CN112903095A - Device for monitoring crosscut scribing temperature on line - Google Patents

Abstract

The invention discloses a device for monitoring the temperature of a crosscut scribing line on line, which comprises a transverse moving chassis component, wherein a transverse moving base component is arranged on the transverse moving chassis component in a threaded reciprocating manner, a temperature measuring probe mounting component is arranged at the bottom of the transverse moving base component in an omnibearing movable manner, the transverse moving base component is enabled to move in a threaded transverse bidirectional reciprocating manner on the transverse moving chassis component through the bidirectional rotation of a first driving motor and the threaded matching of an internal threaded transverse moving block and a transverse moving threaded rod, the omnibearing movement of the temperature measuring probe mounting component on the transverse moving chassis component towards a temperature measuring angle is realized through the rotation of a second driving motor, the linkage matching among a Z-shaped rotating shaft lever, a linkage arm plate and a supporting rod and the omnibearing movement of a movable ball head in a temperature measuring movable ball groove, and the omnibearing movement of the temperature measuring probe mounting component on the transverse moving chassis component is, and clamping and fixing the infrared temperature measurement probe at the end part of the temperature measurement probe mounting component.

Description

Device for monitoring crosscut scribing temperature on line

Technical Field

The invention belongs to the technical field of overflow downdraw method substrate glass manufacturing, and particularly relates to a device for monitoring transverse cutting and scribing temperature on line.

Background

The transverse cutting is one of important processes for manufacturing the plate glass by an overflow down-drawing method, the continuously down-drawn glass plate is transversely cut and then broken off, and then the glass plate is sent to a subsequent process for finish machining, cutting, scribing and breaking off are key points of the transverse cutting process, if the cutting or breaking off is poor, the transverse cutting breaking failure and BOW type change can be caused, the plate breaking is caused in serious conditions, the material flowing state in a furnace is influenced, and therefore, the good cutting state is the guarantee of productivity.

The prior art has the following problems: the cutting quality is determined by the cutting state of the cutter wheel, the cutting state changes along with the service time of the cutter wheel and the abrasion of the cutter teeth, namely the service time of the cutter wheel is prolonged continuously, the cutter teeth are abraded to different degrees, the abrasion is mainly caused by the mutual friction between the cutter teeth and glass in the cutting process, and in addition, the service life of the cutter wheel is influenced by overhigh scribing temperature; the glass powder that produces in cutting process adheres to on the break bar, can hinder the break bar and rule, aggravates the wearing and tearing of sword tooth to a certain extent, consequently, the accessible control crosscut is rule the temperature and is started, judges the temperature to the wearing and tearing that slows down the break bar sword tooth, improves the cutting section, prolongs the influence of break bar life-span and cutting quality.

Disclosure of Invention

To solve the problems set forth in the background art described above. The invention provides a device for monitoring the temperature of transverse cutting and scribing on line, which has the characteristics of convenience in use and capability of monitoring the temperature of transverse cutting and scribing in real time.

In order to achieve the purpose, the invention provides the following technical scheme: a device for monitoring the temperature of a crosscut scribing line on line comprises a transverse moving chassis assembly, wherein a transverse moving base assembly is arranged on the transverse moving chassis assembly in a threaded reciprocating mode, a temperature measuring probe mounting assembly is movably arranged at the bottom of the transverse moving base assembly in an all-around mode, and an infrared temperature measuring probe is fixedly arranged at the end portion of the temperature measuring probe mounting assembly in a clamping mode;

the transverse moving underframe assembly comprises a U-shaped transverse moving underframe plate, a transverse moving threaded rod is rotatably arranged in the U-shaped transverse moving underframe plate through a bearing seat, a first driving motor for driving the transverse moving threaded rod to rotate in two directions is fixedly arranged at one end of the U-shaped transverse moving underframe plate, mounting holes are formed in plate bodies at two ends of the U-shaped transverse moving underframe plate, and a linear moving guide transverse groove is formed in an end panel body of the U-shaped transverse moving underframe plate;

the transverse moving base assembly comprises a fixed vertical rod, an internal thread transverse moving block is fixedly arranged at the top of the fixed vertical rod, a temperature measurement moving block is fixedly arranged at the bottom of the fixed vertical rod, a linear guide convex rod is fixedly arranged on the front end face of the internal thread transverse moving block, a temperature measurement moving ball groove is formed in the temperature measurement moving block, a fixed support lug plate is fixedly arranged on the rear end face of the bottom of the temperature measurement moving block, a second driving motor is fixedly arranged at the top of the fixed support lug plate, a Z-shaped rotating shaft rod is fixedly arranged on a power output shaft of the second driving motor, and a linkage arm plate is rotatably arranged at the bottom of the Z-shaped rotating shaft rod through a bearing seat;

the temperature measuring probe mounting assembly comprises a supporting bottom rod, a movable ball head is fixedly arranged at one end of the supporting bottom rod, a fixed disc is fixedly arranged at the other end of the supporting bottom rod, a supporting support rod is fixedly arranged at the bottom of the movable ball head, a supporting ejector rod is fixedly arranged on the fixed disc, two arc-shaped clamping plates are symmetrically and fixedly arranged at the end part of the supporting ejector rod, a clamping gap is formed between the two arc-shaped clamping plates, a jacking spring and a movable outer sleeve are sleeved on the supporting ejector rod, a jacking disc is fixedly arranged at one end of the movable outer sleeve, and an arc-shaped furling ring tube is fixedly arranged at the other end of the movable outer sleeve;

the two arc-shaped clamping plates are elastically fixed relative to the supporting ejector rod, one end of the jacking spring is abutted against the fixed disc, the other end of the jacking spring is abutted against the jacking and pressing disc, the arc-shaped furling ring pipe automatically moves outwards on the supporting ejector rod through the jacking of the jacking spring in a natural state, and the two arc-shaped clamping plates are always in a clamping state through the automatic jacking and outwards moving of the arc-shaped furling ring pipe;

when the transverse moving underframe assembly and the transverse moving base assembly are assembled for use, the internal thread transverse moving block performs threaded movement on the transverse moving threaded rod, and the linear guide convex rod performs guide movement on the front end panel body of the U-shaped transverse moving base plate through the linear movement guide transverse groove;

when the temperature measuring probe mounting assembly and the transverse moving base assembly are assembled for use, the movable ball head moves in all directions in the temperature measuring movable block through the temperature measuring movable ball groove, and the bottom rod body of the supporting rod is rotatably connected with the end plate body of the linkage arm plate through the bearing seat.

Preferably, the infrared temperature measuring probe is clamped and fixed at the end part of the temperature measuring probe mounting assembly through clamping and clamping between the two arc-shaped clamping plates.

Preferably, the transverse moving base assembly is in threaded transverse bidirectional reciprocating movement on the transverse moving base frame assembly through bidirectional rotation of the first driving motor and threaded cooperation of the internal threaded transverse moving block and the transverse moving threaded rod.

Preferably, the temperature measuring probe mounting assembly can move in all directions towards the temperature measuring angle on the transverse moving base assembly through the rotation of the second driving motor, the linkage fit among the Z-shaped rotating shaft rod, the linkage arm plate and the supporting rod and the all-directional movement of the movable ball head in the temperature measuring movable ball groove.

Preferably, the transversely moving chassis assembly is mounted on a crosscutting apparatus for substrate glass manufacturing by means of fixing bolts and mounting holes.

Compared with the prior art, the invention has the beneficial effects that: when the invention monitors the temperature of the crosscut marking on line, a transversely moving underframe assembly is arranged on crosscut equipment made of substrate glass through a fixed bolt and a mounting hole, and the transverse moving base assembly can transversely and bidirectionally move on the transversely moving underframe assembly through the bidirectional rotation of a first driving motor and the threaded fit of an internal thread transverse moving block and a transverse moving threaded rod, so that the infrared temperature measuring probe can transversely and reciprocally move left and right during the temperature measuring of the crosscut marking, when the temperature measuring probe mounting assembly and the transversely moving base assembly are assembled and used, a movable ball head can omnidirectionally move in the temperature measuring movable block through a temperature measuring movable ball groove, a bottom rod body of a supporting rod is rotatably connected with an end plate body of a linkage arm plate through a bearing seat, and the bottom rod body of the supporting rod can rotatably connect with a Z-shaped rotating shaft lever, the linkage arm plate and the supporting rod through the rotation of a second driving motor and the omnibearing movement of the movable ball head in, the invention realizes the omnibearing movement of the temperature measurement angle of the temperature measurement probe mounting component on the transverse moving base component, and by the way, the omnibearing movement of the temperature measurement angle of the infrared temperature measurement probe during the transverse cutting scribing temperature measurement is realized, the temperature measurement area and the temperature measurement effectiveness are enlarged, the arc-shaped furling ring pipe automatically moves outwards on the supporting ejector rod through the propping of the propping spring, the two arc-shaped clamping plates are always in a clamping state through the automatic propping and outwards moving of the arc-shaped furling ring pipe, and the infrared temperature measurement probe is clamped and fixed at the end part of the temperature measurement probe mounting component through the clamping and clamping between the two arc-shaped clamping plates, thereby facilitating the disassembly and the replacement during the damage of the infrared temperature measurement probe during the temperature measurement, and by the invention, the transverse cutting scribing temperature and the annealing furnace outlet temperature can be monitored in real time during the operation process of the transverse cutting machine, the influence of temperature on the cutting state of the cutter wheel and the influence of temperature on the cutting section and the service life of the cutter wheel are observed, the influence of temperature gradient on warping is favorably analyzed subsequently, the forming quality is improved, the temperature is a main factor influencing the warping of glass, and the method is favorable for subsequent analysis and improvement of the grade and the yield of the glass plate.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a perspective view from another perspective of the present invention;

FIG. 3 is an exploded view of the present invention;

FIG. 4 is a perspective view of the laterally movable undercarriage assembly of the present invention;

FIG. 5 is a perspective view of the laterally movable base assembly, the temperature probe mounting assembly and the infrared temperature probe of the present invention;

FIG. 6 is a perspective view of the laterally displaceable base assembly of the present invention;

FIG. 7 is a perspective view of a temperature probe mounting assembly and an infrared temperature probe of the present invention;

FIG. 8 is a perspective view of the temperature probe mounting assembly of the present invention;

FIG. 9 is an exploded view of the temperature probe mounting assembly of the present invention;

in the figure: 1. laterally moving the chassis assembly; 101. u-shaped transverse moving chassis plates; 102. moving the threaded rod transversely; 103. a first drive motor; 104. a linear movement guide transverse groove; 105. mounting holes; 2. laterally moving the base assembly; 201. fixing the vertical rod; 202. an internal thread transverse moving block; 203. a linear guide convex rod; 204. a temperature measuring movable block; 205. a temperature measuring movable ball groove; 206. fixing the supporting ear plate; 207. a second drive motor; 208. a Z-shaped rotating shaft lever; 209. a linkage arm plate; 3. a temperature probe mounting assembly; 301. a support bottom bar; 302. a movable ball head; 303. a support strut; 304. fixing the disc; 305. supporting the ejector rod; 306. the spring is tightly propped; 307. an arc-shaped clamping plate; 308. a clamping gap; 309. a movable outer sleeve; 310. the jacking and jacking disc is tightly pressed; 311. an arc-shaped furling ring pipe; 4. an infrared temperature probe.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-9, the present invention provides the following technical solutions: a device for monitoring the temperature of a crosscut scribing line on line comprises a transverse moving chassis component 1, wherein a transverse moving base component 2 is arranged on the transverse moving chassis component 1 in a threaded reciprocating mode, a temperature measuring probe mounting component 3 is arranged at the bottom of the transverse moving base component 2 in an omnibearing movable mode, and an infrared temperature measuring probe 4 is fixedly arranged at the end part of the temperature measuring probe mounting component 3 in a clamping mode;

the transverse moving underframe assembly 1 comprises a U-shaped transverse moving underframe plate 101, a transverse moving threaded rod 102 is rotatably arranged inside the U-shaped transverse moving underframe plate 101 through a bearing seat, a first driving motor 103 for driving the transverse moving threaded rod 102 to rotate in two directions is fixedly arranged at one end of the U-shaped transverse moving underframe plate 101, mounting holes 105 are respectively formed in plate bodies at two ends of the U-shaped transverse moving underframe plate 101, and a linear moving guide transverse groove 104 is formed in an end panel body of the U-shaped transverse moving underframe plate 101;

the transverse moving base component 2 comprises a fixed vertical rod 201, an internal thread transverse moving block 202 is fixedly arranged at the top of the fixed vertical rod 201, a temperature measurement moving block 204 is fixedly arranged at the bottom of the fixed vertical rod 201, a linear guide convex rod 203 is fixedly arranged on the front end face of the internal thread transverse moving block 202, a temperature measurement moving ball groove 205 is formed in the temperature measurement moving block 204, a fixed support lug plate 206 is fixedly arranged on the rear end face of the bottom of the temperature measurement moving block 204, a second driving motor 207 is fixedly arranged at the top of the fixed support lug plate 206, a Z-shaped rotating shaft rod 208 is fixedly arranged on a power output shaft of the second driving motor 207, and a linkage arm plate 209 is rotatably arranged at the bottom of the Z-shaped rotating shaft rod 208 through a bearing seat;

the temperature measuring probe mounting component 3 comprises a support bottom rod 301, a movable ball head 302 is fixedly arranged at one end of the support bottom rod 301, a fixed disc 304 is fixedly arranged at the other end of the support bottom rod 301, a support supporting rod 303 is fixedly arranged at the bottom of the movable ball head 302, a support top rod 305 is fixedly arranged on the fixed disc 304, two arc-shaped clamping plates 307 are symmetrically and fixedly arranged at the end part of the support top rod 305, a clamping gap 308 is formed between the two arc-shaped clamping plates 307, a jacking spring 306 and a movable outer sleeve 309 are sleeved on the support top rod 305, a jacking disc 310 is fixedly arranged at one end of the movable outer sleeve 309, and an arc-shaped furling ring tube 311 is fixedly arranged at the other end of the movable outer sleeve;

the two arc-shaped clamping plates 307 are elastically fixed relative to the supporting ejector rod 305, one end of the jacking spring 306 abuts against the fixed disc 304, the other end of the jacking spring 306 abuts against the jacking and pressing disc 310, under a natural state, the arc-shaped furling ring tube 311 automatically moves outwards on the supporting ejector rod 305 through the jacking of the jacking spring 306, and the two arc-shaped clamping plates 307 are always in a clamping state through the automatic jacking and outwards moving of the arc-shaped furling ring tube 311;

when the transverse moving underframe assembly 1 and the transverse moving base assembly 2 are assembled for use, the internal thread transverse moving block 202 moves on the transverse moving threaded rod 102 in a threaded manner, and the linear guide convex rod 203 moves on the front end panel body of the U-shaped transverse moving underframe plate 101 in a guide manner through the linear movement guide transverse groove 104;

when the temperature measurement probe mounting component 3 and the transverse moving base component 2 are assembled for use, the movable ball head 302 moves in the temperature measurement movable block 204 in all directions through the temperature measurement movable ball groove 205, and the bottom rod body of the supporting rod 303 is rotatably connected with the end plate body of the linkage arm plate 209 through the bearing seat.

In this embodiment, preferably, the infrared thermometer 4 is clamped and fixed to the end of the thermometer mounting block 3 by clamping between two arc-shaped clamping plates 307.

In this embodiment, the laterally moving base assembly 2 is preferably threaded laterally and bidirectionally reciprocally moved on the laterally moving base assembly 1 by the bidirectional rotation of the first driving motor 103 and the threaded engagement of the internally threaded laterally moving block 202 and the laterally moving threaded rod 102.

In this embodiment, preferably, the rotation of the second driving motor 207, the linkage fit among the Z-shaped rotating shaft 208, the linkage arm plate 209, and the support rod 303, and the omnidirectional movement of the movable ball 302 in the temperature measuring movable ball groove 205 realize the omnidirectional movement of the temperature measuring probe mounting assembly 3 toward the temperature measuring angle on the lateral movement base assembly 2.

In this embodiment, the traverse chassis assembly 1 is preferably mounted on a crosscutting apparatus for substrate glass manufacturing by means of fixing bolts and mounting holes 105.

The infrared temperature measuring probe 4 of the present invention is a known technology which has been disclosed to be widely used in daily life, and is model number SA50 AC.

The working principle and the using process of the invention are as follows: when the invention monitors the temperature of the crosscut scribing on line, the transverse moving underframe assembly 1 is arranged on crosscut equipment made of substrate glass through a fixed bolt and a mounting hole 105, the transverse moving base assembly 2 can transversely and bidirectionally reciprocate on the transverse moving underframe assembly 1 through the bidirectional rotation of a first driving motor 103 and the threaded matching of an internal thread transverse moving block 202 and a transverse moving threaded rod 102, so that the infrared temperature measuring probe 4 can transversely and reciprocally move left and right during the temperature measurement of the crosscut scribing, when the temperature measuring probe mounting assembly 3 and the transverse moving base assembly 2 are assembled and used, a movable ball head 302 can omnidirectionally move in a temperature measuring movable block 204 through a temperature measuring movable ball groove 205, a bottom rod body of a supporting rod 303 is rotationally connected with an end plate body of a linkage arm plate 209 through a bearing seat, and is rotationally connected with a Z-shaped rotating shaft rod 208, a Z-shaped rotating shaft rod 208 and a transverse moving rod, The linkage matching between the linkage arm plate 209 and the supporting rod 303 and the omnibearing movement of the movable ball head 302 in the temperature measuring movable ball groove 205 realize the omnibearing movement of the temperature measuring probe mounting component 3 towards the temperature measuring angle on the transverse moving base component 2, and by the way, the omnibearing movement of the temperature measuring angle when the infrared temperature measuring probe 4 is used for transverse cutting marking temperature measurement is realized, the temperature measuring area and the temperature measuring effectiveness are enlarged, the arc-shaped furling ring tube 311 automatically moves outwards on the supporting ejector rod 305 by the jacking of the jacking spring 306, the two arc-shaped clamping plates 307 are always in a clamping state by the automatic jacking and outwards moving of the arc-shaped furling ring tube 311, the infrared temperature measuring probe 4 is clamped and fixed at the end part of the temperature measuring probe mounting component 3 by the clamping between the two arc-shaped clamping plates 307, and the replacement of the infrared temperature measuring probe 4 during temperature measurement and use is convenient by the way, by the invention, the cross cutting scribing temperature and the annealing furnace outlet temperature can be monitored in real time in the operation process of the cross cutting machine, the influence of the temperature on the cutting state of the cutter wheel and the influence of the temperature on the cutting section and the service life of the cutter wheel can be observed, the subsequent analysis of the influence of the temperature gradient on the warping is facilitated, the forming quality is improved, the temperature is a main factor influencing the glass warping, and the method is beneficial to the subsequent analysis and the improvement of the grade and the capacity of the glass plate.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. An apparatus for on-line monitoring of crosscut scoring temperature comprising a laterally moving chassis assembly (1), characterized in that: a transverse moving base assembly (2) is arranged on the transverse moving underframe assembly (1) in a threaded reciprocating manner, a temperature measuring probe mounting assembly (3) is movably arranged at the bottom of the transverse moving base assembly (2) in all directions, and an infrared temperature measuring probe (4) is fixedly arranged at the end part of the temperature measuring probe mounting assembly (3) in a clamping manner;

the transverse moving underframe assembly (1) comprises a U-shaped transverse moving underframe plate (101), a transverse moving threaded rod (102) is rotatably arranged inside the U-shaped transverse moving underframe plate (101) through a bearing seat, a first driving motor (103) for driving the transverse moving threaded rod (102) to rotate in two directions is fixedly arranged at one end of the U-shaped transverse moving underframe plate (101), mounting holes (105) are formed in plate bodies at two ends of the U-shaped transverse moving underframe plate (101), and a linear moving guide transverse groove (104) is formed in an end panel body of the U-shaped transverse moving underframe plate (101);

the transverse moving base component (2) comprises a fixed vertical rod (201), an internal thread transverse moving block (202) is fixedly arranged at the top of the fixed vertical rod (201), a temperature measuring movable block (204) is fixedly arranged at the bottom of the fixed vertical rod (201), a linear guide convex rod (203) is fixedly arranged on the front end surface of the internal thread transverse moving block (202), a temperature measuring movable ball groove (205) is arranged inside the temperature measuring movable block (204), and a fixed supporting ear plate (206) is fixedly arranged on the rear end surface of the bottom of the temperature measuring movable block (204), a second driving motor (207) is fixedly arranged at the top of the fixed supporting ear plate (206), a Z-shaped rotating shaft lever (208) is fixedly arranged on a power output shaft of the second driving motor (207), the bottom of the Z-shaped rotating shaft rod (208) is rotatably provided with a linkage arm plate (209) through a bearing seat;

the temperature measuring probe mounting component (3) comprises a supporting bottom rod (301), one end of the supporting bottom rod (301) is fixedly provided with a movable ball head (302), a fixed disc (304) is fixedly arranged at the other end of the supporting bottom rod (301), a supporting strut (303) is fixedly arranged at the bottom of the movable ball head (302), a supporting ejector rod (305) is fixedly arranged on the fixed disc (304), two arc-shaped clamping plates (307) are symmetrically distributed and fixedly arranged at the end part of the supporting ejector rod (305), a clamping gap (308) is formed between the two arc-shaped clamping plates (307), a jacking spring (306) and a movable outer sleeve (309) are sleeved on the supporting ejector rod (305), one end of the movable outer sleeve (309) is fixedly provided with a jacking and jacking disc (310), and the other end of the movable outer sleeve (309) is fixedly provided with an arc-shaped furling ring tube (311);

the two arc-shaped clamping plates (307) are elastically fixed relative to the supporting ejector rod (305), one end of the jacking spring (306) abuts against the fixed disc (304), the other end of the jacking spring (306) abuts against the jacking and pressing disc (310), under a natural state, the arc-shaped furling ring pipe (311) automatically moves outwards on the supporting ejector rod (305) through jacking of the jacking spring (306), and the two arc-shaped clamping plates (307) are always in a clamping state through automatic jacking and outwards moving of the arc-shaped furling ring pipe (311);

when the transverse moving underframe assembly (1) and the transverse moving base assembly (2) are assembled for use, the internal thread transverse moving block (202) moves on the transverse moving threaded rod (102) in a threaded manner, and the linear guide convex rod (203) moves on the front end panel body of the U-shaped transverse moving underframe plate (101) in a guide manner through the linear movement guide transverse groove (104);

when temperature probe installation component (3) and lateral shifting base subassembly (2) assembly use, activity bulb (302) are all-round activity in temperature measurement movable block (204) through temperature measurement activity ball groove (205), the bottom body of rod of support rod (303) passes through the bearing frame and is connected with the tip plate body rotation of linkage arm board (209).

2. The device for on-line monitoring of the temperature of the crosscut scribing line according to the claim 1, wherein: the infrared temperature measuring probe (4) is clamped and fixed at the end part of the temperature measuring probe mounting component (3) through clamping and clamping between the two arc-shaped clamping plates (307).

3. The device for on-line monitoring of the temperature of the crosscut scribing line according to the claim 1, wherein: the transverse moving base component (2) can move in a threaded transverse bidirectional reciprocating mode on the transverse moving base component (1) through bidirectional rotation of the first driving motor (103) and threaded matching of the internal threaded transverse moving block (202) and the transverse moving threaded rod (102).

4. The device for on-line monitoring of the temperature of the crosscut scribing line according to the claim 1, wherein: the temperature measurement probe mounting component (3) can move in all directions towards a temperature measurement angle on the transverse moving base component (2) through the rotation of the second driving motor (207), the linkage fit among the Z-shaped rotating shaft rod (208), the linkage arm plate (209) and the supporting rod (303) and the all-directional movement of the movable ball head (302) in the temperature measurement movable ball groove (205).

5. The device for on-line monitoring of the temperature of the crosscut scribing line according to the claim 1, wherein: the transverse moving chassis assembly (1) is mounted on a transverse cutting device for manufacturing substrate glass through a fixing bolt and a mounting hole (105).

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