CN218995435U - Full-automatic on-line resistance testing mechanism for continuous coating production line - Google Patents

Abstract

The utility model discloses a full-automatic on-line resistance testing mechanism for a continuous coating production line, which comprises a frame, wherein a negative pressure platform for horizontally placing a workpiece to be tested, a negative pressure mechanism for forming negative pressure on the negative pressure platform to adsorb the workpiece to be tested, a turnover mechanism for switching the negative pressure platform between a horizontally placed state and a turned-up state, and a detection mechanism for detecting the workpiece to be tested on the negative pressure platform in the horizontally placed state are arranged on the frame. The negative pressure mechanism is used for forming negative pressure on the negative pressure platform to adsorb a workpiece to be detected, then the negative pressure platform is switched between a flat-lying state and a turned-up state through the turnover mechanism, switching of receiving and detecting stations is realized, and then the detecting mechanism is used for detecting the resistance value of the workpiece to be detected on the negative pressure platform in the flat-lying state, so that automatic detection of the resistance value of the workpiece to be detected is realized, and the operation is stable, the detection precision and the detection efficiency are high.

Description

Full-automatic on-line resistance testing mechanism for continuous coating production line

[ field of technology ]

The application relates to automatic production, in particular to a full-automatic on-line resistance testing mechanism for a continuous coating production line.

[ background Art ]

The resistance values of the conductive glass and the conductive sheet are core functional parameters of the product, the yield of the downstream product is determined, and the existing resistance value test has the problems of unstable operation, low measurement accuracy and low measurement efficiency through manual measurement.

[ utility model ]

In order to solve the technical problems of unstable operation, low measurement accuracy and low measurement efficiency of manually measuring the resistance value of a product, the purpose of the application is to provide a full-automatic online resistance testing mechanism for a continuous coating production line.

The application is realized by the following technical scheme:

the full-automatic on-line resistance testing mechanism for the continuous coating production line comprises a frame, wherein a negative pressure platform for horizontally placing a workpiece to be tested, a negative pressure mechanism for forming negative pressure on the negative pressure platform to adsorb the workpiece to be tested, a turnover mechanism for enabling the negative pressure platform to be switched between a horizontally placed state and a turned-up state, and a detection mechanism for detecting the workpiece to be tested on the negative pressure platform in the horizontally placed state are arranged on the frame.

The full-automatic on-line resistance testing mechanism for the continuous coating production line comprises a base arranged on the frame, a sliding seat capable of moving along the base to be close to or far away from the negative pressure platform, and a probe arranged on the sliding seat for detecting the resistance of the workpiece to be tested.

According to the full-automatic online resistance testing mechanism for the continuous coating production line, the movable arm capable of moving forwards and backwards along the rack is arranged on the rack, and the base is arranged on the movable arm and can move left and right along the movable arm.

According to the full-automatic on-line resistance testing mechanism for the continuous coating production line, one side of the negative pressure platform is hinged to the front end of the frame and can be turned around the hinge position of the negative pressure platform and the frame under the driving of the turning mechanism to be switched between a flat state and a turned-up state.

The full-automatic on-line resistance testing mechanism for the continuous coating production line comprises an air cylinder hinged at the rear end of the frame and a connecting seat hinged at the output end of the air cylinder, wherein the connecting seat is connected with the middle part of the negative pressure platform.

The negative pressure mechanism comprises the exhaust fan arranged on the frame, and the exhaust pipe connected with the exhaust fan and the negative pressure platform, wherein the exhaust pipe comprises a front pipe connected with the negative pressure platform, a rear pipe connected with the exhaust fan and a telescopic hose connected with the front pipe and the rear pipe, and the telescopic hose stretches when the negative pressure platform is switched between a flat state and a turned state.

The full-automatic on-line resistance testing mechanism for the continuous coating production line is characterized in that a plurality of mutually communicated air passages are formed in the negative pressure platform, a plurality of air suction holes communicated with the air passages are formed between the upper ends of the negative pressure platform, and air inlets communicated with the air passages are formed in the lower ends of the negative pressure platform.

According to the full-automatic on-line resistance testing mechanism for the continuous coating production line, the plurality of air inlets are arranged between the lower ends of the negative pressure platforms, the front pipe comprises the plurality of branch pipes connected with the air inlets respectively, and the main pipe communicated with the branch pipes, and the telescopic hose is connected to the main pipe.

According to the full-automatic on-line resistance testing mechanism for the continuous coating production line, the plurality of stop plates for limiting the workpiece to be tested to move away from the negative pressure platform are arranged between the negative pressure platforms.

According to the full-automatic on-line resistance testing mechanism for the continuous coating production line, the stop plates are respectively arranged on the front side edge and the right side edge of the negative pressure platform.

Compared with the prior art, the utility model has the following advantages:

according to the utility model, the negative pressure mechanism is used for forming negative pressure on the negative pressure platform to adsorb the workpiece to be detected, then the negative pressure platform is switched between a flat state and a turned-up state through the turnover mechanism, so that the switching of the material receiving and detecting stations is realized, and then the detecting mechanism is used for detecting the resistance value of the workpiece to be detected on the negative pressure platform in the flat state, so that the automatic detection of the resistance value of the workpiece to be detected is realized, and the operation is stable, the detecting precision and the detecting efficiency are high.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings that are required to be used in the description of the embodiments will be briefly described below.

FIG. 1 is a perspective view of a full-automatic on-line resistance testing mechanism (with a negative pressure platform in a turned-up state) for a continuous coating production line according to an embodiment of the present application;

FIG. 2 is a perspective view of a full-automatic on-line resistance testing mechanism (with a negative pressure platform in a flat state) for a continuous coating production line according to an embodiment of the present application;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a partial enlarged view at B in FIG. 2;

FIG. 5 is a side view of a fully automatic on-line resistance testing mechanism (with a negative pressure platform in a flat state) for a continuous coating production line according to an embodiment of the present application;

FIG. 6 is a cross-sectional view taken at C-C of FIG. 5;

FIG. 7 is a top view of a negative pressure stage in an embodiment of the present application;

fig. 8 is a bottom view of a negative pressure platform in an embodiment of the present application.

[ detailed description ] of the utility model

In order to make the technical problems, technical schemes and beneficial effects solved by the application more clear, the application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

Examples: as shown in fig. 1-8, the full-automatic on-line resistance testing mechanism for the continuous film plating production line comprises a frame 1, a negative pressure platform 2, a negative pressure mechanism 3, a turnover mechanism 4 and a detection mechanism 5, wherein the negative pressure platform 2 is arranged on the upper surface of the frame 1 for horizontally placing a workpiece to be tested, the negative pressure platform 2 is in a horizontally placing state and a turnover state, the negative pressure mechanism 3 is arranged on the frame 1 to enable the negative pressure platform 2 to form negative pressure to adsorb the workpiece to be tested, the turnover mechanism 4 is arranged on the frame 1 to enable the negative pressure platform 2 to be switched between the horizontally placing state and the turnover state, and the detection mechanism 5 is arranged on the frame 1 to detect the resistance value of the workpiece to be tested on the negative pressure platform 2 in the horizontally placing state. The full-automatic online resistance testing mechanism is located on a continuous coating production line, in an initial state, the negative pressure platform 2 is in a turned-up state, when a manipulator transfers a workpiece to be tested on the production line to the negative pressure platform 2, the negative pressure mechanism 3 enables the negative pressure platform 2 to form negative pressure to adsorb and fix the workpiece to be tested, then, the turnover mechanism 4 drives the negative pressure platform 2 to rotate so that the negative pressure platform 2 is switched from the turned-up state to a flat state, then, the detection mechanism 5 detects the resistance value of the workpiece to be tested on the negative pressure platform 2 in the flat state, after detection is completed, the manipulator moves the detected workpiece away from the negative pressure platform 2, and the turnover mechanism 4 drives the negative pressure platform 2 to rotate so that the negative pressure platform 2 is switched from the flat state to the turned-up state, so that circulation is realized. In summary, the full-automatic online resistance testing mechanism realizes automatic detection of the resistance value of the workpiece, and has stable operation, high detection precision and high detection efficiency.

Further, for simplifying the structure, the detecting mechanism 5 includes a base 51 disposed on the frame 1, a slide 52 capable of moving along the base 51 toward or away from the negative pressure platform 2, and a probe 53 disposed on the slide 52 for detecting the resistance value of the workpiece to be detected. Specifically, the number of the probes 53 is one or more.

Further, in order to improve the flexibility and the accuracy of the detection, the detection mechanism 5 is longitudinally moved and laterally moved, the frame 1 is provided with a movable arm 6 capable of moving back and forth along the movable arm, and the base 51 is provided on the movable arm 6 and is capable of moving left and right along the movable arm 6.

Further, in order to improve the stability of the rotation of the negative pressure platform 2, one side of the negative pressure platform 2 is hinged to the front end of the frame, and the negative pressure platform 2 can be turned around the hinge position of the negative pressure platform 2 and the frame 1 under the driving of the turning mechanism 4 to switch between a flat state and a turned-up state.

Further, for simplifying the structure and facilitating implementation, the turnover mechanism 4 comprises a cylinder 41 hinged at the rear end of the frame 1 and a connecting seat 42 hinged at the output end of the cylinder 41, and the connecting seat 42 is spirally connected to the middle part of the negative pressure platform 2.

Further, in order to simplify the structure and facilitate implementation, the negative pressure mechanism 3 includes an exhaust fan 31 disposed on the frame 1, and an exhaust fan 32 connected to the exhaust fan 31 and the negative pressure platform 2, and the exhaust fan 32 includes a front pipe 321 connected to the negative pressure platform 2, a rear pipe 322 connected to the exhaust fan 31, and a flexible pipe 323 connected to the front pipe 321 and the rear pipe 322, where the flexible pipe 323 stretches when the negative pressure platform 2 switches between a flat state and a turned state.

Further, in order to simplify the structure and facilitate implementation, a plurality of air passages (not shown) that are mutually communicated are formed in the negative pressure platform 2, a plurality of air suction holes 22 that are communicated with the air passages are formed between the upper ends of the negative pressure platform 2, and an air inlet hole 23 that is communicated with each air passage is formed at the lower end of the negative pressure platform 2.

Further, in order to improve the adsorption fastness of the workpiece to be tested, a plurality of air inlets 23 are disposed between the lower ends of the negative pressure platform 2, the front pipe 321 includes a plurality of branched pipes 324 respectively connected with the air inlets 23, and a main pipe 325 connected with the branched pipes 324, and the flexible hose 323 is connected to the main pipe 325.

Further, in order to prevent the workpiece to be measured from being separated from the negative pressure platform 2 when the negative pressure platform 2 rotates, a plurality of stop plates 7 for limiting the workpiece to be measured from moving away from the negative pressure platform 2 are arranged between the negative pressure platform 2, specifically, each stop plate 7 is separately arranged on the front side edge and the right side edge of the negative pressure platform 2, and the stop plates 7 are spirally connected to the negative pressure platform 2.

Further, the device also comprises a detection control system (not shown in the figure) arranged on one side of the frame 1, wherein the detection control system is used for receiving the resistance value detected by the detection mechanism 5 and sending out an alarm sound when the detected resistance value is abnormal, so that the screening of defective products, the automatic storage, analysis and tracing of detection data are realized, the intelligent degree is high, and the production management is convenient.

It should be understood that the terms "first," "second," and the like are used in this application to describe various information, but the information should not be limited to these terms, which are used only to distinguish one type of information from another. For example, a "first" message may also be referred to as a "second" message, and similarly, a "second" message may also be referred to as a "first" message, without departing from the scope of the present application. Furthermore, references to orientations or positional relationships by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are based on the orientations or positional relationships shown in the drawings, are merely for purposes of describing the present application and simplifying the description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be configured and operated in a particular orientation, and therefore are not to be construed as limiting the present application.

The foregoing description of one or more embodiments provided in connection with the specific disclosure is not intended to limit the practice of this application to such description. Any approximation, or substitution of techniques for the methods, structures, etc. of the present application or for the purposes of making a number of technological deductions based on the concepts of the present application should be considered as the scope of protection of the present application.

Claims (10)

1. The full-automatic on-line resistance testing mechanism for the continuous coating production line comprises a frame and is characterized in that a negative pressure platform for horizontally placing a workpiece to be tested, a negative pressure mechanism for forming negative pressure on the negative pressure platform to adsorb the workpiece to be tested, a turnover mechanism for enabling the negative pressure platform to be switched between a horizontally placed state and a turned-up state, and a detection mechanism for detecting the workpiece to be tested on the negative pressure platform in the horizontally placed state are arranged on the frame.

2. The fully automatic on-line resistance testing mechanism for a continuous coating production line according to claim 1, wherein the detection mechanism comprises a base arranged on the frame, a sliding seat capable of moving along the base to be close to or far away from the negative pressure platform, and a probe arranged on the sliding seat for detecting the resistance value of a workpiece to be detected.

3. The fully automatic on-line resistance testing mechanism for continuous coating production line according to claim 2, wherein the frame is provided with a movable arm capable of moving back and forth along the frame, and the base is arranged on the movable arm and can move left and right along the movable arm.

4. The fully automatic on-line resistance testing mechanism for a continuous coating production line according to claim 1, wherein one side of the negative pressure platform is hinged to the front end of the frame and can be turned around the hinge part of the negative pressure platform and the frame under the driving of the turning mechanism to switch between a flat state and a turned-up state.

5. The full-automatic on-line resistance testing mechanism for a continuous coating production line according to claim 4, wherein the turnover mechanism comprises a cylinder hinged at the rear end of the frame and a connecting seat hinged at the output end of the cylinder, and the connecting seat is connected to the middle part of the negative pressure platform.

6. The full-automatic on-line resistance testing mechanism for a continuous coating production line according to claim 1, wherein the negative pressure mechanism comprises an exhaust fan arranged on the frame, and an exhaust pipe connecting the exhaust fan and the negative pressure platform, the exhaust pipe comprises a front pipe connected to the negative pressure platform, a rear pipe connected to the exhaust fan, and a telescopic hose connecting the front pipe and the rear pipe, and the telescopic hose stretches when the negative pressure platform is switched between a flat state and a turned-up state.

7. The fully automatic on-line resistance testing mechanism for continuous coating production line according to claim 6, wherein a plurality of mutually communicated air passages are formed in the negative pressure platform, a plurality of air suction holes communicated with the air passages are formed between the upper ends of the negative pressure platform, and air inlets communicated with the air passages are formed in the lower ends of the negative pressure platform.

8. The fully automatic on-line resistance testing mechanism for a continuous coating production line according to claim 7, wherein a plurality of air inlets are arranged between the lower ends of the negative pressure platforms, the front pipe comprises a plurality of branch pipes respectively connected with the air inlets, and a main pipe communicated with the branch pipes, and the telescopic hose is connected to the main pipe.

9. The fully automatic on-line resistance testing mechanism for continuous coating production line according to claim 1, wherein a plurality of stop plates for limiting the workpiece to be tested to move away from the negative pressure platform are arranged between the negative pressure platform.

10. The fully automatic on-line resistance testing mechanism for a continuous coating line according to claim 9, wherein each of the stopper plates is provided separately on a front side edge and a right side edge of the negative pressure stage.

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