CN214308489U - Cavity glass stacking error detection device - Google Patents

Cavity glass stacking error detection device Download PDF

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Publication number
CN214308489U
CN214308489U CN202120629350.XU CN202120629350U CN214308489U CN 214308489 U CN214308489 U CN 214308489U CN 202120629350 U CN202120629350 U CN 202120629350U CN 214308489 U CN214308489 U CN 214308489U
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China
Prior art keywords
probe
auxiliary plate
guide groove
positioning strip
sliding block
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CN202120629350.XU
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Chinese (zh)
Inventor
何丹峰
王小军
李磊
缪映京
沈慧珺
刘小鹿
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Jiangsu Testing Center For Quality Of Construction Engineering Co ltd
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Jiangsu Testing Center For Quality Of Construction Engineering Co ltd
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Abstract

The utility model discloses a hollow glass stacking difference detection device, which comprises a positioning strip and an auxiliary plate which are vertically connected together and form an L-shaped structure, wherein one side of the auxiliary plate adjacent to the positioning strip is used for being attached to one surface of hollow glass to be detected, one side of the positioning strip adjacent to the auxiliary plate is contacted with a bulge on the circumferential surface of the hollow glass to be detected, one side of the positioning strip adjacent to the auxiliary plate is provided with a guide groove which extends and is hollowed along the positioning strip, the guide groove is vertical to the auxiliary plate, a slide block is slidably arranged in the guide groove, a probe which is parallel to the auxiliary plate is arranged in the slide block, two ends of the probe extend out from the slide block, one end of the probe is used for propping against a concave part in the circumferential direction of the hollow glass to be detected, the other end of the probe is provided with a handle, the outer surface of one end of the probe used for propping against the hollow glass to be detected is provided with scales extending along the length direction, and the probe with scales is contacted with the hollow glass, the stacking difference at the probe can be quickly and accurately measured, and the slider drives the probe to move so as to measure the stacking difference at any position.

Description

Cavity glass stacking error detection device
Technical Field
The utility model relates to a cavity glass folds poor detection device belongs to cavity glass and detects technical field.
Background
The hollow glass is a glass product which is formed by two or more pieces of glass which are uniformly separated by effective support and are bonded and sealed at the periphery, so that a dry gas space is formed between glass layers, wherein the stacking difference is one of the size deviation of the hollow glass, and the stacking difference refers to the difference between a convex part and a concave part at the periphery of the hollow glass. The stack difference measurement method specified in the GBT 11944-.
At present, the stack error measurement of the hollow glass is realized by matching a steel tape with the minimum scale of 0.5mm with a straight steel ruler, the steel tape and the straight steel ruler are required to keep certain verticality or parallelism in the measurement process, the measurement error ratio is large, and the measurement accuracy is required to depend on abundant operation experience of measurement personnel. When measuring multi-cavity glass or multilayer doubling glass, if the biggest range upon range of difference is at the middle part of circumference, it is extremely inconvenient to use steel tape and steel ruler cooperation to measure the range upon range of difference, and the error is bigger.
Disclosure of Invention
An object of the utility model is to provide a measure accurate and convenient cavity glass and fold poor detection device, can measure the fold difference at any position of multi-chamber cavity glass or multilayer glued glass accurately effectively.
The utility model adopts the following technical scheme: the utility model provides a cavity glass stacking difference detection device, including perpendicular location strip and the accessory plate that links together formation L shape structure, the accessory plate is used for laminating on cavity glass's that awaits measuring a surface with the one side that the location strip is adjacent, the one side that the location strip is adjacent with the accessory plate contacts with the global protruding department of cavity glass that awaits measuring, the guide slot that extends and the fretwork along the location strip is seted up to the one side that is adjacent with the accessory plate on the location strip, the guide slot is perpendicular with the accessory plate, slidable mounting has the slider in the guide slot, install the probe parallel with the accessory plate in the slider, the both ends of probe are stretched out from the slider, the one end of probe is used for pushing up the depressed part at cavity glass circumference that awaits measuring, the other end is equipped with the handle, the one end surface that the probe is used for pushing up on cavity glass that awaits measuring is equipped with the scale that extends along probe length direction.
The side surface of the auxiliary plate is provided with a graduated scale, the graduated scale is parallel to the scales on the probe, and the starting end of the graduated scale is positioned at the joint of the auxiliary plate and the positioning strip.
The starting end of the guide groove is positioned at the joint of the positioning strip and the auxiliary plate, and the length of the guide groove is greater than the maximum thickness of the hollow glass to be measured.
And the positioning strip is provided with a driving mechanism for driving the sliding block to move along the guide groove.
The driving mechanism comprises an air cylinder, the cylinder body of the air cylinder is fixed at the end part of the positioning strip, the piston rod of the air cylinder is fixedly connected with the sliding block and is parallel to the guide groove, and the sliding block moves along the guide groove under the driving of the piston rod.
The driving mechanism comprises a screw rod, a threaded hole matched with the screw rod is formed in the sliding block, a supporting hole for the screw rod to penetrate through and to be matched with the screw rod in a rotating mode is formed in one end, located in the guide groove, of the positioning strip, a positioning blind hole is formed in the other end of the guide groove, one end of the screw rod penetrates through the supporting hole and the sliding block in sequence, the other end of the screw rod abuts against the inside of the positioning blind hole, and a hand wheel is arranged at the end portion, close to the supporting hole, of the screw rod.
The probe is provided with an external thread at one end close to the handle, and an internal thread hole matched with the external thread of the probe is formed in the sliding block.
The measuring range of the scales on the probe is 2-3 cm.
The precision of the scales on the probe and the precision of the graduated scale are both smaller than 0.5 mm.
The positioning strip and the auxiliary plate are both metal pieces.
The utility model has the advantages that: the utility model discloses a measure frock is location strip and accessory plate that adopts the vertical cross setting, the accessory plate laminating is on cavity glass's that awaits measuring a surface during the use, location strip inboard is leaned on cavity glass global, location strip and the global protruding department contact of cavity glass that awaits measuring, through the global contact of probe with the scale and cavity glass, can be fast accurate measure the pile of probe place position poor, drive the probe through the slider and remove the pile difference that can measure any position of cavity glass along the spout. The utility model discloses when having avoided the cooperation of steel tape measure or steel ruler to measure, hang down straightness or the relatively poor technical problem that leads to measuring error big of depth of parallelism.
Preferably, the side surface of the auxiliary plate is provided with a graduated scale, when the probe is used for measuring the stacking error far away from the auxiliary plate, the stacking error of the hollow glass close to the auxiliary plate can be rapidly read through the graduated scale on the auxiliary plate, so that the maximum stacking difference value can be rapidly judged, and the measurement frequency of the stacking error is reduced.
Preferably, the positioning strip is provided with a driving mechanism for driving the sliding block to move along the guide groove, so that the sliding block drives the probe to move more accurately.
Preferably, a screw driving mechanism is adopted, the hand wheel is rotated to enable the screw to rotate, and the two sides of the sliding block are in sliding fit with the guide groove, so that the sliding block can move along the guide groove when the screw rotates.
Preferably, the cylinder is adopted to drive the sliding block to move, and the sliding block has the characteristic of convenience in operation.
Preferably, the positioning strips and the auxiliary plate are all metal pieces, and the positioning strip has the characteristics of firmness, durability and difficult deformation, so that the high measurement precision is ensured.
Drawings
FIG. 1 is a schematic view of a stack error;
fig. 2 is a schematic structural diagram of an empty glass stacking error detection device according to an embodiment of the present invention;
FIG. 3 is a diagram illustrating a usage state of the device for detecting stack difference of hollow glass in FIG. 1;
FIG. 4 is a vertical cross-sectional view of the positioning strip of FIG. 1;
fig. 5 is another vertical cross-sectional view of the alignment bar of fig. 1.
In the figure: 1-positioning strip, 11-guide groove, 12-slide block, 13-probe, 14-handle, 15-screw rod, 16-support hole, 17-positioning blind hole, 18-hand wheel, 2-auxiliary plate and 21-graduated scale.
Detailed Description
The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.
The utility model relates to an in embodiment empty glass fold difference detection device's structure is shown in fig. 2 to 5, and the hollow glass fold difference detection device of this embodiment is including perpendicular location strip 1 and the accessory plate 2 that links together formation L shape structure, location strip 1 and accessory plate 2 are the metalwork, and accessory plate 2 is used for laminating on one surface of the hollow glass that awaits measuring with the adjacent one side of location strip 1, and location strip 1 contacts with the global arch of the hollow glass that awaits measuring with the adjacent one side of accessory plate 2, and the guide slot 11 that extends and fretwork along the location strip is seted up to the adjacent one side of accessory plate 2 on location strip 1, and guide slot 11 is perpendicular with accessory plate 2, and slidable mounting has slider 12 in guide slot 11, installs probe 13 parallel with accessory plate 2 in the slider 12, and stretch out in slider 12 at the both ends of probe 13, and the one end of probe 13 is used for propping up in the recess of the hollow glass circumference that awaits measuring, The other end is provided with a handle 14, and the outer surface of one end of the probe 13, which is used for propping against the hollow glass to be detected, is provided with scales extending along the length direction of the probe 13.
The side surface of the auxiliary plate 2 is provided with a graduated scale 21, the graduated scale 21 is parallel to the graduation on the probe 13, and the starting end of the graduated scale 21 is positioned at the joint of the auxiliary plate 2 and the positioning strip 1.
The starting end of the guide groove 11 is positioned at the joint of the positioning strip 1 and the auxiliary plate 2, and the length of the guide groove 11 is larger than the maximum thickness of the hollow glass to be measured.
Be equipped with the actuating mechanism that drive slider 12 removed along guide slot 11 on the location strip 1, actuating mechanism includes screw rod 15, be equipped with in the slider 12 with screw rod 15 complex screw hole, the one end that lies in guide slot 11 on the location strip 1 has the support hole 16 that supplies screw rod 15 to pass and with screw rod 15 normal running fit, the other end of guide slot 11 has location blind hole 17, and the one end of screw rod 15 passes in proper order from support hole 16, slider 12, and the other end top of screw rod 15 is in location blind hole 17, and the tip that screw rod 15 is close to support hole 16 is equipped with hand wheel 18.
The probe is provided with an external thread at one end close to the handle, and an internal thread hole matched with the external thread of the probe is formed in the sliding block. The measuring range of the scales on the probe is 2-3 cm. The precision of the scales on the probe and the precision of the graduated scale are both smaller than 0.5 mm.
The measuring tool of the embodiment adopts the positioning strips and the auxiliary plates which are arranged in a vertical cross mode, and the technical problem that the measuring error is large due to poor verticality or parallelism when a steel tape or a straight steel ruler is used for measurement in a matching mode is solved. When the auxiliary plate is used, the auxiliary plate is attached to one surface of hollow glass to be measured, the inner side of the positioning strip leans against the peripheral surface of the hollow glass, the positioning strip is in contact with the protruding part of the peripheral surface of the hollow glass to be measured, the probe with scales is in contact with the peripheral surface of the hollow glass, the stacking error of the position where the probe is located can be measured quickly and accurately, and the probe is driven by the sliding block to move along the sliding groove, so that the stacking error of any part of the hollow glass can be measured. The sliding block is driven by the screw rod when moving, the hand wheel is rotated to rotate the screw rod, and the two sides of the sliding block are in sliding fit with the guide groove, so that the sliding block can move along the guide groove when the screw rod rotates; the length of the probe is adjusted through threads, the probe is extended or shortened by rotating a handle on the probe, the probe is contacted with the circumferential concave part of the hollow glass, and the superposition value can be rapidly read by matching with the scales on the probe.
The above-mentioned embodiment is the utility model relates to a preferred embodiment the utility model discloses in other embodiments, actuating mechanism can also adopt the cylinder, and the cylinder body of cylinder is fixed at the tip of location strip, and the piston rod of cylinder just is parallel with the guide slot with slider fixed connection, and the slider moves along the guide slot under the drive of piston rod.
In other embodiments of the present invention, the manual driving of the slider can be further adopted, and in order to prevent the slider from falling off from the guide groove, the convex-concave matching structure is disposed at the contact position between the guide groove and the slider.
The utility model discloses in other embodiments, can all set up the scale in the both sides of accessory plate, the scale on the accessory plate is not necessary, as long as with whole frock upset, another face of accessory plate hugging closely cavity glass uses the probe also can measure all fold difference values, takes the maximum value as final result.
The utility model discloses in other embodiments, the probe can also adopt the mode of taking out the plug to install on the slider, and during the adjustment probe, the staff pull or press the handle of probe can.
In other embodiments of the present invention, the material of the positioning strip and the auxiliary plate may be organic glass or rigid plastic.

Claims (10)

1. The utility model provides a cavity glass stacking error detection device which characterized in that: the auxiliary plate is vertically connected with one surface of the hollow glass to be detected, one surface of the auxiliary plate adjacent to the positioning strip is used for being attached to one surface of the hollow glass to be detected, one surface of the positioning strip adjacent to the auxiliary plate is contacted with a bulge on the periphery of the hollow glass to be detected, a guide groove extending and hollowed out along the positioning strip is formed in one surface of the positioning strip adjacent to the auxiliary plate, the guide groove is perpendicular to the auxiliary plate, a sliding block is arranged in the guide groove in a sliding mode, probes parallel to the auxiliary plate are arranged in the sliding block, two ends of each probe extend out of the sliding block, one end of each probe is used for supporting a concave part in the circumferential direction of the hollow glass to be detected, a handle is arranged at the other end of each probe, and a scale extending along the length direction of each probe is arranged on the outer surface of one end, which is used for supporting the hollow glass to be detected.
2. The insulating glass stacking error detecting device according to claim 1, wherein: the side surface of the auxiliary plate is provided with a graduated scale, the graduated scale is parallel to the scales on the probe, and the starting end of the graduated scale is positioned at the joint of the auxiliary plate and the positioning strip.
3. The insulating glass stacking error detecting device according to claim 1, wherein: the starting end of the guide groove is positioned at the joint of the positioning strip and the auxiliary plate, and the length of the guide groove is greater than the maximum thickness of the hollow glass to be measured.
4. The insulating glass stacking error detecting device according to claim 1, wherein: and the positioning strip is provided with a driving mechanism for driving the sliding block to move along the guide groove.
5. The insulating glass stacking error detection device according to claim 4, wherein: the driving mechanism comprises an air cylinder, the cylinder body of the air cylinder is fixed at the end part of the positioning strip, the piston rod of the air cylinder is fixedly connected with the sliding block and is parallel to the guide groove, and the sliding block moves along the guide groove under the driving of the piston rod.
6. The insulating glass stacking error detection device according to claim 4, wherein: the driving mechanism comprises a screw rod, a threaded hole matched with the screw rod is formed in the sliding block, a supporting hole for the screw rod to penetrate through and to be matched with the screw rod in a rotating mode is formed in one end, located in the guide groove, of the positioning strip, a positioning blind hole is formed in the other end of the guide groove, one end of the screw rod penetrates through the supporting hole and the sliding block in sequence, the other end of the screw rod abuts against the inside of the positioning blind hole, and a hand wheel is arranged at the end portion, close to the supporting hole, of the screw rod.
7. The insulating glass stacking error detecting device according to claim 1, wherein: the probe is provided with an external thread at one end close to the handle, and an internal thread hole matched with the external thread of the probe is formed in the sliding block.
8. The insulating glass stacking error detecting device according to claim 1, wherein: the measuring range of the scales on the probe is 2-3 cm.
9. The insulating glass stacking error detection device according to claim 2, wherein: the precision of the scales on the probe and the precision of the graduated scale are both smaller than 0.5 mm.
10. The insulating glass stacking error detecting device according to claim 1, wherein: the positioning strip and the auxiliary plate are both metal pieces.
CN202120629350.XU 2021-03-29 2021-03-29 Cavity glass stacking error detection device Active CN214308489U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202120629350.XU CN214308489U (en) 2021-03-29 2021-03-29 Cavity glass stacking error detection device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202120629350.XU CN214308489U (en) 2021-03-29 2021-03-29 Cavity glass stacking error detection device

Publications (1)

Publication Number Publication Date
CN214308489U true CN214308489U (en) 2021-09-28

Family

ID=77837470

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202120629350.XU Active CN214308489U (en) 2021-03-29 2021-03-29 Cavity glass stacking error detection device

Country Status (1)

Country Link
CN (1) CN214308489U (en)

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