grooves, and the opening directions of the clamping grooves of the two oppositely-arranged clamping portions are oppositely arranged.

5. The fully automatic integrated gas cylinder cleaning inverted discharging device according to claim 3, wherein the rotating bracket further comprises a support plate, the support plate is connected with the rotating frame, and the driving part is connected with one surface of the support plate.

6. The full-automatic integrated gas cylinder cleaning and inverted discharging device according to claim 1, wherein a mounting opening is formed in the motor frame body, and the rotating motor is arranged in the motor frame body through the mounting opening.

7. The full-automatic integrated gas cylinder cleaning and inverted discharging device according to claim 1, wherein the base support further comprises a buffer assembly, the buffer assembly is arranged between the motor frame and the rotating frame, one surface of the buffer assembly abuts against the motor frame, and the other surface of the buffer assembly abuts against the rotating frame.

8. The fully automated integrated gas cylinder purging inverted drain device according to claim 7, wherein the buffer assembly comprises a buffer plate and a buffer pad, one side of the buffer plate abuts the rotating frame, and the other side of the buffer plate abuts the motor frame through the buffer pad.

9. The full-automatic integrated gas cylinder cleaning and inverting discharging device according to claim 1, further comprising two parallel conveyer belts, wherein the conveyer belts are disposed on one side of the rotating frame body close to the base pillar, and the conveyer belts are disposed opposite to the valve rotating assembly, and a lifting gap is formed between the two conveyer belts.

10. The utility model provides a full-automatic integrated gas cylinder washs inversion discharge system which characterized in that includes: a guard and fully automated integrated cylinder cleaning inverted drain apparatus as claimed in any one of claims 1 to 9; the protection device comprises a protection support, a protection box and a touch panel, the full-automatic integrated gas cylinder cleaning and inversion discharge device is contained in the protection box, the protection box is arranged in the protection support, the touch panel is connected with the outer surface of the protection box, and the touch panel is further electrically connected with the rotating motor.

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