CN112224954A - A equipment that is used for gas pipeline raw material area to coil up - Google Patents

Abstract

The invention relates to a roll separating device, in particular to a device for separating a raw material belt of a gas pipeline. The technical problem that solve can carry out automatic feeding for rolling up the core for providing one kind, and can carry out the equipment that is used for gas pipeline thread seal area bundling that fuses automatically to the thread seal area. A device for the unboiled tape bundling of gas pipes, comprising: the motor comprises a base, wherein a double-shaft motor is arranged on one side of the top of the base; the first supporting plates are symmetrically and fixedly connected to the middle of one side, far away from the double-shaft motor, of the top of the base; the inclined rail is arranged between the upper parts of the first supporting plates on two sides through bolts. The automatic feeding device achieves the effects of automatically feeding the winding cores and automatically fusing the green tape, and the double-shaft motor can drive the pushing mechanism to operate, so that the winding cores in the inclined rail can be continuously sleeved on the first rotating shaft.

Description

A equipment that is used for gas pipeline raw material area to coil up

Technical Field

The invention relates to a roll separating device, in particular to a device for separating a raw material belt of a gas pipeline.

Background

The gas pipeline raw material belt is an auxiliary article commonly used in water heating installation, is used for pipe fitting joints and enhances the tightness of the pipe fitting joints, and is widely applied to the field of natural gas due to non-toxic and tasteless sealing property, insulating property and corrosion resistance.

At present, the gas pipeline thread seal area all is very big one-tenth when just being produced, need people to roll up into the small book with its bundling, the workman all puts into the machine with rolling up the core earlier usually in the mill, then with thread seal area bonding on the machine, the machine drives and rolls up the core and constantly rotates, thereby continuously convolute thread seal area on rolling up the core, when convoluteing to certain degree, use the hot melt machine to cut off the thread seal area, because the fusing through the hot melt machine, the thread seal area has certain viscosity, the thread seal area can glue on rolling up the core easily, such bundling method is comparatively troublesome, need people's manual constantly to roll up the core and place on the machine, and need people's manual fuse with the hot melt machine with the thread seal area.

Therefore, the invention is needed to invent a device for separating the raw material belt of the gas pipeline, which can automatically feed the winding core and automatically fuse the raw material belt.

Disclosure of Invention

In order to overcome that there is the manual comparatively trouble of material loading to rolling up the core among the prior art, efficiency is not high, and need constantly manual carry out the shortcoming of fusing to the raw material area, and the technical problem that solves is: the utility model provides a can carry out automatic feeding to rolling up the core, and can carry out the equipment that is used for gas pipeline thread seal area bundling that fuses automatically to the thread seal area.

The technical scheme of the invention is as follows: a device for the unboiled tape bundling of gas pipes, comprising: the motor comprises a base, wherein a double-shaft motor is arranged on one side of the top of the base; the first supporting plates are symmetrically and fixedly connected to the middle of one side, far away from the double-shaft motor, of the top of the base; the inclined rail is arranged between the upper parts of the first supporting plates on two sides through bolts; the intermittent displacement mechanism is arranged in the middle of the top of the base, and one side of the intermittent displacement mechanism is connected with an output shaft on one side of the double-shaft motor; the second bearing seat is arranged on one side, close to the double-shaft motor, of the top of the base; the second rotating shaft is rotatably arranged in the second bearing seat; the first bevel gear is welded at the end part of the output shaft at one side of the double-shaft motor; the second bevel gear is welded at the inner end of the second rotating shaft and meshed with the first bevel gear; the pushing mechanism is arranged on one side, close to the double-shaft motor, of the top of the base, and one end of the pushing mechanism is connected with the second rotating shaft; the pushing mechanism is arranged on one side, close to the double-shaft motor, of the top of the base, the pushing mechanism and the material pushing mechanism are located on two sides of the double-shaft motor, and one end of the pushing mechanism is connected with an output shaft on the other side of the double-shaft motor; the servo motor is arranged on one side, close to the double-shaft motor, of the top of the intermittent displacement mechanism in a sliding mode; the touch switch is arranged on one side of the servo motor; the reciprocating displacement mechanism is arranged on the intermittent displacement mechanism and is connected with an output shaft of the servo motor; and the wedge block is fixedly connected to the upper side of the intermittent displacement mechanism and matched with the touch switch.

In one embodiment, the intermittent displacement mechanism comprises: the first gear lack is welded in the middle of an output shaft on one side of the double-shaft motor; the supports are symmetrically and fixedly connected to one side, close to the first supporting plate, of the top of the base; the mounting plate is fixedly connected to the tops of the supports on the two sides, one side of the mounting plate is connected with the servo motor in a sliding mode, one side of the mounting plate is connected with the push-out mechanism, and a sliding groove is formed in the inner side of the mounting plate; the sliding plate is arranged in the sliding groove in a sliding manner; the first rack is welded at the bottom of the sliding plate; the first bearing seats are uniformly installed on the sliding plate at intervals, and the number of the first bearing seats is at least four; the first rotating shaft is arranged in the first bearing seat in an equal rotating mode, and grooves are uniformly spaced outside the first rotating shaft.

In one embodiment, the pushing mechanism comprises: the third bearing seat is arranged on one side, close to the double-shaft motor, of the top of the base; the third rotating shaft is rotatably arranged in the third bearing seat; the transmission assembly is connected to the middle of the third rotating shaft, and the lower end of the transmission assembly is connected with the second rotating shaft; the first rotating handle is arranged at the inner end of the third rotating shaft; the second rotating handle is rotatably arranged at one end of the first rotating handle; the first sliding rail is arranged on one side of the inclined rail; the sliding push plate is arranged in the first sliding rail in a sliding mode, and one side of the sliding push plate is connected with the second rotating handle in a rotating mode.

In one embodiment, the ejecting mechanism comprises: the second sliding rail is arranged on one side, close to the double-shaft motor, of the top of the base; the second gear lack is welded at the outer end of the second rotating shaft; the second rack is arranged on the second sliding rail in a sliding mode and matched with the second gear lack; the second supporting plate is fixedly connected to one side of the top of the base, and the upper part of the second supporting plate is connected with the mounting plate; a first spring connected between the second support plate and the second rack.

In one embodiment, the reciprocating displacement mechanism comprises: the fourth bearing seat is installed at the top of the base and is positioned below the servo motor; the third bevel gear is connected to an output shaft on the other side of the double-shaft motor through a coupler and rotatably connected with the fourth bearing seat; the fifth bearing seat is installed on one side of the bottom of the mounting plate; the fourth rotating shaft is rotatably arranged in the fifth bearing seat; the fourth bevel gear is welded at the bottom end of the fourth rotating shaft and meshed with the third bevel gear; the third gear lack is welded at the top end of the fourth rotating shaft; the mounting seat is arranged on the mounting plate in a sliding mode, and the top end of the mounting seat is connected with the bottom of the servo motor; and the third racks are symmetrically arranged at the bottom of the mounting seat, and the third racks on two sides are matched with the third missing gear.

In one embodiment, the method further comprises the following steps: the supporting rod is fixedly connected to the top of the inclined rail; the hot melting machine is arranged on the upper part of the supporting rod through a bolt; a sixth bearing block mounted on top of the mounting plate; a chuck, the chuck rotary type sets up in the sixth bearing frame, the chuck with the hot melt machine is adjacent.

In one embodiment, the method further comprises the following steps: the grooves on the outer side of the first rotating shaft are connected with the second springs; and the ejection blocks are connected to the outer end of the second spring.

The beneficial effects are that: 1. the automatic feeding device achieves the effects that the roll cores can be automatically fed, and the raw material belt can be automatically fused;

2. the pushing mechanism can be driven to operate by the double-shaft motor, so that a winding core in the inclined rail can be continuously sleeved on the first rotating shaft, and the first rotating shaft is fixed in the sliding plate under the action of the ejection block and the second spring;

3. through the up-and-down movement of the hot melting machine, when enough raw material belts are wound on the winding core, the raw material belts can be fused, so that people do not need to fuse the raw material belts manually;

4. because the frequency of downward movement of the hot melting machine is consistent, the length of the raw material belt wound every time is consistent.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a perspective view of a fourth embodiment of the present invention.

FIG. 6 is a schematic view of a fifth partial body structure according to the present invention.

FIG. 7 is a schematic view of a sixth partial body structure according to the present invention.

Fig. 8 is a schematic view of a partial explosion in perspective according to the present invention.

Labeled as: a base, 2.. a dual-axis motor, 3.. a first support plate, 4.. an inclined rail, 5.. an intermittent displacement mechanism, 50.. a first missing gear, 51.. a bracket, 52.. an installation plate, 53.. a sliding chute, 54.. a sliding plate, 55.. a first rack, 56.. a first bearing seat, 57.. a first rotating shaft, 6.. a second bearing seat, 7.. a second rotating shaft, 8.. a first bevel gear, 9.. a second conical gear, 10.. a pushing mechanism, 100.. a third bearing seat, 101.. a third rotating shaft, 102.. a transmission assembly, 103.. a first rotating handle, 104.. a second rotating handle, 105.. a sliding push plate, 106.. a first sliding rail, 11.. a second sliding rail, 111.. a second sliding chute, 113.. second support plate, 114.. first spring, 12.. servomotor, 121.. touch switch, 13.. reciprocating displacement mechanism, 130.. fourth bearing, 131.. third bevel gear, 132.. fifth bearing, 133.. fourth pivot, 134.. fourth bevel gear, 135.. third missing gear, 136.. third rack, 137.. mount, 14.. wedge, 15.. support bar, 16.. hot melt machine, 17.. sixth bearing, 18.. chuck, 19.. second spring, 20.. ejector block.

Detailed Description

The invention will be further described with reference to examples of embodiments shown in the drawings to which the invention is attached.

Example 1

An apparatus for separating a raw material belt of a gas pipeline is shown in figures 1-6 and 8, and comprises a base 1, a double-shaft motor 2, a first supporting plate 3, an inclined rail 4, an intermittent displacement mechanism 5, a second bearing seat 6, a second rotating shaft 7, a first bevel gear 8, a second bevel gear 9, a material pushing mechanism 10, a pushing mechanism 11, a servo motor 12, a touch switch 121, a reciprocating displacement mechanism 13 and a wedge block 14, wherein the double-shaft motor 2 is installed on the right side of the top of the base 1, the first supporting plate 3 is fixedly connected with the middle of the top of the base 1 in a bilateral symmetry manner, the inclined rail 4 is arranged between the upper parts of the first supporting plates 3 on the left side and the right side through bolts, the intermittent displacement mechanism 5 is arranged on the top of the base 1, the right part of the intermittent displacement mechanism 5 is connected with an output shaft on the front side of the double-shaft motor 2, the, a second rotating shaft 7 is arranged in the second bearing seat 6 in a rotating mode, a first bevel gear 8 is welded at the end portion of an output shaft on the front side of the double-shaft motor 2, a second bevel gear 9 is welded at the left end of the second rotating shaft 7, the second bevel gear 9 is meshed with the first bevel gear 8, a material pushing mechanism 10 is arranged on the right front side of the top of the base 1, the rear end of the material pushing mechanism 10 is connected with the second rotating shaft 7, a pushing-out mechanism 11 is arranged on the right rear side of the top of the base 1, the front end of the pushing-out mechanism 11 is connected with the output shaft on the rear side of the double-shaft motor 2, a servo motor 12 is arranged on the top of the intermittent displacement mechanism 5 in a sliding mode, a touch switch 121 is arranged on the right portion of the servo motor 12, a reciprocating displacement mechanism 13 is arranged on the rear side of the.

The intermittent displacement mechanism 5 comprises a first gear 50, a support 51, a mounting plate 52, a sliding plate 54, a first rack 55, a first bearing seat 56 and a first rotating shaft 57, the first gear 50 is welded in the middle of an output shaft on the front side of the double-shaft motor 2, the support 51 is fixedly connected to the left side and the right side of the rear side of the top of the base 1, the mounting plate 52 is fixedly connected between the tops of the support 51 on the left side and the right side, the right portion of the mounting plate 52 is connected with the servo motor 12 in a sliding manner, the right portion of the mounting plate 52 is connected with the push-out mechanism 11, a sliding groove 53 is formed in the front portion of the mounting plate 52, the sliding plate 54 is arranged in the sliding manner, the first rack 55 is welded at the bottom of the sliding plate 54, the first rack 55 is meshed with the first gear 50, five.

The material pushing mechanism 10 comprises a third bearing seat 100, a third rotating shaft 101, a transmission assembly 102, a first rotating handle 103, a second rotating handle 104, a sliding push plate 105 and a first sliding rail 106, the third bearing seat 100 is installed on the right front side of the top of the base 1, the third rotating shaft 101 is rotatably arranged on the third bearing seat 100, the transmission assembly 102 is connected to the middle of the third rotating shaft 101, the lower end of the transmission assembly 102 is connected with the left portion of the second rotating shaft 7, the first rotating handle 103 is arranged at the left end of the third rotating shaft 101, the second rotating handle 104 is rotatably arranged at the left portion of the first rotating handle 103, the first sliding rail 106 is installed at the right front side of the inclined rail 4, a sliding push plate 105 is slidably arranged in the first sliding rail 106, and the right portion of the sliding push plate 105 is rotatably connected with the.

The pushing mechanism 11 comprises a second slide rail 110, a second lacking gear 111, a second rack 112, a second support plate 113 and a first spring 114, the second slide rail 110 is installed on the right side of the top of the base 1, the second slide rail 110 is provided with the second rack 112 in a sliding mode, the second lacking gear 111 is welded on the right portion of the second rotating shaft 7, the second lacking gear 111 is matched with the second rack 112, the right rear side of the top of the base 1 is fixedly connected with the second support plate 113, the upper portion of the second support plate 113 is connected with the right portion of the mounting plate 52, and the first spring 114 is connected between the front side of the second support plate 113 and the rear portion of the second rack 112.

The reciprocating displacement mechanism 13 comprises a fourth bearing seat 130, a third bevel gear 131, a fifth bearing seat 132, a fourth rotating shaft 133, a fourth bevel gear 134, a third missing gear 135, a third rack 136 and a mounting seat 137, the output shaft at the rear side of the double-shaft motor 2 is connected with the third bevel gear 131 through a coupling, the fourth bearing seat 130 is installed at the rear side of the top of the base 1, the fourth bearing seat 130 is rotatably connected with the third bevel gear 131, the fifth bearing seat 132 is installed at the right side of the bottom of the mounting plate 52, the fourth rotating shaft 133 is rotatably arranged in the fifth bearing seat 132, the fourth bevel gear 134 is welded at the bottom end of the fourth rotating shaft 133, the fourth bevel gear 134 is meshed with the third bevel gear 131, the third missing gear 135 is welded at the top end of the fourth rotating shaft 133, the mounting seat 137 is slidably arranged at the bottom of the right side of the mounting plate 52, the top end of the mounting seat 137 is connected with the bottom of the servo, the third racks 136 on the left and right sides are engaged with the third missing gear 135.

When people need to split the raw material belt for the gas pipeline, the device can be used only, firstly, enough winding cores are placed on the inclined rail 4, then the double-shaft motor 2 is started, an output shaft on the front side of the double-shaft motor 2 can drive the first bevel gear 8 to continuously rotate, so as to drive the second bevel gear 9 and the second rotating shaft 7 to continuously rotate, further drive the material pushing mechanism 10 to operate, the winding cores are pushed by the material pushing mechanism 10 to be contacted with the intermittent displacement mechanism 5, the rest winding cores can automatically roll downwards, one end of the raw material belt is adhered to the winding cores by hands, meanwhile, an output shaft on the rear side of the double-shaft motor 2 drives the reciprocating displacement mechanism 13 to operate, so that the servo motor 12 continuously moves back and forth, when the servo motor 12 moves towards the front side, the touch switch 121 can be contacted with the wedge block 14, then the servo motor 12 is started, when the servo motor 12 moves towards the rear side, the touch switch 121 can be separated from the wedge block 14, the servo motor 12 can be automatically closed, the output shaft of the servo motor 12 can be matched with the intermittent displacement mechanism 5, so that the winding core continuously rotates, the raw material belt is wound on the winding core, when a sufficient amount of raw material belt is wound on the winding core, the raw material belt is cut off by a machine, meanwhile, the output shaft at the front side of the servo motor 12 can drive the first gear lacking 50 to continuously rotate, because the first gear lacking 50 can be matched with the intermittent displacement mechanism 5, when the output shaft of the servo motor 12 is separated from the intermittent displacement mechanism 5, the intermittent displacement mechanism 5 can be pushed to the right side, when the intermittent displacement mechanism 5 is not moved, the output shaft of the servo motor 12 is in contact with the intermittent displacement mechanism 5 again, the second rotating shaft 7 continuously rotates to drive the pushing-out mechanism 11 to push out the winding core wound with the raw material belt, and the process is repeated in such a way, so, one just collects it in front of the push-out mechanism 11 and finally turns off the two-axis motor 2 and resets the intermittent displacement mechanism 5.

The output shaft in front of the dual-shaft motor 2 can drive the first gear 50 to rotate continuously, when the first gear 50 contacts with the first rack 55, the first rack 55 and the sliding plate 54 are pushed to the right, and when the first gear 50 is separated from the first rack 55, the sliding plate 54 and the first rack 55 cannot move, so that the sliding plate 54 can intermittently move to the right, and the first bearing seat 56 and the first rotating shaft 57 are driven to intermittently move to the right. The pushing mechanism 10 moves towards the rear side to push the winding core to the first rotating shaft 57 and push the first rotating shaft 57 towards the rear side for a short distance, because the rear end of the first rotating shaft 57 is provided with the coupler, the first rotating shaft 57 is connected with the output shaft of the servo motor 12, one end of the raw material tape is adhered to the winding core at the moment, the output shaft of the servo motor 12 drives the first rotating shaft 57 to continuously rotate, so that the raw material tape is continuously wound on the winding core, when appropriate, people use a machine to fuse the raw material tape, after the first rotating shaft 57 at the rightmost end drives the raw material tape which is completely wound to move towards the right, one side of the fused raw material tape continues to be adhered to the winding core on the next first rotating shaft 57, the reciprocating is carried out in such a way, the raw material tape can be continuously wound on the winding core, when the sliding plate 54 moves towards the right side to the frontmost end, the double-shaft motor 2 is closed, the sliding plate, and pushes the first rotating shaft 57 forward to reset it.

The second rotating shaft 7 continuously rotates to drive the third rotating shaft 101 to continuously rotate through the transmission component 102, thereby driving the first rotating handle 103 to continuously rotate, because the first rotating handle 103 and the second rotating handle 104 are connected with each other in a rotating manner and the second rotating handle 104 and the sliding push plate 105 are connected with each other in a rotating manner, the first rotating handle 103 drives the sliding push plate 105 to continuously move back and forth, when the sliding push plate 105 moves towards the rear side, the rolling core on the inclined rail 4 is driven to be sleeved on the first rotating shaft 57, and the first rotating shaft 57 is driven towards the rear side, when the sliding push plate 105 moves towards the front side, the sliding push plate 105 is separated from the inclined rail 4, under the action of gravity, the rolling core can roll towards the lower side, and the reciprocating manner can continuously push the rolling core in the inclined rail 4 to the first rotating shaft 57.

The second rotating shaft 7 continuously rotates to drive the second gear lacking 111 to continuously rotate, when the second gear lacking 111 is meshed with the second rack 112, the second rack 112 is driven to move towards the rear side, the first spring 114 is compressed, the sliding plate 54 just moves towards the right side at the moment, when the sliding plate 54 stops moving, under the reset action of the first spring 114, the second rack 112 moves towards the front side, the winding core wound with the raw material belt on the first rotating shaft 57 is pushed out, the reciprocating operation is carried out, and the winding core wound with the raw material belt on the first rotating shaft 57 can be continuously pushed out through the continuous back-and-forth movement of the second rack 112.

The output shaft of the rear side of the double-shaft motor 2 can drive the third bevel gear 131 to rotate continuously, thereby driving the fourth bevel gear 134 and the fourth rotating shaft 133 to rotate continuously, further driving the third gear 135 to rotate continuously, the third gear 135 can be meshed with the third rack 136 on the right side first, and the third racks 136 on the left side and the right side, the mounting seat 137 and the servo motor 12 are pushed to the front side, when the third gear 135 is meshed with the third rack 136 on the left side, the third racks 136 on the left side and the right side can be pushed to the rear side, and thus the servo motor 12 can move back and forth continuously.

Example 2

On the basis of embodiment 1, as shown in fig. 7 to 8, the device further includes a support rod 15, a fuse machine 16, a sixth bearing seat 17 and a chuck 18, the support rod 15 is fixedly connected to the right side of the top of the inclined rail 4, the fuse machine 16 is installed on the rear side of the upper portion of the support rod 15 through a bolt, the sixth bearing seat 17 is installed on the right side of the top of the installation plate 52, and the chuck 18 is rotatably installed in the sixth bearing seat 17.

The spring rack further comprises a second spring 19 and an ejection block 20, grooves are evenly formed in the outer side of the first rotating shaft 57 at intervals, the second spring 19 is connected in each groove, and the ejection block 20 is connected to the outer end of each second spring 19.

People can place the raw material area raw materials on chuck 18, so people just need not manually hold the raw material area raw materials, then hot melt machine 16 on the bracing piece 15 can constantly reciprocate, when having convoluteed the raw material drive of the capacity on rolling up the core, hot melt machine 16 just can the downstream fuse to the raw material area, so just need not manually fuse to the raw material area.

When the winding core is pushed onto the first rotating shaft 57, the winding core will contact with the ejection block 20, and push the ejection block 20 and the first rotating shaft 57 to the rear side, then the ejection block 20 will contact with the first bearing seat 56, the ejection block 20 is pushed inwards, the second spring 19 is compressed, at this time, the winding core just contacts with the sliding plate 54, the ejection block 20 always contacts with the first bearing seat 56, so that the first rotating shaft 57 can rotate continuously in the first bearing seat 56, and the first rotating shaft 57 can be clamped in the first bearing seat 56, because the outer side of the ejection block 20 is arc-shaped, people can push the first rotating shaft 57 to the front side with only slight effort, and under the action of the second spring 19, the ejection block 20 will reset to the outer side.

The present application is described in detail above, and the principles and embodiments of the present application are described herein by using specific examples, which are only used to help understand the method and the core idea of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (7)

1. The utility model provides an equipment that is used for gas pipeline raw material area to split roll which characterized in that, including:

the motor comprises a base (1), wherein a double-shaft motor (2) is arranged on one side of the top of the base (1);

the first supporting plate (3) is symmetrically and fixedly connected to the middle of one side, far away from the double-shaft motor (2), of the top of the base (1);

the inclined rail (4) is arranged between the upper parts of the first supporting plates (3) on two sides through bolts;

the intermittent displacement mechanism (5) is arranged in the middle of the top of the base (1), and one side of the intermittent displacement mechanism (5) is connected with an output shaft on one side of the double-shaft motor (2);

the second bearing block (6), the second bearing block (6) is installed on one side, close to the double-shaft motor (2), of the top of the base (1);

the second rotating shaft (7), the second rotating shaft (7) is rotatably arranged in the second bearing seat (6);

the first bevel gear (8), the first bevel gear (8) is welded at the end part of the output shaft at one side of the double-shaft motor (2);

the second bevel gear (9), the second bevel gear (9) is welded at the inner end of the second rotating shaft (7), and the second bevel gear (9) is meshed with the first bevel gear (8);

the pushing mechanism (10) is arranged on one side, close to the double-shaft motor (2), of the top of the base (1), and one end of the pushing mechanism (10) is connected with the second rotating shaft (7);

the pushing mechanism (11) is arranged on one side, close to the double-shaft motor (2), of the top of the base (1), the pushing mechanism (11) and the material pushing mechanism (10) are located on two sides of the double-shaft motor (2), and one end of the pushing mechanism (11) is connected with an output shaft on the other side of the double-shaft motor (2);

the servo motor (12), the servo motor (12) is arranged on one side of the top of the intermittent displacement mechanism (5) close to the double-shaft motor (2) in a sliding mode;

a touch switch (121), wherein the touch switch (121) is installed on one side of the servo motor (12);

a reciprocating displacement mechanism (13), wherein the reciprocating displacement mechanism (13) is arranged on the intermittent displacement mechanism (5), and the reciprocating displacement mechanism (13) is connected with an output shaft of the servo motor (12);

the wedge block (14), wedge block (14) fixed connection in intermittent displacement mechanism (5) upside, wedge block (14) with touch switch (121) cooperation.

2. The apparatus for the unwinding of the raw tape of gas pipes according to claim 1, characterized in that the intermittent displacement mechanism (5) comprises:

the first gear (50) is welded in the middle of an output shaft on one side of the double-shaft motor (2);

the bracket (51) is symmetrically and fixedly connected to one side, close to the first supporting plate (3), of the top of the base (1);

the mounting plate (52) is fixedly connected to the tops of the supports (51) at two sides, one side of the mounting plate (52) is connected with the servo motor (12) in a sliding mode, one side of the mounting plate (52) is connected with the push-out mechanism (11), and a sliding groove (53) is formed in the inner side of the mounting plate (52);

a slide plate (54), the slide plate (54) being slidably disposed within the chute (53);

a first rack (55), wherein the first rack (55) is welded at the bottom of the sliding plate (54);

the first bearing seats (56), the first bearing seats (56) are installed on the sliding plate (54) at regular intervals, and the number of the first bearing seats (56) is at least two;

first pivot (57), equal rotary type is equipped with in first bearing frame (56) first pivot (57), first pivot (57) outside evenly spaced apart is fluted.

3. The device for the unwinding of the raw material tape for gas pipes according to claim 2, characterized in that the pushing means (10) comprise:

the third bearing seat (100), the third bearing seat (100) is installed on one side of the top of the base (1) close to the double-shaft motor (2);

the third rotating shaft (101) is rotatably arranged on the third bearing seat (100);

the transmission assembly (102), the transmission assembly (102) is connected to the middle part of the third rotating shaft (101), and the lower end of the transmission assembly (102) is connected with the second rotating shaft (7);

the first rotating handle (103), the first rotating handle (103) is arranged at the inner end of the third rotating shaft (101);

the second rotating handle (104), the second rotating handle (104) is rotatably arranged at one end of the first rotating handle (103);

the first sliding rail (106), the first sliding rail (106) is installed on one side of the inclined rail (4);

the sliding push plate (105), the sliding push plate (105) is arranged in the first sliding rail (106), and one side of the sliding push plate (105) is connected with the second rotating handle (104) in a rotating mode.

4. The device for the unwinding of the raw tape for gas pipes according to claim 3, characterized in that the ejecting mechanism (11) comprises:

the second sliding rail (110), the second sliding rail (110) is installed on one side, close to the double-shaft motor (2), of the top of the base (1);

the second gear (111) is welded at the outer end of the second rotating shaft (7);

the second rack (112) is slidably arranged on the second sliding rail (110), and the second rack (112) is matched with the second missing gear (111);

the second supporting plate (113), the second supporting plate (113) is fixedly connected to one side of the top of the base (1), and the upper part of the second supporting plate (113) is connected with the mounting plate (52);

a first spring (114), the first spring (114) being connected between the second support plate (113) and the second rack (112).

5. The apparatus for unwinding raw material tape for gas pipes according to claim 4, wherein the reciprocating displacement mechanism (13) comprises:

a fourth bearing seat (130), wherein the fourth bearing seat (130) is installed on the top of the base (1), and the fourth bearing seat (130) is positioned below the servo motor (12);

the third bevel gear (131) is connected to an output shaft on the other side of the double-shaft motor (2) through a coupler, and the third bevel gear (131) is rotatably connected with the fourth bearing seat (130);

a fifth bearing seat (132), wherein the fifth bearing seat (132) is installed on one side of the bottom of the mounting plate (52);

the fourth rotating shaft (133), the fourth rotating shaft (133) is rotatably arranged in the fifth bearing seat (132);

a fourth bevel gear (134), wherein the fourth bevel gear (134) is welded at the bottom end of the fourth rotating shaft (133), and the fourth bevel gear (134) is meshed with the third bevel gear (131);

a third gear lack (135), wherein the third gear lack (135) is welded at the top end of the fourth rotating shaft (133);

the mounting seat (137) is arranged on the mounting plate (52) in a sliding mode, and the top end of the mounting seat (137) is connected with the bottom of the servo motor (12);

and the third gear racks (136) are symmetrically arranged at the bottoms of the mounting seats (137), and the third gear racks (136) on two sides are matched with the third lacking gear (135).

6. The apparatus for unwinding raw material tape for gas pipeline according to claim 5, further comprising;

the supporting rod (15), the supporting rod (15) is fixedly connected to the top of the inclined rail (4);

the hot melting machine (16), the hot melting machine (16) is installed on the upper part of the support rod (15) through a bolt;

a sixth bearing block (17), said sixth bearing block (17) mounted on top of said mounting plate (52);

a chuck (18), the chuck (18) is rotatably disposed on the sixth bearing seat (17), the chuck (18) is adjacent to the heat fusion machine (16).

7. The apparatus as claimed in claim 6, further comprising:

the grooves on the outer side of the first rotating shaft (57) are connected with the second springs (19);

the ejection blocks (20) are connected to the outer end of the second spring (19).

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