CN111207983B

CN111207983B - Detection test device for bonding material

Info

Publication number: CN111207983B
Application number: CN202010244858.8A
Authority: CN
Inventors: 施羽亚
Original assignee: Baozitan Plum Professional Cooperative In Quchi Township Wushan County
Current assignee: Chongqing Dingliyuan Pharmaceutical Co ltd
Priority date: 2020-03-31
Filing date: 2020-03-31
Publication date: 2020-12-15
Anticipated expiration: 2040-03-31
Also published as: CN111207983A; GB202009031D0

Abstract

The invention discloses a novel bonding material detection test device which comprises a machine body, wherein a test cavity with a front opening is arranged in the machine body, a driving cavity with a rightward opening is arranged in the middle of the inner part of the left end wall of the test cavity, a storage cavity with an upward opening is arranged above the driving cavity, a transfer cavity is arranged below the driving cavity, and a screw cavity is arranged above the test cavity.

Description

Detection test device for bonding material

Technical Field

The invention relates to the technical field of novel bonding material detection, in particular to a detection test device for a bonding material.

Background

The adhesive material is also called adhesive, binder, bonding agent and sticking agent, and refers to a substance which has good adhesive property and can connect two materials together, and the common bonding agents in daily life mainly comprise 502 glue, shoe glue, white latex and the like.

The bonding effect of the current bonding agent is different, the applicable materials are different, so that each novel bonding material needs to be subjected to a certain entity detection process, differential data of bonding performance under different materials can be obtained, an optimization mode is further searched, a current testing device can only perform a detection test by one machine, and thus a test article is clamped for multiple times, the test result is subjected to errors due to different clamping positions at each time, or the bonding performance is different due to different bonding methods of the test article at each time, and the test result is inaccurate.

Disclosure of Invention

Aiming at the technical defects, the invention provides a detection test device for a bonding material, which can overcome the defects.

The invention discloses a detection test device for bonding materials, which comprises a machine body, wherein a test cavity with a front opening is arranged in the machine body, a driving cavity with a right opening is arranged in the middle of the left end wall of the test cavity, a storage cavity with an upward opening is arranged above the driving cavity, a transfer cavity is arranged below the driving cavity, a screw cavity is arranged above the test cavity, a pulley cavity is arranged on the right side above the screw cavity, an output cavity positioned on the right side of the test cavity is arranged below the pulley cavity, a stretching device is arranged in the output cavity, a reset cavity with a left opening is arranged in the right end wall of the output cavity, a rotating cavity is arranged below the test cavity, a gear cavity positioned below the rotating cavity is arranged on the left side of the output cavity, a rotating device is arranged in the gear cavity, and a spring cavity with a right opening is arranged in the left end wall of the gear cavity, the spring cavity is internally provided with a bonding device, and the left end wall of the spring cavity is internally provided with a discontinuous cavity.

Preferably, the rotating device comprises a motor plate slidably disposed in the output cavity, the right end of the motor plate extends into the reset cavity, the upper end of the motor plate is provided with a reset spring fixed in the upper end wall of the reset cavity, the lower end wall of the reset cavity is internally fixed with a reset electromagnet, the motor plate is internally fixed with a main motor, the lower end of the main motor is in power connection with a lower output shaft, the lower end of the lower output shaft is fixed with a first bevel gear, the left end of the first bevel gear is engaged with a second bevel gear, the left end of the second bevel gear is fixed with a second shaft rotatably disposed in the left end wall of the output cavity, the left end of the second shaft extends into the gear cavity and is in splined connection with an intermediate shaft capable of sliding left and right, the left end of the intermediate shaft is fixed with a third bevel gear, and a fourth bevel gear capable of engaging, a fourth shaft rotatably arranged in the upper end wall of the gear cavity is fixed at the upper end of the fourth bevel gear, the upper end of the fourth shaft extends into the rotary cavity and is fixed with a second gear, the left side of the second gear is engaged with the rotary gear, the rotary gear is fixed on the outer side wall of a lower test block rotatably arranged in the lower end wall of the rotary cavity, a lower clamping cavity with an upward opening is arranged at the right side of the upper end surface of the lower test block, a lower clamping block is slidably arranged in the lower clamping cavity, a lower clamping driving cavity with a backward opening is arranged in the lower clamping block, a lower clamping motor is fixed in the upper end wall of the lower clamping driving cavity, the lower end of the lower clamping motor is dynamically connected with a lower clamping shaft, a lower clamping gear is fixed at the lower end of the lower clamping shaft, and a lower clamping rack fixed in the rear end wall of the lower clamping cavity is engaged at the rear side of the lower clamping gear, and a lower driven block which can be in close contact with the lower clamping block is fixed on the left side of the upper end face of the lower test block.

Preferably, the bonding device comprises a third shaft fixed at the left end of the third bevel gear, the left end of the third shaft extends into the spring cavity and is fixedly connected with an interruption block which is rotatably arranged in the spring cavity, the left end of the interruption block is rotatably provided with a cushion block which can slide left and right but cannot rotate, the left end of the interruption block extends into the interruption cavity and is in splined connection with a fifth shaft, an interruption electromagnet is fixed in the left end wall of the interruption cavity, the left end of the cushion block extends into the interruption cavity and can be adsorbed by the interruption electromagnet, a spring arranged on the cushion block is fixed in the left end wall of the spring cavity, the left end of the fifth shaft extends into the transfer cavity and is fixed with a fifth bevel gear, the upper end of the fifth bevel gear is meshed with a sixth bevel gear, and the upper end of the sixth bevel gear is fixed with a sixth shaft rotatably arranged in the upper end wall of the transfer cavity, the upper end of the sixth shaft extends into the driving cavity and is fixed with a first gear, the rear end of the first gear is engaged with a driving rack which is arranged in the rear end wall of the driving cavity in a sliding way, a semi-cylindrical processing block which is arranged in the driving cavity in a sliding manner is fixed at the right end of the driving rack, a left spray head surrounding the right end wall of the treatment block is arranged in the right end wall of the treatment block, the lower end wall of the storage cavity is connected with the left spray head through a transmission pipe, a fixed rod which is opposite to the processing block is fixed in the right end wall of the test cavity, a heating block is fixed at the left end of the fixed rod, a fixed block which can be spliced with the processing block into a cylinder is fixed at the left end of the heating block, and a right nozzle which can be spliced with the left nozzle to form an annular shape is arranged in the left end wall of the fixed block, and the right nozzle is connected with the storage cavity through the transmission pipe.

Preferably, the stretching device comprises an upper output shaft in power connection with the upper end of the main motor, a driving shaft which is rotatably arranged in the upper end wall of the output cavity and can be in spline connection with the upper output shaft is arranged above the upper output shaft, the upper end of the driving shaft extends into the belt wheel cavity and is fixedly provided with a driving belt wheel, a belt is arranged on the driving belt wheel, a driven belt wheel connected through the belt is arranged on the left side of the driving belt wheel, a screw rod which is rotatably arranged in the lower end wall of the belt wheel cavity is fixed at the lower end of the driven belt wheel, the lower end of the screw rod extends to the right side of the inner part of the screw rod cavity and is rotatably arranged in the lower end wall of the screw rod cavity, a lifting plate which is positioned in the screw rod cavity and can slide up and down is in threaded connection with the screw rod cavity, and a lifting rod, the lower extreme of lifter extends to test intracavity and be fixed with the test block, it presss from both sides tight chamber down and the opening is towards the last of left to be provided with the opening in the lower terminal surface of test block, it is provided with tight piece to go up to press from both sides the intracavity slip, it presss from both sides tight drive chamber to be provided with the opening towards the last of back in the tight piece to go up to press from both sides, the lower terminal wall internal fixation that goes up to press from both sides tight drive chamber has last clamping motor, the upper end power connection that goes up clamping motor has last tight axle of clamp, the upper end of going up tight axle of clamp is fixed with the tight gear of clamp, the rear side meshing of going up tight gear of clamp.

The beneficial effects are that: the processing block moves towards the right side, is spliced with the fixed block and tightly clamps the two metal wires, then the bonding material is sprayed to the fracture part of the metal wires, the fracture part is completely covered, then heating is carried out, and solidification of the bonding material is accelerated, so that the bonding process of each bonding operation can be ensured to be the same as much as possible, the probability of error occurrence of an experimental result caused by different bonding modes can be reduced, and the accuracy of the experiment is improved; if the torsion resistance is selected to be tested, the lower test block is rotated through the motor, the metal wire which is bonded completely is twisted, the torsion resistance of the material can be detected, if the tension resistance is selected to be detected, the metal wire which is bonded completely is stretched through the motor, and the tensile resistance of the material can be detected, so that two different test data can be detected on the same device, the clamping times of the test piece are reduced, the environments where the test piece is located are the same, the generation of unnecessary errors is reduced to a certain degree, and the accuracy of the test is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of a bonding material detection test apparatus according to the present invention;

FIG. 2 is an enlarged view of the upper block of FIG. 1;

FIG. 3 is an enlarged view of the lower block of FIG. 1.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-3, for the sake of convenience, the orientations described hereinafter being defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention discloses a detection test device for bonding materials, which comprises a machine body 10, wherein a test cavity 60 with a front opening is arranged in the machine body 10, a driving cavity 14 with a right opening is arranged in the middle of the left end wall of the test cavity 60, a storage cavity 11 with an upward opening is arranged above the driving cavity 14, a transfer cavity 20 is arranged below the driving cavity 14, a screw cavity 57 is arranged above the test cavity 60, a pulley cavity 54 is arranged on the right side above the screw cavity 57, an output cavity 37 positioned on the right side of the test cavity 60 is arranged below the pulley cavity 54, a stretching device is arranged in the output cavity 37, a reset cavity 40 with a left opening is arranged in the right end wall of the output cavity 37, a rotating cavity 23 is arranged below the test cavity 60, a gear cavity 78 positioned below the rotating cavity 23 is arranged on the left side of the output cavity 37, a rotating device is arranged in the gear cavity 78, a spring cavity 29 with a right opening is arranged in the left end wall of the gear cavity 78, a bonding device is arranged in the spring cavity 29, and an interrupted cavity 26 is arranged in the left end wall of the spring cavity 29.

Advantageously, the rotating device comprises a motor plate 42 slidably disposed in the output cavity 37, the right end of the motor plate 42 extends into the reset cavity 40, the upper end of the motor plate is provided with a reset spring 44 fixed in the upper end wall of the reset cavity 40, the lower end wall of the reset cavity 40 is internally fixed with a reset electromagnet 39, the motor plate 42 is internally fixed with a main motor 43, the lower end of the main motor 43 is in power connection with a lower output shaft 41, the lower end of the lower output shaft 41 is fixed with a first bevel gear 38, the left end of the first bevel gear 38 is engaged with a second bevel gear 36, the left end of the second bevel gear 36 is fixed with a second shaft 34 rotatably disposed in the left end wall of the output cavity 37, the left end of the second shaft 34 extends into the gear cavity 78 and is in splined connection with a middle shaft 32 capable of sliding left and right, the left end of the middle shaft 32 is fixed with a third, a fourth bevel gear 33 capable of being meshed is arranged above the third bevel gear 31, a fourth shaft 35 rotatably arranged in the upper end wall of the gear cavity 78 is fixed at the upper end of the fourth bevel gear 33, a second gear 47 is fixed in the rotating cavity 23 at the upper end of the fourth shaft 35, a rotating gear 24 is meshed at the left side of the second gear 47, the rotating gear 24 is fixed on the outer side wall of a lower test block 72 rotatably arranged in the lower end wall of the rotating cavity 23, a lower clamping cavity 69 with an upward opening is arranged at the right side of the upper end surface of the lower test block 72, a lower clamping block 77 is arranged in the lower clamping cavity 69 in a sliding manner, a lower clamping driving cavity 75 with a backward opening is arranged in the lower clamping block 77, a lower clamping motor 76 is fixed in the upper end wall of the lower clamping driving cavity 75, and a lower clamping shaft 74 is dynamically connected to the lower end of the lower clamping motor 76, a lower clamping gear 73 is fixed at the lower end of the lower clamping shaft 74, a lower clamping rack 71 fixed in the rear end wall of the lower clamping cavity 69 is meshed with the rear side of the lower clamping gear 73, and a lower driven block 70 capable of being in close contact with the lower clamping block 77 is fixed on the left side of the upper end face of the lower test block 72.

Advantageously, the bonding device comprises a third shaft 30 fixed at the left end of the third bevel gear 31, the left end of the third shaft 30 extends into the spring cavity 29 and is fixedly connected with a break block 28 rotatably arranged in the spring cavity 29, the left end of the break block 28 is rotatably provided with a cushion block 79 capable of sliding left and right but not rotating, the left end of the break block 28 extends into the break cavity 26 and is in splined connection with a fifth shaft 22, the left end wall of the break cavity 26 is internally fixed with a break electromagnet 25, the left end of the cushion block 79 extends into the break cavity 26 and can be adsorbed by the break electromagnet 25, the left end wall of the spring cavity 29 is internally fixed with a spring 27 mounted on the cushion block 79, the left end of the fifth shaft 22 extends into the transit cavity 20 and is fixed with a fifth bevel gear 21, the upper end of the fifth bevel gear 21 is engaged with a sixth bevel gear 19, a sixth shaft 16 rotatably disposed in the upper end wall of the intermediate chamber 20 is fixed to the upper end of the sixth bevel gear 19, the upper end of the sixth shaft 16 extends into the driving chamber 14 and is fixed with a first gear 13, a driving rack 15 slidably disposed in the rear end wall of the driving chamber 14 is engaged with the rear end of the first gear 13, a semi-cylindrical processing block 18 slidably disposed in the driving chamber 14 is fixed to the right end of the driving rack 15, a left nozzle 17 surrounding the right end wall of the processing block 18 is installed in the right end wall of the processing block 18, the lower end wall of the storage chamber 11 is connected to the left nozzle 17 through a transmission pipe 12, a fixing rod 49 disposed opposite to the processing block 18 is fixed to the right end wall of the test chamber 60, a heating block 51 is fixed to the left end of the fixing rod 49, and a fixing block 48 capable of being spliced with the processing block 18 into a cylinder is fixed to the left end of the heating block 51, a right nozzle 50 which can be spliced with the left nozzle 17 into a ring shape is arranged in the left end wall of the fixed block 48, and the right nozzle 50 is connected with the storage chamber 11 through the transmission pipe 12.

Beneficially, the stretching device includes an upper output shaft 45 in power connection with the upper end of the main motor 43, a driving shaft 46 rotatably disposed in the upper end wall of the output cavity 37 and capable of being in spline connection with the upper output shaft 45 is disposed above the upper output shaft 45, the upper end of the driving shaft 46 extends into the pulley cavity 54 and is fixed with a driving pulley 52, a belt 53 is mounted on the driving pulley 52, a driven pulley 55 connected through the belt 53 is disposed on the left side of the driving pulley 52, a screw 56 rotatably disposed in the lower end wall of the pulley cavity 54 is fixed to the lower end of the driven pulley 55, the lower end of the screw 56 extends to the right inside of the screw cavity 57 and is rotatably disposed in the lower end wall of the screw cavity 57, a lifting plate 58 located in the screw cavity 57 and capable of sliding up and down is connected to the screw 56 in a threaded manner, and a lifting rod 58 slidably disposed in the lower end wall of the screw cavity 57 is fixed to the left side of the lower end of the lifting plate 58 59, the lower extreme of lifter 59 extends to in the test chamber 60 and be fixed with test block 61, be provided with opening down and opening towards the upper clamping chamber 67 of left in going up test block 61's the lower terminal surface, it is provided with last clamp 63 to slide in the clamp chamber 67, it presss from both sides tight driving cavity 62 to be provided with the opening towards the back in the clamp block 63 on going up, it presss from both sides tight motor 66 to go up to press from both sides the lower extreme wall internal fixation of driving cavity 62 to press from both sides, the upper end power of going up clamp motor 66 is connected with and presss from both sides tight axle 65, the upper end of going up clamp axle 65 is fixed with and presss from both sides tight gear 64, the rear side meshing of going up clamp gear 64 is fixed go up and presss from both sides tight rack 68 in the upper clamping.

In the initial state, the upper clamping block 63 is located at the leftmost side of the upper clamping cavity 67, the lower clamping block 77 is located at the rightmost side of the lower clamping cavity 69, the processing block 18 is located in the driving cavity 14, the interrupting electromagnet 25 is energized, the spring 27 is compressed, the third bevel gear 31 is not engaged with the fourth bevel gear 33, the first bevel gear 38 is engaged with the second bevel gear 36, the upper output shaft 45 is not connected with the driving shaft 46, the return electromagnet 39 is energized, the return spring 44 is extended, and the lifting plate 58 is located at the lowermost end of the screw cavity 57.

At the beginning of the operation, a long wire is cut from the middle, and then clamped on the upper test block 61 and the lower test block 72, the upper clamping motor 66 is started, the upper clamping gear 64 is driven to rotate by the upper clamping shaft 65, so that the upper clamping block 63 is moved to the right by the action of the upper clamping rack 68 to clamp a wire, at the same time, the lower clamping motor 76 is started, the lower clamping gear 73 is driven to rotate by the lower clamping shaft 74, so that the lower clamping block 77 is moved leftwards by the action of the lower clamping rack 71 to clamp another wire, and finally the two broken wires can be tightly contacted, the main motor 43 is started, the lower output shaft 41 drives the first bevel gear 38 to rotate, thereby rotating the second bevel gear 36 and thereby rotating the intermediate shaft 32 via the second shaft 34. Thereby driving the third bevel gear 31 to rotate, thereby driving the break block 28 to rotate through the third shaft 30, further driving the fifth bevel gear 21 to rotate through the fifth shaft 22, thereby driving the sixth bevel gear 19 to rotate, further driving the first gear 13 to rotate through the sixth shaft 16, thereby moving the driving rack 15 to the right side, thereby moving the processing block 18 to the right side to splice with the fixed block 48 and tighten two wires, further positioning the broken portion of the wire between the left nozzle 17 and the right nozzle 50, then ejecting the bonding material in the storage cavity 11 to the broken portion of the wire through the transmission pipe 12 by the left nozzle 17 and the right nozzle 50, so that the broken portion is completely covered, then heating the heating block 51 to heat, accelerating the bonding material to solidify, and after the bonding is completed, the main motor 43 rotates reversely, returning the processing block 18 to the initial position, selecting the testing mode to be performed, and if the testing of the torsion resistance is selected, turning off the interrupted electromagnet 25, moving the cushion block 79 to the right side under the action of the spring 27, so that the interrupted block 28 moves the third bevel gear 31 to the right side through the third shaft 30, so that the third bevel gear 31 is engaged with the fourth bevel gear 33, so that the third bevel gear 31 drives the fourth bevel gear 33 to rotate, so that the fourth shaft 35 drives the second gear 47 to rotate, so that the rotary gear 24 is driven to rotate, so that the lower test block 72 rotates, so that the bonded metal wire is twisted, so that the torsion resistance of the material can be detected, and if the testing of the tension resistance is selected, turning off the reset electromagnet 39, so that the motor plate 42 moves upward under the action of the reset spring 44, the first bevel gear 38 and the second bevel gear 36 are disengaged, the upper output shaft 45 is in splined connection with the driving shaft 46, the main motor 43 drives the driving shaft 46 to rotate through the upper output shaft 45, so as to drive the driving pulley 52 to rotate, so as to drive the driven pulley 55 to rotate through the belt 53, so as to drive the screw 56 to rotate, so as to drive the lifting plate 58 to move upwards, so as to drive the upper test block 61 to move upwards through the lifting rod 59, so as to finally enable the bonded material to be stretched, so that the stretch-resistant performance of the material can be detected, after the experiment is finished, the upper clamping motor 66 and the lower clamping motor 76 are respectively started, so as to respectively enable the upper clamping block 63 and the lower clamping block 72 to recover the initial positions, and then the experimental material is taken out.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a bonding material's detection test device, includes organism, rotary device, bonding device, stretching device, its characterized in that: a test cavity with a forward opening is arranged in the machine body, a driving cavity with a right opening is arranged in the middle of the left end wall of the test cavity, a storage cavity with an upward opening is arranged above the driving cavity, a transfer cavity is arranged below the driving cavity, a screw cavity is arranged above the test cavity, a belt wheel cavity is arranged on the right side above the screw cavity, an output cavity positioned on the right side of the test cavity is arranged below the belt wheel cavity, a reset cavity with a leftward opening is arranged in the right end wall of the output cavity, a rotating cavity is arranged below the test cavity, a gear cavity positioned below the rotating cavity is arranged on the left side of the output cavity, a spring cavity with a rightward opening is arranged in the left end wall of the gear cavity, and a break cavity is arranged in the left end wall of the spring cavity; the rotating device comprises a motor plate arranged in the output cavity in a sliding manner, the right end of the motor plate extends into the reset cavity, the upper end of the motor plate is provided with a reset spring fixed in the upper end wall of the reset cavity, the lower end wall of the reset cavity is internally fixed with a reset electromagnet, the motor plate is internally fixed with a main motor, the lower end of the main motor is in power connection with a lower output shaft, the lower end of the lower output shaft is fixed with a first bevel gear, the left end of the first bevel gear is meshed with a second bevel gear, the left end of the second bevel gear is fixed with a second shaft rotatably arranged in the left end wall of the output cavity, the left end of the second shaft extends into the gear cavity and is in splined connection with an intermediate shaft capable of sliding left and right, the left end of the intermediate shaft is fixed with a third bevel gear, a fourth bevel gear capable of being meshed is arranged above the third bevel gear, and the upper end of the fourth bevel, the upper end of the fourth shaft extends into the rotating cavity and is fixed with a second gear; the rotating device further comprises a rotating gear meshed with the left side of the second gear, the rotating gear is fixed on the outer side wall of a lower test block rotatably arranged in the lower end wall of the rotating cavity, a lower clamping cavity with an upward opening is arranged on the right side of the upper end face of the lower test block, a lower clamping block is slidably arranged in the lower clamping cavity, a lower clamping driving cavity with a backward opening is arranged in the lower clamping block, a lower clamping motor is fixed in the upper end wall of the lower clamping driving cavity, the lower end of the lower clamping motor is in power connection with a lower clamping shaft, a lower clamping gear is fixed at the lower end of the lower clamping shaft, a lower clamping rack fixed in the rear end wall of the lower clamping cavity is meshed with the rear side of the lower clamping gear, and a lower driven block capable of being in close contact with the lower clamping block is fixed on the left side of the upper end face of the lower test block; the bonding device comprises a third shaft fixed at the left end of the third bevel gear, the left end of the third shaft extends into the spring cavity and is fixedly connected with an interruption block rotationally arranged in the spring cavity, the left end of the interruption block is rotatably provided with a cushion block which can slide left and right but can not rotate, the left end of the interruption block extends into the interruption cavity and is in splined connection with a fifth shaft, an interrupted electromagnet is fixed in the left end wall of the interrupted cavity, the left end of the cushion block extends into the interrupted cavity and can be adsorbed by the interrupted electromagnet, a spring arranged on the cushion block is fixed in the left end wall of the spring cavity, the left end of the fifth shaft extends into the transfer cavity and is fixed with a fifth bevel gear, a sixth bevel gear is meshed with the upper end of the fifth bevel gear, and a sixth shaft which is rotatably arranged in the upper end wall of the transfer cavity is fixed at the upper end of the sixth bevel gear; the bonding device also comprises a first gear which is fixed at the upper end of the sixth shaft and is positioned in the driving cavity, the rear end of the first gear is engaged with a driving rack which is arranged in the rear end wall of the driving cavity in a sliding way, a semi-cylindrical processing block which is arranged in the driving cavity in a sliding manner is fixed at the right end of the driving rack, a left spray head surrounding the right end wall of the treatment block is arranged in the right end wall of the treatment block, the lower end wall of the storage cavity is connected with the left spray head through a transmission pipe, a fixed rod which is opposite to the treatment block is fixed in the right end wall of the test cavity, a heating block is fixed at the left end of the fixed rod, a fixed block which can be spliced with the processing block into a cylinder is fixed at the left end of the heating block, a right nozzle which can be spliced with the left nozzle to form an annular shape is arranged in the left end wall of the fixed block, and the right nozzle is connected with the storage cavity through the transmission pipe; the stretching device comprises an upper output shaft in power connection with the upper end of the main motor, a driving shaft which is rotatably arranged in the upper end wall of the output cavity and can be in spline connection with the upper output shaft is arranged above the upper output shaft, the upper end of the driving shaft extends into the belt wheel cavity and is fixedly provided with a driving belt wheel, a belt is arranged on the driving belt wheel, a driven belt wheel connected through the belt is arranged on the left side of the driving belt wheel, a screw rod rotatably arranged in the lower end wall of the belt wheel cavity is fixed at the lower end of the driven belt wheel, the lower end of the screw rod extends to the right side of the inner part of the screw rod cavity and is rotatably arranged in the lower end wall of the screw rod cavity, a lifting plate which is positioned in the screw rod cavity and can slide up and down is in threaded connection with the screw rod, and a lifting rod which is, the lower extreme of lifter extends to test intracavity and be fixed with the test block, it presss from both sides tight chamber down and the opening is towards the last of left to be provided with the opening in the lower terminal surface of test block, it is provided with tight piece to go up to press from both sides the intracavity slip, it presss from both sides tight drive chamber to be provided with the opening towards the last of back in the tight piece to go up to press from both sides, the lower terminal wall internal fixation that goes up to press from both sides tight drive chamber has last clamping motor, the upper end power connection that goes up clamping motor has last tight axle of clamp, the upper end of going up tight axle of clamp is fixed with the tight gear of clamp, the rear side meshing of going up tight gear of clamp.