CN119191683A

CN119191683A - An energy-saving intermittent oxygen supply device for glass production

Info

Publication number: CN119191683A
Application number: CN202411393488.9A
Authority: CN
Inventors: 蔡园; 高杨; 陆安庆; 丁冉
Original assignee: Anhui Xinmin Glass Co ltd
Current assignee: Anhui Xinmin Glass Co ltd
Priority date: 2024-10-08
Filing date: 2024-10-08
Publication date: 2024-12-27

Abstract

The invention discloses an intermittent oxygen supply device for energy-saving glass production, which comprises a frame, a bearing die rotating along a rotating seat, a closing component for closing the bearing die, an oxygen supply mechanism for supplying oxygen to the bearing die, a transmission component, a supporting disk, a linkage component and an intermittent oxygen supply mechanism, wherein the bottom end of the frame is provided with the closing component for closing the bearing die, the transmission component is in transmission connection with the supporting disk fixedly connected with the bottom end of the rotating seat, the transmission component is in transmission connection with the linkage component, the linkage component is respectively in transmission connection with the closing component and the oxygen supply mechanism, the supporting disk fixedly connected with the bottom end of the rotating seat is transmitted to the linkage component through the transmission component, and the linkage component drives the closing component and the oxygen supply component to intermittently clamp and close the bearing die and intermittently supply oxygen to ensure that molten materials which are processed in the bearing die are in a molten state, and the quality of glass product molding is prevented from being influenced by impurities generated in a cooling process.

Description

Intermittent oxygen supply device for energy-saving glass production

Technical Field

The invention relates to the technical field of glass production, in particular to an intermittent oxygen supply device for energy-saving glass production.

Background

Because the high borosilicate glass has good fire resistance and high physical strength, compared with common glass, the high borosilicate glass has no toxic or side effect, and the heat resistance is greatly improved, most of the current cutlery boxes and articles for daily use are manufactured by using the high borosilicate glass, the production process of the high borosilicate glass mainly comprises the steps of proportioning raw materials, melting and forming, heat treatment and finish machining, wherein the heat treatment is to anneal or heat treat a glass blank so as to eliminate internal stress and crystal defects, improve the mechanical property and optical property of the glass, and the finish machining is to cut, polish and the like the heat treated glass blank so as to meet the requirements of the required size and surface quality.

The prior art has the defects that when the formed blank (molten material) is subjected to subsequent treatment on a production line, in order to avoid the temperature loss caused by accumulation of the blank (molten material) on a certain station, the molten material in a bearing die is often required to be subjected to oxygen supply to keep the blank state, but the bearing die is required to be clamped and fastened and then is required to be supplied with oxygen to an inner cavity, so that the oxygen supply and the closed clamping are required to be operated in a single control device and a sequential order, the two cannot be matched, and the glass forming efficiency is affected.

Disclosure of Invention

The invention aims to provide an intermittent oxygen supply device for energy-saving glass production, which is characterized in that a supporting disc fixedly connected with the bottom end of a rotating seat is transmitted to a linkage assembly through a transmission assembly, the linkage assembly drives a closing assembly and an oxygen supply assembly to intermittently clamp and close a bearing die and intermittently supply oxygen, so that molten materials which are processed in the bearing die in a substituted way are kept in a molten state, and the quality of glass product molding is prevented from being influenced by impurities generated by cooling in the molding process.

In order to achieve the aim, the invention adopts the following technical scheme that the intermittent oxygen supply device for energy-saving glass production comprises a frame and a bearing die rotating along a rotating seat;

The machine comprises a machine frame, a rotary seat, a supporting plate, a driving assembly, a linkage assembly, a control mechanism and a control mechanism, wherein the machine frame is provided with a closing assembly for carrying the closing of a die, and the top end of the machine frame is provided with an oxygen supply mechanism for carrying the oxygen supply of the die;

The first stroke, the linkage assembly drives the closing assembly to close the bearing die, and the linkage assembly drives the piston assembly positioned in the oxygen supply mechanism to compress the gas;

The second stroke, the linkage assembly drives the closing assembly to extend and separate from the bearing die, and the linkage assembly drives the piston assembly to drive the pressure release assembly to open and close and intermittently supply oxygen to the bearing die;

as a further description of the above technical solution:

the transmission assembly comprises a supporting seat, a rotating shaft rod is rotatably connected to the top end of the supporting seat, transmission wheels are symmetrically and fixedly connected to the two ends of the rotating shaft rod, one end of each transmission wheel is in transmission connection with a supporting disc, and the other end of each transmission wheel is in transmission connection with a driven wheel.

As a further description of the above technical solution:

The linkage assembly comprises a crank shaft rod, support rods are symmetrically arranged at two ends of the crank shaft rod, the support rods are fixed on the frame, one end of the crank shaft rod is fixedly connected with a driven wheel in a penetrating mode, and the driven wheel is meshed with the driving wheel.

As a further description of the above technical solution:

The crankshaft rod comprises a first connecting shaft, two ends of the first connecting shaft are symmetrically provided with a second connecting shaft, the first connecting shaft is fixedly connected with the second connecting shaft through a right-angle mechanism, a connecting piece is arranged at the joint of the first connecting shaft and the second connecting shaft, one end of the first connecting shaft is rotationally connected with a movable arm, one end of the second connecting shaft is rotationally connected with a connecting rod, one end, far away from the second connecting shaft, of the connecting rod is provided with an oxygen supply mechanism, the bottom end of the connecting rod is fixedly connected with a lantern ring, the lantern ring is sleeved on the second connecting shaft, an orientation groove is formed in the connecting rod, an orientation rod is arranged in the orientation groove, and the orientation rod is fixed on a frame.

As a further description of the above technical solution:

The closing component comprises a support, a movable part is arranged in the support in a sliding manner, one end of the movable part is provided with a connecting arm, the other end of the movable part is symmetrically provided with a pulling arm, one end, far away from the movable part, of the pulling arm is rotationally connected with a clamping arm, and the clamping arm is rotationally connected to the support.

As a further description of the above technical solution:

The movable piece comprises a positioning column, fixing strips are symmetrically and fixedly connected to two ends of the positioning column, fixing columns are symmetrically and fixedly connected to two ends of the fixing strips, the fixing columns are matched with the pull arms, a sliding block is fixedly connected to one end of each fixing strip, and the sliding block is arranged in the support in a sliding mode.

As a further description of the above technical solution:

the support comprises a guide plate, a sliding groove is formed in the guide plate, a sliding block is connected in the sliding groove in a sliding mode, one end of the guide plate is fixedly connected with a limiting plate, and a connecting arm is connected in the limiting plate in a sliding mode.

As a further description of the above technical solution:

the oxygen supply mechanism comprises a positioning cylinder, the bottom end of the positioning cylinder is slidably connected with a movable cylinder, a piston assembly is fixedly connected in the movable cylinder, one end of the piston assembly is provided with a pressure relief assembly, the pressure relief assembly is fixed in the movable cylinder, and the pressure relief assembly compresses and releases gas through the piston assembly.

As a further description of the above technical solution:

The piston assembly comprises a connecting rod, a blocking block is fixedly connected to one end of the connecting rod, a fixing rod is fixedly connected to the bottom end of the blocking block and fixed to the movable cylinder, the other end of the connecting rod penetrates through a piston block fixedly connected to the pressure relief assembly, the piston block is arranged in the positioning cylinder, a supporting block is arranged at one end, close to the pressure relief assembly, of the connecting rod, and the supporting block is in supporting adaptation with the pressure relief assembly.

As a further description of the above technical solution:

the pressure relief assembly comprises a support ring, a support spring is fixedly connected to the top end of the support ring, a backing ring is fixedly connected to the top end of the support spring, a valve block is fixedly connected to the array of the top ends of the backing ring, a connecting rod is fixedly connected to the top end of the valve block, a fixing ring is fixedly connected to the connecting rod through a venting ring, and the venting ring is fixed in the positioning cylinder.

The invention provides an intermittent oxygen supply device for energy-saving glass production, which has the following beneficial effects:

According to the invention, the supporting disc fixedly connected with the bottom end of the rotating seat is transmitted to the linkage assembly through the transmission assembly, and the linkage assembly drives the closing assembly and the oxygen supply assembly to intermittently clamp and close the bearing die and intermittently supply oxygen, so that the molten material which is processed in the bearing die is kept in a molten state, and the quality of glass product molding is prevented from being influenced by impurities generated by cooling in the molding process.

Drawings

FIG. 1 is a schematic diagram of an intermittent oxygen supply device for energy-saving glass production;

FIG. 2 is a schematic view of the partial structure of the part A in FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the structure of the support plate according to the present invention;

FIG. 4 is a schematic diagram of a linkage assembly according to the present invention;

FIG. 5 is a schematic view of the structure of the crankshaft lever according to the present invention;

FIG. 6 is a schematic view of a closure assembly according to the present invention;

FIG. 7 is a schematic view of a movable member according to the present invention;

FIG. 8 is a schematic view of the oxygen supply mechanism according to the present invention;

fig. 9 is a schematic structural diagram of a pressure relief assembly according to the present invention.

The legend comprises 1, a rotating seat, 11, a supporting disc, 2, a bearing mould, 3, a frame, 4, a closing component, 41, a bracket, 411, a guide plate, 412, a sliding groove, 413, a limiting plate, 42, a movable piece, 421, a fixed bar, 422, a sliding block, 423, a positioning column, 424, a fixed column, 43, a pulling arm, 44, a clamping arm, 45, a linkage arm, 46, a movable arm, 5, a linkage component, 51, a crankshaft rod, 511, a first connecting shaft, 512, a second connecting shaft, 52, a driven wheel, 53, a connecting piece, 54, a supporting rod, 55, a linkage rod, 56, a lantern ring, 57, a directional groove, 6, an oxygen supply mechanism, 61, a positioning cylinder, 62, a movable cylinder, 63, a piston component, 631, a blocking block, 632, a connecting rod, a piston block, 634, a supporting block, 635, a fixed rod, 64, a pressure relief component, 641, a release ring, 642, a fixed ring, 643, a connecting rod, 644, a valve block, 645, a cushion ring, 646, a supporting spring, 647, a supporting ring, 65, a supporting ring, a transmission rod, 7, a driving wheel, 8, a sleeve, a driving wheel, 82, a rotating shaft, 81, a supporting seat.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Referring to fig. 1-9, an intermittent oxygen supply device for energy-saving glass production comprises a frame 3, a bearing die 2 rotating along a rotating seat 1, a closing component 4 arranged at the bottom end of the frame 3 and used for closing the bearing die 2, an oxygen supply mechanism 6 arranged at the top end of the frame 3 and used for supplying oxygen to the bearing die 2, a transmission component 8, a supporting disc 11 fixedly connected with the bottom end of the rotating seat 1 and used for driving the transmission component 8, and a linkage component 5 connected with the transmission component 8 in a transmission manner, wherein the linkage component 5 is respectively connected with the closing component 4 and the oxygen supply mechanism 6 in a transmission manner, the linkage component 5 has two movement strokes, the first stroke drives the closing component 4 to close the bearing die 2, the linkage component 5 drives a piston component 63 positioned in the oxygen supply mechanism 6 to compress gas, and the second stroke drives the closing component 4 to stretch and separate from the bearing die 2, and the linkage component 5 drives the piston component 63 to drive a pressure relief component 64 to open and close and intermittently supply oxygen to the bearing die 2;

Specifically, the frame 3 is an L-shaped structural support structure, the closed assembly 4 is fixedly connected to one end of the frame 3, the closed assembly 4 is horizontally aligned with the bearing die 2 mounted on the rotary seat 1, the oxygen supply mechanism 6 is mounted and connected to the frame 3, the oxygen supply mechanism 6 is in transmission connection with the closed mechanism through the linkage assembly 5, one end of the transmission connection is provided with the transmission assembly 8, one end of the transmission assembly 8 is in transmission connection with the supporting disc 11 fixedly connected with the bottom end of the rotary seat 1, when the supporting disc 11 drives the linkage assembly 5 through the transmission assembly 8 to move, the linkage assembly 5 is in a first stroke, the linkage assembly 5 drives the closed assembly 4 to clamp the bearing die 2 after filling again, the oxygen supply assembly mounted on the frame 3 is driven by the linkage assembly 5 to compress the gas in the cavity, in a second stroke, the linkage assembly 5 drives the closed assembly 4 to be separated from the clamped bearing die 2, the oxygen supply assembly mounted on the frame 3 is driven by the linkage assembly 5 to release the compressed gas in the cavity through the air release assembly, the released gas is guided into the bearing die 2, the bearing die 2 is convenient to drive the linkage assembly 8 to drive the linkage assembly 5, the linkage assembly 5 to move, the linkage assembly 5 is driven by the bearing die 2 to keep the bearing die 2 in the state after filling, the material is clamped by the bearing die 2, the bearing die 2 is cooled by the linkage assembly, the intermittent cooling device is prevented from being in the intermittent forming state, and the intermittent forming of the product is avoided, and the intermittent forming of the intermittent forming device is produced, and the intermittent forming the product is in the bearing die 2, and the intermittent cooling quality is prevented from producing the intermittent cooling quality by the bearing die and the intermittent cooling device by the bearing assembly and the bearing assembly is in the bottom and the intermittent cooling device;

The transmission assembly 8 comprises a supporting seat 81, a rotating shaft rod 82 is rotatably connected to the top end of the supporting seat 81, driving wheels 83 are symmetrically and fixedly connected to two ends of the rotating shaft rod 82, one end of each driving wheel 83 is in transmission connection with a supporting disc 11, and the other end of each driving wheel 83 is in transmission connection with a driven wheel 52;

Specifically, the supporting seat 81 in the transmission assembly 8 is fixed on the frame 3, two ends of the rotating shaft rod 82 which is rotationally connected with the supporting seat 81 are symmetrically and fixedly connected with the transmission wheel 83, the transmission wheel 83 can be in a gear structure or a friction transmission structure, so that the transmission wheel 83 drives the rotating supporting disc 11 to rotate in the driven wheel 52, and the driven wheel 52 is convenient for driving the power to drive the closing assembly 4 and the oxygen supply assembly to intermittently move;

The linkage assembly 5 comprises a crank shaft rod 51, support rods 54 are symmetrically arranged at two ends of the crank shaft rod 51, the support rods 54 are fixed on the frame 3, one end of the crank shaft rod 51 is fixedly connected with a driven wheel 52 through the support rods 54 and meshed with the driving wheel 83, the crank shaft rod 51 comprises a first connecting shaft 511, two ends of the first connecting shaft 511 are symmetrically provided with a second connecting shaft 512, the first connecting shaft 511 and the second connecting shaft 512 are fixedly connected in a right-angle mechanism, a connecting piece 53 is arranged at the connecting position of the first connecting shaft 511 and the second connecting shaft 512, one end of the first connecting shaft 511 is rotatably connected with a movable arm 46, one end of the second connecting shaft 512 is rotatably connected with a linkage rod 55, one end of the linkage rod 55 far away from the second connecting shaft 512 is provided with an oxygen supply mechanism 6, the bottom end of the linkage rod 55 is fixedly connected with a collar 56, the collar 56 is sleeved on the second connecting shaft 512, a directional groove 57 is formed in the linkage rod 55, a directional rod is arranged in the directional groove 57, and the directional rod is fixed on the frame 3;

Specifically, the crankshaft rod 51 in the linkage assembly 5 is composed of a first connecting shaft 511 and a second connecting shaft 512, the first connecting shaft 511 and the second connecting shaft 512 are fixedly connected in a right-angle vertical state, a connecting piece 53 is arranged between the first connecting shaft 511 and the second connecting shaft 512, the connecting piece 53 is used for supporting and enhancing the stability of the first connecting shaft 511 and the second connecting shaft 512, one end of the first connecting shaft 511 is rotatably connected with a movable arm 46, one end of the movable arm 46, which is far away from the first connecting shaft 511, is in transmission connection with a linkage arm 45, so that when the first connecting shaft 511 rotates along the axis of the driven wheel 52, the first connecting shaft 511 drives the linkage arm 45 to directionally reciprocate through the movable arm 46, the second connecting shaft 512 which is symmetrically and fixedly connected at two ends of the first connecting shaft 511 drives the oxygen supply assembly 4 to directionally move through the linkage rod 55, and the orientation groove 57 arranged in the linkage rod 55 is internally provided with an orientation rod limitation fixed on the frame 3, so that the linkage rod 55 is directionally moved under the drive of the second connecting shaft 512 through the fixedly connected collar 56, and the oxygen supply mechanism 6 is convenient to intermittently compress gas and bear the die 2;

The closing component 4 comprises a support 41, a movable part 42 is arranged in the support 41 in a sliding manner, a connecting arm 45 is arranged at one end of the movable part 42, a pull arm 43 is symmetrically arranged at the other end of the movable part 42, a clamping arm 44 is rotatably connected to one end of the pull arm 43 far away from the movable part 42, and the clamping arm 44 is rotatably connected to the support 41;

Specifically, a movable part 42 is slidably connected in the bracket 41 in the closing component 4, a sliding block 422 in the movable part 42 is slidably arranged in a chute 412 formed by the orientation plate, a fixed bar 421 fixedly connected between the two sliding blocks 422 is used for fixedly connecting a positioning column 423 with a fixed column 424, the positioning column 423 is rotationally connected with a movable arm 46, the fixed column 424 is rotationally connected with a clamping arm 44 through a pulling arm 43, when the movable arm 46 is driven by a first connecting shaft 511 to enable the movable arm 45 to be movably connected with the positioning column 423, and the sliding blocks 422 fixed at two ends of the positioning column 423 move directionally along the chute 412, so that the fixed column 424 symmetrically fixedly connected at two ends of the fixed bar 421 drives the clamping arm 44 to rotationally move along the joint of the clamping arm 44 and the bracket 41 through the pulling arm 43, so that the two clamping arms 44 rotationally move along the joint of the bracket 41, and the bearing die 2 is clamped and closed under the action of the rotational movement of the clamping arm 44;

The oxygen supply mechanism 6 comprises a positioning cylinder 61, the bottom end of the positioning cylinder 61 is connected with a movable cylinder 62 in a sliding manner, a piston assembly 63 is fixedly connected in the movable cylinder 62, one end of the piston assembly 63 is provided with a pressure relief assembly 64, the pressure relief assembly 64 is fixed in the movable cylinder 62, the pressure relief assembly 64 compresses and releases gas through the piston assembly 63, the piston assembly 63 comprises a connecting rod 632, one end of the connecting rod 632 is fixedly connected with a blocking block 631, the bottom end of the blocking block 631 is fixedly connected with a fixed rod 635, the fixed rod 635 is fixed on the movable cylinder 62, the other end of the connecting rod 632 penetrates through the pressure relief assembly 64 and is fixedly connected with a piston block 633, the piston block 633 is arranged in the positioning cylinder 61, one end of the connecting rod 632, which is close to the pressure relief assembly 64, is provided with a supporting block 634, the supporting block 634 is in abutting fit with the pressure relief assembly 64, the pressure relief assembly 64 comprises a supporting ring 647, the top end of the supporting ring 647 is fixedly connected with a supporting spring 646, the top end of the supporting spring 646 is fixedly connected with a backing ring 645, the top end of the backing ring 645 is fixedly connected with a valve block 644, the top of the valve block 644 is fixedly connected with a connecting rod 643, the pressure relief ring 641 penetrates through the top of the piston ring 641, and the gas ring 641 is fixedly connected with a supporting ring 641, and the pressure relief ring 641 is fixedly connected to the supporting ring 641, and the pressure relief ring 64 is fixedly arranged in the positioning cylinder 64;

Specifically, the positioning cylinder 61 and the movable cylinder 62 in the oxygen supply mechanism 6 are in a sleeved movable structure, the piston assembly 63 is fixedly connected in the movable cylinder 62, the piston assembly 63 is in sliding connection with the positioning cylinder 61, two ends of the connecting rod 632 in the piston cylinder are respectively fixedly connected with the blocking block 631 and the piston block 633, the fixed rod 635 fixedly connected with the bottom end of the blocking block 631 is fixedly connected with the movable cylinder 62, when the movable cylinder 62 moves in a directional manner, the blocking block 631 and the piston block 633 are driven to move along the positioning cylinder, when the piston block 633 moves in a directional manner, the abutting block 634 fixedly connected with one end of the piston block 633 abuts against the fixed ring 642 and drives the connecting rod 643 fixedly connected with the bottom end of the fixed ring 642 to move in a directional manner, the valve block 644 fixedly connected with the bottom end of the connecting rod 643 is separated from the air release ring 641, so that the piston block 633 can guide compressed air in the positioning cylinder 61 into the bearing die 2 through the movable cylinder 62, the secondary combustion of the molten material held in the bearing die 2 is facilitated, the exhaust pipe 7 arranged at one end of the movable cylinder 62 is prevented from generating impurities after the temperature reduction, when the piston block is used for collecting the combustion in the bearing die 2, the air flow guide block 633 is used for blowing out of the air guide block 6474, the oxygen supply block 647 is compressed in the air flow is compressed by the air supply cylinder 647 through the movable cylinder, and the air supply device is connected with the air supply valve 647 is conveniently and the air supply device is positioned at the top end of the upper end of the air supply cylinder, and the oxygen supply device is conveniently is connected with the oxygen supply device is replaced by the oxygen supply device is easily and the oxygen supply device is connected with the oxygen supply device, and the oxygen supply device is easy and the oxygen supply device is convenient.

Working principle: a closing component 4 fixedly connected with one end of the frame 3, the closing component 4 is horizontally aligned with the bearing die 2 arranged on the rotating seat 1, an oxygen supply mechanism 6 is arranged on the frame 3, the oxygen supply mechanism 6 is in transmission connection with the closing mechanism through a linkage component 5, one end of the transmission connection is provided with a transmission component 8, one end of the transmission component 8 is in transmission connection with a supporting disk 11 fixedly connected with the bottom end of the rotating seat 1, when the supporting disk 11 drives the linkage component 5 through the transmission component 8 to move, the linkage component 5 drives the closing component 4 to clamp the filled bearing die 2 again for closing, the oxygen supply component arranged on the frame 3 compresses gas in a cavity under the drive of the linkage component 5, and in a second stroke, the linkage component 5 drives the closing component 4 to be separated from the clamped bearing die 2, the oxygen supply assembly arranged on the frame 3 releases the compressed gas in the cavity through the air release assembly under the drive of the linkage assembly 5, and guides the released gas into the bearing die 2, so that the molten material filled in the bearing die 2 is kept in a hot melting state, and the phenomenon that the molten material is cooled in advance in the bearing die 2 to generate impurities is avoided, wherein the crankshaft rod 51 in the linkage assembly 5 consists of a first connecting shaft 511 and a second connecting shaft 512, the first connecting shaft 511 and the second connecting shaft 512 are fixedly connected in a right-angle vertical state, a connecting piece 53 is arranged between the first connecting shaft 511 and the second connecting shaft 512, the connecting piece 53 is used for supporting and reinforcing the stability of the first connecting shaft 511 and the second connecting shaft 512, one end of the first connecting shaft 511 is rotationally connected with a movable arm 46, one end of the movable arm 46 far away from the first connecting shaft 511 is in transmission connection with a linkage arm 45, so that when the first connecting shaft 511 rotates along the axis of the driven wheel 52, the first connecting shaft 511 drives the connecting arm 45 to directionally reciprocate through the movable arm 46, the connecting arm 45 is convenient to drive the closing component 4 to open and close, the second connecting shaft 512 which is symmetrically and fixedly connected with the two ends of the first connecting shaft 511 drives the oxygen supply component to directionally move through the connecting rod 55, wherein the directional groove 57 arranged in the connecting rod 55 is internally provided with a directional rod limit fixed on the frame 3, the connecting rod 55 is driven by the second connecting shaft 512 to directionally move through the fixedly connected lantern ring 56, so that the oxygen supply mechanism 6 compresses gas and intermittently supplies oxygen to the bearing mold 2, the device transmits power of the supporting disc 11 fixedly connected with the bottom end of the rotating seat 1 to the connecting component 5 through the transmission component 8, and the connecting component 5 drives the closing component 4 and the oxygen supply component to intermittently clamp and close the bearing mold 2 and intermittently supply oxygen, so that molten materials which are processed in the bearing mold 2 keep a molten state.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme and the concept of the present invention, and should be covered by the scope of the present invention.

Claims

1. An intermittent oxygen supply device for energy-saving glass production is characterized by comprising a frame (3) and a bearing die (2) rotating along a rotating seat (1);

The machine comprises a frame (3), a driving assembly (8), a supporting disc (11) fixedly connected with the bottom end of a rotating seat (1), a linkage assembly (5) and two motion strokes of the linkage assembly (5), wherein the bottom end of the frame (3) is provided with a closing assembly (4) for bearing the closing of a die (2), the top end of the frame (3) is provided with an oxygen supply mechanism (6) for bearing the oxygen supply of the die (2);

The first stroke, the linkage assembly (5) drives the closing assembly (4) to close the bearing die (2), and the linkage assembly (5) drives the piston assembly (63) positioned in the oxygen supply mechanism (6) to compress the gas;

In the second stroke, the linkage assembly (5) drives the closing assembly (4) to stretch and separate from the bearing die (2), and the linkage assembly (5) drives the piston assembly (63) to drive the pressure relief assembly (64) to open and close and intermittently supply oxygen to the bearing die (2).

2. The intermittent oxygen supply device for energy-saving glass production according to claim 1, wherein the transmission assembly (8) comprises a supporting seat (81), a rotating shaft rod (82) is rotatably connected to the top end of the supporting seat (81), driving wheels (83) are symmetrically and fixedly connected to two ends of the rotating shaft rod (82), one end of each driving wheel (83) is in transmission connection with a supporting disc (11), and the other end of each driving wheel (83) is in transmission connection with a driven wheel (52).

3. The intermittent oxygen supply device for energy-saving glass production according to claim 1, wherein the linkage assembly (5) comprises Qu Zhougan (51), support rods (54) are symmetrically arranged at two ends of the crank shaft rod (51), the support rods (54) are fixed on the frame (3), one end of the crank shaft rod (51) is fixedly connected with a driven wheel (52) through the support rods (54), and the driven wheel (52) is meshed with the driving wheel (83).

4. The intermittent oxygen supply device for energy-saving glass production according to claim 3, wherein the crankshaft rod (51) comprises a first connecting shaft (511), two ends of the first connecting shaft (511) are symmetrically provided with a second connecting shaft (512), the first connecting shaft (511) is fixedly connected with the second connecting shaft (512) through a right-angle mechanism, a connecting piece (53) is arranged at the connecting position of the first connecting shaft (511) and the second connecting shaft (512), one end of the first connecting shaft (511) is rotatably connected with a movable arm (46), one end of the second connecting shaft (512) is rotatably connected with a connecting rod (55), one end of the connecting rod (55) away from the second connecting shaft (512) is provided with an oxygen supply mechanism (6), the bottom end of the connecting rod (55) is fixedly connected with a lantern ring (56), the lantern ring (56) is sleeved on the second connecting shaft (512), a directional groove (57) is formed in the connecting rod (55), a directional rod is arranged in the directional groove (57), and the directional rod is fixed on the frame (3).

5. An intermittent oxygen supply device for energy-saving glass production according to claim 1, characterized in that the closing component (4) comprises a bracket (41), a movable part (42) is arranged in the bracket (41) in a sliding manner, one end of the movable part (42) is provided with a connecting arm (45), the other end of the movable part (42) is symmetrically provided with a pulling arm (43), one end of the pulling arm (43) far away from the movable part (42) is rotationally connected with a clamping arm (44), and the clamping arm (44) is rotationally connected on the bracket (41).

6. The intermittent oxygen supply device for energy-saving glass production according to claim 5, wherein the movable piece (42) comprises a positioning column (423), two ends of the positioning column (423) are symmetrically and fixedly connected with a fixing strip (421), two ends of the fixing strip (421) are symmetrically and fixedly connected with a fixing column (424), the fixing column (424) is matched with the pull arm (43), one end of the fixing strip (421) is fixedly connected with a sliding block (422), and the sliding block (422) is slidably arranged in the support (41).

7. The intermittent oxygen supply device for energy-saving glass production according to claim 5, wherein the bracket (41) comprises a guide plate (411), a chute (412) is formed in the guide plate (411), a sliding block (422) is connected in the chute (412) in a sliding manner, one end of the guide plate (411) is fixedly connected with a limiting plate (413), and a linkage arm (45) is connected in the limiting plate (413) in a sliding manner.

8. The intermittent oxygen supply device for energy-saving glass production according to claim 1, wherein the oxygen supply mechanism (6) comprises a positioning cylinder (61), a movable cylinder (62) is slidably connected to the bottom end of the positioning cylinder (61), a piston assembly (63) is fixedly connected to the movable cylinder (62), a pressure release assembly (64) is arranged at one end of the piston assembly (63), the pressure release assembly (64) is fixed to the movable cylinder (62), and the pressure release assembly (64) compresses and releases gas through the piston assembly (63).

9. The intermittent oxygen supply device for energy-saving glass production according to claim 8, wherein the piston assembly (63) comprises a connecting rod (632), one end of the connecting rod (632) is fixedly connected with a blocking block (631), the bottom end of the blocking block (631) is fixedly connected with a fixing rod (635), the fixing rod (635) is fixed on the movable cylinder (62), the other end of the connecting rod (632) penetrates through the pressure release assembly (64) and is fixedly connected with a piston block (633), the piston block (633) is arranged in the positioning cylinder (61), one end, close to the pressure release assembly (64), of the connecting rod (632) is provided with a supporting block (634), and the supporting block (634) is in abutting fit with the pressure release assembly (64).

10. The intermittent oxygen supply device for energy-saving glass production according to claim 8, wherein the pressure relief assembly (64) comprises a supporting ring (647), a supporting spring (646) is fixedly connected to the top end of the supporting ring (647), a backing ring (645) is fixedly connected to the top end of the supporting spring (646), a valve block (644) is fixedly connected to the array of the top ends of the backing ring (645), a connecting rod (643) is fixedly connected to the top end of the valve block (644), a fixing ring (642) is fixedly connected to the connecting rod (632) penetrating through the venting ring (641), and the venting ring (641) is fixed in the positioning cylinder (61).