CN112659248A - Processing equipment - Google Patents

Abstract

The application discloses processing equipment includes: the device comprises a workpiece, a bearing platform and a negative pressure device; the bearing table is arranged below the workpiece and comprises a bearing surface and a bottom surface which are back to back; the bearing platform is provided with a first through hole and a second through hole, the first through hole penetrates through the bearing surface and the bottom surface and corresponds to a machined part, and the first through hole is used for collecting machining waste; one end of the second through hole is positioned on the side wall of the first through hole and communicated with the first through hole; the negative pressure device is communicated with the other end of the second through hole to generate negative pressure so as to adsorb dust falling into the first through hole from the bearing surface. Through the mode, the processing waste can be removed in time, and the processing waste is prevented from being accumulated.

Description

Processing equipment

Technical Field

The application relates to the field of display, in particular to a processing device.

Background

At present, an ultra-narrow frame or even a frameless design with a high screen occupation ratio has become a development trend of electronic setting, so electronic devices for realizing functions of face recognition, fingerprint recognition, camera shooting and the like are generally installed in a display screen range to avoid occupying the space outside the edge of the display screen to increase the frame width, and therefore holes need to be punched on a display panel for installing the electronic devices. In the prior art, when the product is punched by utilizing processing equipment, the problem of waste accumulation can exist.

Disclosure of Invention

The main technical problem who solves of this application provides a processing equipment, can in time remove the processing waste material, prevents that the processing waste material from piling up.

In order to solve the technical problem, the application adopts a technical scheme that: there is provided a processing apparatus including: the device comprises a workpiece, a bearing platform and a negative pressure device; the bearing table is arranged below the workpiece and comprises a bearing surface and a bottom surface which are back to back; the bearing platform is provided with a first through hole and a second through hole, the first through hole penetrates through the bearing surface and the bottom surface, corresponds to the machined part and is used for collecting machining waste; one end of the second through hole is positioned on the side wall of the first through hole and communicated with the first through hole; the negative pressure device is communicated with the other end of the second through hole to generate negative pressure so as to adsorb dust falling into the first through hole from the bearing surface.

The second through hole is positioned on one side, close to the bearing surface, of the side wall of the first through hole of the bearing platform. Therefore, the dust is adsorbed by the second through hole after falling into the first through hole, and accumulation of the dust on the side wall of the first through hole is effectively reduced.

The number of the second through holes is at least two; preferably, the number of the second through holes is two, and the second through holes are respectively arranged on two opposite sides of the side wall of the first through hole. Set up two second through-holes, can more effectual absorption fall into the dust in the first through-hole. The two second through holes are respectively arranged on two opposite sides of the side wall of the first through hole, so that the situation that part of dust far away from the second through hole cannot be adsorbed to enter the second through hole can be avoided.

The first through hole comprises a first section and a second section, wherein the first section is closer to the bearing surface than the second section, and the aperture of the second section is larger than or equal to that of the first section. Therefore, the first through hole can have a larger space for allowing the waste material to pass through, and the first through hole is prevented from being blocked.

The negative pressure device is also communicated with one end of the first through hole, which is positioned on the bottom surface; preferably, the processing equipment further comprises a dust collection box arranged on the bottom surface of the bearing table, one side of the dust collection box is communicated with the first through hole, and the other side of the dust collection box is communicated with the negative pressure device. The negative pressure device can adsorb the dust that drops from the product into first through-hole, prevents that the dust from wafting other regions of falling to the plummer and causing the dust to pile up.

The processing equipment further comprises an air injection device, wherein the air injection device is positioned on one side of the bearing surface, which is far away from the bottom surface, and is used for injecting air from the bearing surface to the first through hole. The air injection device can blow away the processing waste material retained in the first through hole from the first through hole, so that the first through hole is prevented from being blocked, and the processing waste material is removed in time.

Wherein, the air jet system includes: the air nozzle faces the first through hole; the gas conveying structure is connected with the gas nozzle and used for conveying gas to the inlet of the gas nozzle so that the gas can be sprayed out from the outlet of the gas nozzle. The air jet nozzle structure is used for jetting air, so that the air flow direction can be accurately controlled, and waste materials can be removed.

Wherein, the processing equipment still includes: the driving device is connected with the air injection device and used for driving the air injection device to move; preferably, the driving device is also connected with the workpiece and used for driving the workpiece to move. The driving device can drive the air injection device to move so as to be suitable for punching requirements of different positions.

Wherein, the processing equipment still includes: the fixing plate is fixed on the driving device and connected with the air injection device; preferably, a kidney-shaped hole is formed in one end, connected with the driving device, of the fixing plate, the driving device is provided with a plurality of corresponding fixing components, and the fixing components can be inserted into the kidney-shaped hole to fix the fixing plate; wherein the position of the fixing component in the waist-shaped hole is adjustable. The fixed plate and the driving device are adjustable in position, so that the relative positions of the air injection device and the driving device can be adjusted, and the punching requirements of different products at different positions can be met.

Wherein, the processing equipment still includes: and the control device is coupled with the negative pressure device and used for controlling the negative pressure device to provide negative pressure. The control device can enable the negative pressure device not to be in the starting state all the time, so that energy can be saved.

The beneficial effect of this application is: in contrast to the prior art, the present application provides a processing apparatus including a workpiece, a susceptor, and a negative pressure device. The plummer is provided with first through-hole and second through-hole. The second through hole is arranged on the side wall of the first through hole, one end of the second through hole is communicated with the first through hole, and the other end of the second through hole is communicated with the negative pressure device. The negative pressure device can reduce the gas pressure in the second through hole, so that the gas pressure in the second through hole and the gas pressure in the first through hole have a certain pressure difference, and dust falling into the first through hole can be adsorbed into the second through hole when the dust is positioned near the second through hole. The second through-hole can effectually prevent that the waste material dust from adhering to in first through-hole, avoids first through-hole to be blockked up. Therefore, the processing waste can be removed in time, and the accumulation of the processing waste is reduced.

In addition, because the negative pressure device can promote the gas to flow, the negative pressure device leads the gas flow speed of the product processing area above the first through hole to be accelerated through the second through hole and the first through hole which are communicated with each other. Therefore, heat generated by processing equipment during punching can be taken away, and the product is prevented from being damaged due to overhigh temperature of a punching area.

Drawings

FIG. 1 is a schematic diagram of a processing tool according to an embodiment of the present application;

FIG. 2 is a top view of the carrier of FIG. 1;

FIG. 3 is a schematic cross-sectional view of the carrier of FIG. 2 taken along the direction c-c;

FIG. 4 is a schematic structural diagram of a processing tool according to another embodiment of the present application;

fig. 5 is a schematic structural diagram of an air injection device according to an embodiment of the present application.

Detailed Description

In order to make the purpose, technical solution and effect of the present application clearer and clearer, the present application is further described in detail below with reference to the accompanying drawings and examples.

The inventor finds in long-term research that dropped waste materials can cause waste material accumulation in the hole area of a product if the dropped waste materials cannot be removed in time in the process of punching the product by using processing equipment. The accumulated waste material can rub against the product, causing damage to the product. Moreover, the accumulated waste materials also cause unsmooth ventilation of the punching area, so that heat generated by punching operation cannot be dissipated, the temperature of the hole area of the product rises, and the product is damaged. For example, when using processing equipment to punch display panel, display panel is got rid of the waste material if can not be removed immediately, and the waste material can cause wearing and tearing to display panel to the waste material is piled up and is leaded to the heat that the operation produced of punching can't in time distribute, makes the regional high temperature that punches, scalds display panel, thereby influences display panel's quality.

In order to solve the above problems, the present application provides a processing apparatus, which includes a bearing table and a negative pressure device, wherein the bearing table is provided with a first through hole and a second through hole, the first through hole penetrates through the bearing table, the second through hole is arranged on a side wall of the first through hole, and one end of the second through hole is communicated with the first through hole; the negative pressure device is communicated with the other end of the second through hole, negative pressure is generated to adsorb dust falling into the first through hole from the bearing surface, and therefore machining waste and dust can be removed in time, and accumulation is reduced. As will be explained in detail below.

Referring to fig. 1, 2 and 3, fig. 1 is a schematic structural diagram of a processing apparatus according to an embodiment of the present application. Fig. 2 is a top view of the carrier table of fig. 1. FIG. 3 is a schematic cross-sectional view of the stage of FIG. 2 taken along the direction C-C, i.e., the direction C-C is the observation direction, and the cross-section is observed from the direction indicated by the arrow. The line without arrows indicates the cutting position, i.e. the cross section is formed by cutting the platform in a direction perpendicular to the top view at the position of the line without arrows.

The processing apparatus 10 includes a workpiece 100, a susceptor 200, a base 300, and a negative pressure device 400. The loading platform 200 is disposed on one side of the base 300, the workpiece 100 is located on one side of the loading platform 200 away from the base 300, and the loading platform 200 is disposed below the workpiece 100. The workpiece 100 may be any suitable workpiece 100 for punching. For example, the workpiece 100 may be a drill or a laser emitting device, or the like. The processing apparatus 10 can be used for the punching of a variety of products. In one embodiment, the processing tool 10 may be used for punching processing of display panels.

Referring to fig. 3, the cross-sectional structure of the carrier 200 at the viewing angle in the C-C direction includes a carrier surface a and a bottom surface b opposite to each other; the bearing surface a is used for placing a product to be punched. The carrier 200 is provided with a first through-hole 210 and a second through-hole 220. The first through hole 210 penetrates the bearing surface a and the bottom surface b, corresponds to the workpiece 100, and is used for collecting machining waste. One end of the second through hole 220 is located on the sidewall of the first through hole 210 and is communicated with the first through hole 210.

The negative pressure device 400 is communicated with the other end of the second through hole 220 to generate negative pressure to absorb dust falling from the carrying surface a into the first through hole 210.

Treat the product of punching and add man-hour, can place the position of waiting to punch the product in first through-hole 210 top to wait to punch the produced waste material of product and can drop to first through-hole 210 in the in-process, avoid the waste material to pile up at loading end a. After the processing waste falls into the first through hole 210, dust in a part of the processing waste may adhere to the sidewall of the first through hole 210, so that the aperture of the first through hole 210 is narrowed. Thereby making it difficult for some of the large-sized processing waste to pass through the first through-hole 210, resulting in clogging of the first through-hole 210.

The second through hole 220 is disposed on a side wall of the first through hole 210, and one end of the second through hole 220 is communicated with the first through hole 210, and the other end is communicated with the negative pressure device 400. The negative pressure means 400 can reduce the pressure of the gas in the second through-hole 220 such that the pressure of the gas in the second through-hole 220 has a certain pressure difference with the pressure of the gas in the first through-hole 210, so that the dust falling into the first through-hole 210 can be adsorbed into the second through-hole 220 while being located near the second through-hole 220. The second through holes 220 can effectively prevent the dust from adhering to the first through holes 210, and prevent the first through holes 210 from being blocked. Therefore, the processing waste can be removed in time, and the accumulation of the processing waste is reduced.

In addition, since the negative pressure device 400 can promote the gas flow, the negative pressure device 400 accelerates the gas flow speed in the product processing area above the first through hole 210 through the second through hole 220 and the first through hole 210 which are communicated with each other. Therefore, heat generated by processing equipment during punching can be taken away, and the product is prevented from being damaged due to overhigh temperature of a punching area.

Please refer to fig. 3 for the structure of the first via 210. In an embodiment, the first through hole 210 includes a first section 211 and a second section 212, wherein the first section 211 is closer to the bearing surface a than the second section 212, and an aperture of the second section 212 is greater than or equal to that of the first section 211. The first section 211 of the first through hole 210 communicates with the carrying surface a, the aperture of the first section 211 needs to be similar to that of the hole of the product, and the aperture of the first section 211 needs to be larger than that of the hole of the product. Specifically, the difference between the aperture of the first through hole 210 on the bearing surface a and the aperture of the hole on the product needs to satisfy a predetermined condition. For example, when the workpiece is a laser emitting device, the predetermined condition may be 0 to 4 mm. If the difference between the aperture of the first through hole 210 on the bearing surface a and the aperture of the hole on the product is greater than the predetermined condition, the focus of the laser emitting device may shift, so that the processing equipment may not work normally. By configuring the first through hole 210 such that the second section 212 has a larger aperture than the first section 211, the first through hole 210 can have a larger space for the waste to pass through, thereby preventing the first through hole 210 from being clogged.

The number of the first through holes 210 may be one or more. The number of the first through holes 210 may be determined according to the requirements of the product to be processed. The end of the first through hole 210 located at the bottom surface b may also be connected with the negative pressure device 400 or the dust collecting device. In one embodiment, the negative pressure device 400 is further communicated with one end of the first through hole 210 at the bottom surface b. The negative pressure device 400 can also provide negative pressure to the first through hole 210 at the same time, so that dust falling from the product can be adsorbed into the first through hole 210, and the dust is prevented from drifting to other areas of the bearing table 200 to cause dust accumulation. The negative pressure means 400 can further reduce dust accumulated on the sidewall surface of the first through-hole 210.

Further, the processing equipment 10 further includes a dust box (not shown) disposed on the bottom surface b of the loading platform 200, one side of the dust box is communicated with the first through hole 210, and the other side is communicated with the negative pressure device 400. The dust collecting box is used for collecting dust generated during punching of a product, and the dust can enter the dust collecting box through the first through hole 210 after falling into the first through hole 210. The size of the dust box may be larger than the aperture of the first through hole 210, and the dust box may not be blocked after the dust enters the dust box.

It is understood that one side of the dust collecting box can be simultaneously communicated with the first through hole 210 and the second through hole 220, and the other side is communicated with the negative pressure device 400 to collect dust generated when the product is punched.

Please refer to fig. 3 for the structure of the second via 220. In one embodiment, the second through hole 220 is located on a side of the sidewall of the first through hole 210 of the susceptor 200 close to the bearing surface a. Therefore, dust is adsorbed by the second through hole 220 after falling into the first through hole 210, thereby effectively reducing the accumulation of dust on the side wall of the first through hole 210 and further preventing the first through hole 210 from being blocked by waste dust. And even under the condition that a section of the first through hole 210 close to the bottom surface b is blocked, the second through hole 220 can still adsorb the falling dust, and the dust is prevented from being accumulated on the bearing surface a.

The number of the second through holes 220 is at least two. In an embodiment, the number of the second through holes 220 is two, and the two second through holes are respectively disposed on two opposite sides of the sidewall of the first through hole 210. By providing the two second through holes 220, dust falling into the first through holes 210 can be more effectively adsorbed. The two second through holes 220 are respectively disposed at two opposite sides of the sidewall of the first through hole 210, so that it can be avoided that part of dust far away from the second through hole 220 cannot be adsorbed into the second through hole 220.

The first through hole 210 and the second through hole 220 are connected to the negative pressure device 400. The negative pressure device 400 may be one, and is respectively connected to the first through hole 210 and the second through hole 220 through a pipe, and may simultaneously provide negative pressure to the first through hole 210 and the second through hole 220. Alternatively, the negative pressure device 400 may be a plurality of negative pressure devices, which are respectively connected to the first through hole 210 and the second through hole 220, and respectively provide negative pressure to the first through hole 210 and the second through hole 220. The negative pressure device 400 may be any suitable device capable of generating negative pressure. In one embodiment, the negative pressure device 400 may be a vacuum pump.

In an embodiment, the processing apparatus 10 may further include a control device coupled to the negative pressure device 400 for controlling the negative pressure device 400 to provide the negative pressure. In particular, the control device may comprise a controller for generating a control signal to control the opening or closing of the control valve, and a control valve. The control valve is used for controlling the negative pressure device 400 to provide negative pressure for the first through hole 210 and/or the second through hole 220. The control means may control the negative pressure means 400 to be activated when the processing apparatus starts to punch, to supply the negative pressure, and control the negative pressure means 400 to stop supplying the negative pressure after the processing apparatus finishes punching. The control device can enable the negative pressure device not to be in the starting state all the time, so that energy can be saved.

Referring to fig. 4, fig. 4 is a schematic structural diagram of a processing apparatus according to another embodiment of the present application. The processing apparatus 10 may further include a driving device 500, and the driving device 500 may be connected to the workpiece 100 for driving the workpiece 100 to move. The workpiece 100 can move relative to the bearing table 200 under the driving of the driving device 500 to meet the punching requirements of different positions of different products. The workpiece 100 can be moved relative to the carrier 200 to facilitate placement and removal of the product to be processed.

The processing tool 10 of the present application may also include other devices capable of removing processing waste, as described in more detail below.

In an embodiment, the processing apparatus 10 further includes an air injection device 600, and the air injection device 600 is located on a side of the carrying surface a away from the bottom surface b and is used for injecting air from the carrying surface a to the first through hole 210. The air injection device 600 injects air into the first through hole 210 to blow away the processing waste retained in the first through hole 210 from the first through hole 210, so that the first through hole 210 is prevented from being blocked, and the processing waste is removed in time.

Referring to fig. 5, fig. 5 is a schematic structural diagram of an air injection device 600 according to an embodiment of the present disclosure. In one embodiment, the gas injection device 600 includes: an air nozzle 610 and a gas delivery structure 620. Specifically, the air nozzle 610 faces the first through hole 210; gas delivery structure 620 is coupled to gas nozzle 610 for delivering gas to the inlet of gas nozzle 610 for ejection from the outlet of gas nozzle 610. The gas injection direction can be accurately controlled by using the structure of the gas injection nozzle 610, and gas is injected into the first through hole 210 to remove waste materials. The gas nozzle 610 may be positioned directly above the first through hole 210 so that the gas ejected from the gas nozzle 610 may enter the first through hole 210. Gas delivery structure 620 may be any suitable device capable of driving a gas in motion. In one embodiment, the gas delivery structure 620 may include a gas source and a gas delivery conduit connecting the inlet of the gas nozzle 610 and the gas source, the gas source outputting gas to be delivered to the inlet of the gas nozzle 610 via the gas delivery conduit.

The gas injection device 600 may be configured to be movable relative to the susceptor 200. In an embodiment, the driving device 500 may be connected to the gas injection device 600 for driving the gas injection device 600 to move. The driving device 500 may drive the air injection device 600 to move above the first through hole 210 and close to the first through hole 210 after the punching process is completed, so as to inject air into the first through hole 210 to remove the processing waste remaining in the first through hole 210. In addition, the driving device 500 can also drive the air injection device 600 away from the upper side of the first through hole 210 when the processing apparatus 10 is about to start processing, so as to facilitate the work of the workpiece 100.

The specific connection of the driving device 500 and the air injection device 600 is shown in fig. 5. In one embodiment, the processing tool 10 further comprises a fixing plate 800 connected to the driving device 500 and connected to the gas injection device 600. Specifically, one end of the fixing plate 800 is connected to the air injection device 600, and the other end is fixedly connected to the driving device 500. The fixed plate 800 is fixedly connected with the air nozzle 610 of the air injection device 600, and the inlet of the air nozzle 610 is arranged on the fixed plate 800.

Further, the position of the fixing plate 800 connected to the driving device 500 is adjustable. Specifically, one end of the fixing plate 800 connected to the driving device 500 is provided with a kidney-shaped hole 810, and the driving device 500 is provided with a plurality of corresponding fixing components (not shown in the figure), which can be inserted into the kidney-shaped hole 810 to fix the fixing plate 800. Wherein the position of the fixing member in the kidney-shaped hole 810 is adjustable. The fixing component can be a bolt component or a buckle component and the like. The position of the fixing plate 800 and the driving device 500 is adjustable, so that the relative position of the air injection device 600 and the driving device 500 can be adjusted, and the punching requirements of different positions of different products can be met. For example, for some edge regions where the driving device 500 cannot move, the relative positions of the air injection device 600 and the driving device 500 can be adjusted through the waist-shaped holes 810 on the fixing plate 800, so that the position of the air injection device 600 can be further adjusted in the edge regions.

With continued reference to fig. 4, the processing apparatus 10 further includes a suction cup structure 700 for sucking the product to be punched to move on the carrier 200. The suction cup structure 700 may be connected to a driving device 500, and the suction cup structure 700 may be driven by the driving device 500 to move relative to the carrier stage 200.

In summary, the processing apparatus in one embodiment specifically includes the following steps: and fixing the product to be punched on the bearing surface of the bearing table, wherein the position of the product to be punched is positioned right above the first through hole. And then, the driving device moves the workpiece to a position to be punched to start punching, and meanwhile, the control device controls the negative pressure device to be started to provide negative pressure for the first through hole and the second through hole. After the punching is finished, the workpiece is moved away by the driving device and the air injection device is moved to the position above the first through hole, and the air injection device injects air to the first through hole so as to remove the machining waste remained in the first through hole. The processing device in the embodiment of the application can remove the processing waste in time, and avoids damage to processed products and reduction of processing efficiency caused by accumulation of the processing waste.

The above embodiments are merely examples and are not intended to limit the scope of the present disclosure, and all modifications, equivalents, and flow charts using the contents of the specification and drawings of the present disclosure or those directly or indirectly applied to other related technical fields are intended to be included in the scope of the present disclosure.

Claims (10)

1. A processing apparatus, comprising:

processing a workpiece;

the bearing table is arranged below the workpiece and comprises a bearing surface and a bottom surface which are back to back; the bearing surface is used for placing a product to be punched, the bearing table is provided with a first through hole and a second through hole, and the first through hole penetrates through the bearing surface and the bottom surface, corresponds to the machined part and is used for collecting machining waste; one end of the second through hole is positioned on the side wall of the first through hole and communicated with the first through hole;

and the negative pressure device is communicated with the other end of the second through hole and generates negative pressure to adsorb dust falling into the first through hole from the bearing surface.

2. The processing apparatus of claim 1, wherein the second through hole is located on a side of the first through hole sidewall of the carrier table near the bearing surface.

3. The processing apparatus according to claim 2,

the number of the second through holes is at least two;

preferably, the number of the second through holes is two, and the two second through holes are respectively arranged on two opposite sides of the side wall of the first through hole.

4. The machining apparatus of claim 1, wherein the first through hole includes a first section and a second section, wherein the first section is closer to the load-supporting surface than the second section, and wherein the second section has an aperture that is greater than or equal to the aperture of the first section.

5. The processing equipment according to claim 1, wherein the negative pressure device is also communicated with one end of the first through hole, which is positioned on the bottom surface;

preferably, the processing equipment further comprises a dust collection box arranged on the bottom surface of the bearing table, one side of the dust collection box is communicated with the first through hole, and the other side of the dust collection box is communicated with the negative pressure device.

6. The processing apparatus as set forth in claim 1, further comprising:

and the air injection device is positioned on one side of the bearing surface, which is far away from the bottom surface, and is used for injecting air from the bearing surface to the first through hole.

7. The processing apparatus as set forth in claim 6, wherein the gas injection device comprises:

an air nozzle facing the first through hole;

and the gas conveying structure is connected with the gas nozzle and used for conveying gas to the inlet of the gas nozzle so that the gas is sprayed out from the outlet of the gas nozzle.

8. The processing apparatus as set forth in claim 6, further comprising:

the driving device is connected with the air injection device and used for driving the air injection device to move;

preferably, the driving device is further connected with the workpiece and used for driving the workpiece to move.

9. The processing tool of claim 8, further comprising:

the fixing plate is fixed on the driving device and is connected with the air injection device;

preferably, a kidney-shaped hole is formed in one end, connected with the driving device, of the fixing plate, the driving device is provided with a plurality of corresponding fixing components, and the fixing components can be inserted into the kidney-shaped hole to fix the fixing plate; wherein the position of the fixing component in the kidney-shaped hole is adjustable.

10. The processing apparatus as set forth in claim 1, further comprising:

and the control device is coupled with the negative pressure device and used for controlling the negative pressure device to provide negative pressure.

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