CN216348476U - Sample thickness inspection device for glass material coating - Google Patents

Abstract

The utility model provides a sample thickness inspection device for glass material coating. The glass material sample thickness inspection device for coating film includes: the mounting structure comprises a mounting frame, a first mounting assembly and a second mounting assembly, wherein the first mounting assembly and the second mounting assembly are respectively mounted inside the mounting frame, and the first mounting assembly comprises a pressure sensor and a connecting plate. The sample thickness inspection device for glass material coating provided by the utility model is provided with the first mounting assembly and the second mounting assembly which are respectively provided with the pressure sensors, so that the compression degrees of the two groups of compression structures can be conveniently monitored, the compression degrees are used for controlling the compression clamping force of a sample before coating and a sample after coating to be the same, the second compression plate can synchronously drive the detection rod to move in the process of adjusting the compression degree of the second compression plate on the sample before coating by the second telescopic rod, and when the compression clamping force of the sample before coating and the sample after coating is the same, the moving range of the detection rod is the total coating thickness value of the sample after coating.

Description

Sample thickness inspection device for glass material coating

Technical Field

The utility model relates to the technical field of glass material coating processing equipment, in particular to a sample thickness inspection device for glass material coating.

Background

The performance that glass material itself appeared is mostly rigidity, breakable, easily wearing and tearing, and when practical application, need carry out finish machining and coating film processing to glass material according to the environment of using to increase glass material to installation environment and service environment's adaptability.

When the glass material is coated, due to the requirements of production quality and product safety detection, sampling detection or sample detection needs to be carried out on the coated glass material so as to detect whether the thickness of the coated glass material reaches the standard or not after coating by coating equipment, so that the use safety of the glass material is guaranteed.

When the film coating thickness of the film coating glass material is detected, the thickness is measured after the glass material sample is directly cut, the damage degree is large, the operation steps are complicated, and the sample detection of the glass material products produced in batches is not convenient.

Therefore, it is necessary to provide a device for inspecting the thickness of a sample for coating a glass material to solve the above-mentioned problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a sample thickness inspection device for glass material coating, which solves the problem that the coating thickness of a glass material sample is inconvenient to detect.

In order to solve the technical problem, the utility model provides a sample thickness inspection device for glass material coating, which comprises: the mounting frame comprises a mounting frame, a first mounting assembly and a second mounting assembly, wherein the first mounting assembly and the second mounting assembly are respectively mounted inside the mounting frame, the first mounting assembly comprises a pressure sensor and a connecting plate, and an embedding groove is formed in the connecting plate;

the surface of the rotating part is fixed at the bottom of the mounting rack, and the output end of the rotating part is fixedly connected with a rotating frame;

the first telescopic rod is fixedly arranged on one side of the rotating frame, and the output end of the first telescopic rod is fixedly connected with a linkage plate;

one side of the first pressing plate is fixed on the surface of the linkage plate;

the second telescopic rod is fixedly installed on the surface of the linkage plate, a second pressing plate is fixedly connected to the output end of the second telescopic rod, and a detection rod is fixedly connected to one side of the second pressing plate.

Preferably, the first mounting assembly has the same structure as the second mounting assembly and is horizontally distributed inside the mounting frame.

Preferably, one side of the pressure sensor is fixedly connected with the inner wall of the mounting frame, and the detection end of the pressure sensor is fixedly connected with one side of the connecting plate and used for detecting the pressure applied to the connecting plate.

Preferably, the embedding groove is positioned on one side close to the surface of the first pressing plate and used for installing a sample to be detected.

Preferably, one side of the linkage plate is fixedly connected with at least two limiting sliding shafts, one end of each limiting sliding shaft penetrates through the surface of the rotating frame and extends to the other side of the rotating frame, and the surface of each limiting sliding shaft is in sliding connection with the surface of the rotating frame.

Preferably, the surface of the detection rod is provided with an index scale, and one end of the detection rod penetrates through the surface of the linkage plate and extends to the other side of the linkage plate, so as to detect the telescopic length of the detection rod.

Preferably, the bottom of the first pressing plate is provided with a limiting groove, the back of the first pressing plate is provided with a limiting rod, the limiting rod is of an L-shaped structure, and the back of the second pressing plate is fixedly connected with a reset contact.

Preferably, the detection end of the reset contact is matched with the surface of the limiting rod and used for resetting detection of the second pressure plate.

Compared with the related art, the sample thickness inspection device for glass material coating provided by the utility model has the following beneficial effects:

the utility model provides a sample thickness inspection device for glass material coating, wherein a first mounting assembly and a second mounting assembly are respectively provided with a pressure sensor, so that the pressure degrees of two groups of compression structures can be conveniently monitored, the pressure sensors are used for controlling the pressure clamping force of a sample before coating and a sample after coating to be the same, in the process of adjusting the pressure degree of a second pressing plate on the sample before coating by a second telescopic rod, the second pressing plate can synchronously drive a detection rod to move, and when the pressure clamping force of the sample before coating and the pressure clamping force of the sample after coating are the same, the moving range of the detection rod is the total coating thickness value of the sample after coating.

Drawings

FIG. 1 is a schematic structural view of a first embodiment of a sample thickness inspection device for glass material coating according to the present invention;

FIG. 2 is a schematic structural view of a second embodiment of a sample thickness inspection device for glass material coating according to the present invention;

FIG. 3 is a schematic view of the first platen shown in FIG. 2;

fig. 4 is an enlarged view of the portion a shown in fig. 2.

Reference numbers in the figures:

1. a mounting frame;

2. the device comprises a first mounting component 21, a pressure sensor 22, a connecting plate 23 and an embedding groove;

3. a second mounting assembly;

4. a rotor 41, a turret;

5. the device comprises a first telescopic rod 51, a linkage plate 52 and a limiting sliding shaft;

6. a first press plate 61 and a limit groove;

7. a second telescopic rod 71, a second pressing plate 72 and a detection rod;

8. a limiting rod;

9. and resetting the contact.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

The first embodiment:

referring to fig. 1, in which fig. 1 is a schematic structural diagram of a sample thickness inspection device for glass material coating according to a first embodiment of the present invention. A glass material sample thickness inspection device for coating film includes: the mounting structure comprises a mounting frame 1, a first mounting component 2 and a second mounting component 3, wherein the first mounting component 2 and the second mounting component 3 are respectively mounted inside the mounting frame 1, the first mounting component 2 comprises a pressure sensor 21 and a connecting plate 22, and an embedding groove 23 is formed in the connecting plate 22; the surface of the rotating part 4 is fixed at the bottom of the mounting rack 1, and the output end of the rotating part 4 is fixedly connected with a rotating frame 41; the first telescopic rod 5 is fixedly arranged on one side of the rotating frame 41, and the output end of the first telescopic rod 5 is fixedly connected with a linkage plate 51; a first pressing plate 6, wherein one side of the first pressing plate 6 is fixed on the surface of the linkage plate 51; the second telescopic rod 7 is fixedly installed on the surface of the linkage plate 51, the output end of the second telescopic rod 7 is fixedly connected with a second pressing plate 71, and one side of the second pressing plate 71 is fixedly connected with a detection rod 72.

The first mounting component 2 and the second mounting component 3 are the same in size and connecting structure and are mounted on the inner side of the mounting frame 1 in parallel;

the second installation component 3 is used for installing a sample before coating, and the second installation component 3 is matched with the second pressing plate 71 for use, so that the sample before coating on the second installation component 3 is conveniently pressed.

The first installation component 2 is used for installing the coated sample, and the first installation component 2 is matched with the first pressing plate 6 for use, so that the coated sample on the first installation component 2 can be conveniently pressed.

The first pressing plate 6 corresponding to the first mounting assembly 2 can only move and press through the linkage plate 51;

and the second pressing plate 71 corresponding to the second mounting assembly 3 can be freely adjusted in a telescopic manner on the basis of the positioning of the linkage plate 51 through the second telescopic rod 7, so that the pressing adjustment is further carried out.

The first mounting assembly 2 and the second mounting assembly 3 are respectively provided with a pressure sensor 21, so that the compression degrees of the two groups of compression structures can be conveniently monitored, the compression degrees are used for controlling the compression clamping force of a sample before film coating and a sample after film coating to be the same, in the process that the second telescopic rod 7 adjusts the compression degree of the second pressing plate 71 on the sample before film coating, the second pressing plate 71 can synchronously drive the detection rod 72 to move, and when the compression clamping force of the sample before film coating and the compression clamping force of the sample after film coating are the same, the moving range of the detection rod 72 is the total value of the film coating thickness of the sample after film coating;

if the glass material is single-sided coated, the moving range of the detection rod 72 is the coating thickness of the coated sample;

if the glass material is double-sided coated, the moving range of the detection rod 72 is the double-sided coated thickness of the coated sample, and the average value of the two sides is the thickness of the single-sided coated film.

Rotate piece 4 and be used for driving rotating turret 41 and carry out rotation regulation to in order to drive the connection structure on the rotating turret 41 and rotate to the below of mounting bracket 1, when rotating turret 41 is complete rotatory to the below of mounting bracket 1, the side of mounting bracket 1 exposes outside completely, convenient clearance and the maintenance to the mounting bracket 1 is inside.

The output end of the first telescopic rod 5 is directly connected with the linkage plate 51, and the surface of the linkage plate 51 is parallel to the surface of the mounting frame 1, so that the linkage plate 51 can be conveniently pushed into the mounting frame 1.

The first platen 6 is of the same size and configuration as the second platen 71 and is used for sample compression.

The structure of the first mounting component 2 is the same as that of the second mounting component 3, and the first mounting component and the second mounting component are horizontally distributed in the mounting frame 1.

The installation positions of the first installation component 2 and the second installation component 3 are horizontally distributed, so that two groups of glass materials in different states can be conveniently installed.

One side of pressure sensor 21 with the inner wall fixed connection of mounting bracket 1, the sense terminal of pressure sensor 21 with one side fixed connection of connecting plate 22 is used for detecting the pressure that connecting plate 22 received.

The detection pressure value is controlled within the bearing capacity range of the coating material and the glass material, and the glass material or the coating material is not damaged during pressing.

The pressure sensor 21 is used for detecting the degree of pressure applied when the sample is pressed and compressed after being mounted.

The first installation component 2 and the second installation component 3 are in the same pressed detection mode, and can simultaneously carry out pressing detection on a group of uncoated glass materials and a group of coated glass materials.

The embedding groove 23 is positioned at one side close to the surface of the first pressing plate 6 and is used for installing a sample to be detected.

At least two limiting sliding shafts 52 are fixedly connected to one side of the linkage plate 51, one end of each limiting sliding shaft 52 penetrates through the surface of the rotating frame 41 and extends to the other side of the rotating frame 41, and the surface of each limiting sliding shaft 52 is in sliding connection with the surface of the rotating frame 41.

Linkage plate 51 conveniently drives first clamp plate 6 and second clamp plate 71 synchronous motion in step and adjusts to convenient synchronous centre gripping of carrying out two sets of glass materials in step, when needing to compress tightly, preferentially compress tightly the big coating film back glass material of thickness, rethread second telescopic link 7 drives second clamp plate 71 independent movement and compresses tightly not coating film glass material, and the displacement distance that compresses tightly in-process check rod 72 is the coating film thickness of coating film glass material surface promptly.

The limiting slide shaft 52 provides support and limiting for the sliding of the linkage plate 51, and ensures the stability of the linkage plate 51 during moving.

The surface of the detection rod 72 is provided with an index scale, and one end of the detection rod 72 penetrates through the surface of the linkage plate 51 and extends to the other side of the linkage plate 51, so as to detect the length of the detection rod 72 in a telescopic manner.

The distance of measuring rod 72 when going out is convenient to be distinguished to the graduation scale on it, and measuring rod 72 carries out stationary plane and indicating surface through fixed linkage plate 51 surface when moving, conveniently detects and observes measuring rod 72's skew distance.

The working principle of the sample thickness inspection device for glass material coating provided by the utility model is as follows:

when the coated glass material sample needs to be detected, the uncoated glass material sample and the coated glass material sample are respectively arranged on the second mounting component 3 and the first mounting component 2;

starting the first telescopic rod 5, wherein the first telescopic rod 5 synchronously drives the linkage plate 51 to move, and the linkage plate 51 drives the connecting structure of the first pressing plate 6 and the second pressing plate 71 on the linkage plate to synchronously move and gradually approach to the two groups of samples;

when the surface of the first pressing plate 6 and the surface of the coated glass material are tightly pressed and reach the set pressure value, the surface of the second pressing plate 71 is movably contacted with the surface of the uncoated glass material and does not reach the set pressure value;

starting the second telescopic rod 7, pushing the second pressing plate 71 to tightly press the non-coated glass material by the second telescopic rod 7, and reading the displacement distance of the detection rod 72 when the pressure value detected by the second mounting component 3 reaches the set pressure value and is the same as the pressure value detected by the first mounting component 2, wherein the distance is the total coating thickness of the outer surface of the glass material;

if the glass material is single-sided coated, the coating thickness of the coated sample is obtained;

if the glass material is double-sided coated, the thickness of the double-sided coated film of the coated sample is obtained, and the average value of the double sides is the thickness of the single-sided coated film.

Compared with the related art, the sample thickness inspection device for glass material coating provided by the utility model has the following beneficial effects:

all be equipped with pressure sensor 21 on first installation component 2 and the second installation component 3, the convenience is monitored two sets of compact structure's the pressure degree that receives, it is the same with the sample pressure clamping force degree behind the coating to be used for controlling the coating preceding sample and coating, and adjust the in-process of second clamp plate 71 sample pressure degree before the coating to second telescopic link 7, second clamp plate 71 can drive test bar 72 simultaneously and remove, sample and coating back sample pressure clamping force degree are the same before the coating, the removal scope of test bar 72 is the total value of the coating thickness of sample behind the coating.

Second embodiment:

referring to fig. 2, 3 and 4, a second embodiment of the present application provides another apparatus for inspecting a thickness of a sample for coating a glass material based on a first embodiment of the present application. The second embodiment is only the preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, a second embodiment of the present application provides a sample thickness inspection device for glass material coating, which is different in that the sample thickness inspection device for glass material coating further includes:

the bottom of the first pressing plate 6 is provided with a limiting groove 61, the back of the first pressing plate 6 is provided with a limiting rod 8, the limiting rod 8 is of an L-shaped structure, and the back of the second pressing plate 71 is fixedly connected with a reset contact 9.

The size of first clamp plate 6 is the same with the size of second clamp plate 71, and the bottom all is provided with spacing groove 61 structure, conveniently compresses tightly and spacing with the article that awaits measuring of different shapes.

Since the second pressing plate 71 which is movably connected needs to be reset and adjusted after detection, when the reset position is deviated and misplaced, errors and influences are easily caused on the detected structure;

therefore, the limiting structures of the limiting rod 8 and the reset contact 9 are respectively arranged on the back surface of the first pressing plate 6 and the back surface of the second pressing plate 71, when the second pressing plate 71 moves in a resetting mode, the reset contact 9 can be driven to move synchronously, and when the reset contact 9 contacts with the surface of the limiting rod 8, the first pressing plate 6 and the second pressing plate 71 are distributed in parallel, so that the second pressing plate 71 can be adjusted in a stable resetting mode, and stable operation of equipment is guaranteed.

The detection end of the reset contact 9 is matched with the surface of the limiting rod 8 and used for resetting detection of the second pressing plate 71.

The output end of the reset contact 9 is electrically connected with the control end of the second telescopic rod 7, and is used for controlling the automatic closing of the second telescopic rod 7 during resetting, so that the influence on the normal use of the second telescopic rod 7 due to overlarge position deviation when the second telescopic rod 7 drives the second pressing plate 71 to reset is avoided.

Has the advantages that:

therefore, the limiting structures of the limiting rod 8 and the reset contact 9 are respectively arranged on the back surface of the first pressing plate 6 and the back surface of the second pressing plate 71, when the second pressing plate 71 moves in a resetting mode, the reset contact 9 can be driven to move synchronously, and when the reset contact 9 contacts with the surface of the limiting rod 8, the first pressing plate 6 and the second pressing plate 71 are distributed in parallel, so that the second pressing plate 71 can be adjusted in a stable resetting mode, and stable operation of equipment is guaranteed.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The utility model provides a glass material is sample thickness verifying attachment for coating film which characterized in that includes:

the mounting frame comprises a mounting frame, a first mounting assembly and a second mounting assembly, wherein the first mounting assembly and the second mounting assembly are respectively mounted inside the mounting frame, the first mounting assembly comprises a pressure sensor and a connecting plate, and an embedding groove is formed in the connecting plate;

the surface of the rotating part is fixed at the bottom of the mounting rack, and the output end of the rotating part is fixedly connected with a rotating frame;

the first telescopic rod is fixedly arranged on one side of the rotating frame, and the output end of the first telescopic rod is fixedly connected with a linkage plate;

one side of the first pressing plate is fixed on the surface of the linkage plate;

the second telescopic rod is fixedly installed on the surface of the linkage plate, a second pressing plate is fixedly connected to the output end of the second telescopic rod, and a detection rod is fixedly connected to one side of the second pressing plate.

2. The apparatus of claim 1, wherein the first mounting member has the same structure as the second mounting member and is horizontally disposed inside the mounting frame.

3. The device for testing the thickness of a sample for coating a glass material according to claim 1, wherein one side of the pressure sensor is fixedly connected with the inner wall of the mounting frame, and the detection end of the pressure sensor is fixedly connected with one side of the connection plate for detecting the pressure applied to the connection plate.

4. The apparatus according to claim 1, wherein the fitting groove is formed on a side of the first pressing plate adjacent to the surface thereof for fitting a sample to be inspected.

5. The device for testing the thickness of the sample for coating the glass material as claimed in claim 1, wherein at least two limiting sliding shafts are fixedly connected to one side of the linkage plate, one end of each limiting sliding shaft penetrates through the surface of the rotating frame and extends to the other side of the rotating frame, and the surface of each limiting sliding shaft is connected with the surface of the rotating frame in a sliding mode.

6. The device for testing the thickness of the sample for coating the glass material as claimed in claim 1, wherein the surface of the detection rod is provided with an index scale, and one end of the detection rod penetrates through the surface of the linkage plate and extends to the other side of the linkage plate for detecting the length of the detection rod in extension and retraction.

7. The device for testing the thickness of the sample for coating the glass material according to claim 1, wherein a limiting groove is formed at the bottom of the first pressing plate, a limiting rod is arranged on the back surface of the first pressing plate, the limiting rod is of an L-shaped structure, and a reset contact is fixedly connected to the back surface of the second pressing plate.

8. The device for testing the thickness of a sample for coating a glass material according to claim 7, wherein the detection end of the reset contact is adapted to the surface of the limiting rod for reset detection of the second pressing plate.

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