DE1548205C - Optical testing device for measuring the relative thickness of light-reflecting surface coatings on glass objects or the like - Google Patents

Description

The invention relates to an optical test device for measuring the relative thickness of light reflecting Surface coatings on glass objects or the like, in which the glass object to be tested in a container open at the top rotatably introduced and there in an upright position on a Test station is held, with at least a part

the side wall of the container is transparent and the container contains a liquid which has a refractive index which is approximately the same as that of the glass object, but deviates significantly from the refractive index of the surface coating, as well as a light beam on the glass object with the surface coating rotating around the vertical axis directed and the intensity of the reflected light beam is measured with the aid of a light-sensitive receiving unit and a display device . . ■. '■ ·.

Known optical inspection devices of this type are suitable for measuring the relative thickness of surface coatings on glass objects or the like and have proven to be essential for laboratory use Proven to be satisfactory. However, these devices have proven to be not entirely adequate for running operational use shown. With them is namely the preparation of samples, for example the cutting or separating of small parts or pieces of the glass objects, necessary, a rather cumbersome, i.e. time-consuming, adjustment of the sample holder being necessary can.

It is also known to apply thin coatings to glass objects by using them with the Steaming a substance such as stannous chloride or titanium chloride treated. This surface treatment creates a coating that is believed to be a metal oxide and which determines has very desirable protective and other properties. This coating process is known under the designation "invisible (reflex-free) iridescence", whereby the during this process . resulting surface coating can be extremely thin, d. H. probably less than a quarter wavelength visible light. Surface coatings obviously lead to less economical ones Waste if they are too thick, and undesirable iridescence of the glass objects can also occur. If the surface coatings are too thin their effectiveness is of course impaired:

It is further known, the ability to reflect light ^! of the thin films or coatings of the aforementioned type as a measure of their relative thickness. The glass object is immersed in a liquid which has an index of refraction which is substantially the same as that of the glass, but which differs significantly from the index of refraction of the surface coating. A light beam is directed onto the glass frame which is being subjected to the inspection process and is used as a sample, the intensity of a reflected light beam being measured in the usual way with the aid of a photocell and a measuring device

• Devices for measuring the on are also known on a paper surface, where (that of the surface to be examined exposure of light emitted by a specific light source installed in the device below 15 ° reflected radiation measured by means of a photocell also installed in the device will.

Known devices for measuring the polish condition or the are based on the same principle Reflectivity of glass surfaces or the like, whereby the relatively small piece of glass to be examined placed in a bowl and brought into the beam path in such a way that the photocell detects the reflective absorbs the proportion of light. >

Finally, devices for covering glass surfaces, in particular lenses, are also known. with transparent layers of anti-reflective materials, which are made by vapor deposition in a vacuum be applied. These devices are using outside of the vacuum for the evaporation process and the associated heating device, etc. containing ίο glass receptacles attached light sources and associated Photocells equipped to increase the reflectivity of the treated lens or the like Measure surface to körinen.

The invention is now based on the object of providing an optical test device of the type mentioned at the beginning create with what reflective surface coatings on glass objects of different Size and shape can be measured, the verification not being on a selected small one Part of the glass object is limited and only a simple adjustment is required and not only Coatings on cylindrical glass objects, but also on flat glass objects, can be checked can, so that the tester especially for ongoing operational use outside of the laboratory is suitable.

This object is achieved according to the invention in that the holder of the glass object in an upright position Position of at least one elastic, resilient holding part and at least one of this - Opposite fixed holding part, each at the test station against a side wall of the glass object and set it in its correct position, and that the elastic Holding part on its inside has a downwardly and inwardly inclined control and guide surface has against which the glass object is in its downward movement in the direction of the inspection station that continues to hold the light source in a position outside the container is held that it emits a substantially horizontal beam of light through the transparent wall part throws the container through onto the glass object fixed at the test station, as well as the light-sensitive Receiving unit is held by holding means outside of the container that they the reflected from the surface coating of the glass object through the transparent wall part of the Receives the container passing horizontal light beam. . ', ^ -: ^ ■:

. The optical test device according to the invention has a comfortable adjustability and a high adaptability in use, so that it is on-going operational use in the vicinity of or adjacent to glass cooling furnaces or other operational use Facilities is particularly well suited.

The invention is illustrated below with reference to a in the drawing in its details, preferred embodiment explained in more detail. It shows / ;

1 shows a perspective view of a testing device according to the invention with a glass object placed in the device for its testing.
F i g. 2 shows a horizontal section, essentially along the line 2-2 in FIG. 1,

F i g. 3 is a vertical section, essentially along the line 3-3 in FIG. 2,

5 6

4 shows a partial front view of the device with half of the ring-shaped band to be checked on it.

illustration of a filled in an open position. As in Fig. Shown is the bottle

pivoted photocell holder or carrier. 26 up to a height 34 with the liquid 32

F i g. 5 a horizontal partial section corresponding to the container filled. -

Fig. 2, but when illustrating one on a 5 according to the invention is in the container 30 at least

Test station in the device held in position at least a part of a side wall is provided, the water

Flat glass pieces, and. is parent, and in the illustrated embodiment

6 shows an electrical circuit diagram of the test device, the container 30 is in the form of a glass vessel. at

according to the invention. ■ '■' removed cover plate 22, the glass

The test device according to the invention is conveniently suitable for checking glass objects upwards from the housing, in order to clean it and to replace or and small flat glass pieces without the need to renew the liquid 32. If the Container 30 is limited to this. It is only essential that the film or surface coating to be measured assumes its correct position in the housing 12, 14, 16, 18, 20; for the present trap glass, has. If, for example, moderate parts 36, 36, which are covered with pieces of rubber or tape, surface coatings on plastics, crystals or strips 38, 38 are measured on a rear or transparent crystal complex, the part against the glass vessel 30 is measured. One of the should, the device according to the invention front part of the housing can be easily adapted with such a task, since there are only 20 rubber or tape strips 42 covered part 40 of a considerable difference between the lies against a front one Part of the glass container surface coating and 30 refractive indices. .r basic material is dependent. According to the invention, a holding device (> *

F i g. 1 shows an optical test device, generally designated 10, provided around a glass object on the test stand, with 25 tion I in the container 30 in an upright position on a fixed, flat, plate-like base part 12, which is inserted. This holding device contains at least an upright housing with a front wall, an elastic holding part and at least one further 14, opposing side walls 16, holding part, which are each supported against a side wall 18 and a rear wall 20. In the top view of the object located at the test station I, the housing is generally rectangular and can move so that the object is properly seated, a removable cover part or a flat position is fixed, and it is nevertheless a swivel Plate 22, which is provided with a central opening movement of the object around a vertical opening 24, allow for the free vertical axis. In the illustrated preferred passage of glass objects, for example one embodiment, an elastic or glass bottle 26 is at 44. The bottle 26 is shown in the upright position 35 spring-loaded holding part and at 46, 48 on the .lung at a test station I and is shown through the opposite side of the glass object 26 set holding means to be described in more detail, two fixed holding parts are provided. In addition, which ones she is in contact with. A bottom part is provided which, as can be seen from FIG. 1, can come into contact with the entire unit of a glass object, for example the bottle of the test device of compact, space-saving construction. This bottom part 50 wise, so that the tester can be conveniently transported from one to the other in FIG. 3 with the bottle 26 in contact. Preferably shown starting. - ^ ■:
are according to FIG. 2 provided with 28 handles. Each of the holding parts 46, 48 is in the vertical direction

As illustrated in Figures 2 and 3, a is on. processing so that it changes, as in Fig. 3 "(Q |

its top open container 30 is provided, the 45 visible, essentially from the top to

can accommodate a liquid, the refraction of which extends to the bottom of the container 30. Preferably

dex approximately equal to that of the basic material of the test and, as illustrated in the drawing, are the.: ·. '"

The coated or coated object against the side wall. parts 46, 48 that can be applied

des is, however, of the refractive index of the on a front part of the container 30 from one another

The object of the existing surface coating is arranged 5 ° separately and with the above-mentioned dec-

differs significantly. This liquid is connected to 32 bell plate 22, from which it hangs down.

draws and, in the case of the with one, has surfaces

Surface-coated glass bottle 26 a breach upwards for a corresponding removal of the

index of refraction, which is approximately equal to the index of refraction holding parts 46, 48.

of glass is. For this purpose, xylene (Di- 55, Das against the side wall of the to be checked

methylbenzene) and chlorobenzene (monochlorobenzene) - the part 44 that can be placed on the glass object is attached to a back ■ "■ '

proved to be eminently suitable. ;. Lower part of the container 30 is arranged and is attached to

The container 30 / is, as discussed above, open at its upper end portion with the aid of a suitable upper side, so that glass objects are pivotably held at both pivot pins 52, e.g. 22 ^supported; Existing liquid 32 is conveniently lowered, outstanding support 54 is held. The holding part can. In the case of small glass objects, 44 hangs from the pin 52 through the opening, the object can be lowered into the cover plate 22 at the test station I in the 24 and has an end section 56 completely immersed in the liquid 32, which will be at an angle after. In the case of larger objects, for example 65 protruding on the inside in order to rest against a glass object, in the case of the bottle 26, the liquid 32 can thus be placed against the bottle 26, for example. Be introduced to the object that it is approximately a rearwardly extending approach or full or in any case up to a height above an eyelet 58, a spring 60 is attached, which extends from

7 8

there extends up to a pin 62. The tenon of the wall of the container 30 is thrown. As already

62 is attached to the support 54 so that it is the spring mentioned above, the intensity of the changes

60 holds under slight tension, so that the holding part reflected light beam 92 with the thickness of the

44 clockwise around the pivot pin 52 from the surface coating present in the bottle 26,

pivoted around and its part 56 at the test station I 5 wherein the light beam is also a measure of the

is brought into contact with the glass object. Uniformity of the coating in one with the

The elastic or spring-loaded holding part 44 rotating the bottle in the manner described above

also has a control holding device on its inside around its axis around it.

or guide surface 64 which rests against the lower running annular belt. ^:

Part of a. Glass object, for example against the io The test device according to the invention has

Bottom edge of the bottle 26 when it is moving downwards in the form of a light-sensitive receiving unit

movement in the direction of the test station I can create. a photocell 94, which is on a pivotable

The control or guide surface 64 is inwardly held by holder 96 in its correct position

and at the bottom so inclined that the lower part is one of the ones undergoing the test.

such a glass object is placed against it, so that the surface of the glass object is

that the holding part 44 is pressed outwards and to catch the reflected light beam 92 train. the

the lowering of the glass object to the test stand holder 96 has a small wing or extension 98,

tion I allows. In this way, a glass object is mounted so that it can pivot both on a peg 100

for example the bottle 26, simply facing downwards so that the photocell is in its position shown in FIG.

the control or guide surface 64 pressed, with 20 put in working position and forward or outward in

the holding device automatically swivel the bottle to its inoperative position according to FIG. 4

takes and leaves them on test station I in the correct one. When the photocell is in the operating position,

Location, to which it relies for its verification, as shown in FIG. 1 illustrates a cover plate

Fung by hand to easily rotate 102 around its longitudinal axis is provided.

leaves. Electrical means are also provided. The bottom part 50 is preferably in a vertical position that is connected to the photocell 94 Direction adjustable to make it glass objects from gauge 104 which has a visible display to be able to adapt to different heights, being able to deliver that varies with the intensity of the of the the aforementioned holding member 44 is a relatively on an object subject to inspection has a large swivel range so that it reflects light objects for glass surface coating slightly changed beam with different diameters. The electrical means are of, is usable. A vertically arranged rod 66 of conventional design and include one shown in FIG. 1 and in carries at its lower end the bottom part 50 and the circuit diagram according to FIG. 6 measuring device shown in is in a matching opening 68 one of the Dek-shape of a micro-ammeter 104. The amperecle plate 22 carried blocks 70 displaceable. To 35 meters is with the help of suitable lines to the Phobequemeren Handling of the rod 66, a button cell 94 is attached, preferably a re-72 provided, while a clamping or lockable resistor 108 and an on-off switch screw 74 provided with a similar knob 76 110 are provided. The switch 110 is in FIG. 1 is. In this way, the locking screw 74 can be found on the control panel next to a control button partially unscrew to make a convenient setting 40 108 for the adjustable resistor 108 shown, Len the vertical position of the bottom part 50. An operating button 112 shown in FIG. 1 is possible. After the bottom part is assigned to a controllable transformer 114, the desired te position has been moved, the locking in the circuit diagram of FIG. 6 in a feed circuit screw to be tightened, that it is against for the light source 78. So you can get through the rod 66 applies to the rod and the bottom part 45 adjusting the control button 112 the intensity set in the right location. ■ the light emitted by the light source 78 A front part of the device is a light beam conveniently set or regulate. The in-out source 78 provided, which is used by a switch from a holder for convenient switching on and off 80 and a small holder 84 carrying scissors of the device, the control button 108 for rod 82 existing bracket in their correct 50 changing the sensitivity of the microampereme location is held. The scissor linkage 82 ensures ters 104 can be actuated or adjusted, for adjusting the light source 78 by a horizontal zontal axis and for rectilinear lifting and the invention is a glassware sample with the too Lower the light source. Setting the light-expected smallest diameter at the test source around a vertical axis is done with the help of the 55 tion I attached, the photocell 94 and its Brackets 80 and 84. As particularly shown in FIG. 2, bracket sent to the open position of FIG the light source 78 can be pivoted substantially horizontally. As shown in FIG. 4 can be seen on zontal light beam which is provided through a in a support the container 30 a window that vorze 90 existing, matching opening 86, preferably in the form of an inner and an outer Housing enters and has at its passage through the 60 rectangle 116 and 118, respectively. The outer and the front part of the wall of the container 30, a somewhat larger rectangle 118 is used to form the window or is deflected before he possibly star with the reflected light beam and the Photoan the test station I to neatly register on a front part of a cell 94, d. h: the Glass object, for example the bottle 26, on container 30 while the photocell enters it. A closed position is located in front of the glass object 26, rotated so that Handcnen surface coating of reflected light - the rectangle 118 with the reflected beam Beam 92 is covered at an angle to the beam from 92 and the photocell. This is where the photo light source becomes 78 to the outside through the front part of the cell with its holder, as shown in Fig. 4, after

pivoted outside, but primarily used the smaller or inner rectangle 116 for this purpose can be to adjust the intensity and the position of the light beam from the light source 78 properly. The beam reflected from the smallest diameter glass object or bottle is reflected with respect to the shape of that of larger diameter bottles and flat glass Rays "thrown out" and has to be checked by any through the device Objects reflected rays the largest horizontal dimension. So if the light source works fine has been adjusted so that it represents the "thrown out" ray with respect to the rectangles 116, 118 centered in both the horizontal and vertical directions, the ray exactly coincides the photocell 94 when moved to its closed operating position. Accordingly fall from all other glass objects or rays reflected from flat glass Photocell. Larger diameter glass objects have reflected rays that are in their horizontal Dimensions are slightly smaller than the beam from the object with the smallest diameter, where the beam reflected by flat glass is even narrower. When using the device, the glass jar becomes preferably rotated after the adjustment process so that the rectangles 116 and 118 with the reflected Light beam 92 are brought out of register.

After the setting process, glass objects are attached one after the other at test station I, rotating each glass object to provide a reading of the relative thickness of the Surface coating and its uniformity

. over the length of one running around the object annular band is supplied. When objects of different sizes at the test station are to be attached, no new adjustment process is required, so that a simpler and more effective Test operation is given. ■ »

Now sicri shows that the aforementioned with a small rubber or tape strip 42 covered

The part 40 has a shielding function, i. i.e. that Stray light from the light source, 78 prevented by member 40 and strip or tape 42 is to get directly into the photocell 94, resulting in inaccurate and incorrect readings or readings would result.

In Fig. 5, a piece of flat glass 120 is against the Holding parts 46, 48 and resting on the base part 50

ao and shown lying against the elastic holding part 44. As illustrated in Figs. 3 and 5, lets the holding part 44 is at least approximately up to one point in common with the inner surfaces of the holding parts 46, 48 Pivot the level to move flat glass pieces, such as

for example, the piece 120 brought into position for its examination to be effectively determined. In addition only needs the flat glass piece to be moved down to the test station I so that the Holding part 44 pushed back to a small extent and the piece of glass under normal spring pressure is set in its correct position.

1 sheet of drawings

Claims (9)

Claims: ■ 1. Optical test device for measuring the relative thickness of light-reflecting surface coatings on glass objects od the side wall of the container is transparent and the container contains a liquid which has a refractive index which is approximately the same as that of the glass object, but deviates significantly from the refractive index of the surface coating, as well as a light beam on the glass object with the surface coating rotating around the vertical axis directed and the intensity of the reflected light beam is measured with the aid of a light-sensitive receiving unit and a display device, characterized in that the holder of the glass object (26) in the upright position consists of at least one elastic, resilient holding part (44) and at least s there is a fixed holding part (46, 48) opposite this, each of which rests against a side wall of the glass object at the test station (I) and fixes it in its correct position, and that the elastic holding part (44) has a downward on its inside and on the inside inclined control and guide surface (64) against which the glass object (26) rests during its downward movement in the direction of the test station (I), so that the light source (78) continues to be in one by holding means (80, 84) Position outside the container (30) is held that it throws a substantially horizontal light beam through the transparent wall part of the container through onto the glass object (26) fixed at the test station, as well as the light-sensitive receiving unit (94) by holding means (96) so outside of the container (30) is held so that the reflected from the surface coating of the glass object, through the transparent wall part d it receives horizontal light beam (92) passing through the container. .
.. ■; 2. Test device according to claim 1, characterized in that that the transparent wall part of the container (30) is provided with a window (116,118) is that is between the glass object to be tested (26) and the light-sensitive Can bring the receiving unit (94) with the reflected light beam (92) to coincide. 3. Testing device according to claim 1, characterized in that a removable one above the container (30) Lid (22) is provided, which has a central opening (24) for the free vertical Has passage of the glass object (26), and that on the cover (22) the holding means (44, 46, 48, 50) for the glass object (26) are attached. . , 4. Testing device according to claim 1 to 3, characterized in that the holder of the glass object (26) of at least three holding parts (44, 46, 48) which can be placed against the side wall of the glass object and a base part (50), which rests against the underside of the glass object (26), and that the holding parts (44, 46, 48) are arranged in a separated position so that they are glass objects of can accommodate different diameters. '. ■. · 5. Testing device according to claim 1 to 4, characterized in that the bottom part (50) is adjustable in the vertical direction by adjusting means (66, 74) so that it can accommodate glass objects (26) of different heights, and that at least the elastic holder , part (44) of the holding parts (44, 46, 48) which can be placed against the side wall of the glass object to be tested (26) is extended in the vertical direction. 6. Test device according to claim 1 to 5, characterized in that the elastic holding part (44) spring-loaded inwards in the direction of the other two stationary holding parts (46, 48) is. . 7. Test device according to one of claims 1 to 5, characterized in that the three against the Side wall of the glass object to be tested holding parts (44, 46, 48) in triangular shape are arranged, the elastic, resilient holding part (44) essentially the other two Holding parts (46, 48) opposite and on the glass object subjected to the test (26) impinging light beam runs between the two stationary holding parts (46, 48). 8. Test device according to one of claims 1 to 6, characterized in that the elastic, resilient holding part (44) is pivotally held at its upper end portion and below the Action of a spring (60) or the control or guide surface (64) below its upper End portion inwardly and outwardly pivotable, and that the length of the holding part (44) as well the construction and the arrangement of the spring loading means (60) connected to it as follows are that the lower end portion (56) of the holding part (44) at least approximately up to one with, / the inner surfaces of the other two holding parts v. * (46, .48) common vertical plane is pivotable. . , ν 9. Testing device according to claim 1 and 2, characterized in that outside the container (30) between the light source (78) and the light-sensitive receiving unit (94) shielding means (40, 42) are arranged so that no scattered light from the light source (78 ) can get directly to the light-sensitive receiving unit (94) . . ■. ". ·. ■,. ■ .-, ■ '', '■.> ■ -. ■■■■■}'.%