CN217726300U - Hot pressing quality detection mechanism - Google Patents

Abstract

The utility model relates to a hot pressing detects technical field, specifically disclose a hot pressing quality detection mechanism, be applicable to the picture frame subassembly after the hot pressing and carry out viscidity defect detection, mounting height defect detection and skew defect detection's application scene, shift the mechanism and place the picture frame body in fixed carrier department earlier, pushing and pressing mechanism presses down in order to realize viscidity defect detection to this internal lens body of picture frame, shift the mechanism and place the picture frame body in activity carrier department after that, the position of activity carrier adjustment picture frame subassembly, make optoelectronic component and shooting subassembly can detect the lens body, accomplish mounting height defect detection and skew defect detection from this. The utility model provides a hot pressing quality detection mechanism can carry out hot pressing quality detection to the picture frame subassembly after the hot pressing, and then sorts out the hot pressing defective products before carrying out the equipment of electrical component, reduces follow-up cost of scrapping.

Description

Hot pressing quality detection mechanism

Technical Field

The utility model relates to a hot pressing detects technical field, especially relates to a hot pressing quality detection mechanism.

Background

A VR glasses has been developed that includes a frame assembly and an electrical assembly. Wherein, the picture frame subassembly includes the picture frame body, and the mounting surface department of picture frame body is inwards sunken to form the mounting groove, and the lens body passes through the film and is connected with the tank bottom bonding of mounting groove.

In the upstream process, the tackiness of the film has been activated by the heat pressing device, so that the lens body can be firmly stuck to the frame body. However, in actual production processes, it has been found that upstream equipment often presents quality problems when performing hot pressing operations, such as:

(1) and (3) viscosity defect: the hot pressing time or temperature is insufficient, so that the viscosity of the film cannot be fully activated, and the lens body is pushed by a small force and can be separated from the frame body;

(2) mounting height defect: the hot pressing time or pressure and the like are insufficient, so that the film is not fully compressed, and the lens body protrudes out of the mounting surface of the spectacle frame body after hot pressing;

(3) offset defect: the lens body shifts during hot pressing, which causes the lens body not to fall into the middle position of the mounting groove, namely, the distance between the edge position of the lens body and the groove wall of the mounting groove is uneven.

If the defects are not found in advance, the poor mirror frame assembly is sent to downstream equipment for assembling the electrical assembly, and the scrapping cost of the poor mirror frame assembly found in the follow-up detection process can be greatly increased. Therefore, a hot pressing quality detection mechanism needs to be developed for performing hot pressing quality detection on the hot-pressed mirror frame assembly, so that a hot pressing defective product is sorted out before the electrical assembly is assembled, and further the subsequent scrapping cost is reduced.

The above information disclosed in this background section is only included to enhance understanding of the background of the disclosure and, thus, may contain information that does not form the prior art that is currently known to those of ordinary skill in the art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a hot pressing quality detection mechanism for picture frame subassembly after the hot pressing carries out hot pressing quality testing, so that sort out the hot pressing defective products before carrying out the equipment of electrical component, and then reduce follow-up cost of scrapping.

For reaching above purpose, the utility model provides a hot pressing quality detection mechanism, including conveyer, transfer mechanism, fixed carrier, pushing and pressing mechanism, activity carrier, optoelectronic component and shooting subassembly:

the conveying device is used for conveying the mirror frame carrier loaded with the mirror frame assembly; the spectacle frame component comprises a spectacle frame body and a lens body stuck on the spectacle frame body through a film;

the transfer mechanism is used for executing the transfer operation of the picture frame components between the picture frame carrier and the fixed carrier, between the fixed carrier and the movable carrier and between the movable carrier and the picture frame carrier;

the fixed carrier is used for fixing the mirror frame assembly so as to be pushed by the pushing mechanism;

the pushing mechanism is used for pushing the lens body from one side of the lens body away from the film so as to detect the viscous defect of the frame component;

the movable carrier is used for adjusting the position of the mirror frame assembly so as to detect the photoelectric assembly and the shooting assembly;

the photoelectric component is used for detecting the mounting height defect of the mirror frame component;

the shooting assembly is used for detecting the offset defect of the mirror frame assembly.

Optionally, the transfer mechanism includes:

the suction head is used for adsorbing the mirror frame component;

the driving end of the first linear driving mechanism is connected with the suction head and is used for driving the suction head to move up and down along the Z axis;

the driving end of the second linear driving mechanism is connected with the first linear driving mechanism and used for driving the suction head to move along the Y axis parallel to the feeding direction of the conveying device;

and the driving end of the third linear driving mechanism is connected with the second linear driving mechanism and is used for driving the suction head to move along an X axis vertical to the feeding direction of the conveying device.

Optionally, the pushing mechanism comprises:

a pressing head, which is opposite to the lens body of the mirror frame component in the fixed carrier;

a pressure sensor;

and the driving end of the fourth linear driving mechanism is connected with the pressure head through the pressure sensor and is used for driving the pressure head to press or release the lens body.

Optionally, the movable carrier includes a carrier body, a U-shaped bracket, a first rotary driving mechanism, a second rotary driving mechanism, and a third rotary driving mechanism:

the carrier body is used for placing the mirror frame assembly;

the driving end of the first rotary driving mechanism is connected with the carrier body and used for driving the carrier body to rotate;

the second rotary driving mechanism is arranged on the U-shaped bracket, and the driving end of the second rotary driving mechanism is connected with the first rotary driving mechanism and used for driving the first rotary driving mechanism to rotate around a horizontal axis;

and the driving end of the third rotary driving mechanism is connected with the U-shaped bracket and is used for driving the second rotary driving mechanism to rotate around a vertical axis.

Optionally, the mobile carrier further includes a fifth linear driving mechanism;

and the driving end of the fifth linear driving mechanism is connected with the third rotary driving mechanism and is used for driving the carrier body to reciprocate between the fixed carrier and the photoelectric component.

Optionally, the device further comprises a mounting plate;

the mounting panel is located fifth straight line actuating mechanism keeps away from one side of fixed carrier, just photoelectric component with shoot the subassembly all install in on the mounting panel.

Optionally, the device further comprises a sixth linear driving mechanism;

and the driving end of the sixth linear driving mechanism is connected with the mounting plate and used for driving the mounting plate to move along a Y axis parallel to the feeding direction of the conveying device.

Optionally, the device further comprises a bad storage bin for placing the frame component which is detected to be unqualified.

Optionally, the bad silo includes:

two vertical plates arranged oppositely;

a plurality of storage modules that down interval of follow set up, storage module is including being located two magazine between the vertical board with order about the magazine is close to or keeps away from conveyer's seventh straight line actuating mechanism.

The beneficial effects of the utility model reside in that: the utility model provides a hot pressing quality detection mechanism, transfer mechanism places the picture frame body in fixed carrier department earlier, and pushing and pressing mechanism presses the lens body in the picture frame body in order to realize viscidity defect detection, and transfer mechanism places the picture frame body in activity carrier department after that, and the position of picture frame subassembly is adjusted to the activity carrier for photoelectric component and shooting subassembly can detect the lens body, accomplish mounting height defect detection and skew defect detection from this.

Therefore, the utility model provides a hot pressing quality detection mechanism can carry out hot pressing quality detection to the picture frame subassembly after the hot pressing, and then sorts out the hot pressing defective products before carrying out the electrical component equipment, reduces follow-up cost of scrapping.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the description below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive labor.

Fig. 1 is a schematic structural diagram of a hot pressing quality detection mechanism provided in an embodiment;

fig. 2 is a schematic structural view of the fixed carrier, the pushing mechanism and the movable carrier provided by the embodiment;

fig. 3 is a schematic structural diagram of a defective bin according to an embodiment.

In the figure:

1. a conveying device;

2. a transfer mechanism; 201. a suction head; 202. a first linear drive mechanism; 203. a second linear drive mechanism; 204. a third linear drive mechanism;

3. a fixed carrier;

4. a pushing mechanism; 401. a pressure head; 402. a pressure sensor; 403. a fourth linear drive mechanism;

5. a movable carrier; 501. a carrier body; 502. a U-shaped bracket; 503. a first rotary drive mechanism; 504. a second rotary drive mechanism; 505. a third rotary drive mechanism; 506. a fifth linear drive mechanism;

6. an optoelectronic component;

7. a shooting component;

8. a bad silo; 801. a vertical plate; 802. a material storage module; 8021. a magazine; 8022. a seventh linear drive mechanism;

9. mounting a plate;

10. and a sixth linear drive mechanism.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the embodiments of the present invention are clearly and completely described with reference to the drawings in the embodiments of the present invention, and obviously, the embodiments described below are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present.

Furthermore, the terms "long", "short", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are only for convenience of describing the present invention, but do not indicate or imply that the device or element referred to must have the specific orientation, operate in the specific orientation configuration, and thus, should not be construed as limiting the present invention.

The present invention will be described in detail below with reference to specific embodiments shown in the drawings. However, these embodiments do not limit the present invention, and structural, method, or functional changes that can be made by those skilled in the art according to these embodiments are all included in the scope of the present invention.

The utility model provides a hot pressing quality detection mechanism, be applicable to the picture frame subassembly after the hot pressing and carry out viscidity defect detection, mounting height defect detection and skew defect detection's application scene, shift the mechanism and place the picture frame body in fixed carrier department earlier, pushing and pressing mechanism presses down in order to realize viscidity defect detection to this internal lens body of picture frame, shift the mechanism and place the picture frame body in activity carrier department after that, the position of activity carrier adjustment picture frame subassembly, make photoelectricity subassembly and shooting subassembly can detect the picture frame body, accomplish mounting height defect detection and skew defect detection from this.

Referring to fig. 1 to 3, in the present embodiment, the hot pressing quality detecting mechanism includes a conveying device 1, a transferring mechanism 2, a fixed carrier 3, a pushing mechanism 4, a movable carrier 5, an optoelectronic device 6, a shooting device 7, and a bad bin 8.

Wherein, the first and the second end of the pipe are connected with each other,

the conveying device 1 is used for conveying a mirror frame carrier loaded with mirror frame components; the spectacle frame component comprises a spectacle frame body and a lens body stuck on the spectacle frame body through a film; optionally, the conveying device 1 is a conveying belt or a conveying roller set;

the transfer mechanism 2 is used for executing the picture frame component transfer operation between the picture frame carrier and the fixed carrier 3, between the fixed carrier 3 and the movable carrier 5, between the movable carrier 5 and the picture frame carrier, and between the movable carrier 5 and the bad material bin 8;

the fixed carrier 3 is used for fixing the mirror frame assembly to be pushed by the pushing mechanism 4;

the pushing mechanism 4 is used for pushing the lens body from the side of the lens body far away from the film so as to detect the viscous defect of the frame component;

the movable carrier 5 is used for adjusting the position of the spectacle frame assembly so as to detect the photoelectric assembly 6 and the shooting assembly 7;

the photoelectric component 6 is used for detecting the mounting height defect of the mirror frame component;

the shooting component 7 is used for detecting the offset defect of the mirror frame component;

and the bad stock bin 8 is used for placing the mirror frame component which is detected to be unqualified.

Optionally, the transferring mechanism 2 comprises a suction head 201, a first linear driving mechanism 202, a second linear driving mechanism 203 and a third linear driving mechanism 204. Wherein, the suction head 201 is used for absorbing the lens frame component; the driving end of the first linear driving mechanism 202 is connected with the suction head 201 and is used for driving the suction head 201 to move up and down along the Z axis; the driving end of the second linear driving mechanism 203 is connected with the first linear driving mechanism 202, and is used for driving the suction head 201 to move along the Y axis parallel to the feeding direction of the conveying device 1; the driving end of the third linear driving mechanism 204 is connected to the second linear driving mechanism 203, and is used for driving the suction head 201 to move along the X-axis perpendicular to the feeding direction of the conveying device 1.

In the present embodiment, the pushing mechanism 4 includes a ram 401, a pressure sensor 402, and a fourth linear drive mechanism 403. Wherein the pressing head 401 is opposite to the lens body of the spectacle frame assembly in the fixed carrier 3; the driving end of the fourth linear driving mechanism 403 is connected to the pressing head 401 through the pressure sensor 402, and is used for driving the pressing head 401 to press or release the lens body.

The movable carrier 5 includes a carrier body 501, a U-shaped bracket 502, a first rotation driving mechanism 503, a second rotation driving mechanism 504, a third rotation driving mechanism 505, and a fifth linear driving mechanism 506. The carrier body 501 is used for placing a mirror frame assembly; the driving end of the first rotation driving mechanism 503 is connected to the carrier body 501, and is used for driving the carrier body 501 to rotate; the second rotation driving mechanism 504 is installed on the U-shaped bracket 502, and a driving end of the second rotation driving mechanism 504 is connected to the first rotation driving mechanism 503 for driving the first rotation driving mechanism 503 to rotate around a horizontal axis; the driving end of the third rotation driving mechanism 505 is connected with the U-shaped bracket 502, and is used for driving the second rotation driving mechanism 504 to rotate around a vertical axis; the driving end of the fifth linear driving mechanism 506 is connected to the third rotary driving mechanism 505, and is used for driving the carrier body 501 to reciprocate between the fixed carrier 3 and the optoelectronic component 6.

The hot pressing quality detection mechanism comprises a mounting plate 9 and a sixth linear driving mechanism 10, the mounting plate 9 is positioned on one side of the fifth linear driving mechanism 506 away from the fixed carrier 3, and the photoelectric component 6 and the shooting component 7 are both mounted on the mounting plate 9; the driving end of the sixth linear driving mechanism 10 is connected to the mounting plate 9, and is configured to drive the mounting plate 9 to move along the Y-axis parallel to the feeding direction of the conveying device 1.

The defective storage bin 8 comprises two opposite vertical plates 801 and a plurality of storage modules 802 arranged at intervals from bottom to bottom. The storage module 802 includes a magazine 8021 located between the two vertical plates 801 and a seventh linear driving mechanism 8022 for driving the magazine 8021 to approach or separate from the conveying device 1. Optionally, the number of the stocker modules 802 is three.

It should be noted that each linear driving mechanism may be a telescopic cylinder, a rodless cylinder, or a motor screw assembly, etc., and each rotary driving mechanism may be a servo motor, a rotary cylinder, etc.; the specific structures of the linear driving mechanism and the rotary driving mechanism are not the key points of the present invention, and therefore are not described in detail.

In this embodiment, the working process of the hot pressing quality detection mechanism is as follows:

s10: the conveying device 1 conveys a frame carrier carrying frame components from upstream;

the spectacle frame component comprises a spectacle frame body, wherein the mounting surface of the spectacle frame body is inwards sunken to form a mounting groove, and the lens body is connected with the bottom of the mounting groove in an adhering manner through a rubber sheet;

s20: the first linear driving mechanism 202, the second linear driving mechanism 203 and the third linear driving mechanism 204 cooperate to drive the suction head 201 to transfer the frame assembly from the frame carrier to the fixed carrier 3;

s30: the fourth linear driving mechanism 403 is extended to drive the pressing head 401 to press the lens body from the side of the lens body away from the film, during the pressing process, the reading of the pressure sensor 402 is gradually increased, and when the reading of the pressure sensor 402 reaches a preset value, the fourth linear driving mechanism 403 keeps the position of the pressing head 401 unchanged, that is, the pressing head 401 is pressed against the lens body with a constant pressure for a preset time (for example, 3s or 5 s);

if the indication number of the pressure sensor 402 is basically unchanged within the preset time, the frame assembly is free from the viscous defect, and the viscous defect is qualified for detection;

if the indication number of the pressure sensor 402 is gradually reduced within the preset time, it indicates that the lens body is far away from the frame body, the viscosity of the film is insufficient, and the detection of the viscosity defect of the frame assembly is unqualified;

s40: the transfer mechanism 2 puts the spectacle frame component qualified in viscosity detection into the carrier body 501, and puts the spectacle frame component unqualified in viscosity detection into the material box 8021 on the uppermost layer in the defective bin 8;

s50: after the carrier body 501 is installed in the mirror frame assembly, the five-line driving mechanism extends out to drive the carrier body 501 to move to a position close to the mounting plate 9;

s501: the sixth linear driving mechanism 10 operates to drive the optoelectronic component 6 to move right above the carrier body 501;

then, the first rotation driving mechanism 503, the second rotation driving mechanism 504 and the third rotation driving mechanism 505 cooperate to drive the carrier body 501 to drive the frame assembly to rotate up and down, so that the lens body in the frame assembly can face the optoelectronic assembly 6, the optoelectronic assembly 6 detects the distance difference between the upper surface of the lens body and the mounting surface, and if the difference meets the requirement, the mounting height defect detection is qualified; if the difference value is too large, the defect detection of the installation height is unqualified;

s502: the sixth linear driving mechanism 10 acts to drive the shooting assembly 7 to move right above the carrier body 501;

then, the first rotation driving mechanism 503, the second rotation driving mechanism 504 and the third rotation driving mechanism 505 cooperate to drive the carrier body 501 to drive the spectacle frame assembly to rotate up and down, so that the lens body in the spectacle frame assembly can be right opposite to the shooting assembly 7, the shooting assembly 7 shoots the lens body and the mounting groove, then the minimum distance and the maximum distance between the edge position of the lens body and the groove wall of the mounting groove are analyzed and calculated, if the difference between the minimum distance and the maximum distance meets the requirement, the lens body has small deviation, and the deviation defect detection is qualified; if the difference value between the minimum distance and the maximum distance is too large, the lens body is more deviated, and the deviation defect detection is unqualified;

s60: after the detection is finished:

s601: if the mounting height defect detection and the offset defect detection are qualified, the first linear driving mechanism 202, the second linear driving mechanism 203 and the third linear driving mechanism 204 are in cooperation action, the suction head 201 is driven to place the mirror frame assembly from the movable carrier 5 back into the mirror frame carrier of the conveying device 1, and the conveying device 1 conveys the qualified mirror frame assembly to downstream equipment to execute a subsequent assembly process;

s602: if the mounting height defect detection and/or the offset defect detection are not qualified, the first linear driving mechanism 202, the second linear driving mechanism 203 and the third linear driving mechanism 204 cooperate to drive the suction head 201 to place the picture frame assembly into the topmost material box 8021 from the movable carrier 5, and after the topmost material box 8021 is fully loaded, the seventh linear driving mechanism 8022 drives the fully loaded material box 8021 to move in the direction away from the conveying device 1, so that a production line worker can take off the unqualified picture frame assembly;

after the uppermost magazine 8021 is removed, the lower magazine 8021 is exposed and a defective frame assembly can be subsequently placed in the lower magazine 8021.

The utility model provides a hot pressing quality detection mechanism, transfer mechanism 2 earlier places the picture frame body in 3 departments of fixed carrier, and pushing and pressing mechanism 4 presses down in order to realize viscidity defect detection to this internal lens body of picture frame, transfers mechanism 2 to place the picture frame body in 5 departments of movable carrier after that, and 5 adjustment picture frame subassemblies's of movable carrier position for optoelectronic component 6 can detect the lens body with shooting subassembly 7, accomplishes mounting height defect detection and skew defect detection from this. Therefore, the utility model provides a hot pressing quality detection mechanism can carry out hot pressing quality detection to the picture frame subassembly after the hot pressing, and then sorts out the hot pressing defective products before carrying out the electrical component equipment, reduces follow-up cost of scrapping.

It should be understood that although the specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it will be appreciated by those skilled in the art that the specification as a whole may be appropriately combined to form other embodiments as will be apparent to those skilled in the art.

The above list of detailed descriptions is only for the specific description of the feasible embodiments of the present invention, and they are not intended to limit the scope of the present invention, and all equivalent embodiments or modifications that do not depart from the technical spirit of the present invention should be included within the scope of the present invention.

Claims (9)

1. The utility model provides a hot pressing quality detection mechanism which characterized in that, includes conveyer, transfer mechanism, fixed carrier, pushing and pressing mechanism, activity carrier, optoelectronic component and shoots the subassembly:

the conveying device is used for conveying a picture frame carrier loaded with a picture frame assembly; the spectacle frame component comprises a spectacle frame body and a lens body stuck on the spectacle frame body through a film;

the transfer mechanism is used for executing the transfer operation of the picture frame components between the picture frame carrier and the fixed carrier, between the fixed carrier and the movable carrier and between the movable carrier and the picture frame carrier;

the fixed carrier is used for fixing the mirror frame assembly so as to be pushed by the pushing mechanism;

the pushing mechanism is used for pushing the lens body from one side of the lens body away from the film so as to detect the viscous defect of the frame component;

the movable carrier is used for adjusting the position of the spectacle frame assembly so as to detect the photoelectric assembly and the shooting assembly;

the photoelectric component is used for detecting the mounting height defect of the mirror frame component;

the shooting assembly is used for detecting the offset defect of the mirror frame assembly.

2. The thermocompression quality detection mechanism of claim 1, wherein the transfer mechanism comprises:

the suction head is used for sucking the mirror frame component;

the driving end of the first linear driving mechanism is connected with the suction head and is used for driving the suction head to move up and down along the Z axis;

the driving end of the second linear driving mechanism is connected with the first linear driving mechanism and is used for driving the suction head to move along the Y axis parallel to the feeding direction of the conveying device;

and the driving end of the third linear driving mechanism is connected with the second linear driving mechanism and is used for driving the suction head to move along an X axis vertical to the feeding direction of the conveying device.

3. The thermal compression quality detection mechanism according to claim 1, wherein the urging mechanism includes:

a pressing head, which is opposite to the lens body of the mirror frame component in the fixed carrier;

a pressure sensor;

and the driving end of the fourth linear driving mechanism is connected with the pressure head through the pressure sensor and is used for driving the pressure head to press or release the lens body.

4. The thermal pressing quality detecting mechanism of claim 1, wherein the movable carrier includes a carrier body, a U-shaped bracket, a first rotation driving mechanism, a second rotation driving mechanism and a third rotation driving mechanism:

the carrier body is used for placing the mirror frame assembly;

the driving end of the first rotary driving mechanism is connected with the carrier body and used for driving the carrier body to rotate;

the second rotary driving mechanism is arranged on the U-shaped bracket, and the driving end of the second rotary driving mechanism is connected with the first rotary driving mechanism and used for driving the first rotary driving mechanism to rotate around a horizontal axis;

and the driving end of the third rotary driving mechanism is connected with the U-shaped bracket and is used for driving the second rotary driving mechanism to rotate around a vertical axis.

5. The thermal compression quality detection mechanism of claim 4, wherein the mobile carrier further comprises a fifth linear drive mechanism;

and the driving end of the fifth linear driving mechanism is connected with the third rotary driving mechanism and is used for driving the carrier body to reciprocate between the fixed carrier and the photoelectric component.

6. The hot press quality detection mechanism of claim 5, further comprising a mounting plate;

the mounting panel is located fifth straight line actuating mechanism keeps away from one side of fixed carrier, just photoelectric component with shoot the subassembly all install in on the mounting panel.

7. The thermal compression quality detection mechanism according to claim 6, further comprising a sixth linear drive mechanism;

and the driving end of the sixth linear driving mechanism is connected with the mounting plate and used for driving the mounting plate to move along a Y axis parallel to the feeding direction of the conveying device.

8. The hot pressing quality detection mechanism according to claim 1, further comprising a bad bin for placing the frame component which is detected to be unqualified.

9. The hot pressing quality detection mechanism according to claim 8, wherein the bad bin comprises:

two vertical plates arranged oppositely;

a plurality of storage modules that down interval of follow set up, storage module is including being located two magazine between the vertical board with order about the magazine is close to or keeps away from conveyer's seventh straight line actuating mechanism.

Images