JP6714222B1 - High-grade ceramic tile flatness and backlitness measuring instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose a flatness and backlit photometric measuring instrument for a high-grade ceramic tile. SOLUTION: A main body is provided, an operating space having a front opening is installed in the main body, a check space is installed on a top wall of the operating space, and a check wall is sequentially installed from left to right on the top wall of the check space. A lateral movement slide groove, the check space and the irradiation space are installed, an opening space is installed on the top wall of the lateral movement slide groove, a power space is installed on the top side of the irradiation space, An inspection device capable of inspecting the back light intensity is installed between the irradiation space and the opening space, and the inspection device includes rotating shafts rotatably mounted on the front and rear side walls of the irradiation space. An ultraviolet lamp is installed on the rear side of the rotary shaft, a first bevel gear is fixedly installed on the front side of the rotary shaft, and a drive shaft is rotatably connected to the front and rear side walls of the opening space. A drive gear is fixedly installed on the rear side. [Selection diagram] Figure 1

Description

The present invention relates to the field of ceramic tile inspection, and more particularly to a flatness and backlitness detector for high-grade ceramic tiles.

The ceramic tile is a porcelain or stone-like building or decoration material that is resistant to acids and alkalis made by refining, mixing, pressing, glazeing and sintering refractory metal oxides and semi-metal oxides. .. As the quality of life increases, the quality requirements for ceramic tiles increase, and data such as flatness and backlitness are measured before use. At present, in general, a simple level and light are used for inspection, but most flatness can be measured, and finer roughness cannot be measured. Therefore, in order to improve the production efficiency, the present invention provides a flatness and backlitness measuring instrument for high-grade ceramic tiles.

Chinese Patent Application Publication No. 1073105049

The present invention solves the above problems in the prior art by providing a flatness and backlitness tester for high quality ceramic tiles.

A high-grade ceramic tile flatness and backlight measuring instrument, which includes a main body, in which a working space with a front opening is installed, and a check space is installed on a top wall of the working space. In the top wall of the check space, a lateral movement slide groove is sequentially installed from left to right, the check space and the irradiation space are installed, and an opening space is provided in the top wall of the lateral movement slide groove, and the irradiation space is provided. A power space is installed on the top side of the space, and a measurement device capable of measuring the backlight intensity is installed between the irradiation space and the opening space,
The inspection device includes a rotation shaft rotatably mounted on the front and rear side walls of the irradiation space, an ultraviolet lamp is installed behind the rotation shaft, and a first bevel gear is fixed on the front side of the rotation shaft. Drive shaft is rotatably connected to the front and rear side walls of the opening space, a drive gear is fixedly installed on the rear side of the drive shaft, and a second bevel gear is installed on the front side of the drive shaft. Is fixedly installed, a slide plate groove is formed on a left side wall of the lateral movement slide groove, and a movable slide plate is slidably connected in the slide plate groove. A return spring is connected between the groove and the lateral movement block fixedly slidably connected to the lateral movement slide groove on the right side of the movable slide plate, and the top surface of the lateral movement block is fixed. A sensor is fixedly installed in the inner wall of the laterally moving block that meshes with the drive gear, and a fluorescent plate is fixedly installed on the bottom surface of the sensor.
A control device for controlling the rotation of the inspection device is installed in the power space, a water box is installed on the top side of the check space, and a water spout is installed on a rear side wall of the water box. A check device capable of measuring flatness is installed between the check space and the check space, and a fixing device for sandwiching the ceramic tile is installed in the operating space.

Advantageously, the controller comprises a power motor fixedly mounted on the top wall of the power space, the bottom side of the power motor being rotatable with the bottom wall of the power space and the top wall of the opening space. A power shaft coupled to the power transmission shaft, the power shaft extending downward, penetrating the bottom wall of the power space, entering the opening space, and rotating with the top wall of the opening space. A third bevel gear meshingly meshed with the second bevel gear is fixedly installed on the bottom side of the power shaft, and a vertical axis is rotatably coupled to upper and lower side walls of the power space. A shaft extends downward, penetrates a bottom wall of the power space, enters the irradiation space, and is rotatably connected to a top wall of the irradiation space. A fourth bevel gear meshing with the gear is fixedly installed, and connecting pulleys are symmetrically and fixedly installed in the power space in the vertical axis and the power shaft, and between the connecting pulleys. The connecting belt is connected.

The check device includes a check motor fixedly mounted on a rear side wall of the check space, a motor shaft is rotatably connected to the check motor, and a motor gear is fixedly installed on the motor shaft. An expansion pipe communicating with the water box is installed on the top wall of the check space, and a tooth rod water pipe meshing with the motor gear is fixedly installed on the lower side of the expansion pipe, and the tooth rod water pipe is A check block is fixedly installed on the lower side, a groove communicating with the tooth rod water pipe is formed in the check block, and a water outlet opening downward is installed on the bottom wall of the groove. A thin shaft is rotatably and rotatably connected in the groove, and a stop plate for sealing the tooth rod water pipe is fixedly installed in the thin shaft. The stop plate contacts the stop plate in the groove. The raised blocks are symmetrically and slidably connected to each other, a position limiting space is installed on one side wall of the groove, and a spring block fixedly connected to the protruding block is provided in the position limiting space. It is slidably connected.

Beneficially, the fixing device includes an elevating motor fixedly mounted on a bottom wall of the working space, a short shaft is movably connected to the elevating motor, and a first shaft is provided above the short shaft. Five bevel gears are fixedly installed, lateral lead screws are symmetrically and rotatably connected to the left and right side walls of the working space, and a sixth umbrella meshed with the fifth bevel gear on one side of the lateral lead screws. A gear is fixedly installed, and a screw block slidably connected to the bottom wall of the working space is connected to the lateral lead screw by a screw thread, and a hinge connecting rod is connected to the screw block by a hinge. A moving rod is connected to one side of the hinge connecting rod by a hinge, and a holding block slidably connected to one side wall of the working space is fixedly installed on the top surface of the moving rod.

Beneficially, a fixed block facing the holding block is symmetrically and fixedly installed on the top surface of the working space, and the fixed block cooperates with the holding block to fix the ceramic tile.

Beneficially, a display device is fixedly installed on the left side surface of the main body, the display device and the sensor are wirelessly connected, and the sensor can wirelessly display the discoloration state of the fluorescent plate on the display device. ..

Beneficially, the fixed block and the sandwich block are made of a resin material to ensure a certain hardness and yet have flexibility.

Beneficially, the expansion tube is a plastic material.

Beneficially, the diameter of the drive gear is slightly larger than the diameter of the second bevel gear.

As described above, the beneficial effects of the present invention are as follows: The present invention can measure flatness and backlitness of high-grade ceramic tiles, and can measure backlitness and flatness at the same time as compared with traditional instruments, which is of higher practical use. In addition to having a certain degree, the smoothness of the ceramic tile can be measured by using an ordinary spirit level. According to the present invention, the ceramic tile is fixed by the resin material to secure the inspection result, and at the same time, the high-grade ceramic tile is not damaged and the property loss is avoided. Further, according to the invention of the present application, the flatness of the ceramic tile is measured by a physical method, so that the result of the measurement can be more intuitively obtained, and the backlight can be directly obtained by the display device and the sensor. Give convenience to.

In order to explain the present invention in detail and to explain it conveniently with reference to FIGS. 1 to 4 below, the following directions are defined as follows: FIG. 1 is a front view of the device of the present invention, which is described herein. Each direction is the direction when the device is viewed in the same direction as in FIG.

FIG. 1 is a front view of the entire cross section of the present invention. FIG. 2 is an enlarged view of a part of A of FIG. FIG. 3 is an enlarged view of a part of B of FIG. 4 is a front view of FIG.

As shown in FIGS. 1 to 4, a high-grade ceramic tile flatness and backlight measuring instrument, which includes a main body 21, in which a working space 37 having a front opening is installed, A check space 57 is installed on the top wall of the working space 37, and a lateral movement slide groove 47, the check space 58 and the irradiation space 32 are installed on the top wall of the check space 57 sequentially from left to right. The opening space 26 is installed on the top wall of the lateral movement slide groove 47, the power space 23 is installed on the top side of the irradiation space 32, and the backlight is provided between the irradiation space 32 and the opening space 26. An inspection device 101 capable of measuring the degree is installed, and the inspection device 101 includes a rotation shaft 34 rotatably mounted on the front and rear side walls of the irradiation space 32, and an ultraviolet lamp is provided behind the rotation shaft 34. 36 is installed, the first bevel gear 35 is fixedly installed on the front side of the rotary shaft 34, and the drive shaft 51 is rotatably connected to the front and rear side walls of the opening space 26. A drive gear 50 is fixedly installed on the side, a second bevel gear 52 is fixedly installed on the front side of the drive shaft 51, and a slide plate groove 48 is formed on the left side wall of the lateral movement slide groove 47. The movable slide plate 62 is slidably connected to the slide plate groove 48, and the return spring 49 is connected between the movable slide plate 62 and the slide plate groove 48. A lateral movement block 59 slidably connected to the lateral movement slide groove 47 is fixedly connected to the right side of the lateral movement block 59, and the top surface of the lateral movement block 59 meshes with the drive gear 50. A sensor 60 is fixedly installed on the inner wall of 59, a fluorescent plate 61 is fixedly installed on the bottom surface of the sensor 60, and control for controlling the rotation of the inspection device 101 is provided in the power space 23. An apparatus 102 is installed, a water box 27 is installed on the top side of the check space 58, a water spout 29 is installed on a rear side wall of the water box 27, and a water box 27 is installed between the water box 27 and the check space 58. A check device 103 that can measure flatness is installed, and a fixing device 104 that holds a ceramic tile is installed in the working space 37.

The controller 102 includes a power motor 25 fixedly mounted on the top wall of the power space 23, and a bottom wall of the power space 23 and a top wall of the opening space 26 are provided on the bottom side of the power motor 25. The rotatably connected power shaft 22 is rotatably connected, and the power shaft 22 extends downwardly and penetrates the bottom wall of the power space 23 into the opening space 26 to enter the opening space. A third bevel gear 53, which is rotatably connected to a top wall of the power shaft 26 and is meshed with the second bevel gear 52, is fixedly installed on the bottom side of the power shaft 22. The vertical axis 30 is rotatably connected, the vertical axis 30 extends downwardly, penetrates the bottom wall of the power space 23, enters the irradiation space 32, and rotates with the top wall of the irradiation space 32. A fourth bevel gear 33, which is operably connected and meshes with the first bevel gear 35, is fixedly installed on the bottom side of the vertical shaft 30. Connection pulleys 24 are symmetrically and fixedly installed in the space, and a connection belt 28 is connected between the connection pulleys 24, so that when the power motor 25 is started, the power space 23 and the third space The bevel gear 53, the connecting pulley 24, the vertical axis 30, and the fourth bevel gear 33 rotate.

The check device 103 includes a check motor 65 fixedly mounted on a rear side wall of the check space 58. A motor shaft 31 is movably connected to the check motor 65, and the motor shaft 31 has a motor. A gear 64 is fixedly installed, an expansion tube 63 communicating with the water box 27 is installed on the top wall of the check space 58, and a tooth rod water pipe meshing with the motor gear 64 is installed under the expansion tube 63. 72 is fixedly installed, a check block 67 is fixedly installed below the tooth rod water pipe 72, and a groove 69 communicating with the tooth rod water pipe 72 is formed in the check block 67. A water outlet 66 opening downward is installed in the bottom wall of the groove 69, and a thin shaft 71 is symmetrically and rotatably connected to the groove 69. The thin shaft 71 has the tooth rod water pipe. A stop plate 70 that seals 72 is fixedly installed, and the raised block 68 that is in contact with the stop plate 70 is symmetrically and slidably connected in the groove 69, and is attached to one side wall of the groove 69. Is provided with a position limiting space 73, and a spring block 74 fixedly connected to the protrusion block 68 is slidably connected to the position limiting space 73. When the check motor 65 is activated, the motor shaft is rotated. 31 and the motor gear 64 rotate in conjunction with each other, the tooth rod water pipe 72 moves downward, and the check block 67 moves downward, so that when the raised block 68 comes into contact with the ceramic tile, The raised block 68 moves upward, the stop plate 70 rotates, the groove 69 and the water outlet 66 communicate with each other, water can flow downward, and if the surface of the ceramic tile is not flat. , Water flows out from the gap between the check block 67 and the ceramic tile.

The fixing device 104 includes an elevating motor 40 fixedly mounted on a bottom wall of the working space 37, and a short shaft 39 is movably connected to the elevating motor 40, and a short shaft 39 is installed above the short shaft 39. The fifth bevel gear 55 is fixedly installed, the lateral lead screws 42 are symmetrically and rotatably connected to the left and right side walls of the working space 37, and the fifth bevel gear is attached to one side of the lateral lead screw 42. A sixth bevel gear 56 meshed with 55 is fixedly installed, and a screw block 41 slidably connected to the bottom wall of the working space 37 is connected to the lateral lead screw 42 by a screw thread. A hinge connecting rod 43 is connected to the mountain block 41 by a hinge, a moving rod 44 is connected to one side of the hinge connecting rod 43 by a hinge, and a top surface of the moving rod 44 is connected to one side wall of the working space 37. Since the holding block 45 slidably connected is fixedly installed, when the elevating motor 40 is started after the ceramic tile is placed on the top surface of the holding block 45, the short shaft 39 and the fifth The bevel gear 55, the sixth bevel gear 56, and the lateral lead screw 42 rotate, and the thread block 41 moves to both sides, so that the hinge connecting rod 43 and the moving rod 44 move to the holding block 45. And move the ceramic tile up.

A fixed block 46 facing the holding block 45 is symmetrically and fixedly installed on the top surface of the working space 37. The fixed block 46 cooperates with the holding block 45 to fix the ceramic tile.

A display device 54 is fixedly installed on the left side surface of the main body 21, and the display device 54 and the sensor 60 are wirelessly connected to each other. The sensor 60 wirelessly displays the discolored state of the fluorescent plate 61. Can be displayed on.

The fixing block 46 and the sandwiching block 45 are made of a resin material, and have a certain degree of hardness and flexibility, and prevent the ceramic tile from being crushed.

The expandable tube 63 is made of a plastic material and easily expands and contracts.

By making the diameter of the driving gear 50 a little larger than the diameter of the second bevel gear 52, the ultraviolet rays emitted by the ultraviolet lamp 36 can enter the lateral movement block 59.

When the ceramic tile is inspected, water is poured into the water box 27 through the water spout 29 and then the ceramic tile is placed on the top surface of the sandwiching block 45, and when the lifting motor 40 is started, the short shaft 39 and the fifth bevel gear. 55, the sixth bevel gear 56, and the lateral lead screw 42 rotate, and the thread block 41 moves to both sides, so that the hinge connecting rod 43 and the moving rod 44 move the holding block 45 and the ceramic tile upward. The fixing block 46 cooperates with the sandwiching block 45 to fix the ceramic tile, and by turning on the ultraviolet lamp 36, ultraviolet rays are reflected through the ceramic tile into the lateral moving block 59 and are applied to the fluorescent plate 61. Then, the fluorescent plate 61 discolors, and the sensor 60 wirelessly displays the discolored state of the fluorescent plate 61 on the display device 54, obtains the backlight intensity of the area by the conversion rate of the discoloration, and the inspection of the backlight intensity is completed.
When the power motor 25 is started when the flatness of the ceramic tile is measured, the power space 23, the third bevel gear 53, the connecting pulley 24, the vertical axis 30, and the fourth bevel gear 33 rotate, so that the first The bevel gear 35, the rotation shaft 34, and the ultraviolet lamp 36 rotate, the second bevel gear 52, the drive shaft 51, and the drive gear 50 rotate, and the lateral movement block 59 moves to the left, so that the irradiation point is changed. After the change, the back light intensity is measured again, and after the back light intensity measurement is completed, when the check motor 65 is started, the motor shaft 31 and the motor gear 64 rotate, and the tooth rod water pipe 72 moves downward. When the check block 67 moves downward and the raised block 68 comes into contact with the ceramic tile, the raised block 68 moves upward, whereby the stop plate 70 rotates and the groove 69 communicates with the water outlet 66. Water can flow downwards, and if the surface of the ceramic tile is not flat, water will flow out of the gap between the check block 67 and the ceramic tile, thereby checking the flatness.

The above embodiments are only for explaining the technical idea and features of the present invention, and are intended for those skilled in the art to understand and implement the present invention, and do not limit the scope of the claims of the present invention. Changes that are substantially unchanged based on the present invention are covered by the claims of the present invention.

Claims (9)

A high-grade ceramic tile flatness and backlight measuring instrument, which includes a main body, in which a working space with a front opening is installed, and a check space is installed on a top wall of the working space. In the top wall of the check space, a lateral movement slide groove is sequentially installed from left to right, the check space and the irradiation space are installed, and an opening space is provided in the top wall of the lateral movement slide groove, and the irradiation space is provided. A power space is installed on the top side of the space, and a measurement device capable of measuring the backlight intensity is installed between the irradiation space and the opening space,
The inspection device includes a rotation shaft rotatably mounted on the front and rear side walls of the irradiation space, an ultraviolet lamp is installed behind the rotation shaft, and a first bevel gear is fixed on the front side of the rotation shaft. Drive shaft is rotatably connected to the front and rear side walls of the opening space, a drive gear is fixedly installed on the rear side of the drive shaft, and a second bevel gear is installed on the front side of the drive shaft. Is fixedly installed, a slide plate groove is formed on a left side wall of the lateral movement slide groove, and a movable slide plate is slidably connected in the slide plate groove. A return spring is connected between the groove and the lateral movement block fixedly slidably connected to the lateral movement slide groove on the right side of the movable slide plate, and the top surface of the lateral movement block is fixed. A sensor is fixedly installed in the inner wall of the laterally moving block that meshes with the drive gear, and a fluorescent plate is fixedly installed on the bottom surface of the sensor.
A control device for controlling the rotation of the inspection device is installed in the power space, a water box is installed on the top side of the check space, and a water spout is installed on a rear side wall of the water box. A check device capable of measuring flatness is installed between the check space and the check space, and a fixing device for sandwiching the ceramic tile is installed in the working space. Degree and backlit tester. The controller includes a power motor fixedly mounted on a top wall of the power space, and the bottom side of the power motor is rotatably connected to a bottom wall of the power space and a top wall of the opening space. A power shaft is rotatably connected, the power shaft extends downward, penetrates a bottom wall of the power space, enters the opening space, and is rotatably connected to a top wall of the opening space; A third bevel gear meshing with the second bevel gear is fixedly installed on the bottom side of the power shaft, and a vertical axis is rotatably connected to upper and lower side walls of the power space, and the vertical axis is downward. It extends and penetrates the bottom wall of the power space, enters the irradiation space, is rotatably connected to the top wall of the irradiation space, and meshes with the first bevel gear on the bottom side of the vertical axis. A fourth bevel gear is fixedly installed, connection pulleys are installed symmetrically and fixedly in the power space in the vertical axis and the power shaft, and a connection belt is connected between the connection pulleys. The flatness and backlitness measuring instrument of the high-grade ceramic tile according to claim 1. The check device includes a check motor fixedly mounted on a rear side wall of the check space, a motor shaft is rotatably connected to the check motor, and a motor gear is fixedly installed on the motor shaft. An expansion pipe communicating with the water box is installed on the top wall of the check space, and a tooth rod water pipe meshing with the motor gear is fixedly installed on the lower side of the expansion pipe, and the tooth rod water pipe is A check block is fixedly installed on the lower side, a groove communicating with the tooth rod water pipe is formed in the check block, and a water outlet opening downward is installed on the bottom wall of the groove. A thin shaft is rotatably and rotatably connected in the groove, and a stop plate for sealing the tooth rod water pipe is fixedly installed in the thin shaft. The stop plate contacts the stop plate in the groove. The raised blocks are symmetrically and slidably connected to each other, a position limiting space is installed on one side wall of the groove, and a spring block fixedly connected to the protruding block is provided in the position limiting space. The flatness and backlitness measuring instrument of a high-grade ceramic tile according to claim 1, which is slidably connected. The fixing device includes an elevating motor fixedly attached to a bottom wall of the working space, a short shaft is movably connected to the elevating motor, and a fifth bevel gear is above the short shaft. The laterally extending lead screws are fixedly installed on the left and right side walls of the working space symmetrically and rotatably, and the sixth bevel gear meshing with the fifth bevel gear is fixed to one side of the lateral lead screw. Installed in the horizontal lead screw, a screw thread block slidably connected to the bottom wall of the working space is connected by a screw thread, and a hinge connecting rod is connected to the screw thread block by a hinge. A moving rod is connected to one side of the connecting rod by a hinge, and a holding block slidably connected to one side wall of the working space is fixedly installed on the top surface of the moving rod. An instrument for measuring flatness and backlight of the high-grade ceramic tile according to claim 1. The fixed block facing the holding block is symmetrically and fixedly installed on the top surface of the operating space, and the fixed block can fix the ceramic tile in cooperation with the holding block. 4. A measuring instrument for flatness and backlight of the high-grade ceramic tile according to 4. A display device is fixedly installed on the left side surface of the main body, the display device and the sensor are wirelessly connected, and the sensor can wirelessly display the discoloration state of the fluorescent plate on the display device. An instrument for measuring flatness and backlight of the high-grade ceramic tile according to claim 1. The flatness and backlitness detection of a high-grade ceramic tile according to claim 5, wherein the fixing block and the sandwiching block are made of a resin material and have a certain degree of flexibility while guaranteeing a certain hardness. Measuring instrument. The flatness and backlitness measuring instrument according to claim 3, wherein the expansion tube is made of a plastic material. The flatness and backlight photometric instrument of claim 1, wherein the diameter of the drive gear is slightly larger than the diameter of the second bevel gear.

Images