CN110154412B - Membrane element feeding mechanism of instant through pipe assembling machine - Google Patents

Abstract

The invention provides a membrane element feeding mechanism of an instant through pipe assembling machine, and belongs to the technical field of medical equipment. It has solved the poor problem of stability of current membrane element material loading. The membrane element feeding mechanism of the through pipe assembling machine comprises a vibrating disk, a direct vibrator and a flat feeding block fixed on the direct vibrator, wherein a feeding channel is formed in the upper surface of the flat feeding block, a feeding port of the feeding channel is in butt joint with a discharging port of the vibrating disk. The structure remarkably improves the feeding stability of the membrane element.

Description

Membrane element feeding mechanism of instant through pipe assembling machine

Technical Field

The invention belongs to the technical field of medical equipment, and relates to a through pipe assembling machine, in particular to a film element feeding mechanism of the through pipe assembling machine.

Background

The medical connector is a connector element for providing a port to a medical container, and the medical connector comprises a path for providing fluid flow, namely a through pipe, a through valve arranged in the through pipe for blocking the fluid flow path or a membrane element arranged in the through pipe for blocking the fluid flow path, when the medical connector is used on a patient, the through pipe can be conducted by breaking the through valve or penetrating the membrane element through a needle, so that the infusion is conveniently carried out on the patient. The existing medical connector assembly mode is manually carried out, and the instant through valve or the membrane element is pressed into the instant through pipe through a workpiece, so that the assembly efficiency is low.

At present, chinese patent net discloses a full-automatic carousel formula lock screw machine with rivet screw function [ application publication number: CN106312536A, including lower screw mechanism and lock screw mechanism, lower screw mechanism includes screw shake dish and connects the screw passageway in screw shake dish one side, and screw passageway one side is connected to the screw access port at fixed block side middle part, and the fixed block bottom is equipped with down the screw mouth, and the fixed block passes through screw mouth connection lower screw pipe down in the bottom. The membrane element is hollow cylindric and the one end of membrane element has hammer-shaped head, if will use above-mentioned screw mechanism to carry the membrane element next, in order to guarantee follow-up with the membrane element to impress promptly in the siphunculus, the membrane element needs the head to put up on the screw passageway, but the membrane element that actually enters into in the screw passageway from the screw shake dish does not every can guarantee that the head is put up, partial membrane element appears being the horizontal placement that the head is forward or backward, the membrane element of mistake of putting can't enter into in the screw pipe for the dead phenomenon of card can appear in the assembly of membrane element.

Disclosure of Invention

The invention aims at solving the problems in the prior art, and provides a film element feeding mechanism of an instant through pipe assembling machine, which aims at solving the technical problems that: how to improve the feeding stability of the film element feeding mechanism.

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

The membrane element feeding mechanism of the through pipe assembling machine comprises a vibrating disk, a direct vibrator and a flat feeding block fixed on the direct vibrator, wherein a feeding channel is formed in the upper surface of the flat feeding block, a feeding port of the feeding channel is in butt joint with a discharging port of the vibrating disk.

The vibrating disc is filled with membrane elements, the membrane elements enter the feeding hole of the material conveying channel from the discharging hole of the vibrating disc, and the flat feeding block enables the membrane elements to move from the feeding hole of the material conveying channel to the discharging hole of the material conveying channel under the action of the direct vibrator. The membrane element of this structure is hollow cylindric and the upper end of membrane element has the hammer head, in membrane element's transportation process, most membrane element is vertical put, hammer head up promptly, this kind of put the state and be the membrane element in the correct state of putting of defeated silo way, this structure can not guarantee to enter into the membrane element of defeated silo way and all be vertical put, partial membrane element is the level and puts the state, hammer head forward or backward promptly, when the membrane element of level put the state gets into when removing to breach department, because membrane element is cylindric, flat conveying piece vibrations make membrane element roll down in the breach along the inclined plane, and roll out flat conveying piece through the breach. When the membrane element is located the defeated silo way, the part of membrane element hammer head stretches out outside the defeated silo way, the lateral wall at border is located the hammer head and stretches out one side at the position outside the defeated silo way in the briquetting, the lateral wall at border limits the membrane element and removes towards the breach side in the briquetting, still have the effect of direction concurrently for the membrane element of vertical state of putting is along planar length direction all the time, and the plane is used for supporting the membrane element of vertical state of putting, guarantees that the membrane element of vertical state of putting can pass through the defeated silo way of breach department smoothly, avoids the membrane element of vertical state of putting to roll out the defeated silo way from the breach. The structure can remove the membrane element in the wrong placement state from the material conveying channel, ensures that the membrane element moving to the material outlet position of the material conveying channel is in the correct placement state, avoids the blocking phenomenon of the assembly of the membrane element, and improves the feeding stability of the membrane element.

In the membrane element feeding mechanism of the instant through pipe assembling machine, the pressing block is in a strip shape, two ends of the pressing block extend to the end part of the flat feeding block, and the inner edge of the lower surface of the pressing block is provided with a chamfer. In this structure, the gradient of chamfer and the conical surface phase-match of the conical head of membrane element, and the top of membrane element conical head is located the below of chamfer, and this chamfer is spacing about also carrying out the membrane element, avoids the membrane element to break away from the defeated silo way from the upper end opening of defeated silo way for the briquetting is to the membrane element removal realization whole direction and spacing in defeated silo way.

In the film element feeding mechanism of the instant through pipe assembling machine, the number of the flat feeding blocks is three, one flat feeding block comprises a base plate, the middle part of the base plate is upwards convex to form a boss along the length direction of the base plate, the upper surface of the boss is provided with two conveying channels, the side wall of the boss and the upper surface of the base plate are both provided with notches, the notches of the boss are communicated with the notches of the base plate, the notches of the boss are communicated with the corresponding conveying channels, and the inclined plane extends into the notches of the boss; the other two flat conveying blocks are square strips, the two square strip flat conveying blocks are respectively positioned on two opposite sides of the boss and are fixed on the base plate, the notch of each square strip flat conveying block faces outwards, the lower surface of each square strip flat conveying block is attached to the upper surface of the base plate, and the side wall of each square strip flat conveying block is attached to the side wall of the boss. In the structure, one of the flat conveying blocks is in an inverted T shape, the other two flat conveying blocks are in square strips, the two square strip-shaped flat conveying blocks are divided into two opposite sides of a boss and are all fixed on a base plate, three flat conveying blocks are mutually fixed with a rectangular shape, the structure is compact, four conveying channels are arranged on the three flat conveying blocks, the number of the conveying channels is increased while the structure is compact, the feeding performance is improved, gaps on the flat conveying blocks with the bosses are formed on the side walls of the bosses and the upper surface of the base plate, the lower surfaces of the square strip-shaped flat conveying blocks are abutted against the upper surface of the base plate to realize the upper end of the gap of the closed base plate, the side walls of the square strip-shaped flat conveying blocks are abutted against the side walls of the bosses to realize the side ends of the gap of the closed boss, so that a slideway is formed on the boss and the base plate, a feeding port of the slideway is communicated with the conveying channels, and a discharging port of the slideway is arranged on the side walls of the base plate, so that the horizontal membrane element can fall out of the conveying channels from the slideway tube, and the horizontal rolling channel can be discharged from the horizontal rolling channel on the premise that the four flat conveying elements can be guaranteed.

In the film element feeding mechanism of the instant through pipe assembling machine, the bottom surface of the substrate corresponding to the notch is a downward inclined guide surface, and the guide surface and the inclined surface are in smooth transition. This structure ensures that the membrane element can roll out the flat feed block from the notch on the substrate along the inclined and guide surfaces.

In the membrane element feeding mechanism of the instant through pipe assembling machine, a collecting box is arranged below the direct vibrator, and the collecting box corresponds to the notch in position. This arrangement allows the film elements rolling out of the feed channel to fall into the magazine.

In the membrane element feeding mechanism of the instant passing pipe assembling machine, the membrane element feeding mechanism comprises a support, a blowing pipe, a pressing rod assembly, a material receiving block and a fixing block, wherein the pressing rod assembly is fixed on the support and used for pressing the membrane element into the instant passing pipe, the material receiving block is fixed on the support and is opposite to a discharge hole of a material conveying channel, the fixing block is fixed on the upper surface of the material receiving block, a strip-shaped groove is formed in the upper surface of one end of the material receiving block, which faces the material conveying channel, of the material receiving block, a feeding hole is formed in one end of the strip-shaped groove, which is opposite to the discharge hole of the material conveying channel, a first through hole is formed in the bottom surface of the strip-shaped groove, a second through hole for communicating the strip-shaped groove is formed in the upper surface of the fixing block, the first through hole is opposite to the second through hole, one end of the blowing pipe extends into the second through hole, the other end of the blowing pipe is connected to the pressing rod assembly, a first ejector rod is arranged in the through hole, and a cylinder capable of driving the ejector rod to move up and down is fixed on the support. The membrane element enters the feed inlet of the strip-shaped groove from the discharge hole of the conveying groove, when the membrane element moves to the other end of the strip-shaped groove, the first through hole is positioned below the membrane element, the second through hole is positioned above the membrane element, the cylinder drives the ejector rod to move upwards, the ejector rod pushes the membrane element into the blowing pipe from the strip-shaped groove, the blowing pipe blows the membrane element onto the pressing rod assembly, and the pressing rod assembly is convenient to press the membrane element into the instant through pipe.

In the membrane element feeding mechanism of the instant through pipe assembling machine, the pressure bar assembly comprises a translation plate arranged on the support and a feeding block fixed at the lower end of the translation plate, a third through hole is formed in the upper end face of the feeding block, an inclined hole communicated with the third through hole is formed in the outer wall of the feeding block, one end of the blowing pipe extends into the inclined hole, a pressure bar is arranged in the third through hole in a sliding mode, and a second cylinder for driving the pressure bar to move up and down is fixed on the translation plate. In the structure, the membrane element in the blowing pipe enters the through hole III through the inclined hole, and the cylinder II drives the compression bar to move downwards to press the membrane element in the through hole III into the through pipe.

In the membrane element feeding mechanism of the instant through pipe assembling machine, the translation plate is arranged on the support in a sliding mode, a positioning hole communicated with the third through hole is formed in the lower end face of the feeding block, the positioning hole is of a horn-shaped structure, the aperture of the upper end of the positioning hole is larger than that of the third through hole, and the third air cylinder used for driving the translation plate to move up and down is fixed on the support. Before the compression bar presses the membrane element into the instant through pipe, the air cylinder III drives the translation plate to move downwards so that the upper end of the instant through pipe is inserted into the positioning hole, the upper end of the instant through pipe is positioned, the membrane element can be aligned with the upper end of the instant through pipe, and then the air cylinder II drives the compression bar to move downwards so as to press the membrane element in the through hole III into the instant through pipe.

Compared with the prior art, the membrane element feeding mechanism of the instant through pipe assembling machine has the following advantages: the structure can remove the membrane element in the wrong placement state from the material conveying channel, ensures that the membrane element moving to the material outlet position of the material conveying channel is in the correct placement state, avoids the blocking phenomenon of the assembly of the membrane element, and improves the feeding stability of the membrane element.

Drawings

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

Fig. 2 is a schematic perspective view of three flat feed blocks and compacts of the present invention.

FIG. 3 is a schematic cross-sectional view of three flat feed blocks and compacts of the present invention.

Fig. 4 is a schematic perspective view of three flat feed blocks according to the present invention.

Fig. 5 is a schematic diagram of the explosive structure of three flat feed blocks of the present invention.

Fig. 6 is a schematic perspective view of the structure of the upward pushing membrane element of the present invention.

Fig. 7 is a schematic cross-sectional view of the structure of the upward pushing membrane element of the present invention.

FIG. 8 is a second perspective view of the present invention.

Fig. 9 is a schematic cross-sectional view of the structure of the pressing down element of the present invention.

In the figure, 1, a vibration plate; 1a, a discharge hole; 2. a direct vibrator; 3. a flat feeding block; 3a, a substrate; 3b, a boss; 31. a material conveying channel; 31a, inclined plane; 31b, a plane; 32. a notch; 33. a guide surface; 4. briquetting; 41. chamfering; 5. a collection box; 6. a bracket; 7. blowing a material pipe; 8. a compression bar assembly; 81. a translation plate; 82. a feed block; 82a, through hole three; 82b, inclined holes; 82c, positioning holes; 83. a compression bar; 84. a second cylinder; 85. a third cylinder; 9. a receiving block; 91. a bar-shaped groove; 92. a first through hole; 10. a fixed block; 10a, a second through hole; 11. a push rod; 12. and a first cylinder.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 and 2, the membrane element feeding mechanism of the instant through pipe assembling machine comprises a vibration disc 1, a direct vibrator 2 and a flat feeding block 3 fixed on the direct vibrator 2, wherein a material conveying channel 31 is formed in the upper surface of the flat feeding block 3, and a material inlet of the material conveying channel 31 is in butt joint with a material outlet 1a of the vibration disc 1.

As shown in fig. 2 and 3, a side wall of the flat feeding block 3 is provided with a notch 32 communicated with the feeding channel 31, a slope 31a and a plane 31b are arranged at the position, corresponding to the notch 32, of the bottom surface of the feeding channel 31, the slope 31a is inclined downwards and extends into the notch 32, the upper surface of the flat feeding block 3 is fixedly provided with a pressing block 4 for closing the upper end of the notch 32, the inner edge of the pressing block 4 is positioned above the feeding channel 31, the pressing block 4 is long-strip-shaped, two ends of the pressing block 4 extend to the end part of the flat feeding block 3, and the inner edge of the lower surface of the pressing block 4 is provided with a chamfer 41.

As shown in fig. 3, 4 and 5, in this embodiment, the flat feeding block 3 has three flat feeding blocks, one flat feeding block 3 includes a base plate 3a, the middle of the base plate 3a protrudes upwards along the length direction of the base plate 3a to form a boss 3b, two parallel feeding channels 31 are provided on the upper surface of the boss 3b, the other two flat feeding blocks 3 are square strips, the two square strip flat feeding blocks 3 are respectively located on two opposite sides of the boss 3b and are both fixed on the base plate 3a, the lower surface of the square strip flat feeding block 3 is abutted against the upper surface of the base plate 3a, the side wall of the square strip flat feeding block 3 is abutted against the side wall of the boss 3b, and the feeding channels 31 are provided on the upper surface of the flat feeding block 3. The three flat feeding blocks 3 are fixed together and are rectangular, the structure is compact, four feeding channels 31 are formed in the three flat feeding blocks 3, the number of the feeding channels 31 is increased while the structure is compact, and the feeding performance is improved.

More specifically, the side wall of the boss 3b and the upper surface of the substrate 3a are provided with notches 32, the notches 32 of the boss 3b are communicated with the notches 32 of the substrate, the notches 32 of the boss 3b are communicated with corresponding material conveying channels 31, the notches 32 of the bottom surface of the material conveying channels 31 corresponding to the boss 3b are provided with inclined surfaces 31a and planes 31b, the inclined surfaces 31a incline downwards and extend into the notches 32 of the boss 3b, the bottom surface of the substrate 3a corresponding to the notches 32 is a downward inclined guide surface 33, and smooth transition is realized between the guide surface 33 and the inclined surfaces 31 a. Fang Tiaozhuang the lower surface of the flat feeding block 3 is attached to the upper surface of the base plate 3a to close the upper end of the notch 32 of the base plate 3a, the side wall of the square strip-shaped flat feeding block 3 is attached to the side wall of the boss 3b to close the side end of the notch 32 of the boss 3b, a slideway is formed on the boss 3b and the base plate 3a, a feeding port of the slideway is communicated with the material conveying channel 31, a discharging port of the slideway is positioned on the side wall of the base plate 3a, and the horizontal membrane element is ensured to roll out of the material conveying channel 31 from the slideway. The notch 32 communicated with the material conveying channel 31 is formed in the outer side wall of the Fang Tiaozhuang flat conveying block 3, an inclined surface 31a and a plane 31b are arranged at the position, corresponding to the notch 32, of the bottom surface of the material conveying channel 31, the inclined surface 31a inclines downwards and extends into the notch 32, a film element rolls out of the material conveying channel 31 along the inclined surface 31a and the notch 32, the four material conveying channels 31 on the three flat conveying blocks 3 do not interfere with each other when working, the whole of the three flat conveying blocks 3 is in a rectangular structure after being fixed, and the film element rolls out from two sides of the rectangular structure.

As shown in fig. 1 and 2, the notch 32 of the square bar-shaped flat feeding block 3 corresponds to the notch 32 of the substrate 3a, and the collecting box 5 is arranged below the vibrator 2, and the collecting box 5 corresponds to the notch 32. The membrane elements roll off from opposite sides of the flat feed block 3 into the magazine 5.

As shown in fig. 1, 6 and 7, the film element feeding mechanism comprises a bracket 6, a blowing pipe 7, a pressing rod assembly 8 fixed on the bracket 6 and used for pressing the film element into a through pipe, a receiving block 9 fixed on the bracket 6 and opposite to a discharge hole of a material conveying channel 31, and a fixing block 10 fixed on the upper surface of the receiving block 9, wherein a strip groove 91 is formed in the upper surface of one end of the receiving block 9 facing the material conveying channel 31, one end of the strip groove 91 is provided with a feed inlet butted with the discharge hole of the material conveying channel 31, a first through hole 92 is formed in the bottom surface of the strip groove 91, a second through hole 10a communicated with the strip groove 91 is formed in the upper surface of the fixing block 10, the first through hole 92 is opposite to the second through hole 10a, one end of the blowing pipe 7 extends into the second through hole 10a, the other end of the blowing pipe is connected to the pressing rod assembly 8, a push rod 11 is arranged in the first through hole 92, and a cylinder 12 capable of driving the push rod 11 to move up and down is fixed on the bracket 6. When the film element enters the feed inlet of the strip-shaped groove 91 from the discharge hole of the conveying channel 31 and moves to the other end of the strip-shaped groove 91, the first through hole 92 is positioned below the film element, the second through hole 10a is positioned above the film element, the first cylinder 12 drives the ejector rod 11 to move upwards, and the ejector rod 11 pushes the film element into the blowing pipe 7 from the strip-shaped groove 91.

As shown in fig. 1, 8 and 9, the compression bar assembly 8 comprises a translation plate 81 arranged on the bracket 6, a feeding block 82 fixed at the lower end of the translation plate 81, a through hole III 82a arranged on the upper end surface of the feeding block 82, an inclined hole 82b communicated with the through hole III 82a arranged on the outer wall of the feeding block 82, one end of the blowing pipe 7 extending into the inclined hole 82b, a compression bar 83 arranged in the sliding manner in the through hole III 82a, a cylinder II 84 for driving the compression bar 83 to move up and down fixed on the translation plate 81, a positioning hole 82c communicated with the through hole III 82a arranged on the lower end surface of the feeding block 82 in a sliding manner on the bracket 6, and a cylinder III 85 for driving the translation plate 81 to move up and down fixed on the bracket 6, wherein the positioning hole 82c is in a horn-shaped structure and the aperture of the upper end of the positioning hole 82c is larger than the aperture of the through hole III 82 a. The blowing pipe 7 blows the film element into the inclined hole 82b, the film element enters the through hole III 82a along the inclined hole 82b, the air cylinder III 85 drives the translation plate 81 to move downwards so that the upper end of the instant through pipe is inserted into the positioning hole 82c, the upper end of the instant through pipe is positioned, the film element can be aligned with the upper end of the instant through pipe, and then the air cylinder II 84 drives the pressing rod 83 to move downwards so as to press the film element in the through hole III 82a into the instant through pipe.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (7)

1. The membrane element feeding mechanism of the instant passing pipe assembling machine comprises a vibrating disc (1), a direct vibrator (2) and a flat feeding block (3) fixed on the direct vibrator (2), wherein a feeding groove (31) is formed in the upper surface of the flat feeding block (3), a feeding hole of the feeding groove (31) is in butt joint with a discharging hole (1 a) of the vibrating disc (1), and the membrane element feeding mechanism is characterized in that a notch (32) communicated with the feeding groove (31) is formed in one side wall of the flat feeding block (3), an inclined surface (31 a) and a plane (31 b) are formed in the position, corresponding to the notch (32), of the bottom surface of the feeding groove (31), the inclined surface (31 a) is inclined downwards and extends into the notch (32), a pressing block (4) for sealing the upper end of the notch (32) is fixed on the upper surface of the flat feeding block (3), and the inner edge of the pressing block (4) is located above the feeding groove (31);

The membrane element of the structure is hollow cylindrical, the hammer-shaped head is arranged at the upper end of the membrane element, in the conveying process of the membrane element, the flat conveying block (3) vibrates to enable the membrane element to roll down into the notch (32) along the inclined plane and roll out of the flat conveying block (3) through the notch (32), when the membrane element is positioned in the conveying channel (31), the hammer-shaped head part of the membrane element extends out of the conveying channel (31), the side wall of the inner edge of the pressing block (4) is positioned at one side of the part of the hammer-shaped head extending out of the conveying channel (31), and the side wall of the inner edge of the pressing block (4) limits the membrane element to move towards the notch (32) side, so that the membrane element in the vertical placement state always moves along the length direction of the plane (31 b), the plane (31 b) is used for supporting the membrane element in the vertical placement state, the membrane element in the vertical placement state can smoothly pass through the conveying channel (31) at the notch (32), and the membrane element in the vertical placement state is prevented from rolling out of the conveying channel (31) from the notch (32);

the briquetting (4) is rectangular form and both ends of briquetting (4) all extend to the tip of flat delivery piece (3), the inner edge of briquetting (4) lower surface has chamfer (41), and the gradient of chamfer (41) matches with the conical surface phase-match of the conical head of membrane element, and the top of membrane element conical head is located the below of chamfer (41).

2. The membrane element feeding mechanism of the instant through pipe assembling machine according to claim 1, wherein the horizontal feeding blocks (3) are three, one horizontal feeding block (3) comprises a base plate (3 a), the middle part of the base plate (3 a) is upwards convex to form a boss (3 b) along the length direction of the base plate (3 a), two conveying channels (31) are formed on the upper surface of the boss (3 b), the notches (32) are formed on the side wall of the boss (3 b) and the upper surface of the base plate (3 a), the notches (32) of the boss (3 b) are communicated with the notches (32) of the base plate, the notches (32) of the boss (3 b) are communicated with the corresponding conveying channels (31), and the inclined surfaces (31 a) extend into the notches (32) of the boss (3 b); the other two flat conveying blocks (3) are square-strip-shaped, the two square-strip-shaped flat conveying blocks (3) are respectively positioned on two opposite sides of the boss (3 b) and are both fixed on the substrate (3 a), a notch (32) of each square-strip-shaped flat conveying block (3) faces outwards, the lower surface of each square-strip-shaped flat conveying block (3) is attached to the upper surface of the substrate (3 a), and the side wall of each square-strip-shaped flat conveying block (3) is attached to the side wall of the boss (3 b).

3. Membrane element feeding mechanism of instant through pipe assembling machine according to claim 2, characterized in that the bottom surface of the substrate (3 a) corresponding to the notch (32) is a guiding surface (33) inclined downwards, and the guiding surface (33) and the inclined surface (31 a) are in smooth transition.

4. Membrane element feeding mechanism of a ready-to-use pipe assembly machine according to claim 1 or 2, characterized in that the lower part of the direct vibrator (2) is provided with a collecting box (5), the collecting box (5) corresponds to the position of the notch (32).

5. The membrane element feeding mechanism of the instant passing and assembling machine according to claim 1,2 or 2, wherein the membrane element feeding mechanism comprises a bracket (6), a blowing pipe (7), a compression bar assembly (8) fixed on the bracket (6) and used for pressing the membrane element into the instant passing pipe, a receiving block (9) fixed on the bracket (6) and opposite to a discharging hole of the feeding channel (31), and a fixing block (10) fixed on the upper surface of the receiving block (9), a strip-shaped groove (91) is formed in the upper surface of one end of the receiving block (9) facing the feeding channel (31), a feeding hole which is in butt joint with the discharging hole of the feeding channel (31) is formed in one end of the strip-shaped groove (91), a through hole I (92) is formed in the bottom surface of the strip-shaped groove (91), a through hole II (10 a) which is communicated with the strip-shaped groove (91) is formed in the upper surface of the fixing block (10), a through hole I (92) is opposite to the through hole II (10 a), a through hole II (10 a) is formed in the other end of the blowing pipe (7) and extends into the air cylinder I (8), and the compression bar assembly (11) is driven to move, and the compression bar assembly (11) can be fixed on the first end of the air cylinder (8).

6. The membrane element feeding mechanism of the instant passing-through pipe assembling machine according to claim 5, wherein the pressure rod assembly (8) comprises a translation plate (81) arranged on a support (6), a feeding block (82) fixed at the lower end of the translation plate (81), a through hole III (82 a) is formed in the upper end face of the feeding block (82), an inclined hole (82 b) communicated with the through hole III (82 a) is formed in the outer wall of the feeding block (82), one end of the blowing pipe (7) extends into the inclined hole (82 b), a pressure rod (83) is arranged in the through hole III (82 a) in a sliding mode, and a cylinder II (84) for driving the pressure rod (83) to move up and down is fixed on the translation plate (81).

7. Membrane element feeding mechanism of instant through pipe assembling machine according to claim 6, characterized in that, translation board (81) slides and sets up on support (6), set up locating hole (82 c) of intercommunication through-hole three (82 a) on the lower terminal surface of feeding piece (82), locating hole (82 c) are loudspeaker form structure and the aperture of locating hole (82 c) upper end is greater than the aperture of through-hole three (82 a), be fixed with on support (6) and be used for driving translation board (81) cylinder three (85) reciprocate.