阅读说明：本技术 一种天窗玻璃组合检具及其实施方法 (Skylight glass combined detection tool and implementation method thereof ) 是由 刘文仁 于 2021-09-06 设计创作，主要内容包括：本发明涉及玻璃检测技术领域,公开了一种天窗玻璃组合检具及其实施方法,包括支撑件以及依次设置在支撑件四角内侧的第一稳固部件、第二稳固部件、第三稳固部件和第四稳固部件,支撑件的四角设置有安装钉,支撑件上还设置有模拟块,第一稳固部件、第二稳固部件、第三稳固部件和第四稳固部件结构组成相同,支撑件的上端一侧设置有夹紧部件,支撑件的上端另一侧设置有定位部件；支撑件的一侧还是设置有第一校零件,支撑件的一侧还是设置有第二校零件,本发明的有益效果为通过一个检具可实现一侧固定,进行表面检测、孔径检测、轮廓检测等的全面检测。(The invention relates to the technical field of glass detection, and discloses a skylight glass combined detection tool and an implementation method thereof, wherein the skylight glass combined detection tool comprises a support piece, and a first stabilizing part, a second stabilizing part, a third stabilizing part and a fourth stabilizing part which are sequentially arranged on the inner sides of four corners of the support piece, mounting nails are arranged on the four corners of the support piece, a simulation block is also arranged on the support piece, the first stabilizing part, the second stabilizing part, the third stabilizing part and the fourth stabilizing part have the same structure composition, a clamping part is arranged on one side of the upper end of the support piece, and a positioning part is arranged on the other side of the upper end of the support piece; one side of the supporting piece is provided with a first correcting part, and one side of the supporting piece is provided with a second correcting part.)

1. A skylight glass combined detection tool comprises a support member (1), and a first stabilizing part (2), a second stabilizing part (3), a third stabilizing part (4) and a fourth stabilizing part (5) which are sequentially arranged on the inner sides of four corners of the support member (1), wherein mounting nails (11) are arranged on the four corners of the support member (1), and a simulation block (12) is also arranged on the support member (1), and the skylight glass combined detection tool is characterized in that the first stabilizing part (2), the second stabilizing part (3), the third stabilizing part (4) and the fourth stabilizing part (5) are identical in structure composition, a clamping part (6) is arranged on one side of the upper end of the support member (1), and a positioning part (7) is arranged on the other side of the upper end of the support member (1);

one side of the supporting piece (1) is also provided with a first correcting part (8), and one side of the supporting piece (1) is also provided with a second correcting part (9).

2. The combined checking fixture for skylight glass according to claim 1, wherein the first stabilizing component (2) comprises a supporting base (21) and an upper clamping assembly (23) arranged on the supporting base (21), and a lower clamping assembly (22) is arranged at the upper end of the supporting piece (1) opposite to the upper clamping assembly (23) and is used for preliminarily supporting glass and fixedly clamping the lower clamping assembly (22) by matching with the upper clamping assembly (23).

3. The combined inspection tool for skylight glass according to claim 2, wherein the lower clamping assembly (22) comprises a supporting chassis (221) and a mounting barrel (222) arranged at the upper end of the supporting chassis (221), an adjusting rod (223) is inserted into one side of the mounting barrel (222), and a clamp spring, a clamp strip and other structures can be arranged at the end of the adjusting rod (223) inserted into the mounting barrel (222).

4. The combined skylight glass testing fixture according to claim 3, wherein an opening on one side of the mounting barrel (222) for penetrating the adjusting rod (223) is L-shaped, a main supporting barrel (224) is further disposed on an inner side end of the adjusting rod (223), the main supporting barrel (224) can extend out of the mounting barrel (222), an auxiliary lifting barrel (225) is disposed on an inner side of the main supporting barrel (224), and a return spring is disposed on an inner side end of the auxiliary lifting barrel (225).

5. The combined inspection tool for the skylight glass as claimed in claim 4, wherein the upper clamping assembly (23) comprises a mounting seat (231) and a clamping rod (233) arranged in the middle of the mounting seat (231) and used for clamping the glass, the clamping rod (233) is movably connected with the mounting seat (231) through a pin (232), a lead screw (234) is arranged in the middle of the clamping rod (233) and penetrates through the clamping rod (233) to be in threaded connection with the mounting seat (231), the lead screw (234) can limit the rotation of the clamping rod (233), and a limiting block (235) is further arranged at the front end of the mounting seat (231).

6. A combined skylight glass inspection tool according to claim 5, wherein the clamping component (6) comprises a glass support (61) and a first positioning pin (62) arranged at the upper end of the glass support (61), and the other end of the first positioning pin (62) is arranged in the middle of the adjusting support (63).

7. The combined skylight glass testing fixture according to claim 6, wherein the positioning component (7) comprises a mounting piece (71) and a second positioning pin (72) arranged in the middle of the mounting piece (71), and the second positioning pin (72) movably penetrates through the mounting piece (71).

8. The combined skylight glass testing fixture according to claim 7, wherein the first calibrating component (8) comprises a butt-joint block (81) and a calibrating support block (82) arranged at the upper end of the butt-joint block (81), and the other end of the calibrating support block (82) is provided with a first zero calibration instrument (83).

9. The combined checking fixture for skylight glass according to claim 8, wherein the second calibrating component (9) comprises a clamping block (91) and a stabilizing block (92) arranged on the upper side of one end of the clamping block (91), and a second zero calibration instrument (93) movably penetrates through the upper end of the stabilizing block (92).

10. An implementation method of the skylight glass combination gauge of claim 9, comprising the following steps:

s1: cleaning the upper plane and the hole sites on the upper surface of the simulation block (12), and cleaning other positioning surfaces and positioning pins to ensure that the upper surface is not polluted;

s2: forcibly pressing down a lower clamping assembly (22) of a first stabilizing part (2), a second stabilizing part (3) and a third stabilizing part (4), slightly placing a product on the first stabilizing part (2), the second stabilizing part (3), the third stabilizing part (4) and a fourth stabilizing part (5), tightly attaching a glass bottom plate to a clamping part (6) for positioning, inserting a first positioning pin (62) into a product hole, screwing a locking handle to death, clamping a positioning part (7) first, and pressing an upper clamping assembly (23) tightly to the product to position a part;

s3: detecting whether the peripheral gap between the product and the simulation block (12) reaches a tolerance range through a taper gap ruler, wherein the product is qualified if the peripheral gap is within the tolerance range, and the product is unqualified if the peripheral gap is not within the tolerance range;

s4: detecting whether the peripheral gap between the clamping component (6) and the simulation block (12) reaches a tolerance range through a taper gap ruler, wherein the product is qualified if the peripheral gap is within the tolerance range, and the product is unqualified if the peripheral gap is not within the tolerance range;

s5: inserting the positioning component (7) into the part, wherein the position degree of the product hole is qualified if the positioning component (7) can be smoothly inserted into the part hole, and the position degree of the product hole is unqualified if the positioning component (7) can not be smoothly inserted into the part hole;

s6: the dial indicator measures zero calibration on F by using glass curvature, then a first zero calibration instrument (83) is inserted into a hole position of the simulation block (12) and is vertically inserted, the bottom surface of the first zero calibration instrument is abutted against the simulation block (12), and whether a product is qualified or not is judged according to the numerical value of the dial indicator and is used for detecting the surface of glass;

s7: the dial indicator measures the zero calibration of the zero calibration block by using the glass RIN, then a second calibration part (9) is inserted into a hole position of the simulation block (12), the bottom surface of the second calibration part is abutted against the simulation block (12), and whether a product is qualified or not is judged by the numerical value of the indicator and is used for detecting the outline of the glass;

s8: after the detection is finished, the locking handle is unscrewed to loosen the clamping block, then the clamping component (6) and the positioning component (7) are pulled backwards, and the product is taken down for the detection of the next product.

Technical Field

The invention relates to the technical field of glass detection, in particular to a skylight glass combined detection tool and an implementation method thereof.

Background

Glass is an amorphous inorganic non-metallic material, generally made from a variety of inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash, etc.) as main raw materials, and a small amount of auxiliary raw materials, and its main components are silicon dioxide and other oxides. The chemical composition of the common glass is Na2SiO3, CaSiO3, SiO2 or Na 2O. CaO.6SiO 2, and the like, and the main component is a silicate double salt which is an amorphous solid with a random structure.

However, when the existing skylight glass combination inspection tool detects glass, the glass needs to be fixed, the existing fixing operation is too rough, the damage to the glass is large, and when corner fine inspection is performed, the stability is poor, and the surface detection, the aperture detection, the contour detection and the like of the glass need different inspection tools for detection, so that the operation is troublesome, the operation repetition rate of the detection process is high, and the workload is increased.

To solve the above problems. Therefore, the skylight glass combined gauge and the implementation method thereof are provided.

Disclosure of Invention

The invention aims to provide a skylight glass combined detection tool and an implementation method thereof, one side of the detection tool can be fixed, and surface detection, aperture detection and contour detection can be carried out, so that the problems in the background technology can be solved.

In order to achieve the purpose, the invention provides the following technical scheme: a skylight glass combined checking fixture comprises a supporting piece, and a first stabilizing part, a second stabilizing part, a third stabilizing part and a fourth stabilizing part which are sequentially arranged on the inner sides of four corners of the supporting piece, wherein mounting nails are arranged at the four corners of the supporting piece;

one side of the supporting piece is provided with a first correcting part, and one side of the supporting piece is provided with a second correcting part.

Furthermore, the first stabilizing part comprises a supporting base and an upper clamping assembly arranged on the supporting base, and a lower clamping assembly is arranged at the upper end of the supporting piece opposite to the clamping assembly and used for preliminarily supporting the glass and is matched with the upper clamping assembly to fixedly clamp the lower clamping assembly.

Furthermore, lower clamping component is including supporting the chassis and setting up the installation bucket in supporting the chassis upper end, and one side of installation bucket has inserted the regulation pole, and the regulation pole inserts the inside tip of installation bucket and can be provided with structures such as jump ring, card strip.

Furthermore, an opening, used for penetrating through the adjusting rod, in one side of the mounting barrel is L-shaped, the inner side end of the adjusting rod is further provided with a main supporting barrel, the main supporting barrel can extend out of the mounting barrel, the inner side of the main supporting barrel is provided with an auxiliary lifting barrel, and the inner side end of the auxiliary lifting barrel is provided with a reset spring.

Further, go up clamping unit and include the mount pad and set up the supporting rod in the mount pad middle part for centre gripping glass, the supporting rod passes through the round pin post and is connected with the mount pad swing joint, and the middle part of supporting rod is provided with the lead screw to run through supporting rod and mount pad threaded connection, the lead screw can inject the supporting rod and rotate, and the preceding tip of mount pad still is provided with the restriction piece.

Further, the clamping member includes a glass support and a first positioning pin provided at an upper end of the glass support, and the other end of the first positioning pin is provided at a middle portion of the adjusting support.

Further, the positioning component comprises an installation component and a second positioning pin arranged in the middle of the installation component, and the second positioning pin movably penetrates through the installation component.

Further, the first correcting part comprises a butt joint block and a correcting support block arranged at the upper end of the butt joint block, and a first zero correcting instrument is arranged at the other end of the correcting support block.

Further, the part is rectified to the second includes the grip block and sets up the stable piece in grip block one end upside, and the activity of stable piece upper end is run through and is rectified zero appearance to the second.

The invention provides another technical scheme that: the implementation method of the skylight glass combined gauge comprises the following steps:

s1: cleaning the hole sites on the upper plane and the upper surface of the simulation block, and cleaning other positioning surfaces and positioning pins to ensure that the upper surface is not polluted;

s2: forcibly pressing down lower clamping assemblies of the first stabilizing part, the second stabilizing part and the third stabilizing part, lightly placing a product on the first stabilizing part, the second stabilizing part, the third stabilizing part and the fourth stabilizing part, positioning the glass bottom plate by closely attaching the clamping parts, inserting the first positioning pin into a product hole, screwing the locking handle to be dead, clamping the positioning part first, and pressing the upper clamping assembly tightly to the product to position the part;

s3: detecting whether the peripheral gap between the product and the simulation block reaches a tolerance range or not through a taper gap ruler, wherein the product is qualified if the peripheral gap is within the tolerance range, and the product is unqualified if the peripheral gap is not within the tolerance range;

s4: detecting whether the peripheral gap between the clamping component and the simulation block reaches a tolerance range or not through a taper gap ruler, wherein the product is qualified if the peripheral gap is within the tolerance range, and the product is unqualified if the peripheral gap is not within the tolerance range;

s5: inserting the positioning component into the part, wherein the position degree of the product hole is qualified if the positioning component can be smoothly inserted into the part hole, and the position degree of the product hole is unqualified if the positioning component cannot be smoothly inserted into the part hole;

s6: the dial indicator measures zero calibration on F by using glass curvature, then the first zero calibration instrument is inserted into a hole site of the simulation block and is vertically inserted, the bottom surface of the first zero calibration instrument is abutted against the simulation block, and whether a product is qualified or not is judged according to the numerical value of the dial indicator and is used for detecting the surface of the glass;

s7: the dial indicator measures the zero calibration of the zero calibration block by using the glass RIN, then a second calibration part is inserted into the hole site of the simulation block, the bottom surface of the second calibration part is abutted against the simulation block, and whether the product is qualified or not is judged by the numerical value of the indicator and is used for detecting the glass outline;

s8: after the detection is finished, the locking handle is unscrewed to loosen the clamping block, then the clamping component and the positioning component are pulled backwards, and the product is taken down for the detection of the next product.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention provides a skylight glass combined checking fixture and an implementation method thereof.

2. The invention provides a skylight glass combination checking fixture and an implementation method thereof.

3. According to the skylight glass combination checking fixture and the implementation method thereof, the positioning part is inserted into the part, if the positioning part can be smoothly inserted into the part hole, the product hole position degree is qualified, and if the positioning part cannot be smoothly inserted into the part hole, the product hole position degree is unqualified.

4. The invention provides a skylight glass combined checking fixture and an implementation method thereof.A dial indicator measures zero calibration on F by using glass curvature, then a first zero calibration instrument is inserted into a hole site of a simulation block and is vertically inserted, the bottom surface of the simulation block is abutted against the simulation block, and whether a product is qualified or not is judged by the numerical value of the dial indicator and is used for detecting the surface of glass.

5. The invention provides a skylight glass combined checking fixture and an implementation method thereof.A dial indicator uses glass RIN to measure a zero calibration block for zero calibration, then a second calibration part is inserted into a hole site of a simulation block, the bottom surface of the second calibration part is abutted against the simulation block, and whether a product is qualified or not is judged according to the numerical value of the dial indicator, so that the skylight glass combined checking fixture is used for detecting the glass outline.

Drawings

FIG. 1 is a schematic overall three-dimensional structure diagram of a skylight glass combination gauge of the invention;

FIG. 2 is a schematic top plan view of a support member of the skylight glass combination inspection tool of the present invention;

FIG. 3 is a schematic perspective view of a lower clamping assembly of the skylight glass combination gauge of the present invention;

FIG. 4 is a schematic perspective view of an upper clamping assembly of the skylight glass combination gauge of the present invention;

FIG. 5 is a schematic perspective view of a clamping part of the skylight glass combination gauge of the present invention;

FIG. 6 is a schematic perspective view of a first correcting part of the skylight glass combination gauge of the present invention;

FIG. 7 is a schematic perspective view of a second calibration part of the skylight glass combination gauge.

In the figure: 1. a support member; 11. installing a nail; 12. an analog block; 2. a first stabilizing member; 21. a support base; 22. a lower clamping assembly; 221. a support chassis; 222. installing a barrel; 223. adjusting a rod; 224. a main support tub; 225. an auxiliary lifting barrel; 23. an upper clamping assembly; 231. a mounting seat; 232. a pin; 233. a clamping rod; 234. a screw rod; 235. a limiting block; 3. a second stabilizing member; 4. a third stabilizing member; 5. a fourth stabilizing member; 6. a clamping member; 61. a glass support; 62. a first positioning pin; 63. adjusting the support; 7. a positioning member; 71. a mounting member; 72. a second positioning pin; 8. a first alignment feature; 81. a butt joint block; 82. calibrating the supporting block; 83. a first zero calibration instrument; 9. a second calibration part; 91. a clamping block; 92. a stabilizing block; 93. and a second zero calibration instrument.

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.

The first embodiment is as follows:

in order to solve the technical problem of how to detect the glass combination gap and the hole position degree, the following embodiment is provided;

referring to fig. 1-5, including support piece 1 and set gradually the inboard first firm part 2 in support piece 1 four corners, the second firm part 3, the third firm part 4 and the fourth firm part 5, support piece 1's four corners is provided with installation nail 11, support piece 1 is last still to be provided with analog block 12, first firm part 2, the second firm part 3, the third firm part 4 is the same with the structure constitution of fourth firm part 5, support piece 1's upper end one side is provided with clamping part 6, support piece 1's upper end opposite side is provided with locating part 7.

The first stabilizing part 2 comprises a supporting base 21 and an upper clamping assembly 23 arranged on the supporting base 21, wherein a lower clamping assembly 22 is arranged at the upper end of the supporting part 1 opposite to the upper clamping assembly 23 and is used for preliminarily supporting glass, and the upper clamping assembly 23 is matched to fixedly clamp the lower clamping assembly 22.

The lower clamping assembly 22 comprises a supporting chassis 221 and an installation barrel 222 arranged at the upper end of the supporting chassis 221, an adjusting rod 223 is inserted into one side of the installation barrel 222, the end portion of the adjusting rod 223 inserted into the installation barrel 222 can be provided with a clamp spring, a clamping strip and other structures for limiting the movement of the adjusting rod 223, the adjusting rod 223 can be adjusted, an opening of one side of the installation barrel 222 for penetrating through the adjusting rod 223 is L-shaped, when the adjusting rod 223 is pulled to the bottom of the L-shaped structure, the adjusting rod 223 can be clamped, the inner side end of the adjusting rod 223 is further provided with a main supporting barrel 224, the main supporting barrel 224 can extend out of the installation barrel 222, the inner side of the main supporting barrel 224 is provided with an auxiliary lifting barrel 225, and the inner side end of the auxiliary lifting barrel 225 is provided with a reset spring, so that the auxiliary lifting barrel 225 can have certain elastic support.

Go up clamping unit 23 and include mount pad 231 and set up the centre gripping pole 233 in the middle part of mount pad 231 for the centre gripping glass, centre gripping pole 233 passes through round pin post 232 and mount pad 231 swing joint, be used for making centre gripping pole 233 can rotate, the middle part of centre gripping pole 233 is provided with lead screw 234, and run through centre gripping pole 233 and mount pad 231 threaded connection, lead screw 234 can inject centre gripping pole 233 and rotate, be used for fixed centre gripping pole 233, the front end portion of mount pad 231 still is provided with restricts piece 235.

The clamping component 6 comprises a glass supporting piece 61 and a first positioning pin 62 arranged at the upper end of the glass supporting piece 61, the other end of the first positioning pin 62 is arranged in the middle of the adjusting supporting piece 63, one end of the first positioning pin 62 on the supporting piece 63 can be adjusted through the adjusting supporting piece, so that the whole first positioning pin 62 can move back and forth, and the glass can be conveniently detected and positioned.

The positioning component 7 comprises a mounting piece 71 and a second positioning pin 72 arranged in the middle of the mounting piece 71, wherein the second positioning pin 72 movably penetrates through the mounting piece 71 and can be adjusted for inserting glass for positioning and fixing.

The invention provides another technical scheme that: the implementation method of the skylight glass combined gauge comprises the following steps:

the method comprises the following steps: cleaning the hole sites on the upper plane and the upper surface of the simulation block 12, and cleaning other positioning surfaces and positioning pins to ensure that the upper surface is not dirty;

step two: forcibly pressing down the lower clamping assemblies 22 of the first stabilizing part 2, the second stabilizing part 3 and the third stabilizing part 4, slightly placing a product on the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5, positioning the glass bottom plate by closely attaching the clamping parts 6, inserting the first positioning pin 62 into a product hole, screwing the locking handle to death, clamping the positioning part 7 firstly, and pressing the upper clamping assembly 23 tightly to position a part;

step three: detecting whether the clearance between the product and the periphery of the simulation block 12 reaches a tolerance range through a taper clearance gauge, wherein the product is qualified if the clearance is within the tolerance range, and the product is unqualified if the clearance is not within the tolerance range;

step four: detecting whether the peripheral gap between the clamping part 6 and the simulation block 12 reaches a tolerance range through a taper gap ruler, wherein the product is qualified if the peripheral gap is within the tolerance range, and the product is unqualified if the peripheral gap is not within the tolerance range;

step five: and inserting the positioning component 7 into the part, wherein the product hole position degree is qualified if the positioning component 7 can be smoothly inserted into the part hole, and the product hole position degree is unqualified if the positioning component 7 cannot be smoothly inserted into the part hole.

Example two:

in order to solve the technical problem of how to detect the surface of the glass, the following embodiment is provided;

referring to fig. 1-6, a skylight glass combination testing fixture comprises a support member 1, and a first stabilizing part 2, a second stabilizing part 3, a third stabilizing part 4 and a fourth stabilizing part 5 which are sequentially arranged at the inner sides of four corners of the support member 1, wherein mounting nails 11 are arranged at the four corners of the support member 1, a simulation block 12 is further arranged on the support member 1, the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5 are structurally identical, a clamping part 6 is arranged on one side of the upper end of the support member 1, and a positioning part 7 is arranged on the other side of the upper end of the support member 1.

The first stabilizing part 2 comprises a supporting base 21 and an upper clamping assembly 23 arranged on the supporting base 21, wherein a lower clamping assembly 22 is arranged at the upper end of the supporting part 1 opposite to the upper clamping assembly 23 and is used for preliminarily supporting glass, and the upper clamping assembly 23 is matched to fixedly clamp the lower clamping assembly 22.

The lower clamping assembly 22 comprises a supporting chassis 221 and an installation barrel 222 arranged at the upper end of the supporting chassis 221, an adjusting rod 223 is inserted into one side of the installation barrel 222, the end portion of the adjusting rod 223 inserted into the installation barrel 222 can be provided with a clamp spring, a clamping strip and other structures for limiting the movement of the adjusting rod 223, the adjusting rod 223 can be adjusted, an opening of one side of the installation barrel 222 for penetrating through the adjusting rod 223 is L-shaped, when the adjusting rod 223 is pulled to the bottom of the L-shaped structure, the adjusting rod 223 can be clamped, the inner side end of the adjusting rod 223 is further provided with a main supporting barrel 224, the main supporting barrel 224 can extend out of the installation barrel 222, the inner side of the main supporting barrel 224 is provided with an auxiliary lifting barrel 225, and the inner side end of the auxiliary lifting barrel 225 is provided with a reset spring, so that the auxiliary lifting barrel 225 can have certain elastic support.

Go up clamping unit 23 and include mount pad 231 and set up the centre gripping pole 233 in the middle part of mount pad 231 for the centre gripping glass, centre gripping pole 233 passes through round pin post 232 and mount pad 231 swing joint, be used for making centre gripping pole 233 can rotate, the middle part of centre gripping pole 233 is provided with lead screw 234, and run through centre gripping pole 233 and mount pad 231 threaded connection, lead screw 234 can inject centre gripping pole 233 and rotate, be used for fixed centre gripping pole 233, the front end portion of mount pad 231 still is provided with restricts piece 235.

The clamping component 6 comprises a glass supporting piece 61 and a first positioning pin 62 arranged at the upper end of the glass supporting piece 61, the other end of the first positioning pin 62 is arranged in the middle of the adjusting supporting piece 63, one end of the first positioning pin 62 on the supporting piece 63 can be adjusted through the adjusting supporting piece, so that the whole first positioning pin 62 can move back and forth, and the glass can be conveniently detected and positioned.

The positioning component 7 comprises a mounting piece 71 and a second positioning pin 72 arranged in the middle of the mounting piece 71, wherein the second positioning pin 72 movably penetrates through the mounting piece 71 and can be adjusted for inserting glass for positioning and fixing.

One side of the supporting member 1 is also provided with a first calibrating part 8, which comprises a butt joint block 81 and a calibrating support block 82 arranged at the upper end of the butt joint block 81, and the other end of the calibrating support block 82 is provided with a first zero calibrating instrument 83.

The invention provides another technical scheme that: the implementation method of the skylight glass combined gauge comprises the following steps:

the method comprises the following steps: cleaning the first correcting part 8 by using a cleaning cloth, cleaning the upper plane and the hole sites on the upper surface of the simulation block 12, and cleaning other positioning surfaces and positioning pins to ensure that the upper surface is not dirty;

step two: forcibly pressing down the lower clamping assemblies 22 of the first stabilizing part 2, the second stabilizing part 3 and the third stabilizing part 4, slightly placing a product on the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5, positioning the glass bottom plate by closely attaching the clamping parts 6, inserting the first positioning pin 62 into a product hole, screwing the locking handle to death, clamping the positioning part 7 firstly, and pressing the upper clamping assembly 23 tightly to position a part;

step three: the dial indicator measures zero calibration on F by using glass curvature, then a first zero calibration instrument 83 is inserted into a hole position of the simulation block 12 and vertically inserted, the bottom surface of the first zero calibration instrument is abutted against the simulation block 12, and whether a product is qualified or not is judged according to the numerical value of the indicator;

step four: after the detection is finished, the locking handle is unscrewed to loosen the clamping block, then the clamping component 6 and the positioning component 7 are pulled backwards, and the product is taken down for the detection of the next product.

Example three:

in order to solve the technical problem of how to detect the profile and the surface of a glass combination process and the surface of a single glass product and detect the profile, the following embodiment is provided;

referring to fig. 1-7, a skylight glass combination testing fixture comprises a support member 1, and a first stabilizing part 2, a second stabilizing part 3, a third stabilizing part 4 and a fourth stabilizing part 5 which are sequentially arranged at the inner sides of four corners of the support member 1, wherein mounting nails 11 are arranged at the four corners of the support member 1, a simulation block 12 is further arranged on the support member 1, the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5 are structurally identical, a clamping part 6 is arranged on one side of the upper end of the support member 1, and a positioning part 7 is arranged on the other side of the upper end of the support member 1.

The first stabilizing part 2 comprises a supporting base 21 and an upper clamping assembly 23 arranged on the supporting base 21, wherein a lower clamping assembly 22 is arranged at the upper end of the supporting part 1 opposite to the upper clamping assembly 23 and is used for preliminarily supporting glass, and the upper clamping assembly 23 is matched to fixedly clamp the lower clamping assembly 22.

The lower clamping assembly 22 comprises a supporting chassis 221 and an installation barrel 222 arranged at the upper end of the supporting chassis 221, an adjusting rod 223 is inserted into one side of the installation barrel 222, the end portion of the adjusting rod 223 inserted into the installation barrel 222 can be provided with a clamp spring, a clamping strip and other structures for limiting the movement of the adjusting rod 223, the adjusting rod 223 can be adjusted, an opening of one side of the installation barrel 222 for penetrating through the adjusting rod 223 is L-shaped, when the adjusting rod 223 is pulled to the bottom of the L-shaped structure, the adjusting rod 223 can be clamped, the inner side end of the adjusting rod 223 is further provided with a main supporting barrel 224, the main supporting barrel 224 can extend out of the installation barrel 222, the inner side of the main supporting barrel 224 is provided with an auxiliary lifting barrel 225, and the inner side end of the auxiliary lifting barrel 225 is provided with a reset spring, so that the auxiliary lifting barrel 225 can have certain elastic support.

Go up clamping unit 23 and include mount pad 231 and set up the centre gripping pole 233 in the middle part of mount pad 231 for the centre gripping glass, centre gripping pole 233 passes through round pin post 232 and mount pad 231 swing joint, be used for making centre gripping pole 233 can rotate, the middle part of centre gripping pole 233 is provided with lead screw 234, and run through centre gripping pole 233 and mount pad 231 threaded connection, lead screw 234 can inject centre gripping pole 233 and rotate, be used for fixed centre gripping pole 233, the front end portion of mount pad 231 still is provided with restricts piece 235.

The clamping component 6 comprises a glass supporting piece 61 and a first positioning pin 62 arranged at the upper end of the glass supporting piece 61, the other end of the first positioning pin 62 is arranged in the middle of the adjusting supporting piece 63, one end of the first positioning pin 62 on the supporting piece 63 can be adjusted through the adjusting supporting piece, so that the whole first positioning pin 62 can move back and forth, and the glass can be conveniently detected and positioned.

The positioning component 7 comprises a mounting piece 71 and a second positioning pin 72 arranged in the middle of the mounting piece 71, wherein the second positioning pin 72 movably penetrates through the mounting piece 71 and can be adjusted for inserting glass for positioning and fixing.

One side of the supporting member 1 is also provided with a first calibrating part 8, which comprises a butt joint block 81 and a calibrating support block 82 arranged at the upper end of the butt joint block 81, and the other end of the calibrating support block 82 is provided with a first zero calibrating instrument 83.

One side of support piece 1 still is provided with second correction part 9, and second correction part 9 includes grip block 91 and sets up the piece 92 of stabilizing at grip block 91 one end upside, and the activity of stabilizing the piece 92 upper end is run through has the second to adjust zero appearance 93.

The invention provides another technical scheme that: the implementation method of the skylight glass combined gauge comprises the following steps:

the method comprises the following steps: cleaning the hole sites on the upper plane and the upper surface of the simulation block 12, and cleaning other positioning surfaces and positioning pins to ensure that the upper surface is not dirty;

step two: forcibly pressing down the lower clamping assemblies 22 of the first stabilizing part 2, the second stabilizing part 3 and the third stabilizing part 4, slightly placing a product on the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5, positioning the glass bottom plate by closely attaching the clamping parts 6, inserting the first positioning pin 62 into a product hole, screwing the locking handle to death, clamping the positioning part 7 firstly, and pressing the upper clamping assembly 23 tightly to position a part;

step three: the dial indicator measures zero calibration on F by using glass curvature, then a first zero calibration instrument 83 is inserted into a hole position of the simulation block 12 and is vertically inserted, the bottom surface of the first zero calibration instrument is abutted against the simulation block 12, and whether a product is qualified or not is judged according to the numerical value of the dial indicator and is used for glass surface detection;

step four: the dial indicator measures zero calibration of the zero calibration block by using glass RIN, then the second calibration part 9 is inserted into a hole position of the simulation block 12, the bottom surface of the second calibration part is abutted against the simulation block 12, and whether a product is qualified or not is judged according to the numerical value of the indicator and is used for detecting the outline of the glass.

In summary, the following steps: the invention relates to a skylight glass combined checking fixture and an implementation method thereof, which comprises a supporting piece 1, a first stabilizing part 2, a second stabilizing part 3, a third stabilizing part 4 and a fourth stabilizing part 5 which are sequentially arranged at the inner sides of four corners of the supporting piece 1, a lower clamping assembly 22 of the first stabilizing part 2, the second stabilizing part 3 and the third stabilizing part 4 is pressed down by force, then products are lightly placed on the first stabilizing part 2, the second stabilizing part 3, the third stabilizing part 4 and the fourth stabilizing part 5, a glass bottom plate is tightly attached to the clamping part 6 for positioning, then a first positioning pin 62 is inserted into a product hole, a locking handle is screwed, the upper clamping assembly 23 is tightly pressed by the positioning part 7 to position the products, whether the clearance between the products and the periphery of a simulation block 12 reaches a tolerance range or not is detected through a taper clearance ruler, if the products are qualified in the tolerance range, if the gap is not in the tolerance range, the gap is unqualified, whether the gap between the clamping component 6 and the simulation block 12 reaches the tolerance range is detected by a taper gap ruler, if the product is qualified within the tolerance range, and if the product is not qualified within the public range, the positioning component 7 is inserted into the part, if the positioning component 7 can be smoothly inserted into the part hole, the product hole position degree is qualified, if the positioning component can not be smoothly inserted into the part hole, the product hole position degree is unqualified, the dial indicator uses the glass curvature to measure the zero calibration on the F, then the first zeroing gauge 83 is inserted into the hole of the analog block 12, vertically inserted, with the bottom surface abutting against the analog block 12, judging whether the product is qualified or not according to the numerical value of the table, using a glass RIN to measure the zero calibration block for zero calibration by a dial indicator, then, the second correcting part 9 is inserted into the hole position of the simulation block 12, the bottom surface of the second correcting part is abutted against the simulation block 12, and whether the product is qualified or not is judged according to the numerical value of the table and is used for detecting the glass outline.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.