CN217578676U - Torch device and glass processing machine tool - Google Patents

Abstract

The utility model relates to a glass processing equipment field particularly, relates to a blast burner device and glass processing machine tool. The torch device comprises a first multi-tube torch body, an oxygen supply assembly, a coal gas supply assembly and an air supply assembly; the oxygen supply assembly comprises a first oxygen pipe and an oxygen bottle, and two ends of the first oxygen pipe are respectively communicated with the oxygen bottle and the first oxygen inlet; the gas supply assembly comprises a first gas pipe and a gas bottle, and two ends of the first gas pipe are respectively communicated with the gas bottle and the first gas inlet; the air supply assembly comprises a first air pipe and an air compressor, and two ends of the first air pipe are respectively communicated with the air compressor and a first air inlet; the blowtorch device can adjust flame form and temperature when processing glass instrument to avoid appearing the uneven problem of annealing temperature, thereby can ensure the continuity of glass instrument when processing man-hour, improve glass instrument quality and success rate.

Description

Torch device and glass processing machine tool

Technical Field

The utility model relates to a glass processing equipment field particularly, relates to a blast burner device and glass processing machine tool.

Background

Glass working machines generally refer to special lathes for welding, fusing or other thermal processing of glass articles. The glass tube processing lathe is different from a common machining lathe in that the glass tube processing lathe is provided with a clamping disc capable of clamping a glass tube and synchronously rotating and a flame lamp capable of moving back and forth.

At present, glass processing machines in the market mostly adopt two gas paths (liquefied petroleum gas and oxygen), and arc-shaped multi-nozzle row-type blowlamps are adopted as lamp caps. The design aims at the aspects of repeated processing of single products of glass standard parts such as a connecting interface of a glass pipeline, a solar heat collecting pipe and the like, and shows strong technological advantages, and pure oxygen flame with multiple arc-shaped nozzles is fully applied to processing large-diameter instruments. However, the arc-shaped multi-nozzle row type blowtorch is lack of diversity in flame adjustment and adjustability in flame temperature due to the two paths of air sources, and the flame shape and the temperature of the nozzles cannot be independently adjusted, so that the arc-shaped multi-nozzle row type blowtorch has many limitations particularly in the aspect of processing non-standard glass instruments.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a blowtorch device and glass processing machine tool, it can be when processing the glass instrument, adjusts flame form and temperature to avoid appearing the uneven problem of annealing temperature, thereby can ensure the continuity of glass instrument when adding man-hour, improve glass instrument quality and success rate.

The embodiment of the utility model is realized like this:

in a first aspect, the present invention provides a torch device, which includes a first multi-tube torch body, an oxygen supply assembly, a gas supply assembly, and an air supply assembly;

the first multi-tube blowtorch main body is used for being connected with the sliding seat; the first multi-tube torch body comprises a first oxygen inlet, a first coal gas inlet and a first air inlet;

the oxygen supply assembly comprises a first oxygen pipe and an oxygen bottle, and two ends of the first oxygen pipe are respectively communicated with the oxygen bottle and the first oxygen inlet; the gas supply assembly comprises a first gas pipe and a gas bottle, and two ends of the first gas pipe are respectively communicated with the gas bottle and the first gas inlet; the air supply assembly comprises a first air pipe and an air compressor, and two ends of the first air pipe are respectively communicated with the air compressor and a first air inlet;

wherein, the first oxygen pipe, the first gas pipe and the first air pipe are respectively provided with a first oxygen regulating valve, a first gas regulating valve and a first air regulating valve.

In an alternative embodiment, the first multi-tube torch body further includes a second oxygen inlet; the oxygen supply assembly further comprises a second oxygen pipe; two ends of the second oxygen pipe are respectively communicated with the oxygen cylinder and the second oxygen inlet;

wherein, the second oxygen pipe is provided with a second oxygen regulating valve.

In an alternative embodiment, the burner apparatus further comprises a second multi-tube burner body connected to the sliding base, the second multi-tube burner body comprising a third oxygen inlet, a second gas inlet, and a second air inlet;

the oxygen supply assembly also comprises a third oxygen pipe, and two ends of the third oxygen pipe are respectively communicated with the oxygen cylinder and the third oxygen inlet; the gas supply assembly also comprises a second gas pipe, and two ends of the second gas pipe are respectively communicated with the gas bottle and the second gas inlet; the air supply assembly also comprises a second air pipe, and two ends of the second air pipe are respectively communicated with the air compressor and the second air inlet;

wherein, the third oxygen pipe and the second air pipe are respectively provided with a third oxygen regulating valve and a second air regulating valve, and the second gas pipe is provided with a pedal regulating valve.

In an alternative embodiment, the second multi-tube torch body further comprises a fourth oxygen inlet; the oxygen supply assembly further comprises a fourth oxygen tube; two ends of a fourth oxygen pipe are respectively communicated with the oxygen cylinder and a fourth oxygen inlet;

wherein, a fourth oxygen regulating valve is arranged on the fourth oxygen pipe.

In an alternative embodiment, a third oxygen regulating valve is located at the connection of the third oxygen pipe and the third oxygen inlet; the fourth oxygen regulating valve is positioned at the joint of the fourth oxygen pipe and the fourth oxygen inlet.

In an optional embodiment, the blast lamp device further comprises a connecting plate, and the connecting plate is connected with the sliding seat; the connecting plate includes first connecting portion and second connecting portion, and first connecting portion are used for being connected with first multitube blowtorch main part, and the second connecting portion are used for being connected with second multitube blowtorch main part, first connecting portion and second connecting portion interval.

In an optional embodiment, the first connecting portion and the second connecting portion are distributed on two sides of the sliding seat.

In a second aspect, the utility model provides a glass processing machine tool, which comprises a machine tool main body, a sliding seat and the blowtorch device;

the base that slides is connected with lathe main part movably, and first multitube blowtorch main part and second multitube blowtorch main part all are connected with the base that slides.

In an optional embodiment, the glass processing machine tool further comprises a hand wheel adjusting plate, and the hand wheel adjusting plate is connected with the sliding seat;

the first gas regulating valve and the first air regulating valve are both connected with the hand wheel regulating plate.

In an optional embodiment, the glass processing machine further comprises a mounting plate, and the mounting plate is connected with the hand wheel adjusting plate;

the first oxygen regulating valve, the second oxygen regulating valve and the second air regulating valve are all connected with the mounting plate.

The utility model discloses beneficial effect includes:

the blowtorch device comprises a first multi-tube blowtorch main body, an oxygen supply assembly, a coal gas supply assembly and an air supply assembly; the first multi-tube blowtorch main body is used for being connected with the sliding seat; the first multi-tube torch body comprises a first oxygen inlet, a first coal gas inlet and a first air inlet; the oxygen supply assembly comprises a first oxygen pipe and an oxygen bottle, and two ends of the first oxygen pipe are respectively communicated with the oxygen bottle and the first oxygen inlet; the gas supply assembly comprises a first gas pipe and a gas bottle, and two ends of the first gas pipe are respectively communicated with the gas bottle and the first gas inlet; the air supply assembly comprises a first air pipe and an air compressor, and two ends of the first air pipe are respectively communicated with the air compressor and a first air inlet; wherein, the first oxygen pipe, the first gas pipe and the first air pipe are respectively provided with a first oxygen regulating valve, a first gas regulating valve and a first air regulating valve.

From this, this blowtorch device is at the in-process of work, through the first oxygen import in the first multitube blowtorch main part, the setting of first coal gas import and first air intlet, can form the multichannel gas circuit, and at the supply oxygen, the in-process of coal gas and air, can be through first oxygen control valve, first coal gas control valve and first air control valve are respectively to oxygen, the flow of coal gas and air is adjusted, thereby can be when being applied to glass processing machine tool processing glass instrument, the accessible is to oxygen, the adjustment of the flow of coal gas and air, adjust flame form and temperature, and avoid appearing the uneven problem of annealing temperature, thereby can ensure the continuity of glass instrument when processing man-hour, improve glass instrument quality and success rate.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on these drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a torch device according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a glass processing machine according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a first multi-tube torch body according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a second multi-tube torch body according to an embodiment of the present invention;

fig. 5 is a schematic structural view of the wheel adjusting plate and the mounting plate according to an embodiment of the present invention.

200-glass processing machine; 210-a machine tool body; 220-a sliding seat; 230-a handwheel adjusting plate; 240-mounting plate; 100-a torch device; 110-a first multi-tube torch body; 120-an oxygen supply assembly; 130-gas supply assembly; 140-an air supply assembly; 111-a first oxygen inlet; 112-a first gas inlet; 113-a first air inlet; 121-a first oxygen pipe; 122-an oxygen cylinder; 131-a first gas pipe; 132-gas bottles; 141-a first air tube; 142-an air compressor; 123-a first oxygen regulating valve; 133-a first gas regulating valve; 143-a first air adjustment valve; 114-a second oxygen inlet; 124-second oxygen pipe; 125-second oxygen regulating valve; 150-a second multi-tube torch body; 151-third oxygen inlet; 152-a second gas inlet; 153-a second air inlet; 126-a third oxygen tube; 134-a second gas pipe; 144-a second air tube; 127-a third oxygen regulating valve; 145-a second air adjustment valve; 135-foot operated regulating valve; 154-fourth oxygen inlet; 128-a fourth oxygen tube; 129-fourth oxygen regulating valve.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate the directions or positional relationships based on the directions or positional relationships shown in the drawings, or the directions or positional relationships that the products of the present invention are usually placed when used, and are only for the convenience of describing the present invention and simplifying the description, but do not indicate or imply that the device or element indicated must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another, and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical" and the like do not imply that the components are required to be absolutely horizontal or pendant, but rather may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 4, the present embodiment provides a torch device 100, the torch device 100 includes a first multi-tube torch body 110, an oxygen supply assembly 120, a gas supply assembly 130, and an air supply assembly 140;

the first multi-tube torch body 110 is used for connecting with the sliding base 220; the first multi-burner body 110 includes a first oxygen inlet 111, a first gas inlet 112 and a first air inlet 113, and it should be noted that a in fig. 3 is a schematic structural view of the first multi-burner body 110 from a first viewing angle, and B in fig. 3 is a schematic structural view of the first multi-burner body 110 from a second viewing angle;

the oxygen supply assembly 120 comprises a first oxygen pipe 121 and an oxygen cylinder 122, wherein two ends of the first oxygen pipe 121 are respectively communicated with the oxygen cylinder 122 and the first oxygen inlet 111; the gas supply assembly 130 includes a first gas pipe 131 and a gas bottle 132, and two ends of the first gas pipe 131 are respectively communicated with the gas bottle 132 and the first gas inlet 112; the air supply assembly 140 includes a first air pipe 141 and an air compressor 142, and both ends of the first air pipe 141 are respectively communicated with the air compressor 142 and the first air inlet 113;

the first oxygen pipe 121, the first gas pipe 131 and the first air pipe 141 are respectively provided with a first oxygen regulating valve 123, a first gas regulating valve 133 and a first air regulating valve 143.

The operation principle of the torch apparatus 100 is:

referring to fig. 1 to 4, the torch apparatus 100 includes a first multi-tube torch body 110, an oxygen supply unit 120, a gas supply unit 130, and an air supply unit 140; the first multi-tube torch body 110 is used for connecting with the sliding base 220; the first multi-tube torch body 110 includes a first oxygen inlet 111, a first gas inlet 112, and a first air inlet 113; two ends of the first oxygen pipe 121 are respectively communicated with the oxygen bottle 122 and the first oxygen inlet 111; two ends of the first gas pipe 131 are respectively communicated with the gas bottle 132 and the first gas inlet 112; both ends of the first air pipe 141 are respectively communicated with the air compressor 142 and the first air inlet 113; the first oxygen pipe 121, the first gas pipe 131 and the first air pipe 141 are respectively provided with a first oxygen regulating valve 123, a first gas regulating valve 133 and a first air regulating valve 143.

Therefore, in the operation process of the torch device 100, a plurality of gas paths can be formed by the arrangement of the first oxygen inlet 111, the first gas inlet 112 and the first air inlet 113 on the first multi-tube torch main body 110, and in the process of supplying oxygen, gas and air through the plurality of gas paths, the flow rates of oxygen, gas and air can be respectively adjusted through the first oxygen adjusting valve 123, the first gas adjusting valve 133 and the first air adjusting valve 143, so that when the torch device is applied to a glass processing machine 200 to process glass instruments, the flame shape and temperature can be adjusted by adjusting the flow rates of oxygen, gas and air, and the problem of non-uniform annealing temperature can be avoided, thereby ensuring the continuity of the glass instruments during processing and improving the quality and success rate of the glass instruments.

Further, in the present embodiment, in order to expand the range of adjusting the flame shape and temperature, the first multi-tube burner body 110 further includes a second oxygen inlet 114; the oxygen supply assembly 120 further includes a second oxygen tube 124; two ends of the second oxygen tube 124 are respectively communicated with the oxygen cylinder 122 and the second oxygen inlet 114; wherein, the second oxygen pipe 124 is provided with a second oxygen regulating valve 125.

Thus, the first oxygen control valve 123 and the second oxygen control valve 125 can expand the adjustable range of the flow rate of oxygen to the first multi-burner body 110, so that the burner device 100 can adjust the flame shape and temperature, and the burner device 100 can diversify the flame shape and temperature.

Furthermore, based on the above, in the present embodiment, the burner apparatus 100 may further include a second multi-tube burner main body 150, the second multi-tube burner main body 150 is connected to the sliding base 220, the second multi-tube burner main body 150 includes a third oxygen inlet 151, a second gas inlet 152 and a second air inlet 153, it should be noted that C in fig. 4 is a schematic structural diagram of a first viewing angle of the first multi-tube burner main body 110, and D in fig. 4 is a schematic structural diagram of a second viewing angle of the first multi-tube burner main body 110;

the oxygen supply assembly 120 further comprises a third oxygen pipe 126, and two ends of the third oxygen pipe 126 are respectively communicated with the oxygen cylinder 122 and the third oxygen inlet 151; the gas supply assembly 130 further comprises a second gas pipe 134, and two ends of the second gas pipe 134 are respectively communicated with the gas bottle 132 and the second gas inlet 152; the air supply assembly 140 further comprises a second air pipe 144, and two ends of the second air pipe 144 are respectively communicated with the air compressor 142 and the second air inlet 153;

the third oxygen pipe 126 and the second air pipe 144 are respectively provided with a third oxygen regulating valve 127 and a second air regulating valve 145, and the second gas pipe 134 is provided with a foot control valve 135.

Similar to the operation principle of the first multi-tube torch body 110, a plurality of gas paths can be formed by the third oxygen inlet 151, the second gas inlet 152 and the second air inlet 153 on the second multi-tube torch body 150, and in the process of supplying oxygen, gas and air through the plurality of gas paths, the flows of oxygen, gas and air can be respectively adjusted through the third oxygen regulating valve 127, the foot regulating valve 135 and the second air regulating valve 145, so that when the multi-tube torch is applied to a glass processing machine 200 for processing glass instruments, the flame shape and temperature can be adjusted by adjusting the flows of oxygen, gas and air, and the problem of non-uniform annealing temperature can be avoided, thereby ensuring the continuity of the glass instruments during processing, and improving the quality and success rate of the glass instruments.

Also, the second multi-tube torch body 150 further includes a fourth oxygen inlet 154; the oxygen supply assembly 120 further comprises a fourth oxygen tube 128; the two ends of the fourth oxygen tube 128 are respectively communicated with the oxygen cylinder 122 and the fourth oxygen inlet 154; the fourth oxygen pipe 128 is provided with a fourth oxygen regulating valve 129.

Thus, the third oxygen control valve 127 and the fourth oxygen control valve 129 can expand the adjustable range of the flow rate of oxygen to the second multi-burner main body 150, so that the burner apparatus 100 can adjust the flame shape and temperature, and the burner apparatus 100 can further diversify the flame shape and temperature.

In summary, referring to fig. 1-4, in the present embodiment, the torch apparatus 100 may include a first multi-torch body 110 and a second multi-torch body 150, and thus, by such an arrangement, the positions of the first multi-torch body 110 and the second multi-torch body 150 may be adjusted, so that the first multi-torch body 110 is used as a main combustion lamp, and the second multi-torch body 150 is used as an auxiliary combustion lamp, so that the first multi-torch body 110 completes the melting process and annealing of the glass instrument, and the processes of side joint, side hole expansion, side annealing and the like of the glass instrument in the processing process may be completed by the second multi-torch body 150, thereby ensuring the continuity of the processes of the glass instrument in the processing process.

Further, referring to fig. 1-4, in the present embodiment, when the third oxygen regulating valve 127 and the fourth oxygen regulating valve 129 are provided, for convenience of operation, the third oxygen regulating valve 127 is located at the connection of the third oxygen pipe 126 and the third oxygen inlet 151; a fourth oxygen regulating valve 129 is located at the connection of the fourth oxygen line 128 and the fourth oxygen inlet 154.

Based on the above-mentioned structural arrangement, when the first and second multi-burner bodies 110 and 150 are connected to the slide mount 220 of the glass processing machine 200, the burner apparatus 100 further includes a connection plate connected to the slide mount 220 for facilitating the connection of the first and second multi-burner bodies 110 and 150; the connection plate includes a first connection portion for connecting with the first multi-torch main body 110 and a second connection portion for connecting with the second multi-torch main body 150, the first connection portion being spaced apart from the second connection portion. And the first connecting portion and the second connecting portion are distributed on both sides of the sliding seat 220.

It should be noted that, when the first connection portion and the second connection portion are arranged, since the first multi-tube torch main body 110 is used for completing the fusion processing and annealing of the glass instrument, and the processes of side connection, side hole expansion, side annealing and the like of the glass instrument in the processing process are completed by the second multi-tube torch main body 150, when the first connection portion and the second connection portion are arranged, the first connection portion and the second connection portion can be distributed on both sides of the sliding seat 220 along the sliding direction of the sliding seat 220 relative to the glass processing machine 200, and the sliding direction is the direction from one of the glass clamping seats to the other glass clamping seat.

Further, referring to fig. 1-5, based on the above, the present embodiment further provides a glass processing machine 200, wherein the glass processing machine 200 includes a machine body 210, a sliding seat 220, and the torch device 100;

in order to accomplish the processes of melting and annealing of the glass instrument, and the processes of side joining, side hole expanding, side annealing, etc. of the glass instrument during the processing process when the glass processing machine 200 processes the glass instrument, the torch device 100 includes the first multi-torch main body 110 and the second multi-torch main body 150;

specifically, the sliding base 220 is movably connected to the machine tool main body 210, and both the first multi-tube torch main body 110 and the second multi-tube torch main body 150 are connected to the sliding base 220.

Further, in the present embodiment, in order to facilitate rapid adjustment of the supply of oxygen, gas and air to the first and second multi-torch bodies 110 and 150, a first oxygen regulating valve 123, a second oxygen regulating valve 125, a third oxygen regulating valve 127, a fourth oxygen regulating valve 129, a first gas regulating valve 133, a foot regulating valve 135, a first air regulating valve 143 and a second air regulating valve 145 are provided;

as described above, in order to facilitate the operation of the third oxygen control valve 127, the fourth oxygen control valve 129 and the foot-operated control valve 135, the third oxygen control valve 127 is located at the connection point of the third oxygen pipe 126 and the third oxygen inlet 151, the fourth oxygen control valve 129 is located at the connection point of the fourth oxygen pipe 128 and the fourth oxygen inlet 154, and the foot-operated control valve 135 is installed on the ground;

in order to facilitate the operation of the first air regulating valve 123, the second air regulating valve 125, the first gas regulating valve 133, the first air regulating valve 143 and the second air regulating valve 145, the glass processing machine 200 further comprises a handwheel regulating plate 230 and a mounting plate 240, the handwheel regulating plate 230 is connected with the sliding seat 220, and the mounting plate 240 is connected with the handwheel regulating plate 230; the hand wheel adjusting plate 230 is used for installing a hand wheel, and the sliding seat 220 can be driven to move relative to the machine tool main body 210 through operation;

the first gas regulating valve 133 and the first air regulating valve 143 are connected to the hand wheel regulating plate 230, and the first oxygen regulating valve 123, the second oxygen regulating valve 125 and the second air regulating valve 145 are connected to the mounting plate 240.

In summary, referring to fig. 1-5, the glass processing machine 200 of the present embodiment has the following advantages:

the gas circuit is diversified, the improved glass processing machine tool 200 is changed from two gas circuits (liquefied petroleum gas and oxygen) to four gas source gas circuits (liquefied petroleum gas, oxygen, pure oxygen and air), the problems that the flame shape of a glass instrument is inconvenient to adjust and the annealing temperature is uneven during processing are solved, and the process problems that the glass instrument cannot complete the side connection, side reaming, side annealing and the like of the glass instrument on the glass processing machine tool 200 are solved;

the burning lamp has obvious adjusting effect, the flame temperature of the improved first multi-tube blowtorch body 110 and the improved second multi-tube blowtorch body 150 can be switched from 550 ℃ annealing temperature to 1300 ℃ pure oxygen temperature, the flame area of the lamp wick can be freely adjusted, the process requirements of side joint, side reaming, side annealing and the like of the glass instrument on the glass processing machine tool 200 are met, the continuity of the working procedures in the processing of the glass instrument is ensured, and the working efficiency is greatly improved.

The improved glass processing machine tool 200 meets the requirements of actual work, achieves the purpose of design improvement and reduces the expenditure of related money.

Based on the above, the steps of processing the double-jacket glass instrument by using the glass processing machine 200 are as follows:

firstly, the double-jacket glass instrument is made of GG-17 high borosilicate glass, and a section of phi 100 long 440mm glass tube is embedded into a section of phi 60 long 420mm glass tube;

placing the double-jacket glass instrument on a glass processing machine tool 200, and fixing the double-jacket glass instrument by chucks at two ends of the glass processing machine tool 200;

the supply of gas, oxygen and air in the first multi-tube torch body 110 is adjusted through the first oxygen adjusting valve 123, the second oxygen adjusting valve 125, the first gas adjusting valve 133 and the first air adjusting valve 143, the flaring of the upper end of the glass tube with phi 100 is completed, and the glass tube with phi 160 is fused and sealed with the upper end surface of the glass tube with phi 160;

after the sealing annealing is finished, the supply of coal gas, oxygen and air in the second multi-tube torch body 150 is adjusted on the outer side surface of the phi 160 glass tube through a third oxygen adjusting valve 127, a fourth oxygen adjusting valve 129, a pedal adjusting valve 135 and a second air adjusting valve 145 to complete side hole expansion and fusion sealing of a section of phi 10 glass tail tube;

the other end adopts the same process to finish operation, and after integral annealing, a closed double-layer jacket circulating glass instrument with phi 160 as the outer diameter and phi 100 as the inner diameter and an upper interface and a lower interface is formed.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A torch device characterized by:

the torch device comprises a first multi-tube torch main body, an oxygen supply assembly, a coal gas supply assembly and an air supply assembly;

the first multi-tube blowtorch main body is used for being connected with the sliding seat; the first multi-tube torch body comprises a first oxygen inlet, a first coal gas inlet and a first air inlet;

the oxygen supply assembly comprises a first oxygen pipe and an oxygen bottle, and two ends of the first oxygen pipe are respectively communicated with the oxygen bottle and the first oxygen inlet; the gas supply assembly comprises a first gas pipe and a gas bottle, and two ends of the first gas pipe are respectively communicated with the gas bottle and the first gas inlet; the air supply assembly comprises a first air pipe and an air compressor, and two ends of the first air pipe are respectively communicated with the air compressor and the first air inlet;

the first oxygen pipe, the first gas pipe and the first air pipe are respectively provided with a first oxygen regulating valve, a first gas regulating valve and a first air regulating valve.

2. The torch device according to claim 1, wherein:

the first multi-tube torch body further comprises a second oxygen inlet; the oxygen supply assembly further comprises a second oxygen tube; two ends of the second oxygen pipe are respectively communicated with the oxygen bottle and the second oxygen inlet;

wherein, a second oxygen regulating valve is arranged on the second oxygen pipe.

3. The torch device according to claim 1, wherein:

the blowtorch device also comprises a second multi-tube blowtorch main body, the second multi-tube blowtorch main body is connected with the sliding seat, and the second multi-tube blowtorch main body comprises a third oxygen inlet, a second coal gas inlet and a second air inlet;

the oxygen supply assembly further comprises a third oxygen pipe, and two ends of the third oxygen pipe are respectively communicated with the oxygen cylinder and the third oxygen inlet; the gas supply assembly also comprises a second gas pipe, and two ends of the second gas pipe are respectively communicated with the gas bottle and the second gas inlet; the air supply assembly further comprises a second air pipe, and two ends of the second air pipe are respectively communicated with the air compressor and the second air inlet;

the third oxygen pipe and the second air pipe are respectively provided with a third oxygen regulating valve and a second air regulating valve, and the second gas pipe is provided with a pedal regulating valve.

4. A torch device according to claim 3, wherein:

the second multi-tube torch body further comprises a fourth oxygen inlet; the oxygen supply assembly further comprises a fourth oxygen tube; two ends of the fourth oxygen pipe are respectively communicated with the oxygen cylinder and the fourth oxygen inlet;

and a fourth oxygen regulating valve is arranged on the fourth oxygen pipe.

5. The torch device according to claim 4, wherein:

the third oxygen regulating valve is positioned at the joint of the third oxygen pipe and the third oxygen inlet; the fourth oxygen regulating valve is positioned at the joint of the fourth oxygen pipe and the fourth oxygen inlet.

6. The torch device according to claim 3, wherein:

the blowtorch device also comprises a connecting plate, and the connecting plate is connected with the sliding seat; the connecting plate comprises a first connecting part and a second connecting part, the first connecting part is used for being connected with the first multi-tube burner main body, the second connecting part is used for being connected with the second multi-tube burner main body, and the first connecting part and the second connecting part are spaced.

7. The torch device according to claim 6, wherein:

the first connecting part and the second connecting part are distributed on two sides of the sliding seat.

8. The utility model provides a glass processing machine tool which characterized in that:

the glass processing machine comprises a machine body, a sliding seat and a blast lamp device according to any one of claims 1-7;

the sliding seat is movably connected with the machine tool main body, and the first multi-tube blowtorch main body and the second multi-tube blowtorch main body are connected with the sliding seat.

9. The glass processing machine of claim 8, wherein:

the glass processing machine tool also comprises a hand wheel adjusting plate, and the hand wheel adjusting plate is connected with the sliding seat;

the first gas regulating valve and the first air regulating valve are both connected with the hand wheel regulating plate.

10. The glass processing machine of claim 9, wherein:

the glass processing machine tool also comprises an installation plate, and the installation plate is connected with the hand wheel adjusting plate;

the first oxygen regulating valve, the second oxygen regulating valve and the second air regulating valve are all connected with the mounting plate.

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