CN212944994U - Novel corrosion-resistant precision mold - Google Patents

Abstract

The utility model belongs to the technical field of dies, in particular to a novel corrosion-resistant precision die, which comprises a precision die main body, a stamping mechanism, a fixing mechanism and a base, wherein the top of the precision die main body is embedded and connected with the stamping mechanism, the bottom of the precision die main body is embedded and connected with the fixing mechanism, one end of the stamping mechanism is embedded and connected with a supporting plate, one side of the inside of the top of the stamping mechanism is embedded and connected with a control box, the other side of the inside of the top of the stamping mechanism is embedded and connected with a microprocessor, the stamping mechanism is helpful for facilitating an operator to carry out extrusion forming on materials inside a high-temperature corrosion-resistant material die cavity, the practicability of the device is improved, the fixing mechanism is formed by combining a shock absorber, a fixer, a rotator, a connector, a high-temperature corrosion-resistant material die, the stability of the high-temperature corrosion-resistant material die cavity is improved, and the high-temperature corrosion-resistant material die cavity can have wide development prospect in the future.

Description

Novel corrosion-resistant precision mold

Technical Field

The utility model relates to the technical field of molds, in particular to a novel corrosion-resistant precision mold.

Background

The mould is a mould and a tool for obtaining a required product by injection molding, blow molding, extrusion, die casting or forging forming, smelting, stamping and other methods in industrial production.

At present, the position of arrangement that raw and other materials often can appear when processing is being processed to current precision mould is not accurate enough, it is not very good that the even degree of height and heat during notes material is mastered, the mould soft or hard condition that often can appear producing is not uniform, common precision mould functional and structure are all more single, the operating mode is loaded down with trivial details, during production, it is very inconvenient to remove, and because the corrosion resisting property of mould is relatively poor, cause its life to subtract the weak point, for this reason, we propose a precision mould with accurate positioning function.

Therefore, how to design a novel corrosion-resistant precision mold becomes a problem to be solved at present.

Disclosure of Invention

An object of the utility model is to provide a novel corrosion-resistant accurate mould to solve the function singleness that proposes in the above-mentioned background art, the loaded down with trivial details and the relatively poor problem of corrosion resisting property of operation mode.

In order to achieve the above object, the utility model provides a following technical scheme: a novel corrosion-resistant precision die comprises a precision die main body, a stamping mechanism, a fixing mechanism and a base, wherein the stamping mechanism is connected to the top of the precision die main body in an embedded manner, the fixing mechanism is connected to the bottom of the precision die main body in an embedded manner, a supporting plate is connected to one end of the stamping mechanism in an embedded manner, a control box is connected to one side of the inside of the top of the stamping mechanism in an embedded manner, a microprocessor is connected to the other side of the inside of the top of the stamping mechanism in an embedded manner, a connecting plate is connected to the top of the stamping mechanism in an embedded manner, a hydraulic telescopic column is connected to the bottom end of the connecting plate in an embedded manner, a stamping device is connected to the bottom end of the hydraulic telescopic column in an embedded manner, a high-temperature corrosion-resistant material protective wall is connected to the surface of the stamping device, the top end of the other side of the high-temperature corrosion-resistant material protection groove is connected with an infrared thermal imager in an embedded manner, the top end of the high-temperature corrosion-resistant material protection groove is connected with a fixed plate in an embedded manner, the top end of the fixing plate is embedded and connected with a shock absorber, the other side of the top end of the shock absorber is embedded and connected with a fixer, the middle part of the top end of the shock absorber is connected with a rotator in an embedded manner, the top end of the rotator is connected with a connector in an embedded manner, the top end of the connector is movably connected with a high-temperature corrosion-resistant material die cavity, the top end of the high-temperature corrosion-resistant material die cavity is embedded and connected with a cushion pad, the other end of the stamping mechanism is connected with a control panel in an embedded manner, the top of the front of the stamping mechanism is connected with a sealing door in an embedded manner, the bottom of precision mould main part embedding is connected with the base, the bottom embedding of base is connected with the slipmat, the preceding bottom through connection of punching press mechanism has the observation window.

Preferably, a pressure sensor is embedded and connected in the punching block.

Preferably, one end of the high-temperature corrosion-resistant material die cavity is connected with a heater in an embedded mode.

Preferably, the top end of the stamping mechanism is connected with an alarm in an embedded mode.

Preferably, the stamping mechanism is formed by combining a supporting plate at one end of the stamping mechanism, a control box at one side inside the top of the stamping mechanism, a microprocessor at the other side inside the top of the stamping mechanism, a connecting plate at the top of the stamping mechanism, a hydraulic telescopic column at the bottom end of the connecting plate, a stamping device at the bottom end of the hydraulic telescopic column, a high-temperature corrosion-resistant material protecting wall on the surface of the stamping device, a telescopic rod at the top inside the stamping device and a stamping block at the bottom end of the telescopic rod.

Preferably, the fixing mechanism is formed by combining a high-temperature corrosion-resistant material protection groove at the bottom of the fixing mechanism, an infrared thermal imager at the top end of the other side of the high-temperature corrosion-resistant material protection groove, a fixing plate at the top end of the high-temperature corrosion-resistant material protection groove, a shock absorber at the top end of the fixing plate, a fixer at the other side of the top end of the shock absorber, a rotator in the middle of the top end of the shock absorber, a connector at the top end of the rotator, a high-temperature corrosion-resistant material die groove at the top end of the connector and a cushion pad at the top end.

Compared with the prior art, the beneficial effects of the utility model are that:

1. this kind of novel corrosion-resistant precision mold, punching press mechanism are formed by backup pad, control box, microprocessor, connecting plate, the flexible post of hydraulic pressure, punching press ware, high temperature corrosion resistant material guard wall, telescopic link and the common combination of punching press piece to reach the effect to material extrusion, punching press mechanism helps making things convenient for operating personnel to carry out extrusion to high temperature corrosion resistant material die cavity internal material, thereby has improved the practicality of device.

2. This kind of novel corrosion-resistant precision mould, fixed establishment is by high temperature corrosion resistant material protection groove, infrared thermal imager, fixed plate, bumper shock absorber, fixer, circulator, connector, high temperature corrosion resistant material die cavity and cushion make up jointly and form to reach and carry out the effect fixed to high temperature corrosion resistant material die cavity, fixed establishment helps making things convenient for operating personnel to fix high temperature corrosion resistant material die cavity, thereby has improved the stability of high temperature corrosion resistant material die cavity.

Drawings

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

FIG. 2 is a schematic view of the overall cross-sectional structure of the present invention;

FIG. 3 is a schematic view of the cross-sectional structure of the punching mechanism of the present invention;

fig. 4 is a schematic view of the sectional structure of the fixing mechanism of the present invention.

The labels in the figure are: 1. precision mould main part, 2, punching press mechanism, 201, the backup pad, 202, the control box, 203, microprocessor, 204, the connecting plate, 205, hydraulic telescoping post, 206, the punching press, 207, high temperature corrosion resistant material protecting wall, 208, the telescopic link, 209, the punching press piece, 2010, pressure sensors, 3, fixed establishment, 301, high temperature corrosion resistant material protecting groove, 302, infrared thermal imager, 303, the fixed plate, 304, the bumper shock absorber, 305, the fixer, 306, the circulator, 307, the connector, 308, high temperature corrosion resistant material die cavity, 309, the heater, 3010, the blotter, 4, the alarm, 5, control panel, 6, sealing door, 7, the base, 8, slipmat, 9, observation window.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention based on the embodiments of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a novel corrosion-resistant precision die comprises a precision die main body 1, a stamping mechanism 2, a fixing mechanism 3 and a base 7, wherein the top of the precision die main body 1 is connected with the stamping mechanism 2 in an embedded manner, the bottom of the precision die main body 1 is connected with the fixing mechanism 3 in an embedded manner, one end of the stamping mechanism 2 is connected with a supporting plate 201 in an embedded manner, one side of the inside of the top of the stamping mechanism 2 is connected with a control box 202 in an embedded manner, the other side of the inside of the top of the stamping mechanism 2 is connected with a microprocessor 203 in an embedded manner, the top of the stamping mechanism 2 is connected with a connecting plate 204 in an embedded manner, the bottom end of the connecting plate 204 is connected with a hydraulic telescopic column 205 in an embedded manner, the bottom end of the hydraulic telescopic column 205 is connected with a stamping device 206 in an embedded manner, the bottom of the fixing mechanism 3 is connected with a high-temperature corrosion-resistant material protection groove 301 in an embedded manner, the top end of the other side of the high-temperature corrosion-resistant material protection groove 301 is connected with an infrared thermal imager 302 in an embedded manner, the top end of the high-temperature corrosion-resistant material protection groove 301 is connected with a fixing plate 303 in an embedded manner, the top end of the fixing plate 303 is connected with a shock absorber 304 in an embedded manner, the other side of the top end of the shock absorber 304 is connected with a fixer 305 in an embedded manner, the middle part of the top end of the shock absorber 304 is connected with a rotator 306 in an embedded manner, the top end of the rotator 306 is connected with a connector 307 in an embedded manner, the top end of the connector 307 is movably connected with a high-temperature corrosion-resistant material die groove 308, the top end of the high-temperature corrosion-resistant material die groove, the bottom end of the base 7 is embedded and connected with an anti-slip pad 8, and the front bottom of the stamping mechanism 2 is connected with an observation window 9 in a penetrating way.

Preferably, the inside embedding of punching press piece 209 is connected with pressure sensors 2010, when the device is at the in-process, microprocessor 203 of the inside opposite side in punching press mechanism 2 top begins the operation, thereby the inside pressure sensors 2010 of control punching press piece 209 begins the operation, and then pressure sensors 2010 monitors the pressure on punching press piece 209, when pressure on punching press piece 209 reaches the setting value, and then pressure sensors 2010 transmits relevant temperature data to microprocessor 203, microprocessor 203 processes data, and then show through control panel 5, thereby can realize carrying out data measurement to the pressure on punching press piece 209 often, pressure sensors 2010 helps monitoring the pressure on punching press piece 209, detect pressure whether normal, thereby the multifunctionality of device has been improved.

Preferably, the heater 309 is connected to one end of the high-temperature corrosion-resistant material die cavity 308 in an embedded manner, when the device needs to heat the material in the high-temperature corrosion-resistant material die cavity 308 in the using process, an operator controls the heater 309 at one end of the high-temperature corrosion-resistant material die cavity 308 to start operating through the control panel 5, so that the heating wires inside the heater 309 start heating, and further heat the material in the high-temperature corrosion-resistant material die cavity 308, thereby improving the temperature of the material in the high-temperature corrosion-resistant material die cavity 308, the heaters 309 are two, the heaters 309 are symmetrically arranged on two sides of the high-temperature corrosion-resistant material die cavity 308, thereby improving the heating speed, the heater 309 is beneficial to facilitating the operator to heat the material in the high-temperature corrosion-resistant material die cavity 308, and further improving the versatility of.

Preferably, the top embedding of punching press mechanism 2 is connected with alarm 4, operating personnel begins to start through 5 controlling means of control panel, thereby the microprocessor 203 controlling means of the inside opposite side in 2 tops of punching press mechanism begins to operate, and then alarm 4 on 2 tops of punching press mechanism begins to operate, thereby microprocessor 203 monitors the behavior of device, the inside a plurality of inductors that are provided with of device, if the short circuit appears in the device or receive the damage, the inductor is to information transmission to microprocessor 203, microprocessor 203 handles data, and then control alarm 4 begins to report to the police, thereby remind whether operating personnel detection device is normal, alarm 4 helps reminding operating personnel to detect each instrument in the device, whether detection device is normal, thereby the security of device has been improved.

Preferably, the stamping mechanism 2 is formed by combining a supporting plate 201 at one end of the stamping mechanism 2, a control box 202 at one side inside the top of the stamping mechanism 2, a microprocessor 203 at the other side inside the top of the stamping mechanism 2, a connecting plate 204 at the top of the stamping mechanism 2, a hydraulic telescopic column 205 at the bottom end of the connecting plate 204, a stamping device 206 at the bottom end of the hydraulic telescopic column 205, a high-temperature corrosion-resistant material protecting wall 207 on the surface of the stamping device 206, a telescopic rod 208 at the top inside the stamping device 206 and a stamping block 209 at the bottom end of the telescopic rod 208, when an operator fixes the high-temperature corrosion-resistant material die cavity 308, the operator injects materials into the high-temperature corrosion-resistant material die cavity 308, and controls the hydraulic telescopic column 205 at the bottom end of the connecting plate 204 to extend through the control panel 5, so that the high-temperature corrosion-resistant material protecting wall 207 on the surface of the stamping, and then the telescopic link 208 extension at the inside top of operating personnel control punching press 206 to the punching press piece 209 that drives the telescopic link 208 bottom extrudes high temperature corrosion resistant material die cavity 308 inside material, and then makes material extrusion, punching press mechanism 2 helps making things convenient for operating personnel to carry out extrusion to high temperature corrosion resistant material die cavity 308 inside material, thereby has improved the practicality of device.

Preferably, the fixing mechanism 3 is formed by combining a high temperature corrosion resistant material protection groove 301 at the bottom of the fixing mechanism 3, an infrared thermal imager 302 at the top end of the other side of the high temperature corrosion resistant material protection groove 301, a fixing plate 303 at the top end of the high temperature corrosion resistant material protection groove 301, a shock absorber 304 at the top end of the fixing plate 303, a fixer 305 at the other side of the top end of the shock absorber 304, a rotator 306 at the middle part of the top end of the shock absorber 304, a connector 307 at the top end of the rotator 306, a high temperature corrosion resistant material die groove 308 at the top end of the connector 307, and a cushion 3010 at the top end of the high temperature corrosion resistant material die groove 308, when an operator needs to use the device, the operator puts a template to be used into the high temperature corrosion resistant material die groove 308 at the top end of the connector 307, the template has different shapes, and the operator can replace the template, thereby fixing the high temperature corrosion resistant material die groove 308 on the fixing, the thermal distribution condition when the infrared thermal imaging system 302 on the other side top end of the high-temperature corrosion-resistant material protection groove 301 helps can sense the injection mold, through the setting of the infrared thermal imaging system, the thermal distribution can be displayed, thereby facilitating the control of operators, the shock absorber 304 on the top end of the fixing plate 303 plays a good shock absorption role, thereby enabling the equipment to be more stable during the operation, the rotator 306 in the middle of the top end of the shock absorber 304 helps to facilitate the rotation of the operators to the high-temperature corrosion-resistant material mold groove 308, the fixing mechanism 3 helps to facilitate the fixation of the operators to the high-temperature corrosion-resistant material mold groove 308, and the stability of the high-temperature corrosion-resistant material mold groove 308 is improved.

The working principle is as follows: firstly, the fixing mechanism 3 is formed by combining a high-temperature corrosion-resistant material protection groove 301 at the bottom of the fixing mechanism 3, an infrared thermal imager 302 at the top end of the other side of the high-temperature corrosion-resistant material protection groove 301, a fixing plate 303 at the top end of the high-temperature corrosion-resistant material protection groove 301, a shock absorber 304 at the top end of the fixing plate 303, a fixer 305 at the other side of the top end of the shock absorber 304, a rotator 306 at the middle part of the top end of the shock absorber 304, a connector 307 at the top end of the rotator 306, a high-temperature corrosion-resistant material die groove 308 at the top end of the connector 307 and a buffer 3010 at the top end of the high-temperature corrosion-resistant material die groove 308, when an operator needs to use the device, the operator puts a template to be used into the high-temperature corrosion-resistant material die groove 308 at the top end of the connector 307, the template has different shapes, and the operator can replace the template, thereby fixing, the thermal distribution condition when the infrared thermal imaging system 302 on the other side top end of the high-temperature corrosion-resistant material protection groove 301 helps can sense the injection mold, through the setting of the infrared thermal imaging system, the thermal distribution can be displayed, thereby facilitating the control of operators, the shock absorber 304 on the top end of the fixing plate 303 plays a good shock absorption role, thereby enabling the equipment to be more stable during the operation, the rotator 306 in the middle of the top end of the shock absorber 304 helps to facilitate the rotation of the operators to the high-temperature corrosion-resistant material mold groove 308, the fixing mechanism 3 helps to facilitate the fixation of the operators to the high-temperature corrosion-resistant material mold groove 308, and the stability of the high-temperature corrosion-resistant material mold groove 308 is improved.

Then, one end of the high temperature corrosion resistant material mold cavity 308 is embedded and connected with a heater 309, when the device needs to heat the material in the high temperature corrosion resistant material mold cavity 308 in the using process, an operator controls the heater 309 at one end of the high temperature corrosion resistant material mold cavity 308 to start operating through the control panel 5, so that the heating wires inside the heater 309 start heating, and further heat the material in the high temperature corrosion resistant material mold cavity 308, thereby improving the temperature of the material in the high temperature corrosion resistant material mold cavity 308, the heaters 309 are provided with two, the heaters 309 are symmetrically arranged at two sides of the high temperature corrosion resistant material mold cavity 308, thereby improving the heating speed, the heater 309 is beneficial to facilitating the operator to heat the material in the high temperature corrosion resistant material mold cavity 308, and further improving the versatility of the device.

Next, the stamping mechanism 2 is formed by combining a supporting plate 201 at one end of the stamping mechanism 2, a control box 202 at one side inside the top of the stamping mechanism 2, a microprocessor 203 at the other side inside the top of the stamping mechanism 2, a connecting plate 204 at the top of the stamping mechanism 2, a hydraulic telescopic column 205 at the bottom end of the connecting plate 204, a stamping device 206 at the bottom end of the hydraulic telescopic column 205, a high-temperature corrosion-resistant material protecting wall 207 on the surface of the stamping device 206, a telescopic rod 208 at the top inside the stamping device 206 and a stamping block 209 at the bottom end of the telescopic rod 208, when an operator fixes the high-temperature corrosion-resistant material die cavity 308, the operator injects a material into the high-temperature corrosion-resistant material die cavity 308, and controls the hydraulic telescopic column 205 at the bottom end of the connecting plate 204 to extend through the control panel 5, so that the high-temperature corrosion-resistant material protecting wall 207 on the surface of, and then the telescopic link 208 extension at the inside top of operating personnel control punching press 206 to the punching press piece 209 that drives the telescopic link 208 bottom extrudes high temperature corrosion resistant material die cavity 308 inside material, and then makes material extrusion, punching press mechanism 2 helps making things convenient for operating personnel to carry out extrusion to high temperature corrosion resistant material die cavity 308 inside material, thereby has improved the practicality of device.

Next, the inside embedding of punching press piece 209 is connected with pressure sensors 2010, when the device is at the in-process, microprocessor 203 of the inside opposite side in punching press mechanism 2 top begins the operation, thereby the inside pressure sensors 2010 of control punching press piece 209 begins the operation, and then pressure sensors 2010 monitors the pressure on punching press piece 209, when pressure on punching press piece 209 reaches the setting value, and then pressure sensors 2010 transmits relevant temperature data to microprocessor 203, microprocessor 203 handles data, and then show through control panel 5, thereby can realize carrying out data measurement to the pressure on punching press piece 209 often, pressure sensors 2010 helps monitoring the pressure on punching press piece 209, detect pressure whether normal, thereby the multifunctionality of device has been improved.

Finally, the top end of the punching mechanism 2 is embedded and connected with an alarm 4, an operator controls the device to start through a control panel 5, so that the microprocessor 203 on the other side of the inside of the top of the press mechanism 2 controls the apparatus to start operating, and then the alarm 4 at the top end of the punching mechanism 2 starts to operate, so that the microprocessor 203 monitors the operation condition of the device, a plurality of sensors are arranged in the device, if the device is shorted or damaged, the sensor transmits information to the microprocessor 203, the microprocessor 203 processes the data, and then the alarm 4 is controlled to start alarming, thereby reminding an operator whether the detection device is normal or not, the alarm 4 is helpful for reminding the operator to detect each instrument in the device, whether the detection device is normal or not, thereby improving the safety of the device, which is the working principle of the novel corrosion-resistant precision die.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a novel corrosion-resistant precision mold, includes precision mold main part (1), punching press mechanism (2), fixed establishment (3) and base (7), its characterized in that: the top of the precision mold main body (1) is embedded and connected with a stamping mechanism (2), the bottom of the precision mold main body (1) is embedded and connected with a fixing mechanism (3), one end of the stamping mechanism (2) is embedded and connected with a supporting plate (201), one side of the inside of the top of the stamping mechanism (2) is embedded and connected with a control box (202), the other side of the inside of the top of the stamping mechanism (2) is embedded and connected with a microprocessor (203), the top of the stamping mechanism (2) is embedded and connected with a connecting plate (204), the bottom of the connecting plate (204) is embedded and connected with a hydraulic telescopic column (205), the bottom of the hydraulic telescopic column (205) is embedded and connected with a stamping device (206), the surface of the stamping device (206) is embedded and connected with a high-temperature corrosion-resistant material protective wall (207), and the inside, the bottom end of the telescopic rod (208) is embedded and connected with a stamping block (209), the bottom of the fixing mechanism (3) is embedded and connected with a high-temperature corrosion-resistant material protection groove (301), the top end of the other side of the high-temperature corrosion-resistant material protection groove (301) is embedded and connected with an infrared thermal imager (302), the top end of the high-temperature corrosion-resistant material protection groove (301) is embedded and connected with a fixing plate (303), the top end of the fixed plate (303) is embedded and connected with a shock absorber (304), the other side of the top end of the shock absorber (304) is embedded and connected with a fixer (305), a rotator (306) is embedded and connected in the middle part of the top end of the shock absorber (304), the top end of the rotator (306) is embedded and connected with a connector (307), the top end of the connector (307) is movably connected with a high-temperature corrosion-resistant material die cavity (308), the top end of the high-temperature corrosion-resistant material die cavity (308) is embedded and connected with a buffer cushion (3010).

2. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: the other end embedding of punching press mechanism (2) is connected with control panel (5), the preceding top embedding of punching press mechanism (2) is connected with sealing door (6), the bottom embedding of precision mould main part (1) is connected with base (7), the bottom embedding of base (7) is connected with slipmat (8), the preceding bottom through connection of punching press mechanism (2) has observation window (9).

3. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: a pressure sensor (2010) is embedded and connected in the stamping block (209).

4. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: one end of the high-temperature corrosion-resistant material die cavity (308) is embedded and connected with a heater (309).

5. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: the top end of the punching mechanism (2) is connected with an alarm (4) in an embedded manner.

6. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: the stamping mechanism (2) is formed by jointly combining a supporting plate (201) at one end of the stamping mechanism (2), a control box (202) at one side inside the top of the stamping mechanism (2), a microprocessor (203) at the other side inside the top of the stamping mechanism (2), a connecting plate (204) at the top of the stamping mechanism (2), a hydraulic telescopic column (205) at the bottom end of the connecting plate (204), a stamping device (206) at the bottom end of the hydraulic telescopic column (205), a high-temperature corrosion-resistant material protection wall (207) on the surface of the stamping device (206), a telescopic rod (208) at the top inside the stamping device (206) and a stamping block (209) at the bottom end of the telescopic rod (208).

7. A novel corrosion-resistant precision mold as claimed in claim 1, wherein: the fixing mechanism (3) is formed by combining a high-temperature corrosion-resistant material protection groove (301) at the bottom of the fixing mechanism (3), an infrared thermal imager (302) at the top end of the other side of the high-temperature corrosion-resistant material protection groove (301), a fixing plate (303) at the top end of the high-temperature corrosion-resistant material protection groove (301), a shock absorber (304) at the top end of the fixing plate (303), a fixer (305) at the other side of the top end of the shock absorber (304), a rotator (306) at the middle part of the top end of the shock absorber (304), a connector (307) at the top end of the rotator (306), a high-temperature corrosion-resistant material die groove (308) at the top end of the connector (307) and a cushion pad (3010) at the top end of.

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