CN217947153U - Meshbelt button test machine - Google Patents

Abstract

The utility model belongs to the technical field of the button test, the meshbelt button test machine that provides, including quick-witted case, meshbelt conveying mechanism, detection stop gear, button in place snatch and drag mechanism and display mechanism. The mesh belt conveying mechanism is located in the case, arranged below the station operating platform and used for conveying mesh belt buttons along the mesh belt channel. The in-place detection limiting mechanism is arranged in the test station groove and used for detecting the woven belt button conveyed to the test station groove and limiting and fixing the woven belt button. The button snatchs to drag the mechanism setting on quick-witted case, is located test station groove one side for snatch the meshbelt button after spacing is fixed down, and go upward and drag the button on the meshbelt button and send in order to obtain dragging power signal. The display mechanism is in signal connection with the button grabbing and pulling mechanism and is used for receiving pulling force signals and displaying the stress state. Through above structure setting to realize the technological effect of automatic test meshbelt button fastness, effectively promote the efficiency of the fastness test of meshbelt button.

Description

Meshbelt button test machine

Technical Field

The utility model relates to a button test technical field especially relates to a meshbelt button test machine.

Background

Referring to fig. 1, the button made of woven tape includes woven tape and a plurality of buttons arranged at intervals. Wherein, the meshbelt is rectangular shape, including the meshbelt 01 that sets up the pin thread and the meshbelt 02 that sets up the box. The male buckle comprises a male buckle connecting part 03 and a male buckle cap 06, the male buckle connecting part and the male buckle cap are oppositely arranged and are respectively fixed on an upper woven belt surface and a lower woven belt surface of a woven belt provided with the male buckle. The box includes box connecting portion 04 and box buckle cap 05, and box connecting portion and box buckle cap set up relatively, fix respectively on the last braid face and the lower braid face of the meshbelt that sets up the box.

In production practice, in order to ensure the firmness of the fastening cap and the connecting part on the woven belt, the firmness test of the woven belt button is usually required. The cap and the connecting part are pulled respectively by utilizing the woven belt of the male buckle and the woven belt of the female buckle, for example, the male buckle connecting part and the male buckle cap which are fixed on the woven belt of the male buckle are pulled, and the recording buckle cap is pulled from the woven belt to drop the sustainable time and the borne maximum pulling force. In order to realize the test of the fastness of the woven tape button, the prior art mainly carries out manual pulling test and record through a simple recording tool and a tensiometer.

In the test is dragged to the manual work, the operator gets from the meshbelt button, utilizes the tensiometer to drag the button, and whole testing process will rely on the operation experience usually, wastes time and energy, and efficiency is on the low side.

In conclusion, the existing woven tape button firmness testing technology has the technical problem of low efficiency.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a following scheme.

A button webbing tester, comprising:

the machine box comprises a station operating platform and a test station slot; the test station groove is positioned on the station operating platform, a braid channel is arranged on the station operating platform along a straight line, and the braid channel penetrates through the test station groove;

the mesh belt conveying mechanism is positioned in the case, arranged below the station operating platform and used for conveying mesh belt buttons along the mesh belt channel;

the in-place detection limiting mechanism is arranged in the test station groove and used for detecting the braid buttons conveyed to the test station groove and limiting and fixing the braid buttons;

the button grabbing and pulling mechanism is arranged on the case, is positioned on one side of the test station groove, and is used for grabbing the braid buttons after limiting and fixing in a downward mode and pulling the buttons on the braid buttons in an upward mode to obtain a pulling force signal to send out;

and the display mechanism is in signal connection with the button grabbing and pulling mechanism and is used for receiving the pulling force signal and displaying the stress state.

In an improved mode, the chassis is of a rectangular structure.

Preferably, the in-place detection limiting mechanism comprises: the in-place detection assembly and the limiting assembly; the in-place detection assembly is arranged on the limiting assembly; the in-place detection assembly detects and conveys the braid button of the test station groove, and the limiting assembly limits and fixes the braid button in place.

Preferably, the spacing subassembly includes:

the lifting support part is arranged at the upper end of the case; the lifting support part carries out lifting movement, and supports the mesh belt button from the bottom surface of the mesh belt button when the lifting support part rises for a preset stroke;

the opening and closing pressing block is positioned above the lifting supporting part; the opening and closing pressing block is opened to form a testing gap, and part of the braid button is exposed out of the testing gap; the bottom surface of the opening and closing press block presses part of the mesh belt button down, and the mesh belt button is pressed by matching with the ascending supporting force of the lifting supporting part;

the anti-warping pressing block is arranged on one side of the opening and closing pressing block; the anti-warping pressing block compresses the opening-closing pressing block to prevent the lifting supporting part from jacking up the opening-closing pressing block.

Preferably, the button grabbing and pulling mechanism comprises:

the strut is arranged at the upper end of the case and positioned at one side of the test station groove, and the test station groove is arranged on the case;

the transmission mechanism is connected with the strut and used for providing lifting power;

the grabbing component is connected with the transmission mechanism; after the transmission mechanism drives the grabbing component to move downwards for a first stroke, the grabbing component moves downwards for a second stroke to the test station slot to grab the braid button; the grabbing component grabs the braid button and then rises to pull the braid button.

Preferably, the pillar includes a straight plate mounting surface on which the transmission mechanism is mounted in a vertical direction.

Preferably, the grabbing assembly comprises a main slide block and a first stroke lifting grabbing part; the back of the main sliding block is connected with the transmission mechanism in a sliding mode, and the front of the main sliding block is connected with the first stroke lifting and grabbing portion.

Preferably, the first stroke lifting grabbing part comprises a connecting plate and a second stroke grabbing part; the back of the connecting plate is connected with the front of the main sliding block, and the second stroke grabbing part is connected with the front of the connecting plate in a sliding mode.

Preferably, the second stroke catching portion includes a slave slider and a catching portion; the back surface of the slave sliding block is connected with the front surface of the connecting plate in a sliding mode, and the front surface of the slave sliding block is connected with the grabbing portion.

Preferably, the display mechanism includes a display, and the display is disposed on the chassis.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model provides a meshbelt button test machine, including quick-witted case, meshbelt conveying mechanism, detection stop gear, button in place snatch and drag mechanism and display mechanism. The machine case comprises a station operating platform and a test station groove, the test station groove is positioned on the station operating platform, a braid channel is arranged on the station operating platform along a straight line, and the braid channel penetrates through the test station groove. The mesh belt conveying mechanism is located in the case, arranged below the station operating platform and used for conveying mesh belt buttons along the mesh belt channel. The in-place detection limiting mechanism is arranged in a test station groove and used for detecting and conveying a braid button in the test station groove and limiting and fixing the braid button. The button snatchs to drag the mechanism setting on quick-witted case, is located test station groove one side for snatch spacing fixed meshbelt button down, and go upward and drag the button on the meshbelt button in order to obtain to drag the power signal and send. The display mechanism is in signal connection with the button grabbing and pulling mechanism and is used for receiving pulling force signals and displaying the stress state. Through above structure setting to can realize the technological effect of automatic test meshbelt button fastness, effectively promote the efficiency of the fastness test of meshbelt button.

Drawings

FIG. 1 is a structural view of a button of a woven tape in the prior art;

FIG. 2 is a first schematic view of a woven button tester;

FIG. 3 is a schematic view showing a part of a woven tape button testing machine;

FIG. 4 is a second schematic view of a part of a woven button tester;

FIG. 5 is a third schematic view of a part of a woven button tester;

FIG. 6 is a schematic view of a part of the structure of a woven tape button testing machine;

FIG. 7 is a schematic view showing a part of the structure of a woven tape button testing machine;

FIG. 8 is a schematic view showing a part of a woven tape button testing machine;

FIG. 9 is a seventh schematic view of a part of the woven button testing machine;

fig. 10 is a schematic view eight of a partial structure of the woven tape button testing machine;

FIG. 11 is a schematic view nine of a partial structure of a woven tape button testing machine;

fig. 12 is a partial structural schematic view ten of the woven tape button testing machine.

Description of the drawings:

400. a station operating platform;

6000. an in-place detection limiting mechanism; 7000. a mesh belt conveying mechanism; 8000. a button grabbing and pulling mechanism; 9000. a display mechanism; 6001. an in-place detection assembly; 6002. a limiting component;

601. a lifting detection part; 603. a chassis; 604. testing a station groove; 605. mounting grooves; 606. a support plane; 607. sensing a contact position; 608. a semi-cylindrical groove; 609. a semicircular bottom; 610. a bevel groove; 611. a rectangular block; 612. a force transfer lever; 613. a limiting hole;

700. a lifting support; 701. opening and closing a pressing block; 702. anti-warping pressing blocks; 703. testing a gap; 704. pressing the left block; 705. a right pressing block; 706. a first press block mounting groove; 707. a first pressing block; 708. a first power mechanism; 709. a second press block mounting groove; 710. a second pressing block; 711. and a second power mechanism.

800. A support post; 801. a transmission mechanism; 802. a grasping assembly; 803. a straight plate mounting surface; 804. a main slider; 805. a first stroke lifting grabbing part; 806. a connecting plate; 807. a second stroke catching part; 808. a slave slider; 809. a grasping section; 810. grabbing a control head; 811. grabbing fingers; 812. a finger root; 813. a finger; 814. a finger; 815. and (6) grasping the ring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein.

It should be understood that, in the various embodiments of the present invention, the sequence numbers of the processes do not mean the sequence of the execution sequence, and the execution sequence of the processes should be determined by the functions and the inherent logic thereof, and should not constitute any limitation to the implementation process of the embodiments of the present invention.

It should be understood that in the present application, "comprising" and "having" and any variations thereof, is intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that, in the present invention, "a plurality" means two or more. "and/or" is merely an association describing an associated object, meaning that three relationships may exist, for example, and/or B, may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship. "comprising a, B and C", "comprising a, B, C" means that all three of a, B, C are comprised, "comprising a, B or C" means comprising one of a, B, C, "comprising a, B and/or C" means comprising any 1 or any 2 or 3 of a, B, C.

The technical solution of the present invention will be described in detail with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments.

Example one

Referring to fig. 2 to 12, the present embodiment provides a woven tape button testing machine, including:

a chassis 603 including a station console 400 and a test station slot 604; the testing station groove 604 is positioned on the station operating table 400, a braid channel is arranged on the station operating table 400 along a straight line, and the braid channel penetrates through the testing station groove 604;

the mesh belt conveying mechanism 7000 is located in the case 603, is arranged below the station operating platform 400, and is used for conveying mesh belt buttons along the mesh belt channel;

the in-place detection limiting mechanism 6000 is arranged in the test station groove 604 and used for detecting the braid buttons conveyed to the test station groove 604 and limiting and fixing the braid buttons;

the button grabbing and pulling mechanism 8000 is arranged on the case 603, is positioned on one side of the testing station groove 604, and is used for grabbing the braid buttons after limiting and fixing in a descending manner and pulling the buttons on the braid buttons in an ascending manner to obtain pulling force signals to send out;

and the display mechanism 9000 is in signal connection with the button grabbing and pulling mechanism 8000 and is used for receiving the pulling force signal and displaying the stress state.

It should be noted that, in this embodiment, the case 603 is used to perform station operation, and specifically, the station operating platform 400 and the test station groove 604 may be provided, the test station groove 604 is located on the station operating platform 400, a braid channel is arranged on the station operating platform 400 along a straight line, and the braid channel passes through the test station groove 604, so that the strip-shaped braid button can be automatically transported on the case 603, and the firmness of the button can be tested. Specifically, the chassis 603 may be configured in a rectangular structure.

It should be further noted that the webbing conveying mechanism 7000, located in the case 603, is disposed below the station operating platform 400, and is configured to convey the webbing button along the webbing channel, so as to cooperate with the webbing channel to automatically convey the strip-shaped webbing button. The webbing conveying mechanism 7000 can be implemented by adopting conventional technical means such as a belt transmission mechanism in the prior art, and is not described herein again.

It should be further noted that the in-place detection limiting mechanism 6000 detects the braid button conveyed to the test station slot 604, and then limits and fixes the braid button, so that the button grabbing and pulling mechanism 8000 can grab and pull the braid button.

What still need explain is that the button snatchs and drags mechanism 8000 down and snatchs the meshbelt button after spacing is fixed to it drags the button on the meshbelt button in order to obtain to drag power signal and send to go up, thereby realizes button fastness information acquisition.

It should be further noted that the display mechanism 9000 is in signal connection with the button grabbing and pulling mechanism 8000, and is configured to receive a pulling force signal to display a stress state, so as to conveniently control the quality of the woven button. For example, the maximum stress or the continuous stress of the woven belt button when being pulled can be known.

In one particular example, the display mechanism 9000 comprises a display disposed on the chassis 603.

It should be further noted that, in the woven tape button testing machine provided in this embodiment, the woven tape conveying mechanism 7000 is located in the case 603, and is disposed below the station operating platform 400, and is used for conveying the woven tape button along the woven tape channel. The in-place detection limiting mechanism 6000 is arranged in the testing station groove 604 and used for detecting the woven belt button conveyed to the testing station groove 604 and limiting and fixing the woven belt button. The button snatchs and pulls mechanism 8000 setting on quick-witted case 603, is located test station groove 604 one side for snatch spacing fixed meshbelt button down, and go up and pull the button on the meshbelt button and send in order to obtain pulling the power signal. And the display mechanism 9000 is in signal connection with the button grabbing and pulling mechanism 8000 and is used for receiving a pulling force signal and displaying the stress state. Through above structure setting to realize the technological effect of automatic test meshbelt button fastness, effectively promote the efficiency of the fastness test of meshbelt button.

Example two

Referring to fig. 2 to 12, on the basis of the above embodiments, in the present embodiment, an in-place detection limiting mechanism 6000 is provided, which includes: an in-place detection assembly 6001 and a limiting assembly 6002; the in-place detection assembly 6001 is arranged on the limiting assembly 6002; the detection subassembly 6001 that targets in place detects the meshbelt button of carrying the test station groove 604, and the spacing subassembly 6002 is to the meshbelt button that targets in place carry out spacing fixed.

In a preferred embodiment, the stop assembly 6002 includes:

a lifting support 700 provided at the upper end of the cabinet 603; the lifting support part 700 performs lifting movement, and supports the braid button from the bottom surface thereof when the lifting support part ascends for a preset stroke;

an opening and closing pressing block 701 located above the lifting support 700; the opening and closing pressing block 701 is opened to form a testing gap 703, and the braid button is exposed out of the testing gap 703; the bottom surface of the opening and closing press block 701 presses part of the braid button downwards, and the braid button is pressed by matching with the ascending supporting force of the ascending and descending supporting part 700;

the anti-warping pressing block 702 is arranged on one side of the opening and closing pressing block 701; the anti-tilting pressing block 702 presses the opening and closing pressing block 701 to prevent the opening and closing pressing block 701 from being tilted upward by the lifting and lowering support 700.

On the other hand, the lifting support 700 needs to be described below.

First, the elevation supporting part 700 is a structure capable of performing an elevation movement.

Secondly, when the stroke was preset in the rising to lift supporting part 700, can support the meshbelt button from the bottom surface of meshbelt button, realize carrying out spacing technological effect to the meshbelt button from the bottom.

It can be understood that because the meshbelt in the meshbelt button is flexible object, if do not have the holding power of bottom surface, the meshbelt takes place down couch easily or unsmooth, causes the difficult normal clear of subsequent handling.

On the other hand, the openable and closable block 701 needs to be described below.

First, the opening/closing pressure block 701 has an opening/closing function.

Secondly, the opening and closing pressing block 701 is located above the lifting support part 700, the lifting support part 700 is shielded when the lifting support part is closed, a test gap 703 is formed when the lifting support part is opened, and part of the mesh belt button is exposed out of the test gap 703.

Finally, the bottom surface of the opening and closing pressing block 701 presses part of the braid button downwards, the braid is limited from top to bottom, and uneven fluctuation of the braid is avoided. Meanwhile, the ascending supporting force of the ascending and descending supporting part 700 presses the mesh belt button and also pushes up the bottom surface of the opening and closing press block 701, so that the technical effects of pressing the mesh belt up and down and limiting the mesh belt are achieved.

In a preferred example, the switching compact 701 includes a left compact 704 and a right compact 705; the left pressing block 704 is positioned on the left side above the lifting support part 700, and the right pressing block 705 is positioned on the right side above the lifting support part 700; the left pressing block 704 and the right pressing block 705 cover the lifting support part 700 when closed, and a test gap 703 is formed when opened to expose part of the mesh belt button. Specifically, the left pressing block 704 and the right pressing block 705 are closed when moving towards each other, and are opened when moving in the opposite direction.

It should be noted that the test slit 703 exposes a part of the braid button, which includes a button to be subjected to a firmness test. The test gap 703 is used to allow the grabbing mechanism above the chassis to extend into the gap to grab the button to be tested for firmness.

It should be further noted that the left pressing block 704 and the right pressing block 705 may be connected to a power structure such as a motor or an air cylinder in the prior art, so as to control the left pressing block 704 and the right pressing block 705 to move in opposite directions or in opposite directions.

Note that the left presser block 704 and the right presser block 705 are covered above the elevation support part 700, which means that the elevation support part 700 is shielded from above when the left presser block 704 and the right presser block 705 are closed integrally.

On the other hand, the warping prevention compact 702 needs to be explained as follows.

First, the anti-tilting pressing block 702 serves to prevent the opening/closing pressing block 701 from tilting or deforming when the lifting/lowering support 700 pushes the opening/closing pressing block 701 upward, thereby reducing the limiting effect.

Secondly, in order to realize the anti-warping effect of the anti-warping pressing block 702, the anti-warping pressing block 702 is arranged on one side of the opening and closing pressing block 701, so that the anti-warping pressing block 702 is pressed against the opening and closing pressing block 701, and the lifting and lowering support part 700 is prevented from jacking up the opening and closing pressing block 701. The anti-warping pressing block 702 arranged on one side of the opening and closing pressing block 701 may mean that the anti-warping pressing block 702 is arranged on one side of the upper surface of the opening and closing pressing block 701, so that the anti-warping pressing block 702 can press the opening and closing pressing block 701 by pressing down, and the lifting support 700 is prevented from lifting the opening and closing pressing block 701 upwards.

In a preferred example, one side of the left pressing block 704 is provided with a first pressing block installation groove 706; the warp prevention compact 702 includes a first compact 707; a first pressing block 707 is installed on the first pressing block installation groove 706, and is connected with a first power mechanism 708 arranged on the case 603; the first power mechanism 708 is located on one side of the first presser block 707.

In a preferred example, one side of the right pressing block 705 is provided with a second pressing block installation groove 709; the warping prevention compact 702 includes a second compact 710; the second pressing block 710 is installed on the second pressing block installation groove 709 and connected with a second power mechanism 711 arranged on the case 603; the second power mechanism 711 is located at one side of the second pressing block 710.

In a preferred embodiment, the in-place detection assembly 6001 includes:

an elevation sensing part 601 installed at the top end of the elevation supporting part 700; when the button cap of the mesh belt button reaches the top end of the lifting detection part 601 and presses the lifting detection part 601, the lifting detection part 601 downwards transmits a pressure signal;

the control part sends a rising control signal and a mesh belt transmission pause signal after receiving the pressure signal; the elevation supporting part 700 receives an elevation control signal to upwardly move the support webbing, and the elevation detecting part 601 receives an elevation control signal to upwardly move the support buckle cap; the webbing transmission suspension signal is received by the webbing conveying mechanism 7000 and then suspends the driving of the movement of the webbing.

On the other hand, the following description is necessary for the elevation detection unit 601.

It can be understood that the elevation detection part 601 is installed on the top end of the elevation supporting part 700, so that the elevation detection part 601 and the elevation supporting part 700 can form a mechanism integrally, the structure is compact, and the installation space is saved.

When the button cap of the button webbing reaches the tip end depression/elevation detection section 601 of the elevation detection section 601, the elevation detection section 601 transmits a pressure signal downward, and can specify information that the button cap has reached the test station.

In a preferred example, a vertical installation groove 605 is formed at the top end of the elevation supporting part 700, and the elevation sensing part 601 is installed in the installation groove 605 to be independently elevated in the installation groove 605.

It should be noted that the mounting groove 605 is disposed at the top end of the elevation supporting part 700 for mounting the elevation detecting part 601, so that the elevation detecting part 601 can independently ascend and descend in the mounting groove 605, the structure is compact, and the mounting space is saved.

In a preferred example, the elevation support part 700 includes a support plane 606, and the support plane 606 supports the webbing after the elevation support part 700 is elevated.

It should be noted that, the webbing has flexibility, and the portion of the lifting support portion 700 for supporting the webbing is set as the support plane 606, so that the technical effects of full contact and gapless support can be achieved.

In a preferred embodiment, the lifting detection part 601 comprises a sensing contact position 607, and the sensing contact position 607 is arranged at the top end of the lifting detection part 601; when the button cap of the button with webbing reaches the sensing contact position 607 and presses the sensing contact position 607, the elevation detection portion 601 transfers a pressure signal downward.

The top end of the lifting detection part 601 is provided with a sensing contact position 607 for contacting the snap cap to perform sensing transmission of force, so that the lifting detection part 601 transmits a pressure signal downwards.

In a preferred embodiment, the inductive contact portion 607 includes a semi-cylindrical recess 608, the bottom surface of the semi-cylindrical recess 608 is a semi-circular bottom 609, and the semi-circular bottom 609 contacts the snap cap to receive the depression of the snap cap.

It should be noted that both the semi-cylindrical groove 608 and the semi-cylindrical bottom 609 can be adapted to the shape of the snap cap, so that when the snap cap presses the inductive contact portion 607, the lifting detection portion 601 receives downward pressure and transmits a pressure signal downward.

In a modified embodiment, the inductive contact 607 further includes a chamfered groove 610; the top of the chute 610 is connected to the semi-circular bottom 609 of the semi-cylindrical groove 608, and the semi-circular bottom 609 contacts the buckle cap where the webbing falls off, so that the center of gravity of the buckle cap is biased toward the chute 610.

It should be noted that the semi-cylindrical groove 608 is connected with the inclined-edge groove 610, the bottom surface of the semi-cylindrical groove 608 is a semi-cylindrical bottom 609, the shape of the buckle cap is circular, and after the circular buckle cap falls off the semi-cylindrical bottom 609, the gravity center of the buckle cap is deviated to the inclined-edge groove 610, so that the buckle cap on the sensing contact position 607 continues to move after contacting the sensing contact position 607, and the buckle cap moves and falls under the action of gravity instead of staying at the sensing contact position 607.

It should be noted that, in the present modified embodiment, the semicircular bottom 609 of the semi-cylindrical groove 608 is used to cooperate with the bevel edge groove 610, so as to facilitate the recovery of the fallen buckle cap in the subsequent process after the buckle cap falls off.

Illustratively, the lifting detection part 601 comprises a rectangular block 611, and the inductive contact position 607 is arranged in the middle of the top end of the rectangular block 611.

In one embodiment, the lifting detection portion 601 further includes a force transmission rod 612, and the force transmission rod 612 is disposed at the bottom end of the rectangular block 611. The bottom of the mounting groove 605 is provided with a limiting hole 613, and the force transmission rod 612 passes through the limiting hole 613.

On the other hand, the control unit needs to be described below.

The control part sends out rising control signal and meshbelt transmission pause signal after receiving the pressure signal, the lift supporting part 700 receives rising control signal and supports the meshbelt with the upward movement, the lift detection portion 601 receives rising control signal and supports the buckle cap with the upward movement, meshbelt transmission pause signal is received by meshbelt conveyor 7000 back pause drive meshbelt motion, thereby realize when meshbelt button targets in place, pause meshbelt motion and upwards support meshbelt and button, with cooperation next process, reach the technological effect who promotes meshbelt button test machine degree of automation.

It should be noted that the receiving of the pressure signal and the sending of the rising control signal and the webbing transmission pause signal by the control portion may be implemented by a hardware circuit or a module in the prior art, and those skilled in the art are familiar with the implementation manner thereof, and the description of this embodiment is omitted.

It should be noted that the webbing conveying mechanism 7000 is used as a control object of the control unit, and can transmit the webbing by using a transmission method such as a crawler belt, a belt, etc. in a conventional method, and this mechanism is not the invention of the present invention, and those skilled in the art know how to implement this mechanism, and it is not described here.

It should be further noted that the mechanisms such as the lifting support 700 and the lifting detection portion 601 may receive signals and provide power by using conventional means such as a servo motor, so as to drive the lifting support 700 and the lifting detection portion 601, and those skilled in the art know the principle and implementation thereof, and are not described herein again.

EXAMPLE III

Referring to fig. 2-12, in the present embodiment, based on the above embodiments, there is provided a button grabbing and pulling mechanism 8000, including:

the strut 800 is arranged at the upper end of the case 603 and is positioned at one side of the test station slot 604, and the test station slot 604 is arranged on the case 603;

the transmission mechanism 801 is connected with the strut 800 and is used for providing lifting power;

the grabbing component 802 is connected with the transmission mechanism 801; after the transmission mechanism 801 drives the grabbing component 802 to move downwards for a first stroke, the grabbing component 802 moves downwards for a second stroke to the test station slot 604 to grab the webbing button.

On the other hand, the support column 800 needs to be explained as follows.

First, the pillar 800 is disposed at the upper end of the case 603, so as to provide the grabbing component 802 on the pillar 800, so that the grabbing component 802 can move up and down in the vertical direction to grab the webbing button of the test station slot 604 on the case 603. With such a structure, the support 800 and the housing 603 can be integrally mounted, and a compact tester can be obtained.

Secondly, the manner of disposing the test station slot 604 on the chassis 603 may be various, in this embodiment, the test station slot 604 is preferably disposed on the upper surface of the chassis 603, and further, the test station slot 604 is disposed in the middle of the upper surface of the chassis 603. Wherein, test station groove 604 needs to set up in the below of pillar 800 one side, makes things convenient for subassembly 802 that snatchs on the pillar 800 to move up and down in vertical direction, snatchs the meshbelt button of test station groove 604.

Finally, the part of the braid button to be grabbed is on the testing station slot 604, and waits for the grabbing component 802 to grab. How to transport the part of the braid button that needs to be grabbed to the testing station slot 604 and how to fix the part on the testing station slot 604 is not a technical problem to be solved by the embodiment, and is not described herein again.

In a preferred example, the pillar 800 includes a straight plate mounting surface 803, and the transmission mechanism 801 is mounted on the straight plate mounting surface 803 in a vertical direction.

It should be noted that the straight mounting surface 803 may provide a flat and spacious mounting position, which facilitates the assembly of the transmission mechanism 801. The transmission mechanism 801 is installed along the vertical direction, so that large stroke selection is provided in the vertical direction, and lifting control is facilitated.

On the other hand, the transmission mechanism 801 needs to be described below.

First, the transmission mechanism 801 is provided on the column 800 and connected to the column 800.

Secondly, the transmission 801 is used to provide lifting power, and the purpose of the transmission is to drive the grabbing component 802 to move up and down. It should be understood that the transmission mechanism 801 may be a servo motor module, a conveyor belt module, or any other conventional technical means, which will not be described herein.

In one aspect, the grasping element 802 is described as follows.

First, the primary function of the grabbing assembly 802 is to grab the strap button.

Further, snatch subassembly 802 and can also be used for dragging the meshbelt button, specifically, snatch subassembly 802 and rise after snatching the meshbelt button, can drag the meshbelt button.

Secondly, the grabbing component 802 is connected with a transmission mechanism 801, and the transmission mechanism 801 can provide lifting power for the grabbing component 802. It is noted that the purpose of the lifting of the grabbing component 802 is to efficiently and automatically grab the strap button, and for this purpose, the grabbing component 802 needs to be distinguished in the lifting stroke.

Specifically, the gripper assembly 802 travels down a first stroke, and may reach the set height quickly. The grabbing component 802 descends for a second stroke, can accurately reach the position above the braid button, and grabs the braid button in the test station groove 604. It should be noted that, because the part of the braid button to be grabbed has a small volume and a high requirement on precision, the speed of the grabbing component 802 descending the second stroke can be slower than the speed of descending the first stroke, thereby achieving the technical effect of fine adjustment of the descending position.

In a preferred example, the grasping assembly 802 includes a main slide 804 and a first stroke lift grasping portion 805; the back of the main sliding block 804 is connected with the transmission mechanism 801 in a sliding manner, and the front of the main sliding block 804 is connected with the first stroke lifting and grabbing part 805.

In a preferred example, the first stroke lifter grip 805 includes a connecting plate 806 and a second stroke grip 807; the back of the connecting plate 806 is connected to the front of the main slider 804, and the second stroke catching portion 807 is slidably connected to the front of the connecting plate 806.

In a preferred example, the second stroke grip 807 includes a slave slide 808 and a grip 809; the slider 808 is slidably connected to the front surface of the connecting plate 806 from the rear surface thereof, and the slider 808 is connected to the grasping portion 809 from the front surface thereof.

It should be noted that the grabbing part 809 can be driven by the slider 808 to move up and down, so as to fine adjust the downward position of the grabbing part 809, and achieve the technical effect of accurately grabbing the button.

In a preferred example, the grasping section 809 includes a grasping control head 810 and grasping fingers 811; the grabbing control head 810 is connected with the front surface of the slave sliding block 808; the grabbing fingers 811 are located at the lower end of the grabbing control head 810 and are movably connected with the grabbing control head 810.

It should be noted that the grabbing fingers 811 are located at the lower end of the grabbing control head 810 and movably connected to the grabbing control head 810, so that the grabbing control head 810 can control the grabbing fingers 811 to gather to grab in the middle or release to the periphery.

In a preferred example, the gripping fingers 811 are a plurality of gripping fingers 811; a plurality of gripping fingers 811 form a loop along the lower end of the gripping control head 810. Specifically, gripping fingers 811 include a finger base 812, a finger stem 813, and a finger head 814; the finger root 812 is connected with the finger rod 813 at an obtuse angle; finger 814 is disposed at the lower end of finger 813 in line with the direction of extension of finger 813.

It should be noted that, the plurality of gripping fingers 811 form a circle along the lower end of the gripping control head 810, and when gathering to the middle to grip the braid button, the braid button can be gripped more firmly. In addition, the finger root 812 is connected with the finger rod 813 at an obtuse angle, so that the grabbing finger 811 can approach to the middle part, and grabbing control is facilitated.

In a preferred example, the lower end of the fingers 814 is provided with a gripping ring 815, the gripping ring 815 being arranged in a vertical direction. It should be noted that the lower end of the finger 814 is provided with the grabbing ring 815, and the grabbing ring 815 is arranged along the vertical direction, so that the grabbing ring 815 can be adapted to a circular button structure, and accurate grabbing is realized.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. The utility model provides a meshbelt button test machine which characterized in that includes:

the machine case comprises a station operating platform and a test station slot; the test station groove is positioned on the station operating table, a braid channel is arranged on the station operating table along a straight line, and the braid channel penetrates through the test station groove;

the mesh belt conveying mechanism is positioned in the case, arranged below the station operating platform and used for conveying mesh belt buttons along the mesh belt channel;

the in-place detection limiting mechanism is arranged in the test station groove and used for detecting the braid buttons conveyed to the test station groove and limiting and fixing the braid buttons;

the button grabbing and pulling mechanism is arranged on the case, is positioned on one side of the testing station groove, and is used for grabbing the braid buttons which are fixed in a limiting mode in a descending mode and pulling the buttons on the braid buttons in an ascending mode to obtain a pulling force signal to send out;

and the display mechanism is in signal connection with the button grabbing and pulling mechanism and is used for receiving the pulling force signal and displaying the stress state.

2. The button webbing tester as claimed in claim 1, wherein the housing is of a rectangular configuration.

3. The woven tape button testing machine as claimed in claim 1, wherein the in-place detection limiting mechanism comprises: the in-place detection assembly and the limiting assembly; the in-place detection assembly is arranged on the limiting assembly; the in-place detection assembly detects and conveys the mesh belt button of the test station groove, and the limiting assembly is used for limiting and fixing the mesh belt button in place.

4. The button webbing tester as claimed in claim 3, wherein the position limiting assembly comprises:

the lifting support part is arranged at the upper end of the case; the lifting support part carries out lifting movement, and supports the braid button from the bottom surface of the braid button when the lifting support part rises for a preset stroke;

the opening and closing pressing block is positioned above the lifting and supporting part; the opening and closing pressing block is opened to form a test gap, and part of the braid button is exposed out of the test gap; the bottom surface of the opening and closing press block presses part of the braid button down, and the braid button is pressed by matching with the ascending supporting force of the lifting supporting part;

the anti-warping pressing block is arranged on one side of the opening and closing pressing block; the anti-warping pressing block compresses the opening-closing pressing block to prevent the lifting supporting part from jacking up the opening-closing pressing block.

5. The woven tape button testing machine as claimed in claim 1, wherein said button grabbing and pulling mechanism comprises:

the strut is arranged at the upper end of the case and positioned at one side of the test station groove, and the test station groove is arranged on the case;

the transmission mechanism is connected with the strut and used for providing lifting power;

the grabbing component is connected with the transmission mechanism; after the transmission mechanism drives the grabbing component to move downwards for a first stroke, the grabbing component moves downwards for a second stroke to the test station slot to grab the braid button; the grabbing component grabs the braid button and then rises to pull the braid button.

6. The woven tape button testing machine as claimed in claim 5, wherein said post includes a bar mounting surface, said bar mounting surface having said actuator mounted thereon in a vertical orientation.

7. The button webbing tester as claimed in claim 5, wherein the gripping assembly includes a main slider and a first stroke elevation gripping portion; the back of the main sliding block is connected with the transmission mechanism in a sliding mode, and the front of the main sliding block is connected with the first stroke lifting grabbing portion.

8. The woven tape button testing machine as claimed in claim 7, wherein said first stroke elevating gripping portion includes a connecting plate and a second stroke gripping portion; the back of the connecting plate is connected with the front of the main sliding block, and the second stroke grabbing part is connected with the front of the connecting plate in a sliding mode.

9. The button webbing tester as claimed in claim 8, wherein the second stroke gripping portion includes a slave slide and a gripping portion; the back surface of the slave sliding block is connected with the front surface of the connecting plate in a sliding mode, and the front surface of the slave sliding block is connected with the grabbing portion.

10. The button webbing tester according to any one of claims 1-9, wherein the display mechanism includes a display, the display being disposed on the case.

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