Intelligent thickness detector for glass production and detection method
阅读说明:本技术 一种玻璃生产用智能化厚度检测仪及检测方法 (Intelligent thickness detector for glass production and detection method ) 是由 殷玲 于 2021-10-19 设计创作,主要内容包括:本发明公开了一种玻璃生产用智能化厚度检测仪及检测方法,属于玻璃生产领域。一种玻璃生产用智能化厚度检测仪,包括安装板,所述安装板的一侧设有触发组件,所述触发组件的顶部通过活动杆连接有气体箱,所述气体箱固定安装在所述安装板的一侧,且气体箱内壁的底面固定安装有密封罩,所述密封罩的内部滑动连接有活塞块,所述活塞块的底部固定安装所述活动杆,所述密封罩的一侧贯穿开设有进气孔;本发明通过设置压紧轮、密封罩、活塞块、活动杆、进气孔、气筒箱和印刷板等结构组件,从而使得本装装置,可以快速测量玻璃的厚度,并给合格的玻璃打上印记,相对于现有技术,本装置测量成本低廉,测量效率高,测量准确度高。(The invention discloses an intelligent thickness detector for glass production and a detection method, and belongs to the field of glass production. An intelligent thickness detector for glass production comprises a mounting plate, wherein a trigger assembly is arranged on one side of the mounting plate, the top of the trigger assembly is connected with a gas box through a movable rod, the gas box is fixedly mounted on one side of the mounting plate, a sealing cover is fixedly mounted on the bottom surface of the inner wall of the gas box, a piston block is connected to the inside of the sealing cover in a sliding mode, the movable rod is fixedly mounted at the bottom of the piston block, and an air inlet hole is formed in one side of the sealing cover in a penetrating mode; according to the invention, the pressing wheel, the sealing cover, the piston block, the movable rod, the air inlet hole, the air cylinder box, the printing plate and other structural components are arranged, so that the device can rapidly measure the thickness of glass and mark the qualified glass.)
1. An intelligent thickness detector for glass production is characterized by comprising an installation plate (1), a trigger assembly is arranged on one side of the mounting plate (1), the top of the trigger assembly is connected with a gas box (105) through a movable rod (108), the gas box (105) is fixedly mounted on one side of the mounting plate (1), and the bottom surface of the inner wall of the gas box (105) is fixedly provided with a sealing cover (106), the interior of the sealing cover (106) is connected with a piston block (107) in a sliding way, the bottom of the piston block (107) is fixedly provided with the movable rod (108), one side of the sealing cover (106) is provided with an air inlet hole (109) in a penetrating way, one side of the gas box (105) is communicated with the gas cylinder box (2) through a hose (4), the bottom of air cylinder box (2) is movably connected with a printing box (3) through a connecting rod (205), and a printing plate (301) is connected in the printing box (3) in a sliding mode.
2. The intelligent thickness detector for glass production according to claim 1, wherein the trigger assembly comprises a rotating rod (101), the rotating rod (101) is connected to one side of the mounting plate (1) through a rotating shaft in a rotating mode, one side of the rotating rod (101) is connected with a pressing wheel (102) through a rotating pin in a rotating mode, a positioning pin (103) is fixedly connected to one side of the mounting plate (1) and one side of the rotating rod (101), and the positioning pins (103) are connected through tension springs (104).
3. The intelligent thickness detector for glass production according to claim 2, wherein a rubber ring is fixedly sleeved on the surface of the pressing wheel (102); the bottom end of the movable rod (108) is in contact with the top surface of the rotating rod (101).
4. The intelligent thickness detector for glass production according to claim 1, wherein an air inlet pipe (5) is installed on one side of the air box (105) in a penetrating manner, and an air inlet end of the air inlet pipe (5) is communicated with an output end of an air pump.
5. The intelligent thickness detector for glass production according to claim 1, wherein the inside of the sealing cover (106) is cylindrical, the circumferential outer wall of the piston block (107) is fixedly sleeved with a rubber sealing ring, and the surface of the rubber sealing ring is in relative sliding connection with the inner wall of the sealing cover (106).
6. The intelligent thickness detector for glass production according to claim 1, wherein a first spring (110) is fixedly connected to the top surface of the piston block (107), and the top end of the first spring (110) is fixedly connected to the top surface of the inner wall of the sealing cover (106).
7. The intelligent thickness detector for glass production according to claim 1, wherein the air inlet (109) is cylindrical, and the thickness of the piston block (107) is 3-4 cm larger than the diameter of the sealing cover (106).
8. The intelligent thickness detector for glass production according to claim 1, the air cylinder box (2) is fixedly arranged on one side of the mounting plate (1), a partition plate (201) is arranged in the air cylinder box (2), the partition board (201) divides the interior of the air cylinder box (2) into an air cavity (202) and a movable cavity (203), a movable plate (204) is connected inside the movable cavity (203) in a sliding manner, the bottom of the movable plate (204) is fixedly connected with the connecting rod (205), the top surface of the movable plate (204) is fixedly connected with a second spring (206), the top end of the second spring (206) is fixedly connected with the top surface of the inner wall of the movable cavity (203), the bottom of the partition plate (201) is provided with a communicating hole (207) in a penetrating way, and the communicating hole (207) communicates the gas chamber (202) and the movable chamber (203).
9. The intelligent thickness detector for glass production according to claim 1, wherein a first material guide groove (302) is formed in one side of the printing box (3), a second material guide groove (303) is formed in one side of the printing plate (301), the first material guide groove (302) and the second material guide groove (303) correspond to each other, a third spring (304) is fixedly connected to the top surface of the printing plate (301), and the top end of the third spring (304) is fixedly connected to the top surface of the inner wall of the printing box (3);
one side of printing case (3) is run through and is installed connecting pipe (305), the top fixedly connected with liquid reserve tank (306) of connecting pipe (305).
10. A post-glass detection method using the intelligent thickness detector for glass production of claim 1.
Technical Field
The invention relates to the technical field of glass production, in particular to an intelligent thickness detector for glass production and a detection method.
Background
The glass is an amorphous inorganic non-metallic material, is generally prepared by taking various inorganic minerals as main raw materials and adding a small amount of auxiliary raw materials, is widely applied to buildings and is used for wind insulation and light transmission.
In the field of toughened glass, the thickness of the toughened glass needs to be measured after the glass is produced, generally by manual measurement, and a small part of the toughened glass is measured by an optical instrument.
However, the two thickness measurement methods have disadvantages that the measurement and detection cost of an optical instrument is high, the production requirement of a production line is not met, manual measurement is low in cost, measurement needs to be carried out piece by piece, the efficiency is low, and the measurement result has errors due to human factors.
Disclosure of Invention
The invention aims to solve the problems of high detection cost, low detection efficiency and easy error in the prior art, and provides an intelligent thickness detector and a detection method for glass production.
In order to achieve the purpose, the invention adopts the following technical scheme:
the utility model provides a glass production is with intelligent thickness detection appearance, includes the mounting panel, one side of mounting panel is equipped with the trigger subassembly, the top of trigger subassembly is connected with the gas tank through the movable rod, gas tank fixed mounting be in one side of mounting panel, and the bottom surface fixed mounting of gas tank inner wall has the sealed cowling, the inside sliding connection of sealed cowling has the piston piece, the bottom fixed mounting of piston piece the movable rod, the inlet port has been run through to one side of sealed cowling, one side of gas tank has the gas cylinder case through the hose intercommunication, the bottom of gas cylinder case has the printing box through connecting rod swing joint, the inside sliding connection of printing box has the printing plate.
In order to realize screening qualified glass, preferably, trigger the subassembly and include the dwang, the dwang pass through the axis of rotation rotate connect in one side of mounting panel, one side of dwang is rotated through the rotation pin and is connected with the pinch roller, and the equal fixedly connected with locating pin in one side of mounting panel and dwang, two connect through the extension spring between the locating pin.
In order to protect the glass, preferably, a rubber ring is fixedly sleeved on the surface of the pressing wheel; the bottom of the movable rod is in contact with the top surface of the rotating rod.
In order to achieve complete functions, preferably, an air inlet pipe is installed on one side of the air box in a penetrating mode, and an air inlet end of the air inlet pipe is communicated with an output end of the air pump.
In order to achieve perfect functions, preferably, the inside of the sealing cover is cylindrical, a rubber sealing ring is fixedly sleeved on the circumferential outer wall of the piston block, and the surface of the rubber sealing ring is in relative sliding connection with the inner wall of the sealing cover.
In order to realize the resetting, preferably, a first spring is fixedly connected to the top surface of the piston block, and the top end of the first spring is fixedly connected to the top surface of the inner wall of the sealing cover.
In order to achieve normal functions, the air inlet hole is preferably cylindrical, and the thickness of the piston block is 3-4 cm larger than the diameter of the sealing cover.
In order to realize marking a mark for qualified glass, preferably, the gas cylinder box is fixedly mounted on one side of the mounting plate, a partition plate is arranged inside the gas cylinder box, the partition plate divides the inside of the gas cylinder box into a gas cavity and a movable cavity, the movable cavity is slidably connected with a movable plate, the movable plate is fixedly connected with the bottom of the movable plate, a second spring is fixedly connected with the connecting rod and the top surface of the movable plate, the top end of the second spring is fixedly connected with the top surface of the inner wall of the movable cavity, a communicating hole is formed in the bottom of the partition plate in a penetrating mode, and the communicating hole communicates the gas cavity with the movable cavity.
In order to achieve normal functions, preferably, a first guide chute is formed in one side of the printing box, a second guide chute is formed in one side of the printing plate, the printing plate and the second guide chute correspond to each other, a third spring is fixedly connected to the top surface of the printing plate, and the top end of the third spring is fixedly connected to the top surface of the inner wall of the printing box.
In order to store ink, preferably, a connecting pipe is installed on one side of the printing box in a penetrating manner, and a liquid storage cylinder is fixedly connected to the top end of the connecting pipe.
A post-glass detection method adopting the intelligent thickness detector for glass production.
Compared with the prior art, the invention provides an intelligent thickness detector for glass production, which has the following beneficial effects:
this intelligent thickness detector is used in glass production through setting up tight pulley, sealed cowling, piston piece, movable rod, inlet port, cylinder case and printing plate isotructure subassembly to make this dress device, can the rapid survey glass's thickness, and make the seal of a government organization in old china for qualified glass, for prior art, this device measurement low cost, measurement efficiency is high, and measuring accuracy is high.
Drawings
FIG. 1 is a schematic three-dimensional structure diagram of an intelligent thickness detector for glass production according to the present invention;
FIG. 2 is a schematic top view of an intelligent thickness detector for glass production according to the present invention;
FIG. 3 is a schematic view of the internal structure of the inflator case of the intelligent thickness detector for glass production according to the present invention;
FIG. 4 is a schematic view of the internal structure of a gas box of the intelligent thickness detector for glass production according to the present invention;
fig. 5 is a schematic view of the internal structure of a printing box of the intelligent thickness detector for glass production provided by the invention.
In the figure: 1. mounting a plate; 101. rotating the rod; 102. a pinch roller; 103. positioning pins; 104. a tension spring; 105. a gas box; 106. a sealing cover; 107. a piston block; 108. a movable rod; 109. an air inlet; 110. a first spring; 2. a gas cylinder box; 201. a partition plate; 202. a gas chamber; 203. a movable cavity; 204. a movable plate; 205. a connecting rod; 206. a second spring; 207. a communicating hole; 3. a printing box; 301. a printing plate; 302. a first material guide chute; 303. a second guiding gutter; 304. a third spring; 305. a connecting pipe; 306. a liquid storage cylinder; 4. a hose; 5. an air inlet pipe.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.
In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.
Example 1:
referring to fig. 1-5, an intelligent thickness detector for glass production, including mounting panel 1, one side of mounting panel 1 is equipped with trigger assembly, trigger assembly's top is connected with gas tank 105 through movable rod 108, gas tank 105 fixed mounting is in one side of mounting panel 1, and the bottom surface fixed mounting of gas tank 105 inner wall has sealed cowling 106, the inside sliding connection of sealed cowling 106 has piston block 107, the bottom fixed mounting movable rod 108 of piston block 107, the perforating hole has been seted up to gas tank 105's bottom, movable rod 108 passes the perforating hole, one side of sealed cowling 106 runs through and has seted up inlet port 109, one side of gas tank 105 has cylinder case 2 through hose 4 intercommunication, the bottom of cylinder case 2 has printing box 3 through connecting rod 205 swing joint, the inside sliding connection of printing box 3 has printing plate 301.
Example 2:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a cylinder box 2 through a hose 4, the bottom of the cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, the trigger assembly comprises a rotating rod 101, the rotating rod 101 is rotatably connected to one side of the mounting plate 1 through a rotating shaft, one side of dwang 101 rotates through the rotating pin and is connected with pinch roller 102, and the equal fixedly connected with locating pin 103 in one side of mounting panel 1 and dwang 101, connect through extension spring 104 between two locating pins 103, when the glass of having produced is carried pinch roller 102 through the conveyer belt under, pinch roller 102 compresses tightly glass under the effect of spring, because glass all has certain thickness, pinch roller 102 must upwards lift a little, glass keeps away from the back under the effect of extension spring 104, pinch roller 102 resets.
Example 3:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a cylinder box 2 through a hose 4, the bottom of the cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, the trigger assembly comprises a rotating rod 101, the rotating rod 101 is rotatably connected to one side of the mounting plate 1 through a rotating shaft, one side of the rotating rod 101 is rotatably connected with a pressing wheel 102 through a rotating pin, one side of the mounting plate 1 and one side of the rotating rod 101 are fixedly connected with positioning pins 103, the two positioning pins 103 are connected through a tension spring 104, when the produced glass is conveyed to the position right below the pressing wheel 102 through a conveying belt, the pressing wheel 102 presses the glass under the action of a spring, the pressing wheel 102 tends to lift upwards slightly due to the fact that the glass has a certain thickness, the pressing wheel 102 resets after the glass is far away from, and a rubber ring is fixedly sleeved on the surface of the pressing wheel 102 to prevent the pressing wheel 102 from damaging the glass; the bottom end of the movable lever 108 contacts the top surface of the rotating lever 101, and when the rotating lever 101 moves upward, the movable lever 108 also moves upward.
Example 4:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a gas cylinder box 2 through a hose 4, the bottom of the gas cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, an air inlet pipe 5 is installed in one side of the gas tank 105 in a penetrating manner, and the air inlet end of the gas inlet pipe 5 is communicated with the output end of an air pump, thereby providing the air source for the device and improving the function of the device.
Example 5:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a cylinder box 2 through a hose 4, the bottom of the cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, the trigger assembly comprises a rotating rod 101, the rotating rod 101 is rotatably connected to one side of the mounting plate 1 through a rotating shaft, one side of the rotating rod 101 is rotatably connected with a pressing wheel 102 through a rotating pin, one side of the mounting plate 1 and one side of the rotating rod 101 are fixedly connected with positioning pins 103, the two positioning pins 103 are connected through a tension spring 104, when the produced glass is conveyed to the position right below the pressing wheel 102 through a conveying belt, the pressing wheel 102 presses the glass under the action of a spring, the pressing wheel 102 tends to lift upwards slightly due to the fact that the glass has a certain thickness, the pressing wheel 102 resets after the glass is far away from, and a rubber ring is fixedly sleeved on the surface of the pressing wheel 102 to prevent the pressing wheel 102 from damaging the glass; the bottom end of the movable rod 108 contacts the top surface of the rotating rod 101, and when the rotating rod 101 moves upward, the movable rod 108 also moves upward;
the inside of the sealing cover 106 is cylindrical, the circumferential outer wall of the piston block 107 is fixedly sleeved with a rubber sealing ring, and the surface of the rubber sealing ring is in relative sliding connection with the inner wall of the sealing cover 106, so that the sealing performance is improved.
Example 6:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a cylinder box 2 through a hose 4, the bottom of the cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, the trigger assembly comprises a rotating rod 101, the rotating rod 101 is rotatably connected to one side of the mounting plate 1 through a rotating shaft, one side of the rotating rod 101 is rotatably connected with a pressing wheel 102 through a rotating pin, one side of the mounting plate 1 and one side of the rotating rod 101 are fixedly connected with positioning pins 103, the two positioning pins 103 are connected through a tension spring 104, when the produced glass is conveyed to the position right below the pressing wheel 102 through a conveying belt, the pressing wheel 102 presses the glass under the action of a spring, the pressing wheel 102 tends to lift upwards slightly due to the fact that the glass has a certain thickness, the pressing wheel 102 resets after the glass is far away from, and a rubber ring is fixedly sleeved on the surface of the pressing wheel 102 to prevent the pressing wheel 102 from damaging the glass; the bottom end of the movable rod 108 contacts the top surface of the rotating rod 101, and when the rotating rod 101 moves upward, the movable rod 108 also moves upward;
the interior of the sealing cover 106 is cylindrical, a rubber sealing ring is fixedly sleeved on the circumferential outer wall of the piston block 107, and the surface of the rubber sealing ring is in relative sliding connection with the inner wall of the sealing cover 106, so that the sealing property is improved; the top surface of the piston block 107 is fixedly connected with a first spring 110, and the top end of the first spring 110 is fixedly connected with the top surface of the inner wall of the sealing cover 106, so that the piston block 107 can be conveniently reset.
Specifically, the air inlet 109 is cylindrical, and the thickness of the piston block 107 is 3-4 cm larger than the diameter of the sealing cover 106, so that the piston block 107 can block the air inlet 109, and the device has normal function.
Example 7:
referring to fig. 1-5, an intelligent thickness detector for glass production comprises a mounting plate 1, a trigger assembly is arranged on one side of the mounting plate 1, the top of the trigger assembly is connected with a gas tank 105 through a movable rod 108, the gas tank 105 is fixedly arranged on one side of the mounting plate 1, a sealing cover 106 is fixedly arranged on the bottom surface of the inner wall of the gas tank 105, a piston block 107 is slidably connected inside the sealing cover 106, the movable rod 108 is fixedly arranged at the bottom of the piston block 107, a through hole is formed in the bottom of the gas tank 105, the movable rod 108 penetrates through the through hole, an air inlet hole 109 is formed in one side of the sealing cover 106 in a penetrating manner, one side of the gas tank 105 is communicated with a cylinder box 2 through a hose 4, the bottom of the cylinder box 2 is movably connected with a printing box 3 through a connecting rod 205, a printing plate 301 is slidably connected inside the printing box 3, the trigger assembly comprises a rotating rod 101, the rotating rod 101 is rotatably connected to one side of the mounting plate 1 through a rotating shaft, one side of the rotating rod 101 is rotatably connected with a pressing wheel 102 through a rotating pin, one side of the mounting plate 1 and one side of the rotating rod 101 are fixedly connected with positioning pins 103, the two positioning pins 103 are connected through a tension spring 104, when the produced glass is conveyed to the position right below the pressing wheel 102 through a conveying belt, the pressing wheel 102 presses the glass under the action of a spring, the pressing wheel 102 tends to lift upwards slightly due to the fact that the glass has a certain thickness, the pressing wheel 102 resets after the glass is far away from, and a rubber ring is fixedly sleeved on the surface of the pressing wheel 102 to prevent the pressing wheel 102 from damaging the glass; the bottom end of the movable rod 108 contacts the top surface of the rotating rod 101, and when the rotating rod 101 moves upward, the movable rod 108 also moves upward;
the interior of the sealing cover 106 is cylindrical, a rubber sealing ring is fixedly sleeved on the circumferential outer wall of the piston block 107, and the surface of the rubber sealing ring is in relative sliding connection with the inner wall of the sealing cover 106, so that the sealing property is improved; the top surface of the piston block 107 is fixedly connected with a first spring 110, and the top end of the first spring 110 is fixedly connected with the top surface of the inner wall of the sealing cover 106, so that the piston block 107 can be conveniently reset.
Specifically, the air inlet hole 109 is cylindrical, and the thickness of the piston block 107 is 3-4 cm larger than the diameter of the sealing cover 106, so that the piston block 107 can block the air inlet hole 109, and the device has normal function;
the gas cylinder box 2 is fixedly arranged on one side of the mounting plate 1, a partition plate 201 is arranged inside the gas cylinder box 2, the partition plate 201 divides the inside of the gas cylinder box 2 into a gas cavity 202 and a movable cavity 203, the movable cavity 203 is connected with the movable plate 204 in a sliding mode, the bottom of the movable plate 204 is fixedly connected with a connecting rod 205, the top surface of the movable plate 204 is fixedly connected with a second spring 206, the top end of the second spring 206 is fixedly connected with the top surface of the inner wall of the movable cavity 203, a communicating hole 207 is formed in the bottom of the partition plate 201 in a penetrating mode, the communicating hole 207 is communicated with the gas cavity 202 and the movable cavity 203, high-pressure gas enters the gas cavity 202 from the hose 4, the communicating hole 207 pushes the movable plate 204 to overcome the elasticity of the second spring 206, and therefore the printing plate 301 at the lowest end is far away from the surface of the conveying belt.
Specifically, a first guide chute 302 is formed in one side of the printing box 3, a second guide chute 303 is formed in one side of the printing plate 301, the first guide chute 302 and the second guide chute 303 correspond to each other, a third spring 304 is fixedly connected to the top surface of the printing plate 301, the top end of the third spring 304 is fixedly connected to the top surface of the inner wall of the printing box 3, the movable plate 204 moves downward under the action of the second spring 206 until the printing plate 301 contacts with the glass, the printing plate 301 and the printing box 3 start to slide relatively, and when the first guide chute 302 is communicated with the second guide chute 303, ink is printed on the glass through the printing plate 301, so that the glass is qualified.
Specifically, one side of printing box 3 runs through and installs connecting pipe 305, and the top fixedly connected with liquid storage cylinder 306 of connecting pipe 305 adds the ink to the inside of liquid storage cylinder 306 during the use to cover the cap.
A method for detecting glass after adopting an intelligent thickness detector for glass production comprises the following specific operation method that the device can be fixed on a glass production conveying line through bolts, the rolling direction of a pressing wheel 102 is enabled to be consistent with the conveying direction, a certain amount of ink is added at a liquid storage cylinder 306, the output end of an air pump is connected to the air inlet end of an air inlet pipe 5, at the moment, an air inlet hole 109 is blocked by a piston block 107, the inside of an air box 105 is equivalent to a closed space, high-pressure air enters the inside of an air cavity 202 from a hose 4, a movable plate 204 is pushed by a communication hole 207 to overcome the elasticity of a second spring 206, so that a printing plate 301 at the lowest end is far away from the surface of the conveying belt, when the produced glass passes through the conveying belt and is conveyed to the position right below the pressing wheel 102, the pressing wheel 102 presses the glass under the action of the spring, and the glass has a certain thickness, the pressing wheel 102 tends to slightly lift upwards, when the thickness of the measured glass is qualified, the pressing wheel 102 moving upwards drives the rotating rod 101 to move upwards for a certain stroke, the rotating rod 101 pushes the movable rod 108 to move upwards, and then the piston block 107 also moves upwards, when the lowest end of the piston block 107 can not cover the lowest end of the air inlet hole 109 any more, high-pressure air overflows through the air inlet hole 109 and the through hole where the movable rod 108 is located, at the moment, the air is insufficient for maintaining the movable plate 204 in the original state, the movable plate 204 moves downwards under the action of the second spring 206 until the printed plate 301 contacts the glass, the printed plate 301 and the printing box 3 start to slide relatively, when the first guide chute 302 is communicated with the second guide chute 303, ink is printed on the glass through the printed plate 301 to represent that the glass is qualified, when the glass leaves the pressing wheel 102, under the action of the tension spring 104, the first spring 110, the second spring 206 and the third spring 304, the elements are reset for the next glass measurement.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.