CN212127984U

CN212127984U - Vacuum glass support distribution system

Info

Publication number: CN212127984U
Application number: CN202020534300.9U
Authority: CN
Inventors: 王章生; 李金玉; 吴海燕
Original assignee: Luoyang Landglass Technology Co Ltd
Current assignee: Luoyang Landi Titanium Metal Vacuum Glass Co ltd
Priority date: 2020-04-13
Filing date: 2020-04-13
Publication date: 2020-12-11
Anticipated expiration: 2030-04-13

Abstract

The utility model discloses a vacuum glass support distribution system, which comprises a transmission section, a control system, a driving device and a separating device; the conveying section comprises a conveying rack and a conveying roller way, and a supporting beam is arranged on the conveying rack; the separation device comprises a base, a vibrator, a separation cavity assembly, a separation executive part and a material pipe; the vibrator is arranged on the separation cavity assembly, the separation cavity assembly is obliquely arranged, a groove for accommodating a single support is arranged on the upper edge of one side, close to the discharge hole, of the separation executing piece, and the accommodating groove is communicated with the discharge hole through the groove in the reciprocating movement process of the separation executing piece passing through the separation cavity assembly; the two or more separating devices are arranged on the supporting beam at intervals; the driving device is connected with the separation executing parts of the plurality of separation devices. When the cloth is put, the separating executive component reciprocates once, only one support can be taken away, and the phenomenon that a plurality of supports are put at one time can not occur.

Description

Vacuum glass support distribution system

Technical Field

The utility model relates to a vacuum glass's preparation equipment field specifically is a system is put to vacuum glass support cloth.

Background

In the process of manufacturing vacuum glass, because two pieces of glass are in a vacuum state, a support needs to be arranged in a vacuum layer to bear the external atmospheric pressure, the particle size range of a middle support is between 0.1mm and 0.5mm, the existing separation method is to sort particles by a spiral vibration disc, send the particles into a material receiving pipe one by one through intermittent air flow on and off of compressed air and distribute the particles on the surface of the glass; in the process of separation, the intensity of air current can influence the degree of accuracy of separation, causes and to appear unnecessary particulate matter phenomenon at the glass surface, need examine the support quantity on glass surface after laying, and unnecessary support need be clear away, mends once more and puts, increases the inspection cost, and the production beat extension, production efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a vacuum glass support distribution system which has novel and unique structure and convenient use and can realize the single-particle separation of the support; the specific technical scheme is as follows:

a vacuum glass support distribution system comprises a transmission section, a control system, a driving device and a separation device; the conveying section comprises a conveying rack and a conveying roller way arranged on the conveying rack, and a supporting cross beam is arranged on the conveying rack; the separation device comprises a base, a vibrator, a separation cavity assembly, a separation executive part and a material pipe; the base of the separating device is arranged on the supporting cross beam, the separating device is sequentially provided with a separating cavity assembly, a separating executing part and a material pipe from top to bottom, the vibrator is arranged on the separating cavity assembly, the separating cavity assembly is provided with a feed inlet, an accommodating groove and a discharge outlet, the feed inlet is communicated with the accommodating groove, the discharge outlet is communicated with the material pipe, the separating cavity assembly is obliquely arranged with a horizontal plane, the separating executing part penetrates through the separating cavity assembly and is arranged at the lower part of the accommodating groove in a reciprocating mode, a groove for accommodating a single supporting object is arranged on the side, close to the discharge outlet, of the separating executing part along the upper edge, and the accommodating groove is communicated with the discharge outlet through; the two or more separating devices are arranged on the supporting beam at intervals; the driving device is connected with the separation executing parts of the plurality of separation devices.

Furthermore, the driving devices are multiple, and at least one driving device is connected with the separation executing parts of the separation devices.

The glass conveying device further comprises a movement control mechanism, wherein the movement control mechanism is arranged on the rack and used for controlling the supporting cross beam to move along the glass conveying direction and/or perpendicular to the glass conveying direction.

The separation device further comprises a hopper and a limiting baffle, the separation cavity assembly is arranged on a bottom plate inclined to the horizontal plane through the limiting baffle, the separation cavity assembly comprises an upper separation cavity plate and a lower separation cavity plate which are arranged in parallel, the upper separation cavity plate is provided with the feed inlet, and the lower separation cavity plate is provided with the discharge outlet; the containing groove is a convex-shaped containing groove and is arranged on the end surface of the upper separation cavity plate far away from the hopper and/or the end surface of the lower separation cavity plate close to the hopper; the feed inlet is communicated with the hopper through a protruding part at the upper end of the convex accommodating groove of the feed inlet, the discharge outlet is communicated with the groove of the separation executive part through the lower part of the convex accommodating groove, and the separation executive part moves back and forth along the lower part of the convex accommodating groove.

Further, the thickness of the convex accommodating groove is d, and the thickness of the support is d₁The maximum distance between any two points on the cross section of the support is d₂Then d is₁<d<d₂And d is<2d₁。

Further, the height of the groove of the separation executive component is h, the width of the groove of the separation executive component is w, and the maximum distance between any two points on the cross section of the support is d₂Then d is₂<h,d₂<w, and d₂The difference from h is in the range of 0.01mm to 0.5mm, d₂The difference from w is in the range of 0.01mm-0.5 mm.

Further, the separation performing member is plate-shaped or rod-shaped.

Further, the separation chamber subassembly is 5 to 75 with the contained angle of horizontal plane.

Further, the angle between the separation chamber assembly and the horizontal plane is preferably 25 ° to 75 °.

Further, a gap is reserved between the limiting baffle and the separation cavity assembly.

Furthermore, the separation chamber component is made of wear-resistant and non-magnetic materials, and an observation window is arranged on the upper separation chamber plate and used for observing the state of the support in the accommodating groove and the condition that the support is conveyed by the separation executive part.

Further, the material pipe is a transparent pipe, and a sensor is arranged on the pipe wall of the material pipe.

Further, the sensor is an optical fiber sensor.

The optical fiber sensor is characterized by further comprising a leakage repairing device, wherein the leakage repairing device comprises a leakage repairing movement control mechanism, a leakage repairing driving device and a leakage repairing separation device, the leakage repairing separation device is arranged on the supporting cross beam, and when the optical fiber sensor cannot detect that a support passes through, the leakage repairing device is used for supplementing the support leaked by the separation device.

The utility model discloses when the system is put to vacuum glass support cloth, separation executive component reciprocating motion once can only take away a support, can not appear once laying the phenomenon of a plurality of supports.

Drawings

FIG. 1 is a front view of a schematic configuration of a vacuum glass support placement system;

FIG. 2 is a left side view of the vacuum glass support placement system;

FIG. 3 is a schematic top view of the vacuum glass support placement system;

FIG. 4 is a schematic structural view of a blanking assembly;

FIG. 5 is a partial enlarged view of FIG. 4B;

FIG. 6 is a schematic view of the separation apparatus;

FIG. 7 is a cross-sectional view A-A of FIG. 6;

FIG. 8 is a schematic view of the separation principle of the separation device;

FIG. 9 (a) is a schematic view showing a slope on one side of the protrusion at the upper end of the convex-shaped receiving groove;

FIG. 9 (b) is a schematic view showing the arrangement of the two sides of the protrusion at the upper end of the convex-shaped receiving groove as slopes;

FIG. 10 is an enlarged view of a portion of FIG. 7C;

FIG. 11 is a schematic view of the connection structure of the driving device and the separating device;

FIG. 12 is a schematic side view of the support;

FIG. 13 (a) is a schematic view of a quadrilateral cross-section of the support; FIG. 13 (b) is a schematic view of a cross-section of a support being pentagonal; FIG. 13 (c) is a schematic view of a cross-section of a support being hexagonal; FIG. 13 (d) is a schematic view of a support with a circular cross-section;

FIG. 14 is a front view of the split actuator;

FIG. 15 is a side view of a breakaway actuator.

In the figure: 1. a base; 2. A cylinder fixing plate; 3. a cylinder; 4. A separator plate connecting plate; 5. A separation plate; 51. separating the grooves; 6. A hopper; 7. a separation chamber assembly; 71. an upper separation chamber plate; 72. a lower separation chamber plate; 8. a material pipe; 9. an optical fiber sensor; 10. a material pipe clamp; 11. a vibrator; 12. a support; 13. a limit baffle; 131. an upper baffle plate; 132. a lower baffle plate; 14. a base plate;

s1, a transmission segment; s11, conveying the rack; s12, power transmission; s13, conveying a roller way; s2, glass; s3, transversely moving the bracket; s4, a transverse movement control mechanism; s5, supporting a beam; s6, a separation device; s7, a material pipe lifting mechanism; s71, a blanking assembly; s711, a material pipe; s712, a guide sleeve; s713, compressing the spring; s714, a transition joint; s72, a guide assembly; s73, lifting power; s74, fixing plates; and S8, a leakage repairing device.

Detailed Description

The present invention will be more fully described with reference to the following examples. The present invention may be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein.

Spatially relative terms, such as "upper," "lower," "left," "right," and the like, may be used herein for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. It will be understood that the spatial terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "below" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "lower" can encompass both an upper and a lower orientation. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

The glass conveying direction is set to be longitudinal, and the direction perpendicular to the glass conveying direction is set to be transverse.

As shown in fig. 1 to 3, the vacuum glass support placing system in the present embodiment includes a conveying section S1, a control system (not shown), a cylinder 3, and a separating device S6. The transport section S1 includes a transport rack S11 and a transport table S13 on the transport rack S11. The transmission power S12 provides driving force for the transmission roller way S13; generally, the motor drives the conveying roller way S13 through a belt or a chain wheel after passing through a speed reducer, and when a servo motor is adopted, the speed reducer can be omitted. The control system is a PLC control system and is positioned in an electric control cabinet of the vacuum glass production line, and the PLC control system is electrically connected with a transmission power S12 device, the cylinder 3 and the separating device S6 of the transmission roller way S13 and controls the rotation of the transmission roller way S13 and the separation and arrangement of the supports 12. The glass S2 is placed on the conveying roller way S13 and can move back and forth along the conveying roller way S13. The top surface of the transmission rack S11, the left side and the right side of the transmission roller way S13 are respectively provided with a transverse moving support S3, and a supporting beam S5 is erected on the transverse moving support S3. The separating devices S6 are arranged on the supporting beam S5 through the base 1, the number of the separating devices S6 is two or more, and the number of the separating devices S6 is six in the embodiment; the separating devices S6 are arranged on the supporting beam S5 at intervals in a line shape, or arranged on the supporting beam S5 at intervals in an array shape, in this embodiment, as shown in fig. 2, the separating devices S6 are arranged on the supporting beam S5 at intervals in a line shape; the connection structure of the cylinders 3 and the separating devices S6 is shown in fig. 11, the number of the cylinders 3 may be one or more, but at least one cylinder 3 is connected with the separating plates 5 of a plurality of separating devices S6, in this embodiment, the number of the cylinders 3 is two, each cylinder 3 is connected with the separating plates 5 of three separating devices S6, the cylinder body of the cylinder 3 is fixed on the supporting beam S5 through the cylinder fixing plate 2, the piston rod is connected with the separating plate 5 of each separating device S6 through the separating plate connecting plate 4, and one end of the supporting beam S5 is further provided with a transverse movement control mechanism S4; so that the separating apparatus S6 can be traversed along the supporting beam S5. The traverse support S3 is horizontally disposed. In the figure, the traverse support S3 is disposed perpendicular to the moving direction of the glass S2; the glass sheet may be inclined at an angle of 45 degrees, 30 degrees or the like with respect to the moving direction of the glass sheet S2.

In order to arrange the supports 12, the system is also provided with a material pipe lifting mechanism S7; when the cloth is placed, the blanking assembly S71 descends, the separating device S6 separates the support 12, and the support 12 falls from the material pipe 8; the blanked assembly S71 rests on the surface of the glass S2. Then, the blanking assembly S71 is lifted to avoid the support 12 colliding with the lower end of the blanking assembly S71 when the glass S2 moves forwards; after the blanking assembly S71 rises to the right position, the conveying roller way S13 rotates to drive the glass S2 to move forward to reach a stepping distance, and the support 12 is placed again; forming an array of supports on the surface of the glass S2; in the utility model discloses an in other embodiments, also can glass keep motionless, movement control mechanism includes lateral shifting control mechanism S4 and longitudinal movement control mechanism, wherein the longitudinal movement control mechanism control supporting beam S5' S vertical step-by-step removal, longitudinal movement control mechanism is connected with PLC control system electricity, blanking subassembly S71 rises the back that targets in place, longitudinal movement control mechanism drives supporting beam S5 and reaches a step-by-step distance, lay supporter 12 once more, form the supporter array on glass S2 surface.

As shown in fig. 4, the blanking assembly S71 includes a material tube S711, a guide sleeve S712, a compression spring S713, and a transition joint S714. The material pipe 8 of the separating device S6 is inserted into the material hole through hole in the center of the material pipe S711, and a gap is formed between the outer wall of the material pipe 8 and the inner wall of the material hole through hole. The upper end of the material pipe S711 is provided with a step surface; the outer diameter of the upper end of the step surface is large, and the outer diameter of the lower end of the step surface is small. The guide sleeve S712 is sleeved on the small end of the material pipe S711, and a compression spring S713 and a transition joint S714 are arranged downwards in sequence. The transition joint S714 is fixed at the lower end of the material pipe S711 through threads, bayonets or pins; the guide sleeve S712 and the transition joint S714 hold the compression spring S713 in a compressed state. The guide sleeve S712 is fixed on the fixing plate S74; when the fixing plate S74 descends, the compression spring S713 pushes the transition joint S714, ensuring that the lower end surface of the transition joint S714 is in close contact with the surface of the glass S2. When the fixing plate S74 rises, the guide sleeve S712 drives the material tube S711 to rise through the step surface.

The supporting beam S5 is also provided with a material pipe lifting mechanism S7. The material pipe lifting mechanism S7 comprises a guide assembly S72, a lifting power S73 and a fixing plate S74. The guide assembly S72 is composed of a guide sleeve and a guide rod. The lifting power S73 adopts an electric cylinder or an air cylinder. The fixing plate S74 is driven by the lifting power S73 to move up and down.

As shown in fig. 5, the inner cavity of the transition joint S714 is provided with an inverted conical transition section, and the bottom of the inner cavity of the transition joint S714 is flared, so as to ensure that the support 12 is accurately positioned at the falling point on the glass S2 after being arranged by the transition section, and prevent the support from rebounding and running or bouncing off the glass S2.

The shape of the support 12 can be a round cake shape or a cross section of a polygonal cake shape (as shown in fig. 12 and 13), and here, a round cake-shaped object with a cross section diameter of 0.5mm-0.9mm and a thickness of 0.2mm-0.4mm is taken as an example for illustration. As shown in fig. 6 and 7, the vacuum glass support separation device S6 in the present embodiment includes a base 1, a hopper 6, a vibrator 11, a separation chamber assembly 7, a limit baffle 13, a separation plate 5, and a material pipe 8; the base 1 is arranged on a supporting beam S5, and the separating device S6 is sequentially provided with a hopper 6, a separating cavity assembly 7, a separating plate 5 and a material pipe 8 from top to bottom; in order to avoid clogging of the support, the separation chamber assembly 7 is provided with a vibrator 11; the vibrator 11 generates vibration to drive the separation cavity assembly 7 to vibrate, the separation cavity assembly 7 is made of wear-resistant and non-magnetic materials, the fluidity of support particles is improved through vibration, and the supports 12 are guaranteed to be distributed in a loose state; the separation cavity assembly 7 comprises an upper separation cavity plate 71 and a lower separation cavity plate 72 which are arranged in parallel, wherein an observation window is arranged on the upper separation cavity plate 71 to observe the state of the supports in the convex-shaped containing grooves and the condition that the supports are conveyed by the separation plates 5. The separation chamber assembly 7 is arranged on a floor 14 inclined to the horizontal, the separation chamberA limit baffle 13 is arranged outside the assembly 7, and a gap is reserved between the limit baffle 13 and the separation cavity assembly 7 to ensure that the separation cavity assembly 7 can vibrate; the upper separation cavity plate 71 is provided with a feed inlet communicated with the hopper 6, and the lower separation cavity plate 72 is provided with a discharge outlet communicated with the material pipe 8; the end surface of the upper separation cavity plate 71 far away from the hopper 6 and/or the end surface of the lower separation cavity plate 72 near the hopper 6 are/is provided with a convex-shaped accommodating groove; the separating plate 5 is movably arranged at the lower part of the convex-shaped containing groove, is connected with the cylinder 3 and is driven by the cylinder 3 to reciprocate along the lower part of the containing groove; the convex part at the upper end of the convex accommodating groove is communicated with the hopper 6 through the feeding hole; the separation plate 5 is provided with a separation groove 51 for accommodating a single supporter along one side adjacent to the protrusion of the upper end of the "convex" shaped accommodation groove. The direction of reciprocation on the plane of the separating plate 5 is defined as the width direction, the direction perpendicular to the direction of reciprocation as the height direction, and the direction perpendicular to the plane of the separating plate 5 as the thickness direction. The separating plate 5 is in clearance fit with the lower part of the convex-shaped containing groove, and the clearance is smaller than the thickness d of the support 12₁Preventing the supporter 12 from coming out of the upper end protrusion of the "convex" shaped receiving groove from the gap during the reciprocating motion of the separation plate 5; the thickness d of the convex-shaped accommodating groove is larger than that of the support 12₁And the thickness d of the convex-shaped accommodating groove is smaller than the cross-sectional diameter d of the support 12₂To ensure that the supports 12 are arranged only in a manner that the bottom surface falls on the lower separation cavity plate 72 under the vibration action of the separation cavity assembly which is arranged obliquely to the horizontal plane; the thickness d of the convex accommodating groove is less than the thickness d of the support 12₁Twice, the double-layer arrangement of the supports in the convex-shaped containing groove is avoided; the width w of the separation groove 51 is smaller than the width w of the separation plate 5₁(ii) a Thickness d of the separating plate 5₃Greater than the thickness d of the support 12₁(ii) a The height h of the separation grooves 51 is greater than the cross-sectional diameter d of the support 12₂The difference between the two is 0.1mm-0.2mm, the width w of the separation groove 51 is larger than the cross-sectional diameter d of the support 12₂And the difference between the two is 0.1mm-0.2mm, the support 12 can be ensured to smoothly enter the separation groove 51, and the separation groove 51 can only accommodate a single support.

An upper baffle plate 131 and a lower baffle plate 132 are arranged outside the separation cavity assembly 7; the upper separation chamber plate 71, the lower separation chamber plate 72, and the bottom plate 14 are assembled together by an upper baffle 131 and a lower baffle 132 of an L-shape. The bottom plate 14 is fixed on the base 1 obliquely to the horizontal plane.

The separation plate 5 is reciprocated over a distance such that the separation grooves 51 receive the supports 12 from the "male" receiving slots and convey the supports 12 into the discharge opening of the connecting channel of the lower separation chamber plate 72 to the feed pipe 8.

As shown in fig. 9, two sides or one side of the convex part at the upper end of the convex-shaped containing groove can be set to be slope surfaces, and the slope surfaces are communicated with the separating plate 5 through a channel at the slope bottom, so that the advancing resistance of the separating plate when carrying the support 12 is further reduced.

The plate-shaped separation actuator in the figure is not limited to the one shown in the figure, and may be a rod-shaped separation actuator. When a round bar is used, the end portion should be treated, such as punched, to ensure that the groove is on the top surface during installation.

As shown in fig. 8, a separation groove 51 for accommodating a single supporter may be further provided at a lower edge of a side of the separation performing member away from the protrusion of the upper end of the "convex" shaped accommodation groove; when the separating plate 5 is worn by the groove at one side of the convex part at the upper end of the convex-shaped accommodating groove, the separating plate is turned over for use, and the service life of the separating executive component is prolonged.

In order to find out the separation fault in time, the material pipe 8 is made into a transparent pipe by adopting glass or other transparent materials, and a sensor is arranged on the pipe wall of the material pipe 8 to detect whether a support falls down. The sensor is fixed on the material pipe 8 through a material pipe clamp 10.

The sensor adopts the optical fiber sensor 9, and the detection sensitivity is higher.

The leakage repairing device comprises a leakage repairing movement control mechanism, a leakage repairing driving device and a leakage repairing separation device; the leakage-repairing movement control mechanism is electrically connected with the PLC control system and is used for controlling the leakage-repairing separation device to move longitudinally and/or transversely; the leakage-repairing separation device is arranged on the supporting cross beam, has the structure consistent with that of the separation device S6 and is used for supplementing the support 12 leaked by the separation device S6; in this embodiment, when the optical fiber sensor 9 cannot detect that a support passes through, the PLC control system may record position information of the missed support, transmit the position information to a transmission power and a missed support movement control mechanism of the transmission section, rotate a transmission roller table S13 to drive a glass S2 to move forward and stop below a supporting beam where the missed support separation device is located, the missed support movement control mechanism controls the missed support separation device to move laterally and stop below the missed support separation device, start the missed support driving device, and complete the missed support replacement at the position by once or multiple times of the missed support placement until the optical fiber sensor 9 detects that the support passes through.

The included angle between the bottom plate 14 and the horizontal plane is 25-75 degrees; the support particles can move by means of gravity; and excessive extrusion of gravity on the support is reduced, so that the support pile is easy to loosen, and smooth flow of support particles is ensured.

The inner diameter of the material pipe 8 is larger than the diameter of the support 12, and the difference between the inner diameter and the diameter is 0.1mm-0.2mm, so that the support 12 can smoothly pass through the material pipe.

In the embodiment, the cylinder 3 is adopted to push the separating plate 5 to reciprocate; the electric cylinder can also be used for driving; or a stepping motor is adopted to drive the crank connecting rod mechanism to push the separating plate 5 to reciprocate.

During operation, the blanking assembly S71 descends, and the demagnetized supports 12 are placed into the hoppers 6 at the tops of the separating devices S6; starting the vibrator, wherein the supporters 12 are arranged in a loose single layer mode according to the sequence of entering the convex containing grooves; starting the cylinder 3, pushing out the separating plate 5 of each separating device S6, enabling the support 12 to fall into the separating groove 51 at one end of the separating plate 5 close to the protruding part at the upper end of the convex-shaped containing groove under the action of the vibrator, enabling the separating plate 5 to move rightwards, conveying the support 12 in the separating groove 51 to the discharge port, stopping driving the cylinder 3, and enabling the support 12 to penetrate through the bottom plate 14 from the discharge port to enter the material pipe 8; the support 12 is discharged from the bottom end of the tube 8, passes through the blanking assembly S71, and falls on the glass surface. The cylinder 3 is reversely driven and the separating plate 5 of each separating means S6 is retracted so that the separating groove 51 is brought into the protrusion of the upper end of the "convex" shaped receiving groove.

Has the advantages that:

1. the convex accommodating groove forms a certain included angle with the horizontal direction, so that the support can automatically form a single-layer sequencing state during feeding;

2. through vibration, a gap appears in the support in the separation process, the support can easily, quickly and accurately enter the groove of the separation plate, and the success rate of the support separation is improved;

3. the thickness of the support is smaller than that of the separating plate, and a small gap is formed between the support and the convex accommodating groove in the separating process, so that the support is not easy to wear;

4. when the cloth is put, the separating plate reciprocates once, only one support can be taken away, and the phenomenon that a plurality of supports are put at one time can not occur;

5. one driving device is simultaneously connected with the separation executing parts of the plurality of separation devices, so that the cost of the laying system is reduced, and the laying efficiency of the supports is improved.

6. When the support is leaked, the leakage repairing device supplements the support leaked by the separating device until the optical fiber detects that the support falls down, so that the support is ensured to be distributed without leakage.

The above examples are only for illustrating the present invention, and besides, there are many different embodiments, which can be conceived by those skilled in the art after understanding the idea of the present invention, and therefore they are not listed here.

Claims

1. A vacuum glass support distribution system is characterized by comprising a transmission section, a control system, a driving device and a separation device; the conveying section comprises a conveying rack and a conveying roller way arranged on the conveying rack, and a supporting cross beam is arranged on the conveying rack; the separation device comprises a base, a vibrator, a separation cavity assembly, a separation executive part and a material pipe; the base of the separating device is arranged on the supporting cross beam, the separating device is sequentially provided with a separating cavity assembly, a separating executing part and a material pipe from top to bottom, the vibrator is arranged on the separating cavity assembly, the separating cavity assembly is provided with a feed inlet, an accommodating groove and a discharge outlet, the feed inlet is communicated with the accommodating groove, the discharge outlet is communicated with the material pipe, the separating cavity assembly is obliquely arranged with a horizontal plane, the separating executing part penetrates through the separating cavity assembly and is arranged at the lower part of the accommodating groove in a reciprocating mode, a groove for accommodating a single supporting object is arranged on the side, close to the discharge outlet, of the separating executing part along the upper edge, and the accommodating groove is communicated with the discharge outlet through; the two or more separating devices are arranged on the supporting beam at intervals; the driving device is connected with the separation executing parts of the plurality of separation devices.

2. The vacuum glass support placement system according to claim 1, wherein the driving means is a plurality of driving means, at least one driving means being connected to the separation performing members of a plurality of the separation means.

3. The vacuum glass support placement system according to claim 1, further comprising a movement control mechanism disposed on the frame for controlling the movement of the support beam along the glass conveying direction and/or perpendicular to the glass conveying direction.

4. The vacuum glass support distribution system of claim 1, wherein the separation device further comprises a hopper and a limit baffle, the separation chamber assembly is arranged on a bottom plate inclined to the horizontal plane through the limit baffle, the separation chamber assembly comprises an upper separation chamber plate and a lower separation chamber plate which are arranged in parallel, the upper separation chamber plate is provided with the feed inlet, and the lower separation chamber plate is provided with the discharge outlet; the containing groove is a convex-shaped containing groove and is arranged on the end surface of the upper separation cavity plate far away from the hopper and/or the end surface of the lower separation cavity plate close to the hopper; the feed inlet is communicated with the hopper through a protruding part at the upper end of the convex accommodating groove of the feed inlet, the discharge outlet is communicated with the groove of the separation executive part through the lower part of the convex accommodating groove, and the separation executive part moves back and forth along the lower part of the convex accommodating groove.

5. The vacuum glass support distribution system of claim 4, wherein the thickness of said "convex" receiving slot is setD, the thickness of the support is d₁The maximum distance between any two points on the cross section of the support is d₂Then d is₁<d<d₂And d is<2d₁。

6. The vacuum glass support laying system of claim 1, wherein let the separation actuator groove height be h, the separation actuator groove width be w, and the maximum distance between any two points on the support cross-section be d₂Then d is₂<h,d₂<w, and d₂The difference from h is in the range of 0.01mm to 0.5mm, d₂The difference from w is in the range of 0.01mm-0.5 mm.

7. The vacuum glass support distribution system of claim 1, wherein the separation actuator is plate-shaped or rod-shaped.

8. The vacuum glass support distribution system of claim 1, wherein the separation chamber assembly is angled from 5 ° to 75 ° from horizontal.

9. The vacuum glass support distribution system of claim 8, wherein the separation chamber assembly is preferably angled from 25 ° to 75 ° from horizontal.

10. The vacuum glass support distribution system of claim 4, wherein a gap is left between the limiting baffle and the separation chamber assembly.

11. The vacuum glass support distribution system of claim 4, wherein the separation chamber assembly is made of a wear-resistant and non-magnetic material, and the upper separation chamber plate is provided with an observation window for observing the state of the support in the receiving groove and the condition of the support transported by the separation actuator.

12. The vacuum glass support placement system according to claim 1, wherein the tube is a transparent tube, and a sensor is disposed on a wall of the tube.

13. The vacuum glass support placement system according to claim 12, wherein the sensor is an optical fiber sensor.

14. The vacuum glass support distribution system of claim 13, further comprising a leak repairing device, wherein the leak repairing device comprises a leak repairing movement control mechanism, a leak repairing driving device and a leak repairing separating device, the leak repairing separating device is arranged on the supporting beam, and the leak repairing device is used for supplementing the support leaked by the separating device when the optical fiber sensor cannot detect that the support passes through.