CN217918824U - A mark device is pasted in gas detection that is used for reverse osmosis membrane element next processing - Google Patents

Abstract

The application provides a subsides mark device is examined to gas for reverse osmosis membrane element next processing, include along X to the gas detection mechanism that sets up, labeller constructs and horizontal transfer subassembly, the gas detection mechanism has gas detection centre of grip, gas detection mechanism and vacuum pump connection, labeller constructs including pasting mark centre gripping subassembly, paste the mark subassembly, it has a mark centre gripping to paste the mark centre gripping subassembly, horizontal transfer subassembly is along X to setting up in gas detection centre gripping center and mark centre gripping below, horizontal transfer subassembly is along X to the reverse osmosis membrane element conveying that mechanism department was examined to gas to pasting mark centre gripping subassembly, paste mark subassembly cooperation displacement in order to accomplish the mark, this application need not manual operation, can automize the gas detection of accomplishing reverse osmosis membrane element's back pass and paste mark work, have and reduce the cost of labor, improve advantages such as machining efficiency and quality.

Description

A mark device is pasted in gas detection that is used for reverse osmosis membrane element next processing

Technical Field

The application relates to the technical field of water filtration, in particular to a gas detection labeling device for subsequent processing of reverse osmosis membrane elements.

Background

Along with the improvement of the water quality requirement of drinking water, a pure water system gradually enters a drinking water system of every family. The water purifier in the existing market generally adopts a reverse osmosis membrane element, the reverse osmosis membrane element can filter impurities such as organic matters, colloid, bacteria, viruses and the like in raw water, and particularly has extremely high filtering efficiency on impurities such as inorganic salt, heavy metal ions and the like.

The reverse osmosis membrane element forms the finished product after production, the producer need carry out the gas tightness detection of back pass to the reverse osmosis membrane element of oneself producing, and then judge that the membrane element is the yields or the defective products, back pass process flow is for cutting edge the filter core, seal cover O type circle, and move the gas and examine and determine whether gas leakage and leakage, present filter core side cut mode is mostly through the manual filter core of taking on cutting on the machine, cover O type circle is also through manual direct lasso, the inspection of soaking behind the compressed air, directly let in compressed air promptly in ultrafiltration water purifier, then soak ultrafiltration water purifier wholly in the aquatic, whether the observation can leak gas and produce the bubble in the aquatic, then weather the water on the ultrafiltration water purifier.

In this way, the manual operation efficiency is low, and the processing cost of the filter element is improved. Moreover, the manufacturing cost is high due to large requirements on manpower and working hours, whether air leakage or water leakage exists needs to be judged by visual inspection of people, and human factors have great influence on the inspection result.

Disclosure of Invention

The utility model provides a target device is pasted in gas detection for reverse osmosis membrane element processing of following times to remedy above-mentioned prior art's defect, realize need not manual operation, automatic directly to accomplish whole actions.

The embodiment of the application can be realized by the following technical scheme:

the utility model provides a gas detection labeling device for reverse osmosis membrane element next processing, is fixed in on the installation base, gas detection labeling device includes along X to gas detection mechanism, labeller structure and the horizontal transfer subassembly that sets up, gas detection mechanism has gas detection centre of grip, gas detection mechanism and vacuum pump connection, labeller structure is including pasting a mark centre gripping subassembly, pasting the mark subassembly, paste mark centre gripping subassembly and have a mark centre gripping center, horizontal transfer subassembly along X to set up in gas detection centre gripping center with paste mark centre gripping below, horizontal transfer subassembly along X to incite somebody to action gas detection mechanism department's reverse osmosis membrane element conveys to paste mark centre gripping subassembly, paste mark centre gripping subassembly paste mark subassembly cooperation displacement in order to accomplish and paste the mark.

Further, the mechanism is examined to gas includes third mount table, fourth apex portion and fifth apex portion, third mount table fixed connection in on the installation base, fourth apex portion with fifth apex portion along Y to sliding connection in on the mesa of third mount table makes fourth apex portion with form gas detection centre of holding between the fifth apex portion, fourth apex portion with fifth apex portion is along Y to sliding displacement.

Furthermore, the transverse transfer assembly comprises a transfer sliding plate and a material receiving table, the transfer sliding plate is arranged below the gas detection clamping center and the labeling clamping center along the X direction, and the material receiving table is connected to the upper part of the transfer sliding plate in a sliding manner along the X direction;

the bottom of the transfer sliding plate is connected with the air cylinder, and under the driving action of the air cylinder, the transfer sliding plate moves up and down along the Z-axis direction, so that the material receiving table is driven to move up and down.

Furthermore, the transverse transfer component further comprises two material receiving frames, the two material receiving frames are respectively arranged at two ends of the material receiving table, the two material receiving frames are oppositely arranged along the Y direction, a clamping opening is formed in the top of each material receiving frame, and the material receiving frames slide along the Y direction of the material receiving table.

Furthermore, the labeling and clamping assembly comprises a sixth pointed end portion, a seventh pointed end portion and a displacement plate assembly, the sixth pointed end portion and the seventh pointed end portion are oppositely arranged on the displacement plate assembly along the Y direction, so that a labeling and clamping center is formed between the sixth pointed end portion and the seventh pointed end portion of the labeling and clamping assembly, the sixth pointed end portion and the seventh pointed end portion are respectively connected onto the displacement plate assembly in a sliding mode along the Y direction, and the displacement plate assembly drives the sixth pointed end portion and the seventh pointed end portion to synchronously displace along the Z direction.

Further, displacement board subassembly through connection in the top and bottom of installation base, the displacement board subassembly is "concave" word form, the displacement board subassembly includes first displacement board and second displacement board, the both sides of first displacement board with the both sides sliding connection of second displacement board, second displacement board fixed connection in the bottom of installation base, first displacement board with second displacement board middle part is through the lead screw and the bearing frame threaded connection who mutually supports, realizes first displacement board for installation base is along Z to the displacement.

Further, labeller still includes the side position mounting bracket, side position mounting bracket fixed connection in on the installation base, paste mark subassembly sliding connection in side position mounting bracket one side and top, paste the mark subassembly and follow the Y of side position mounting bracket is to, Z displacement, paste the mark subassembly with paste mark centre gripping subassembly and cooperate the completion and paste the mark action.

Further, paste the mark subassembly and still include label blowing axle, rolling unit subassembly, moulding unit subassembly, third moulding running roller and the driven running roller of a plurality of that the height straggly set up, label blowing axle rolling unit subassembly set up respectively in top position installation department both sides, moulding unit subassembly the third moulding running roller is located paste the mark subassembly bottom, the third moulding running roller with moulding unit subassembly cooperatees and forms and presses a central subassembly, press a central subassembly with paste a mark centre gripping center is corresponding, press a central subassembly with paste a mark centre gripping subassembly and cooperate.

Furthermore, the moulding unit component comprises a first moulding roller, a second moulding roller and a moulding plate, wherein the first moulding roller and the second moulding roller are arranged in a staggered manner, and the moulding plate is positioned between the first moulding roller and the second moulding roller and faces the third moulding roller.

Furthermore, the winding unit assembly is connected with the motor through a belt and comprises a first material receiving driving shaft and two second material receiving driving shafts which are in staggered pressing, the two second material receiving driving shafts are respectively connected with the first material receiving driving shaft and the motor, and the first material receiving driving shaft is connected with the motor.

The air detection labeling device for the next processing of the reverse osmosis membrane element provided by the embodiment of the application at least has the following beneficial effects:

this application need not manual operation, can automize and directly accomplish the gas detection of reverse osmosis membrane element back pass and paste mark work, has avoided the manual operation in-process because the error that the manual work caused has improved work efficiency, and the industry integrated level is high, has and reduces the cost of labor, improves advantages such as machining efficiency and quality.

Drawings

FIG. 1 is a schematic view of the overall structure of an air-detecting and labeling apparatus for the subsequent processing of reverse osmosis membrane elements according to the present application;

fig. 2 is a schematic structural view of a labeling clamping assembly in the present application;

fig. 3 is a schematic structural view of the labeling assembly and the side mounting frame in the present application.

Reference numerals in the figures

6-a gas detection mechanism; 60-a third mounting table, 61-a fourth apex portion; 62-a fifth apex portion; 63-transferring the sliding plate; 64-a receiving table; 65-material receiving frame;

7-a labeling mechanism; 71-sixth apex portion; 72-seventh apex portion; 73-a first displacement plate; 74-a second displacement plate; a 75-side position mounting bracket; 751-side mounting a fixing plate; 76-a labelling assembly; 760-side position mounting part; 761-label discharge shaft; 762-a first material receiving driving shaft; 763 secondary collecting driving shaft; 764-a driven roller; 765-first pressure rubber roller; 766-second glue pressing roller; 767 top mounting part; 768-a caulk plate; 769 third glue roller;

9-mounting a base.

Detailed Description

Hereinafter, the present application will be further described based on preferred embodiments with reference to the accompanying drawings.

In addition, for convenience of understanding, various components on the drawings are enlarged (thick) or reduced (thin), but this is not intended to limit the scope of the present application.

Singular references also include plural references and vice versa.

In the description of the embodiments of the present application, it should be noted that if the terms "upper", "lower", "inner", "outer", etc. are used for indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings or the orientation or positional relationship which is usually arranged when the products of the embodiments of the present application are used, the description is only for convenience and simplicity, but the indication or suggestion that the referred device or element must have a specific orientation, be constructed in a specific orientation and be operated, and thus, the application cannot be construed as being limited. Moreover, the terms first, second, etc. may be used in the description to distinguish between different elements, but these should not be limited by the order of manufacture or by importance to be understood as indicating or implying any particular importance, and their names may differ from their names in the detailed description of the application and the claims.

The terminology used in the description presented herein is for the purpose of describing embodiments of the application and is not intended to be limiting of the application. It is also to be understood that, unless otherwise expressly stated or limited, the terms "disposed," "connected," and "connected" are intended to be open-ended, i.e., may be fixedly connected, detachably connected, or integrally connected; they may be mechanically coupled, directly coupled, indirectly coupled through intervening media, or may be interconnected between two elements. The specific meaning of the above terms in the present application will be specifically understood by those skilled in the art.

In the present application, the directions of the upper, lower, left and right sides are based on the angles shown in the corresponding drawings, and for convenience of description, the spatial position directions of the air detection labeling device for the next processing of the reverse osmosis membrane element in the present application are set as X, Y and Z directions for description, please refer to fig. 1.

Figure 1 is this application a gas detection labeling device overall structure schematic diagram for reverse osmosis membrane element next time processing, as shown in figure 1, a gas detection labeling device for reverse osmosis membrane element next time processing is fixed in on the installation base 9, gas detection labeling device includes along X to gas detection mechanism 6, labeling mechanism 7 and the horizontal transfer subassembly that sets up, gas detection mechanism 6 has gas detection centre gripping, gas detection mechanism 6 and vacuum pump connection for reverse osmosis membrane element to the centre gripping carries out the gas tightness and detects, labeling mechanism 7 is including pasting a mark centre gripping subassembly, side position mounting bracket 75 and pasting mark subassembly 76, paste mark centre gripping subassembly and have a mark centre gripping center for carry out the subsides mark work to gas detection qualified reverse osmosis membrane element, horizontal transfer subassembly along X to set up in gas detection centre gripping with paste mark centre gripping below, horizontal transfer subassembly is along X to conveying to paste the mark element, be used for with gas detection qualified reverse osmosis membrane element from gas detection mechanism 6 shifts to paste mark centre gripping subassembly department, the centre gripping subassembly reverse osmosis membrane subassembly (76) cooperation displacement is in order to accomplish the mark centre gripping subassembly department.

Specifically, the air detection mechanism 6 includes a third mounting platform 60, a fourth apex portion 61 and a fifth apex portion 62, the third mounting platform 60 is fixedly connected to the mounting base 9, a table top of the third mounting platform 60 has a certain distance with respect to a mounting surface of the mounting base 9, the fourth apex portion 61 and the fifth apex portion 62 are oppositely arranged on the table top of the third mounting platform 60 along the Y direction, so that an air detection clamping center is formed between the fourth apex portion 61 and the fifth apex portion 62, and the fourth apex portion 61 and the fifth apex portion 62 can be slidably displaced along the Y direction to be respectively inserted into two ends of a central tube of a reverse osmosis membrane element, so as to clamp the reverse osmosis membrane element.

The fifth apex portion 62 is connected with the cylinder, the fifth apex portion 62 towards the fourth apex portion 61 displacement under the drive effect of cylinder, correspondingly, the fourth apex portion 61 is connected with cylinder vacuum pump, under the cylinder effect of cylinder vacuum pump, the fourth apex portion 61 towards the fifth apex portion 62 displacement that slides, until the fourth apex portion 61 with the fifth apex portion 62 cooperate and insert respectively to the center tube both ends of reverse osmosis membrane element, under the effect of vacuum pump, the fourth apex portion 61 carries out evacuation, pressurize to reverse osmosis membrane element, whether can maintain in certain extent through measuring this reverse osmosis membrane element negative pressure value in certain time, and then judges the gas tightness of this reverse osmosis membrane element.

Transversely shift the subassembly including shifting slide 63, connecing material platform 64, shift slide 63 along X to set up in gas detection centre of gripping the below at subsides mark centre of gripping, connect material platform 64 along X to sliding connection in shift slide 63 upper portion, shift slide 63 is inside hollow bilayer structure, the hollow layer of shifting slide 63 is provided with the lead screw, connect material platform 64 with shift slide 63 realizes along X to the slip displacement through the lead screw and the bearing frame of mutually supporting, shift slide 63's lead screw by motor drive, under the drive effect of motor, shift slide 63 drives connect material platform 64 to shift along the X of lead screw to, after the gas detection of reverse osmosis's membrane element detects qualifiedly, connect material platform 64 will the reverse osmosis membrane element that the subassembly centre gripping was examined to gas detection shifts subsides mark mechanism 7 to paste mark work.

The bottom of the transfer sliding plate 63 is connected with an air cylinder, and under the driving action of the air cylinder, the transfer sliding plate 63 moves up and down along the Z-axis direction, so that the material receiving table 64 is driven to move up and down, and the reverse osmosis membrane elements can be transferred up and down along the Z-axis by the material receiving table 64 according to the clamping requirements.

In some preferred embodiments, the transverse transfer assembly further includes two material receiving frames 65, the two material receiving frames 65 are respectively disposed at two ends of the material receiving table 64, the two material receiving frames 65 are oppositely disposed along the Y direction, and a clamping opening is disposed at the top of each material receiving frame 65 for clamping an end portion of the central tube of the reverse osmosis membrane element.

In some preferred embodiments, the bottom of the material receiving frame 65 is in threaded connection with the material receiving table 64 through a screw rod and a bearing seat which are matched with each other, and the material receiving table 64 is driven by a motor to drive the material receiving frame 65 to slide and move along the Y direction of the material receiving table 64, so that the material receiving frame is suitable for clamping reverse osmosis membrane elements of different models.

Fig. 2 is a structural schematic diagram of subsides mark centre gripping subassembly in this application, as fig. 2 shows, it includes sixth apex portion 71, seventh apex portion 72, displacement board subassembly to paste mark centre gripping subassembly, sixth apex portion 71 with seventh apex portion 72 along Y to the opposite direction set up in on the displacement board subassembly, make paste mark centre gripping subassembly sixth apex portion 71 with form between the seventh apex portion 72 and paste mark centre gripping, sixth apex portion 71, seventh apex portion 72 respectively along Y to sliding connection in on the displacement board subassembly, the displacement board subassembly drives sixth apex portion 71 seventh apex portion 72 is along Z to synchronous displacement for qualified reverse osmosis membrane element is examined to the centre gripping gas, and the displacement is to pasting the mark position.

Specifically, the sixth apex portion 71 and the seventh apex portion 72 are both connected to the cylinder, and under the driving action of the cylinder, the sixth apex portion 71 and the seventh apex portion 72 respectively slide and displace along the Y direction of the displacement plate assembly.

In some preferred embodiments, one end of the central shaft of the sixth pointed end portion 71 is connected to a motor, and the other end of the central shaft is used for clamping a central pipe of a reverse osmosis membrane element, and under the driving action of the motor, the central shaft of the sixth pointed end portion 71 drives the clamped reverse osmosis membrane element to rotate so as to cooperate with the reverse osmosis membrane element to complete labeling.

Displacement board subassembly through connection in the upper and lower of installation base 9, the displacement board subassembly is "concave" word form, the displacement board subassembly includes first displacement board 73 and second displacement board 74, the both sides of first displacement board 73 with the both sides sliding connection of second displacement board 74, second displacement board 74 fixed connection in the bottom of installation base 9, first displacement board 73 with second displacement board 74 middle part is through mutually supported lead screw and bearing frame threaded connection, realizes first displacement board 73 for installation base 9 is along Z to the displacement.

Specifically, first displacement plate 73 is connected with the one end of lead screw, second displacement plate 74 and bearing frame fixed connection, bearing frame one side is provided with the motor, motor fixed mounting in second displacement plate 74, the motor with the bearing frame passes through driving belt and links together, under the drive effect of motor, the lead screw is along Z to the displacement, and then drives first displacement plate 73 is along Z displacement from top to bottom, first displacement plate 73 with second displacement plate 74 takes place relative displacement, and then realizes the displacement board subassembly drives sixth apex portion 71 seventh apex portion 72 is along Z to the displacement.

Side position mounting bracket 75 fixed connection in on the installation base 9, side position mounting bracket 75 is used for supporting paste mark subassembly 76, paste mark subassembly 76 sliding connection in side position mounting bracket 75 one side and top, paste mark subassembly 76 and follow side position mounting bracket 75's Y to, Z to the displacement, paste mark subassembly 76 with paste mark centre gripping subassembly and cooperate the completion and paste the mark action.

The side of subsides mark subassembly 76 is connected with the cylinder, and under the cylinder drive effect, mark subassembly 76 is followed the Z of side position mounting bracket 75 is to sliding displacement, simultaneously, the top and the rodless cylinder of mark subassembly 76 are connected for mark subassembly 76 can be followed Y and to sliding displacement, under the drive effect of two cylinders, makes mark subassembly 76 can realize the displacement motion of Z, Y to.

Fig. 3 is the structural schematic diagram of subsides mark subassembly 76 and side position mounting bracket 75 in this application, as shown in fig. 3, side position mounting bracket 75 includes side position installation fixed plate 751, mark subassembly 76 still includes side position installation department 760, side position installation department 760 along Y to through connection in mark subassembly 76, just side position installation department 760's middle part is long rod form, side position installation department 760's one end with one side sliding connection of side position mounting bracket 75 is used for satisfying mark subassembly 76 along Z to displacement, Y to the displacement demand.

Side position installation fixed plate 751 with side position installation department 760 sliding connection, side position installation department 760 is connected with the cylinder, and under the cylinder drive effect, side position installation department 760 is followed the Z of side position installation fixed plate 751 is to sliding displacement, and then realizes subsides mark subassembly 76 is in the displacement motion of Z.

Paste mark subassembly 76 top and be provided with top position installation department 767, top position installation department 767 is connected with the cylinder, and in the drive action of cylinder, top position installation department 767 drives paste mark subassembly 76 and follow the Y of side position installation department 760 is to the displacement motion.

Paste mark 76 still includes label blowing axle 761, rolling unit subassembly, moulding unit subassembly, third moulding running roller 769 and the driven running roller 764 of a plurality of that the height straggly set up, label blowing axle 761 rolling unit subassembly set up respectively in top position installation department 767 both sides, moulding unit subassembly the third moulding running roller 769 is located paste mark 76 bottom, third moulding running roller 769 with moulding unit subassembly cooperatees and forms and presses a central subassembly, press a central subassembly with paste mark centre gripping center is corresponding, press a central subassembly with paste mark centre gripping subassembly cooperatees for press paste the label in paste mark centre gripping intracardiac reverse osmosis membrane element's surface.

Specifically, the glue pressing unit assembly includes a first glue pressing roller 765, a second glue pressing roller 766 and a glue pressing plate 768, the first glue pressing roller 765 and the second glue pressing roller 766 are arranged in a staggered manner, the glue pressing plate 768 is located between the first glue pressing roller 765 and the second glue pressing roller 766 and is arranged towards the third glue pressing roller 769, when the glue tape of the label discharging shaft 761 is conveyed to the second glue pressing roller 766 through a plurality of driven rollers 764 and is then conveyed back to the first glue pressing roller 765 and the winding unit assembly through the third glue pressing roller 769, the glue pressing plate 768 is accommodated in the glue tape passing through the glue pressing unit assembly, and therefore when the label is adhered to the surface of the reverse osmosis membrane element, the glue pressing plate 768 can adhere the pressure on the label to the surface of the reverse osmosis membrane element.

The winding unit assembly is connected with the motor through a belt and comprises a first material collecting driving shaft 762 and two second material collecting driving shafts 763 which are in staggered press fit, the two second material collecting driving shafts 763 are respectively connected with the first material collecting driving shaft 762 and the motor, meanwhile, the first material collecting driving shaft 762 is connected with the motor, the winding unit assembly provides power for recovering the adhesive tape under the driving effect of the motor, and meanwhile, the tension for recovering the adhesive tape is guaranteed.

In some preferred embodiments, an elastic frame is disposed outside the third pressure rubber roller 769, and the third pressure rubber roller 769 is disposed on one side of the labeling assembly 76 through the elastic frame, so that when the third pressure rubber roller 769 is in displacement contact with the reverse osmosis membrane element in the labeling clamping center, the spring of the elastic frame can provide a buffer to reduce the damage to the device when the two are in collision contact.

While the foregoing has described the detailed description of the embodiments of the present application, it will be apparent to those skilled in the art that various changes and modifications can be made herein without departing from the principles of the application, and it is intended to cover all such changes and modifications as fall within the scope of the appended claims.

Claims (10)

1. The utility model provides a mark device is pasted in gas detection for processing next time behind reverse osmosis membrane element, is fixed in on installation base (9), its characterized in that:

gas detection subsides mark device is including examining mechanism (6), labeller mechanism (7) and horizontal transfer subassembly to the gas that sets up along X, gas is examined mechanism (6) and is had gas detection centre of grip, gas is examined mechanism (6) and vacuum pump connection, labeller mechanism (7) are including pasting a mark centre gripping subassembly, mark subassembly (76), mark centre gripping subassembly has a mark centre gripping center, horizontal transfer subassembly along X to set up in gas is examined centre gripping center with mark centre gripping center below, horizontal transfer subassembly along X to with the reverse osmosis membrane component conveying of gas detection mechanism (6) department mark centre gripping subassembly, mark centre gripping subassembly mark subassembly (76) cooperation displacement is in order to accomplish the subsides mark.

2. The air detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 1, characterized in that:

gas detection mechanism (6) include third mount table (60), fourth apex portion (61) and fifth apex portion (62), third mount table (60) fixed connection in on installation base (9), fourth apex portion (61) with fifth apex portion (62) along Y to sliding connection in on the mesa of third mount table (60), make fourth apex portion (61) with form gas detection centre gripping between fifth apex portion (62), fourth apex portion (61) with fifth apex portion (62) along Y to sliding displacement.

3. The gas detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 1, which is characterized in that:

the transverse transfer assembly comprises a transfer sliding plate (63) and a material receiving table (64), the transfer sliding plate (63) is arranged below the gas detection clamping center and the labeling clamping center along the X direction, and the material receiving table (64) is connected to the upper part of the transfer sliding plate (63) in a sliding manner along the X direction;

the bottom of the transfer sliding plate (63) is connected with the cylinder, and under the driving action of the cylinder, the transfer sliding plate (63) moves up and down along the Z-axis direction, so that the material receiving platform (64) is driven to move up and down.

4. The gas detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 3, characterized in that:

horizontal transfer unit still includes two and connects work or material rest (65), two connect work or material rest (65) set up respectively in connect material platform (64) both ends, two connect work or material rest (65) to being opposite direction along Y to setting up, it is provided with the centre gripping opening to connect work or material rest (65) top, connect work or material rest (65) to follow the Y that connects material platform (64) is to sliding displacement.

5. The air detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 1, characterized in that:

paste mark centre gripping subassembly and include sixth apex portion (71), seventh apex portion (72), displacement plate subassembly, sixth apex portion (71) with seventh apex portion (72) along Y to opposite direction set up in on the displacement plate subassembly for paste mark centre gripping between sixth apex portion (71) of mark centre gripping subassembly and seventh apex portion (72) forms and pastes mark centre gripping, sixth apex portion (71), seventh apex portion (72) respectively along Y to sliding connection in on the displacement plate subassembly, displacement plate subassembly drives sixth apex portion (71), seventh apex portion (72) along Z to synchronous displacement.

6. The gas detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 5, wherein:

displacement board subassembly through connection in the top and bottom of installation base (9), the displacement board subassembly is "concave" word form, the displacement board subassembly includes first displacement board (73) and second displacement board (74), the both sides of first displacement board (73) with the both sides sliding connection of second displacement board (74), second displacement board (74) fixed connection in the bottom of installation base (9), first displacement board (73) with second displacement board (74) middle part is through screw and bearing frame threaded connection of mutually supporting, realizes first displacement board (73) for installation base (9) are along Z to the displacement.

7. The gas detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 1, which is characterized in that:

labeling mechanism (7) still include side position mounting bracket (75), side position mounting bracket (75) fixed connection in on installation base (9), paste mark subassembly (76) sliding connection in side position mounting bracket (75) one side and top, paste mark subassembly (76) and follow the Y of side position mounting bracket (75) is to, Z is to the displacement, paste mark subassembly (76) with paste mark centre gripping subassembly and cooperate and accomplish and paste the mark action.

8. The gas detection labeling device for the subsequent processing of the reverse osmosis membrane element according to claim 7, characterized in that:

paste mark subassembly (76) and still include label blowing axle (761), rolling unit subassembly, moulding unit subassembly, third moulding running roller (769) and a plurality of driven running roller (764) that the height straggly set up, label blowing axle (761) rolling unit subassembly set up respectively in top position installation department (767) both sides, moulding unit subassembly third moulding running roller (769) are located paste mark subassembly (76) bottom, third moulding running roller (769) with moulding unit subassembly cooperatees and forms and presses central subassembly, press paste central subassembly with it is corresponding to paste mark centre gripping center, press paste central subassembly with it cooperatees to paste mark centre gripping subassembly.

9. The air detection labeling device for the subsequent processing of the reverse osmosis membrane element as claimed in claim 8, wherein:

the glue pressing unit assembly comprises a first glue pressing roller wheel (765), a second glue pressing roller wheel (766) and a glue pressing plate (768), the first glue pressing roller wheel (765) and the second glue pressing roller wheel (766) are arranged in a staggered mode, and the glue pressing plate (768) is located between the first glue pressing roller wheel (765) and the second glue pressing roller wheel (766) and arranged towards the third glue pressing roller wheel (769).

10. The air detection labeling device for the subsequent processing of the reverse osmosis membrane element as claimed in claim 9, wherein:

the winding unit component is connected with the motor through a belt and comprises a first material receiving driving shaft (762) and two second material receiving driving shafts (763) which are in staggered pressing, the two second material receiving driving shafts (763) are respectively connected with the first material receiving driving shaft (762) and the motor, and the first material receiving driving shaft (762) is connected with the motor.

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