CN113582513A - Multi-station glass molding system and method of making same - Google Patents

Abstract

A multi-station glass molding system includes a plurality of processing stations, a measurement station, and a plurality of transport mechanisms. The measuring station is connected to a first of the processing stations. The measuring station comprises a base, a pressing plate, a servo motor, a power supply and a controller. The base may carry a mold. The servo motor may drive the platen. The power supply is electrically connected with the servo motor. The controller is electrically connected with the servo motor. A method for manufacturing the multi-station glass molding system is also provided.

Description

Multi-station glass molding system and method of making same

Technical Field

The present disclosure relates to molding systems and methods, and particularly to a multi-station glass molding system and a method for manufacturing the same.

Background

Since the glass lens is superior to the plastic lens in temperature resistance, it is suitable for an optical lens in the application fields of vehicle use, security, and the like where the variation in environmental temperature is large. In recent years, as the demand for the above-mentioned application fields has exploded, the demand for manufacturing glass lenses has also sharply increased.

The molding systems for manufacturing glass lenses can be classified into two types, one is a single-station glass molding system, and the other is a multi-station glass molding system. The single station glass molding system is a method that integrates multiple glass molding manufacturing processes into the same processing station, as compared to the multiple station glass molding system that distributes the different manufacturing processes among the different processing stations. The single station glass molding system is slow to manufacture and is difficult to meet the existing manufacturing requirements. For faster manufacturing speeds, multi-station glass molding systems have become the mainstream for glass lens manufacturing.

However, in the conventional multi-station glass molding system, the thickness of the molded workpiece cannot be known on the production line, and the inspection of the batch is required to be performed until the thickness is detected, so that the yield is reduced and unnecessary man-hours are increased.

Disclosure of Invention

The invention provides a multi-station glass molding system, which can monitor the manufacturing distance and the variation of the molding process on a production line in real time, and can reduce the cost of workpieces manufactured by the multi-station glass molding system.

One embodiment of the present invention provides a multi-station glass molding system including a plurality of processing stations, a measurement station, and a plurality of conveyance mechanisms. The measuring station is connected to a first of the processing stations. The measuring station comprises a base, a pressure plate, a servo motor, a power supply and a controller. The base can carry a mold. The servo motor may drive the platen. The power supply is electrically connected with the servo motor. The controller is electrically connected with the servo motor. A conveying mechanism is arranged between two of the processing stations or between the first processing station and the measuring station.

In view of the above, in the multi-station glass molding system according to the embodiment of the invention, the mold for the unprocessed workpiece (glass material) and the mold for the processed workpiece (glass lens) are respectively applied with downward pressure to respectively obtain the first and second height data. Then, the embossing distance is obtained by the first and second height data. The multi-station glass molding system and the manufacturing method of the glass molding lens can judge whether the processed workpiece (glass lens) is good or not according to the molding distance. Therefore, the multi-station glass molding system can monitor the manufacturing distance and the variation of the molding process on the production line in real time, and can reduce the cost of the subsequent quality management. In addition, the invention also provides a manufacturing method for manufacturing the multi-station glass molding system.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented in accordance with the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more clearly understood, the following preferred embodiments are described in detail with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic view of a multi-station glass press molding system according to an embodiment of the present invention.

Fig. 2A to 2H are schematic diagrams illustrating a process of molding a glass lens using the multi-station glass molding system of the embodiment of fig. 1.

Fig. 3 is a flowchart of the steps of the first routine.

Fig. 4 is a flowchart of steps of the second routine.

Fig. 5 is a flowchart of the steps of the third routine.

FIG. 6 is a graph of press distance versus different workpieces produced using the multiple station glass press system of the embodiment of FIG. 1.

FIG. 7 is a flowchart illustrating steps for manufacturing a multiple station glass press system according to one embodiment of the present invention.

Detailed Description

FIG. 1 is a schematic view of a multi-station glass press molding system according to an embodiment of the present invention. Fig. 2A to 2H are schematic diagrams illustrating a process of molding a glass lens using the multi-station glass molding system of the embodiment of fig. 1. Fig. 3 is a flowchart of the steps of the first routine. Fig. 4 is a flowchart of steps of the second routine. Fig. 5 is a flowchart of the steps of the third routine. FIG. 6 is a graph of press distance versus different workpieces produced by the multi-station glass press system of the embodiment of FIG. 1, wherein the abscissa of FIG. 6 represents different workpieces (e.g., 15 workpieces produced by the multi-station glass press system 100 of FIG. 1) and the ordinate represents the press distance associated with the respective workpieces.

Referring to fig. 1 and fig. 2A to 2H, in the present embodiment, the multi-station glass molding system 100 includes a measuring station MS, a plurality of processing stations PS 1-PS 5 (five for example), a controller C, and a plurality of transport structures TM 0-TM 5 (six for example). The above elements are described in detail in the following paragraphs.

Referring to fig. 1, 2A, 2G and 2H, in the present embodiment, the measurement station MS is dedicated to the steps of measuring the workpiece and determining whether the mold used is correct in the glass molding process. The measuring station MS includes a base station BS, a base B, a link R1, a mold M, a platen P1, a servo motor SM1, a power supply PS, and a controller C. The base B is arranged on the base station BS. The base B has an accommodating space AS. And a mold M is arranged in the accommodating space AS of the base B. The mold M comprises an upper mold core M1 and a lower mold core M2(mold core). The pressure plate P1 is disposed above the upper mold core M1 and is mechanically coupled to one end of the tie bar R1. The servomotor SM1 is mechanically coupled to the other end of the link R1, wherein the link R1 is adapted to receive pressure from the servomotor SM1 to drive the platen P1 to move the platen P1 in the axial direction of the link R1. The power supply PS is used to supply current to the servo motor SM 1. The controller C is electrically connected to the servo motor SM 1. In this embodiment, the Controller C may be a calculator, a Microprocessor (MCU), a Central Processing Unit (CPU), or other Programmable Controller (Microprocessor), a Digital Signal Processor (DSP), a Programmable Controller, an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (PLD), or the like, but the invention is not limited thereto.

These processing stations PS 1-PS 5 are dedicated to different steps in the glass molding process, respectively. Referring to fig. 1 and 2B to 2G, the processing station PS1 (or the first processing station) serves as a relay station for guiding the unprocessed workpiece W from the measuring station MS and guiding the processed workpiece W' to the measuring station MS. Station PS2 (or the second station) is dedicated to the preheating step in the glass molding process. The processing stations PS3 (or called third processing station) and PS4 (or called fourth processing station) are dedicated to the first and second heating and pressing steps of the glass molding process, respectively. Processing station PS5 (or fifth processing station) is dedicated to the cooling step in the glass molding process. The processing stations PS 1-PS 5 can also be considered as different zones where different steps are performed. The specific architecture of each processing station PS 1-PS 5 is described in the following paragraphs.

Referring to fig. 2B, processing station PS1 includes conveyor CB.

Referring to fig. 2C, processing station PS2 includes heaters H1, H2 (or first heater) and link R2. The heaters H1 and H2 are members that can generate heat when energized, and the heaters H1 and H2 are disposed to face each other. One end of the link R2 is mechanically coupled to the heater H1, wherein the link R2 is adapted to be forced to drive the heater H1 so that the heater H1 moves in the axial direction of the link R2.

Referring to fig. 2D, the processing station PS3 includes a servo motor SM2, heaters H3, H4, a link R3, and a platen P2. The heaters H3, H4 are provided to face each other. Platen P2 is disposed between heater H3 and upper mold core M1 and is thermally coupled to heater H3. The servo motor SM2 is mechanically coupled to the link R3, wherein the link R3 is adapted to receive a force from the servo motor SM2 to drive the heater H3 to move the heater H3 in an axial direction of the link R2.

Referring to fig. 2E, the processing station PS4 has a similar structure to that of processing station PS3 because its function is similar to that of processing station PS3, and thus is not described herein again.

Referring to fig. 2F, processing station PS5 includes heaters H5, H6, and link R3. The heaters H5, H6 are provided to face each other. One end of the link R3 is mechanically coupled to the heater H5, wherein the link R3 is adapted to be forced to drive the heater H5 so that the heater H5 moves in the axial direction of the link R3.

Referring to fig. 1 and fig. 2A to fig. 2G, in the present embodiment, the conveying structures TM0 to TM5 are, for example, structures capable of gripping or pushing the workpiece W and conveying the workpiece W in one direction. The conveying structures TM 0-TM 5 (indicated by arrows) may be conveying arms or motors with push rods, but are not limited thereto.

It should be noted that the above-mentioned architecture is only used to illustrate the basic components of the embodiment that perform the steps of each processing station, and in other embodiments, different components may be added to perform different steps in different processing stations, which is not limited by the invention. Moreover, it can be seen that the number of processing stations can be increased or decreased, as desired, and the invention is not limited to the number of processing stations.

The operation of the multi-station glass molding system 100 of the present embodiment will be described in detail in the following paragraphs.

Referring to fig. 1 and 2A, first, a base B carrying a mold M is transferred to a base station BS of a measuring station MS by a conveying mechanism (e.g., a robot arm, not shown). In the measuring station MS, the mold M is opened to separate the upper and lower mold cores M1, M2, and the unprocessed work piece W (e.g., glass material) is placed on the lower mold core M2 of the mold M to complete the loading step.

Next, the controller C executes the first program PD1, wherein the first program PD1 sequentially includes three steps S1 to S3 as shown in fig. 3.

Step S1: the servo motor SM1 controlling the measuring station MS drives the platen P1 to apply a downward pressure to the mold M including the unprocessed workpiece W.

Step S2: then, the controller C detects the current value supplied from the power supply PS of the processing station PS1 to the servo motor SM1 of the processing station PS 1.

Step S3: the controller C determines whether the current value is greater than or equal to a first predetermined value, wherein if the current value of the servo motor SM1 is equal to the first predetermined value, the current value supplied to the servo motor SM1 by the power supply PS is just enough to enable the servo motor SM1 to drive the platen P1, so that the upper mold core M2 located below the platen P1 can touch the unprocessed workpiece W. Therefore, if the current value of the servo motor SM1 is greater than or equal to the first predetermined value, the encoder of the servo motor SM1 obtains a first height data HT1 of the platen P1 according to the current value and a first time duration applied to the current value. The first height data HT1 represents the height of the pressing plate P1 pressing the unprocessed workpiece W (or the position corresponding to the top of the mold M, i.e., the upper surface of the upper mold insert M1). If the controller C determines that the current value is smaller than the first preset value, which means that the upper mold core M2 does not touch the unprocessed workpiece W, the controller C sends a control signal to the power supply PS to enable the power supply PS to adjust the current value supplied to the servo motor SM1 to be greater than or equal to the first preset value, and the controller C captures the first height data HT1 according to the above steps until the current value satisfies the condition that the current value is greater than or equal to the first preset value.

After the controller C completes the first sequence PD1, the servo motor SM1 drives the link R1 to move the platen P1 away. The transport mechanism TM0 moves the base B on which the unprocessed workpiece W is mounted, the dies M1 and M2 from the measurement station MS to the processing station PS 1.

It should be noted that, in a general case, the first height data HT1 includes the heights of the mold M and the unprocessed workpiece W, and if the value of the first height data HT1 falls within a normal height range, it indicates that the height ranges of the mold M and the unprocessed workpiece W are normal. If not, it indicates that there is a problem with the mold M or the unprocessed workpiece W, and the controller C may also send an alarm signal to remind the user to check the mold M or the unprocessed workpiece W.

Referring to fig. 1 and fig. 2B, the conveyor TM0 sets the base B on the conveyor CB to prepare for the start of molding the glass lens. The transport mechanism TM1 then moves the base B from the processing station PS1 to the processing station PS 2.

Referring to fig. 1 and 2C, in processing station PS2, link R2 drives heater H1 to move down to contact upper mold core M1, so that mold M is held by heaters H1 and H2. The heaters H1, H2 transfer heat to the workpiece W to preheat the workpiece W to complete the preheating step, wherein the temperature range of the entire preheating step falls within the range of 40 degrees celsius to 500 degrees celsius, but is not limited thereto. After the preheating step, the link R2 drives the heater H1 to move away from the upper mold insert M1, and the conveyor TM2 moves the base B with the preheated workpiece W from the processing station PS2 to the processing station PS 3.

Referring to fig. 1 and 2D, the susceptor B is disposed on the heater H4 by the conveying mechanism TM 2. In the processing station PS3, the servo motor SM2 drives the link R3 to drive the heater H3 and the platen P2 to move downward to heat and apply pressure to the mold M at the same time, so as to complete the first heating and pressing step, wherein the temperature range of the whole first heating and pressing step falls within the range of 500 degrees to 600 degrees, but not limited thereto. After the first heating and pressing step is completed, the link R3 drives the platen P2 to move away from the upper mold insert M1, and the conveyor TM3 moves the base B with the workpiece W after the first heating and pressing step from the processing station PS3 to the processing station PS 4.

Referring to fig. 1 and fig. 2E, the susceptor B is disposed on the heater H4 by the conveying mechanism TM 3. In the processing station PS4, since the flow of the second heating and pressing step is the same as that of the processing station PS3, the description is omitted here, and the temperature range of the whole second heating and pressing step falls within the range of 500 degrees celsius to 600 degrees celsius, but not limited thereto. After the second heating and pressing step is completed, the link R3 drives the platen P2 to move away from the upper mold insert M1, and the conveyor TM4 moves the base B with the workpiece W after the second heating and pressing step from the processing station PS4 to the processing station PS 5.

Referring to fig. 1 and fig. 2E, the susceptor B is disposed on the heater H6 by the conveying mechanism TM 4. In processing station PS5, link R4 drives heater H5 to move down to contact upper mold core M1, so that mold M is held by heaters H5 and H6, wherein the temperature range of the whole cooling step falls within, but not limited to, 590 to 20 degrees celsius, for example. Thus, the workpiece W' is less likely to be chipped by rapid cooling. To this end, the workpiece W' (a processed workpiece, such as a glass lens) is substantially processed. After the cooling step is completed, the conveyor TM5 finally moves the base B with the processed workpiece W' from the processing station PS5 to the processing station PS 1.

Referring to fig. 1 and 2F, after being sent to the processing station PS1, the conveyor mechanism TM0 moves the base B carrying the dies M1 and M2 and the processed workpiece W' from the processing station PS1 to the measuring station MS. Referring to fig. 4, at this time, the controller C executes the second process PD2, wherein the second process PD2 sequentially includes the following three steps S4 to S6.

Step S4: the controller C again controls the servo motor SM1 of the measuring station MS to drive the platen P1 to apply a downward pressure to the mold M including the processed workpiece W'.

Step S5: then, the controller C detects the current value supplied to the servo motor SM1 by the power supply PS of the measurement station MS.

Step S6: the controller C determines whether the current value is greater than or equal to a second preset value. Similarly, if the current value of the servo motor SM1 is equal to the second predetermined value, the current value supplied to the servo motor SM1 by the power supply PS is just enough to enable the servo motor SM1 to drive the platen P1, so that the upper mold core M2 located below the platen P1 can hit the processed workpiece W'. Therefore, if the current value of the servo motor SM1 is greater than or equal to the second predetermined value, which indicates that the upper mold core M2 touches the processed workpiece W', the encoder of the servo motor SM1 obtains a second height data HT2 of the platen P1 according to the current value and a second time duration applied to the current value. The second height data HT2 represents the height of the pressing plate P1 pressing the processed workpiece W' (or the position corresponding to the top of the mold M, i.e., the upper surface of the upper mold insert M1). If the controller C determines that the current value is smaller than the second preset value, the controller C sends a control signal to the power supply PS to enable the power supply PS to adjust the current value supplied to the servo motor SM1 to be greater than or equal to the second preset value, and the controller C retrieves the second height data HT2 according to the above steps until the current value meets the condition that the current value is greater than or equal to the second preset value.

Referring to fig. 1, fig. 2G, fig. 5 and fig. 6 again, next, the controller C executes the third program PD3, and the third program PD3 includes the following steps S7 and S8.

Step S7: the controller C compares the first and second height data to obtain the press-forming distance of the mold M, wherein the controller C obtains the press-forming distance by subtracting the first and second height data HT1, HT2 and obtaining the absolute value.

Step S8: the controller C further compares the pressing distance between the mold M and the processed workpiece W ' with a predetermined pressing distance range a, referring to fig. 6, if the pressing distance between the mold M and the processed workpiece W ' falls within the predetermined pressing distance range a, which indicates that there is no problem in the manufacturing process of the processed workpiece W ', the controller C notifies the multi-station glass molding system 100 to continue operating. If the pressing distance of the die M from the processed workpiece W 'falls outside the preset pressing distance range a, the manufacturing process representing the processed workpiece W' is problematic (e.g., the workpiece 14 of fig. 6). At this time, the controller C sends an alarm signal to notify the user to stop the multi-station glass molding system 100 or directly stop the multi-station glass molding system 100.

Referring to fig. 2H again, at this time, the servo motor SM1 drives the platen P1 to move away from the upper mold core M2, and the mold M is opened to take out the processed workpiece W' (glass lens) to complete the blanking step.

In view of the above, in the multi-station glass press molding system 100 of the present embodiment, the controller C applies the downward pressure to the mold M including the unprocessed workpiece W and the mold M including the processed workpiece W' by the first and second programs PD1 and PD2, respectively, to obtain the first and second height data HT1 and HT2, respectively, and then obtains the press-forming distance of the mold M by the third program PD3 for the first and second height data HT1 and HT 2. The controller C can determine whether the processed workpiece W' is good or not according to the pressing distance. Further, if the controller C finds that the processed workpiece W' is a defective product according to the press-forming distance, the operation of the multi-station glass press molding system 100 may be stopped or an alarm signal may be issued to notify the user of the removal of the obstacle. Therefore, the multi-station glass molding system 100 can monitor the manufacturing distance and the variation of the molding process on the production line in real time, and can reduce the cost of the subsequent quality management.

FIG. 7 is a flowchart illustrating steps for manufacturing a multiple station glass press system according to one embodiment of the present invention.

Referring to FIG. 7, a flowchart of steps for manufacturing a multi-station glass press system includes the following steps S100-S300, which are described in sections below.

Step S100: a plurality of processing stations PS 1-PS 5 are assembled.

Step S200: the measuring station MS is assembled and connected to the first processing station PS1 of these processing stations PS1 to PS5, and includes a base B, a platen P1, a servo motor SM1, a power supply PS, and a controller C. The base B may carry the mold M. The servo motor SM1 can drive the platen P1. The power supply PS is electrically connected to the servo motor SM 1. The controller C is electrically connected to the servo motor SM 1.

Step S300: a plurality of conveying mechanisms TM 0-TM 5 are assembled, and one conveying mechanism is arranged between the processing stations PS 1-PS 5 or between the first processing station PS1 and the measuring station MS.

In summary, in the multi-station glass molding system according to the embodiment of the present invention, the mold of the unprocessed workpiece (glass cutting material) and the mold including the processed workpiece (glass lens) are respectively applied with downward pressure to respectively obtain the first and second height data. Then, the embossing distance is obtained by the first and second height data. The multi-station glass molding system and the manufacturing method of the glass molding lens can judge whether the processed workpiece (glass lens) is good or not according to the molding distance. In addition, the invention also provides a manufacturing method for manufacturing the multi-station glass molding system.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A multi-station glass molding system, comprising:

a plurality of processing stations;

a measurement station coupled to a first of the plurality of processing stations, wherein the measurement station comprises:

a base provided with a mold;

a pressure plate;

the servo motor is connected with the pressure plate;

a power supply electrically connected to the servo motor; and

a controller electrically connected to the servo motor, an

The conveying mechanism is arranged between every two processing stations or between the first processing station and the measuring station.

2. The multi-station glass molding system of claim 1,

the controller can execute a first program, a second program and a third program, wherein,

the first program sequentially includes: controlling the servo motor to drive the platen to apply a down force to the mold including a raw workpiece;

detecting the current value supplied to the servo motor by the power supply;

judging whether the current value is greater than or equal to a first preset value, if so, capturing first height data in an encoder of the servo motor;

the second procedure sequentially comprises: controlling the servo motor to drive the platen to apply a down force to the mold including the machined workpiece;

detecting the current value supplied to the servo motor by the power supply;

judging whether the current value is greater than or equal to a second preset value, if so, capturing second height data in an encoder of the servo motor;

the third program includes: and comparing the first height data with the second height data to obtain the pressing distance of the die.

3. The system of claim 2, wherein in the step of determining whether the current value is greater than or equal to the first predetermined value in the first procedure, if not, the controller sends a control signal to the power supply to enable the power supply to adjust the current value supplied to the servo motor to be greater than or equal to the first predetermined value.

4. The system of claim 2, wherein in the step of determining whether the current value is greater than or equal to the second predetermined value in the second procedure, if not, the controller sends a control signal to the power supply to enable the power supply to adjust the current value supplied to the servo motor to be greater than or equal to the second predetermined value.

5. The multi-station glass press system as in claim 2, wherein the third program of the controller further comprises:

judging whether the press-manufacturing distance of the die falls within a preset press-manufacturing distance range,

if so, the controller informs the multi-station glass molding system to operate continuously.

6. The multi-station glass molding system according to claim 5, wherein in the step of determining whether the molding distance of the mold falls within a preset molding distance range,

if not, the controller sends out an alarm signal or directly stops the multi-station glass molding system.

7. The multi-station glass molding system of claim 1, wherein the plurality of processing stations further comprises at least one hot press processing station and a cool down processing station, the cool down processing station being located downstream of the at least one hot press processing station,

the hot pressing station includes a first heater and a first connecting rod,

the first link is mechanically coupled to the first heater,

the cooling processing station includes a second heater and a second connecting rod,

the second link is mechanically coupled to a second heater,

wherein,

when the mold including a workpiece is conveyed by one of the conveying mechanisms between the first heaters, the first link drives the first heater mechanically coupled thereto to pressurize the mold including the workpiece and the first heater heats the mold including the workpiece;

when the mold including the workpiece is conveyed between the second heaters by one of the conveying mechanisms, the second link drives the second heaters mechanically coupled thereto to pressurize the mold including the workpiece and the second heaters cool the mold including the workpiece.

8. The multi-station glass molding system of claim 1, wherein the plurality of processing stations further comprises the first processing station, a second processing station, a third processing station, a fourth processing station, and a fifth processing station, the plurality of transport mechanisms further comprises a zeroth transport mechanism, a first transport mechanism, a second transport mechanism, a third transport mechanism, a fourth transport mechanism, and a fifth transport mechanism,

wherein,

the first processing station is respectively connected with the measuring station and the second processing station through the zeroth conveying mechanism and the first conveying mechanism,

the first processing station is connected with the second processing station through the first conveying mechanism;

the second processing station is connected with the third processing station through the second conveying mechanism;

the third processing station is connected with the fourth processing station through the third conveying mechanism;

the fourth processing station is connected with the fifth processing station through the fourth conveying mechanism; and

the fifth processing station is connected with the first processing station through the fifth conveying mechanism.

9. A method of making a multi-station glass molding system (in a modification of any of the following instructions ), comprising:

assembling a plurality of processing stations;

assembling a measuring station and connecting the measuring station with a first processing station of the plurality of processing stations, wherein the measuring station comprises a base, a pressing plate, a servo motor, a power supply and a controller, the base can bear a mold, the servo motor can drive the pressing plate, the power supply is electrically connected with the servo motor, and the controller is electrically connected with the servo motor; and

and assembling a plurality of conveying mechanisms, wherein one conveying mechanism is arranged between every two processing stations or between the first processing station and the measuring station.

10. The method of claim 9, wherein the plurality of processing stations further comprises the first processing station, a second processing station, a third processing station, a fourth processing station, and a fifth processing station, and the plurality of transport mechanisms further comprises a zeroth transport mechanism, a first transport mechanism, a second transport mechanism, a third transport mechanism, a fourth transport mechanism, and a fifth transport mechanism, wherein,

the first processing station is respectively connected with the measuring station and the second processing station through the zeroth conveying mechanism and the first conveying mechanism,

the first processing station is connected with the second processing station through the first conveying mechanism;

the second processing station is connected with the third processing station through the second conveying mechanism;

the third processing station is connected with the fourth processing station through the third conveying mechanism;

the fourth processing station is connected with the fifth processing station through the fourth conveying mechanism; and

the fifth processing station is connected with the first processing station through the fifth conveying mechanism.

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