CN211317235U - Numerical control infrared ray measurement flatness device - Google Patents

Abstract

The utility model discloses a numerical control infrared ray measurement plane degree device, wherein, including the chassis, the translation guide rail structure that is equipped with on the chassis, the supporting structure that is equipped with on the chassis of translation guide rail structure one side, be equipped with on the supporting structure and measure the vertical guide rail structure that the backplate, the translation guide rail structure that is equipped with are structural, and the infrared emission caliber that is equipped with at vertical guide rail structure. The infrared emission measurer measures the upper, lower, left and right sides of the surface of the back plate under the action of the balance guide rail and the vertical guide rail. The utility model discloses have quick effective measuring effect.

Description

Numerical control infrared ray measurement flatness device

Technical Field

The utility model relates to a measuring tool field, in particular to numerical control infrared ray measurement flatness device.

Background

In order to achieve the visual ultrathin effect of the television, the back panel of the liquid crystal television also tends to be thinned. At present, most of the back plates of liquid crystal televisions in the market adopt flat design structures such as ultrathin galvanized plates, aluminum alloy plates and the like, but the structure of the ultrathin back plate has high requirement on flatness, the detection mode adopts a measurement method of adding a plug gauge on a traditional measuring table, and the condition is that the influence error on the self weight and gravity of the back plate is small; if the method is adopted, only the flatness of the periphery of the back plate can be measured, but the flatness measurement of the middle position of the back plate is difficult, so that whether the produced incoming material and the produced and formed back plate meet the flatness requirement or not can not be quickly judged, and whether the whole body achieves the expected benefit or not can not be quickly judged.

SUMMERY OF THE UTILITY MODEL

In view of the above problems, an object of the present invention is to provide a numerical control infrared flatness measuring device capable of fast and effective measurement

In order to realize the above object, the utility model provides a pair of numerical control infrared ray measurement plane degree device, wherein, including the chassis, the translation guide rail structure that is equipped with on the chassis, the supporting structure that is equipped with on the chassis of translation guide rail structure one side, be equipped with on the supporting structure and measure the backplate of volume, the vertical guide rail structure that is equipped with on the translation guide rail structure, and the infrared emission caliber that is equipped with on the vertical guide rail structure. The infrared emission measurer measures the upper, lower, left and right sides of the surface of the back plate under the action of the balance guide rail and the vertical guide rail.

In some embodiments, the support structure includes a support plate provided on the bottom frame, first fixing blocks provided on the bottom frame on both sides of the bottom end of the support plate, first and second fixing support plates provided in the support plate in sequence, and quick clamps provided on both sides of the first and second fixing support plates, respectively.

In some embodiments, the translation guide rail structure includes a bottom rod disposed on the bottom frame, a first rear cover disposed on the bottom rod, a first face cover disposed at one end of the first rear cover and connected to the first rear cover, and a first cover cap disposed at two sides of the first rear cover and spaced apart from the rear cover, a first cover frame sleeved on the first face cover, a first lead screw disposed inside a space formed between the first rear cover and the first face cover and crossing the inner space, a first threaded sleeve disposed on the first lead screw and fixedly connected to the first cover frame, and a first motor disposed at one end of the first lead screw.

In some embodiments, the vertical guide rail structure includes a second vertical rear cover disposed on the first cover, a second cover disposed at two ends of the second rear cover and connected to the second rear cover, and a second cover disposed at two sides of the second rear cover and spaced apart from the second rear cover, a second fixing block disposed on the first cover and fixed to the second rear cover, a second bracket disposed on the second cover, a second lead screw traversing the inner space and disposed inside a space formed between the second rear cover and the second cover, a second thread sleeve disposed on the second lead screw and fixedly connected to the second bracket, and a second motor disposed at two ends of the second lead screw.

In some embodiments, the device further comprises a control processing host connected with the infrared emission measurer and arranged on the chassis.

The beneficial effects of the utility model are that have quick effective measuring effect. The plane degree of the backboard can be measured in the process of transmitting infrared rays through the transmitter, the process is numerical control automatic, an accurate measurement result can be obtained quickly, the overall benefit is improved, and the effect of quick and effective measurement is realized.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of another view angle of the present invention;

fig. 3 is a schematic view of the exploded structure of the present invention.

Detailed Description

The following describes the present invention in further detail with reference to the accompanying drawings.

As shown in fig. 1-3, a numerical control infrared ray flatness measuring device comprises a bottom frame 1, a translation guide rail structure 2 arranged on the bottom frame 1, a support structure 3 arranged on the bottom frame 1 on one side of the translation guide rail structure 2, a back plate 4 to be measured arranged on the support structure 3, a vertical guide rail structure 5 arranged on the translation guide rail structure 2, and an infrared ray emission measurer 6 arranged on the vertical guide rail structure 5. The infrared emission measurer 6 measures the upper, lower, left and right sides of the surface of the back plate 4 under the action of the balance guide rail and the vertical guide rail. The support structure 3 comprises a support plate 31 arranged on the bottom frame 1, first fixing blocks 32 arranged on the bottom frame 1 at two sides of the bottom end of the support plate 31, a first fixing support plate 33 and a second fixing support plate 34 which are sequentially arranged on the support plate 31, and quick clamps 35 respectively arranged on two sides of the first fixing support plate 33 and the second fixing support plate 34. The translation guide rail structure 2 comprises a bottom rod 21 arranged on the chassis 1, a first rear cover 22 arranged on the bottom rod 21, a first face cover 23 which is connected with the first rear cover 22 in part and has two sides spaced apart from the rear cover and arranged at one end of the first rear cover 22, a first sleeve 24 sleeved on the first face cover 23, a first screw rod which traverses the inner space and is arranged in the space formed between the first rear cover 22 and the first face cover 23, a first thread sleeve fixedly connected with the first sleeve 24 and arranged on the first screw rod, and a first motor 25 arranged at one end of the first screw rod. The vertical guide rail structure 5 includes a second vertical rear cover 51 disposed on the first cover 22, a second cover 52 disposed at two ends of the second rear cover 51 and partially connected to the second rear cover 51, and having two sides spaced apart from the second rear cover, a second fixing block 53 disposed on the first cover 23 and used for fixing the second rear cover and the second rear cover 51, a second sleeve 54 sleeved on the second cover 52, a second screw rod disposed inside a space formed between the second rear cover 51 and the second cover 52 and crossing the inner space, a second threaded sleeve disposed on the second screw rod and fixedly connected to the second sleeve 54, and a second motor 55 disposed at two ends of the second screw rod. The device also comprises a control processing host 7 connected with the infrared emission measurer 6 and arranged on the underframe 1.

The mode that traditional horizontal mode of keeping flat was measured has been broken through in the application, places 4 vertical directions of backplate, overcomes self weight gravity influence factor, and motor and removal axle are added to the upper and lower direction about, through the plane degree of transmitter transmission infrared measurement backplate 4, so the process can realize measuring the plane degree of 4 any positions of backplate, and the process numerical control is automatic, can obtain accurate measuring result fast, improves the overall efficiency, has realized quick effective measuring effect.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (5)

1. A numerical control infrared ray flatness measuring device is characterized by comprising a bottom frame, a translation guide rail structure arranged on the bottom frame, a support structure arranged on the bottom frame on one side of the translation guide rail structure, a back plate to be measured arranged on the support structure, a vertical guide rail structure arranged on the translation guide rail structure and an infrared ray emission measurer arranged on the vertical guide rail structure;

the infrared emission measurer measures the upper, lower, left and right sides of the surface of the back plate under the action of the balance guide rail and the vertical guide rail.

2. The numerical control infrared ray flatness measuring device according to claim 1, wherein the supporting structure includes a supporting plate provided on the bottom frame, first fixing blocks provided on the bottom frame on both sides of the bottom end of the supporting plate, a first fixing support plate and a second fixing support plate provided in sequence on the supporting plate, and quick clamps provided on both sides of the first fixing support plate and the second fixing support plate, respectively.

3. A numerical control infrared ray flatness measuring apparatus according to claim 2, wherein said translation guide structure includes a bottom bar provided on the base frame, a first rear cover provided on the bottom bar, a first face cover provided at one end of the first rear cover and connected to the first rear cover and having both sides spaced from the rear cover, a first housing provided on the first face cover, a first lead screw provided inside a space formed between the first rear cover and the first face cover and crossing the inner space, a first screw housing provided on the first lead screw and fixedly connected to the first housing, and a first motor provided at one end of the first lead screw.

4. A numerical control infrared ray flatness measuring device according to claim 2, wherein said vertical guide structure includes a second vertical rear cover provided on the first cover, a second cover provided at both ends of the second rear cover and connected to the second rear cover and having both sides spaced from the rear cover, a second fixing block provided on the first cover and fixing the second cover and the second rear cover, a second bracket provided on the second cover, a second lead screw provided inside the space formed between the second rear cover and the second cover and crossing the inner space, a second threaded sleeve provided on the second lead screw and fixedly connected to the second bracket, and a second motor provided at both ends of the second lead screw.

5. A numerical control infrared ray measurement flatness device according to claim 1, 2 or 3, further comprising a control processing host connected to the infrared ray emission measurer on the chassis.

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