Search

CN-121976738-A - Copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass and production line thereof

CN121976738ACN 121976738 ACN121976738 ACN 121976738ACN-121976738-A

Abstract

The invention discloses a copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass and a production line thereof, which relate to the technical field of hollow glass, wherein two conductive glasses are arranged at the top and the bottom of a lead-containing glass plate, a copper mesh is bonded between two adjacent conductive glasses through PVB films, the lead-containing glass plate is connected with the adjacent conductive glass through a separation strip, an assembly cavity is arranged in the middle of the separation strip, a separation frame is embedded in the assembly cavity, a plurality of micropores are formed in the top surface and the bottom surface of the separation frame, and a plurality of pressure stabilizing holes are formed in the two sides of the separation strip.

Inventors

  • ZHANG MANREN
  • YANG LICHAO
  • JIN CHENGLONG
  • XU HAIDONG

Assignees

  • 赋腾河北节能科技有限责任公司

Dates

Publication Date
20260505
Application Date
20260209

Claims (10)

  1. 1. The lead-containing radiation-proof hollow conductive glass with the copper mesh composite interlayer comprises a lead-containing glass plate (1), and is characterized in that functional glass components (2) are arranged at the top and the bottom of the lead-containing glass plate (1), and the functional glass components (2) comprise conductive glass (202); Two pieces of conductive glass (202) are arranged at the top and the bottom of the lead-containing glass plate (1), a copper mesh (204) is bonded between two adjacent pieces of conductive glass (202) through a PVB film (203), and the lead-containing glass plate (1) is connected with the adjacent pieces of conductive glass (202) through a spacer (206); An assembly cavity (207) is formed in the middle of the isolation strip (206), a separation frame (208) is embedded in the assembly cavity (207), an air passage (209) is formed in the middle of the separation frame (208), a plurality of micropores (210) are formed in the surfaces of the top surface and the bottom surface of the separation frame (208), molecular sieves (211) are filled in the cavities at the top and the bottom of the separation frame (208), an assembly groove (212) is formed in the top and the bottom of the isolation strip (206), and an energy absorption strip (213) is embedded in the assembly groove (212); Two spacer (206) one side is connected with gas-supply pipe (216), a plurality of gas-supply holes (217) have been seted up to spacer (208) one side, a plurality of steady voltage hole (218) are all seted up to spacer (206) both sides, gas-supply pipe (216) one side is linked together with air flue (209) through adjacent steady voltage hole (218), adjacent two gas-supply pipe (216) one end is connected with gas-collecting box (228).
  2. 2. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to claim 1, wherein a buffer hole (214) is formed in the bottom of the energy absorption strip (213), the energy absorption strip (213) and the adjacent conductive glass (202) are bonded through a butyl rubber sheet (215), a silicone rubber layer (219) is smeared between the lead-containing glass plate (1) and the conductive glass (202) on the outer side of the isolation strip (206), and the copper mesh (204) is positioned between the two PVB rubber sheets (203).
  3. 3. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass as claimed in claim 1, wherein the isolating strips (206) are distributed around the lead-containing glass plate (1), and four isolating strips (206) located at the same level are connected end to end in sequence.
  4. 4. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to claim 1, wherein one end of the gas collecting box (228) is connected with a branch pipe (229), one side of the supporting frame (227) is connected with a main gas pipe (231), one end of the main gas pipe (229) is connected with one side of the main gas pipe (231), one end of the main gas pipe (231) is connected with one end of an electronic barometer (232) through a gas transmission tee joint, the other end of the electronic barometer (232) is connected with one end of an electric gas valve (235) through a dual-purpose gas pump (233), the other end of the electric gas valve (235) is connected with an output end of a gas storage tank (234), the output end of the electronic barometer (232) is electrically connected with an input end of an external controller, and the input ends of the dual-purpose gas pump (233) and the electric gas valve (235) are electrically connected with an output end of the external controller.
  5. 5. The lead-containing radiation-proof hollow conductive glass with the copper mesh composite interlayer according to claim 2, wherein two sides of the outer side of the silicone adhesive layer (219) are symmetrically connected with splicing frames (222), two sides of the outer side of the silicone adhesive layer (219) are symmetrically connected with supporting frames (227), gaps between the splicing frames (222) and the silicone adhesive layer (219) are filled with rubber gaskets (220), gaps between the supporting frames (227), the rubber gaskets (220) and the conductive glass (202) are coated with sealing adhesive layers (225), and gaps between the splicing frames (222), the rubber gaskets (220) and the conductive glass (202) are coated with sealing adhesive layers (225).
  6. 6. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to claim 5, wherein copper sheets (205) are welded on two sides of the copper mesh (204), the rubber gasket (220) is provided with a wiring duct (221), the copper sheets (205) are located inside the wiring duct (221), and the conductive glass (202) and the copper sheets (205) are electrically connected with an output end of an external controller through wires.
  7. 7. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to claim 5, wherein a bottom sealing gasket (226) is embedded in a gap at one end of the spliced frame (222), and a top sealing gasket (230) is embedded in a gap at the other end of the spliced frame (222) and positioned outside the gas collecting box (228); the novel splicing device is characterized in that a plurality of thread cylinders (236) are arranged at equal intervals on two sides of the splicing frame (222), the tops of the thread cylinders (236) are fixed at one end of a connecting piece (237) through screws, sealing grooves (223) are formed in two sides of the splicing frame (222), and sealing strips (224) are movably embedded in the sealing grooves (223).
  8. 8. A production line of the copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass, which is characterized in that the production line is used for the copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to any one of claims 1 to 7, a conveyor (4) is provided with a glass production line (3), and the glass production line (3) comprises a movable guide rail (301); Two movable guide rails (301) are arranged at the bottom of the conveyor (4), fixed plates (302) are slidably arranged at two ends of each movable guide rail (301), two adjacent fixed plates (302) positioned on the same side are connected through a linkage rod (303), a fixed motor (304) is arranged at one side of the bottom of the conveyor (4), a bidirectional screw (305) is rotatably arranged between the two movable guide rails (301), the middle of each linkage rod (303) is respectively connected with two ends of the bidirectional screw (305) through threaded holes, and the output end of each fixed motor (304) is connected with one end of each bidirectional screw (305); Four lifting guide rails (306) are arranged at one end of the conveyor (4), a supporting plate (307) is connected between two adjacent lifting guide rails (306), a turnover frame (311) is arranged in the middle of the top of the supporting plate (307), a bottom conveying belt (312) is rotatably arranged in the middle of the two turnover frames (311), clamping cylinders (313) are arranged at two ends of two sides of the bottom conveying belt (312), a top conveying belt (314) is fixed between the output ends of the clamping cylinders (313), a turnover motor (315) is arranged at one side of the turnover frame (311), and the output end of the turnover motor (315) is connected with one end of a rotating shaft of the bottom conveying belt (312); the lead-containing glass plate (1) and the functional glass assembly (2) are positioned on top of the conveyor (4).
  9. 9. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass production line according to claim 8, wherein lifting blocks (308) are connected to two ends of the supporting plate (307), the lifting blocks (308) are located inside the lifting guide rail (306) and are slidably connected with the lifting guide rail (306), a lifting screw (309) is rotatably installed inside the lifting guide rail (306), the lifting screw (309) is connected with adjacent lifting blocks (308) through screw holes, a lifting motor (310) is installed at the top of the lifting guide rail (306), and the output end of the lifting motor (310) is connected with one end of the top of the lifting screw (309).
  10. 10. The production line of the copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass according to claim 9, wherein a contact surface between the fixed plate (302) and the movable guide rail (301) is a smooth surface, the top end of the fixed plate (302) penetrates through the conveyor (4), and input ends of the fixed motor (304), the lifting motor (310) and the overturning motor (315) are electrically connected with an external power output end through an external controller.

Description

Copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass and production line thereof Technical Field The invention relates to the technical field of hollow glass, in particular to a copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass and a production line thereof. Background Radiation-proof glass refers to special glass with the function of protecting radioactive rays such as x-rays, gamma rays and the like, and in recent years, with the development of fields such as radiology, atomic energy industry and the like, radiation protection problems are also receiving extensive attention, and mainly include nickel alloy wire mesh shielding, high-lead optical glass, radiation-proof organic glass added with metal elements and the like. In the Chinese patent with the application number of CN201822194020.3 and the name of hollow glass, two glass plates of the patent are respectively abutted against two side plates of an aluminum parting bead, the outer edge of the glass plate is sealed by sealant, the outer edge of the aluminum parting bead is provided with ventilation holes, the aluminum parting bead is filled with dry particles, and the inner side of the ventilation plate is fixedly provided with a strip-shaped spring, so that the ventilation holes are effectively prevented from being blocked, the contact area between the dry particles and air is improved, and the drying effect is improved; The inside gas of glass hollow layer is dried only through the bleeder vent in this patent, and the gas mobility in the glass hollow layer is poor, when glass is great, be located the fixed molecular sieve in glass four sides and be difficult to get rid of the inside moisture in hollow layer, drying effect is poor, and prior art's anti-radiation cavity electrically conductive glass electromagnetic shield effect is poor, and leaded glass board light transmissivity is poor, medical staff observes the patient condition of being inconvenient for, the result of use is poor, and current hollow glass is when the difference in temperature is great outside day and night, lead to the tired ageing of sealant easily under the stress effect that expend with heat and contract with cold produced, glass life is shorter. Disclosure of Invention The invention provides a copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass and a production line thereof, which can effectively solve the problems that the existing hollow glass in the prior art is poor in drying effect, electromagnetic shielding effect and light transmittance, inconvenient for medical staff to observe the condition of a patient, and easy to cause fatigue and aging of sealant under the action of stress generated by thermal expansion and cold contraction when the temperature difference between the day and the night of the existing hollow glass is large, and the service life of the glass is short. The copper mesh composite interlayer lead-containing radiation-proof hollow conductive glass comprises a lead-containing glass plate, wherein functional glass components are arranged at the top and the bottom of the lead-containing glass plate, and the functional glass components comprise conductive glass; Two pieces of conductive glass are arranged at the top and the bottom of the lead-containing glass plate, a copper mesh is bonded between two adjacent pieces of conductive glass through a PVB film, and the lead-containing glass plate is connected with the adjacent pieces of conductive glass through a spacer; An assembly cavity is formed in the middle of the isolation strip, a separation frame is embedded in the assembly cavity, an air passage is formed in the middle of the separation frame, a plurality of micropores are formed in the surfaces of the top surface and the bottom surface of the separation frame, molecular sieves are filled in cavities at the top and the bottom of the separation frame, assembly grooves are formed in the top and the bottom of the isolation strip, and energy absorbing strips are embedded in the assembly grooves; Two barrier ribs are connected with the gas pipe on one side, a plurality of gas transmission holes are formed in one side of the barrier ribs, a plurality of pressure stabilizing holes are formed in two sides of the barrier ribs, one side of the gas pipe is communicated with the air duct through adjacent pressure stabilizing holes, and one end of the gas pipe is connected with the gas collecting box. According to the technical scheme, the buffer holes are formed in the bottoms of the energy absorption strips, the energy absorption strips are bonded with adjacent conductive glass through the butyl rubber sheets, the outside of the isolation strip is positioned between the lead-containing glass plate and the conductive glass and coated with the silicone rubber layers, and the copper mesh is positioned between the two PVB rubber sheets. According to the tec