CN219363511U - Glass cutting cooling splinter device - Google Patents

Abstract

The utility model belongs to the technical field of glass cutting and splitting, and particularly relates to a glass cutting and cooling splitting device, which comprises a frame, wherein a workbench is arranged on the frame and used for placing glass after laser cutting; the pressing cylinder is arranged above the workbench and is used for covering the inner glass block along the cutting line; the cooling mechanism is used for introducing a low-temperature cooling medium into the pressing cylinder, and the low-temperature cooling medium is used for cooling the inner glass block; the push rod mechanism is arranged above the workbench and is used for applying thrust to the inner glass block or the outer glass block; the low-temperature cooling medium is introduced into the pressing cylinder to cool the inner glass block, so that the inner glass block is cooled rapidly, the inner glass block is split with the outer glass block along the cutting line under the action of the pulling force generated by cold contraction, then the pushing force is applied to the inner glass block or the outer glass block through the push rod mechanism, and the inner glass block is completely separated from the outer glass block under the dual actions of the pulling force generated by cold contraction and the pushing force applied by the push rod mechanism, so that the separation success rate is high.

Description

Glass cutting cooling splinter device

Technical Field

The utility model belongs to the technical field of glass cutting and splitting, and particularly relates to a glass cutting and cooling splitting device.

Background

Glass is widely used as a basic material in furniture industry in various furniture and household articles. After cutting the glass by laser, the glass is still integral and does not naturally separate along the cutting track, and then needs to be separated by a splitting process.

In the prior art, a part of glass can be separated by cooling the part of the glass, so that the glass expands with heat and contracts with cold, and the part of the glass is cooled by spraying cold water to the part of the glass in the current cooling mode, however, the mode of cooling the glass by spraying cold water only is insufficient for separating the glass along with the increase of the thickness of the glass, the problem of reworking caused by incomplete separation of the glass easily occurs or the problem of low separation success rate although the glass can be separated is solved.

Disclosure of Invention

The utility model aims to provide a glass cutting cooling splitting device, which aims to solve the technical problems that in the prior art, the cooling capacity of cold water is limited, and the glass is not separated sufficiently by simply spraying cold water or the separation success rate is not high although the glass can be separated.

In order to achieve the above object, the embodiment of the present utility model provides a glass cutting cooling lobe device, including;

the glass cutting machine comprises a frame, wherein a workbench is arranged on the frame and used for placing glass after laser cutting, and the surface of the glass is divided into an inner glass block and an outer glass block along a cutting line;

the pressing cylinder is arranged above the workbench and corresponds to the inner glass block up and down, and is used for covering the inner glass block along the cutting line;

the cooling mechanism is used for introducing a low-temperature cooling medium into the pressing cylinder, and the low-temperature cooling medium is used for cooling the inner glass block; and

and the push rod mechanism is arranged above the workbench and is used for applying thrust to the inner glass block or the outer glass block.

Optionally, a sealing ring is arranged at the bottom of the pressing cylinder, and when the pressing cylinder covers the inner glass block along the cutting line, the sealing ring is in sealing contact with the inner glass block or the outer glass block along the cutting line.

Optionally, a lifting mechanism is arranged on the frame, and the lifting mechanism comprises a vertical frame and a first driving piece; the stand is arranged on the stand, the first driving piece is arranged on the stand, the pressing cylinder is arranged on the first driving piece, the first driving piece is used for driving the pressing cylinder to move up and down, and the pressing cylinder covers the inner glass block along the cutting line when moving down.

Optionally, the push rod mechanism comprises a mounting frame, a second driving piece and a push rod; the mounting frame is arranged on the frame, the second driving piece is arranged on the mounting frame, the push rod is arranged on the second driving piece, the second driving piece is used for driving the push rod to push the middle part of the inner glass block so as to apply thrust to the inner glass block, or the second driving piece is used for driving the push rod to push the periphery of the outer glass block so as to apply thrust to the outer glass block.

Optionally, a push block is arranged at the bottom of the push rod.

Optionally, the cooling mechanism is a gas tank, the low-temperature cooling medium is low-temperature liquefied gas, and the low-temperature liquefied gas is stored in the gas tank; the outer wall of the pressure cylinder is provided with an inlet, the inlet is connected with the gas tank through a gas pipe, and low-temperature liquefied gas is introduced into the pressure cylinder through the gas tank.

Optionally, the cryogenic liquefied gas is liquid argon, liquid helium, liquid neon, liquid nitrogen, liquid oxygen, liquid hydrogen, liquid methane, or liquefied natural gas.

Optionally, a horizontal transplanting mechanism is arranged on the frame, the workbench is arranged on the horizontal transplanting mechanism, and the horizontal transplanting mechanism is used for driving the workbench to move between the cooling lobe position and the loading and unloading position.

Optionally, the workbench comprises a top plate, a bottom plate and a plurality of support rods connected between the top plate and the bottom plate; the top plate penetrates through a blanking hole provided with a clearance inner glass block.

Optionally, the cooling mechanism is a cold water tank, the low-temperature cooling medium is cold water, and the cold water is stored in the cold water tank; the outer wall of the pressure cylinder is provided with an inlet, the inlet is connected with the cold water tank through a water pipe, and cold water is introduced into the pressure cylinder through the cold water tank. And a waste collection vehicle is arranged below the workbench.

Compared with the prior art, the one or more technical schemes in the glass cutting cooling lobe device provided by the embodiment of the utility model have at least one of the following technical effects:

the inner glass block and the outer glass block which are separated from the glass surface along the cutting line by laser cutting are still in a connected state, the low-temperature cooling medium is introduced into the pressing cylinder and contacts with the inner glass block to cool the inner glass block, so that the inner glass block is rapidly cooled, the inner glass block is split with the outer glass block along the cutting line under the action of the pulling force generated by cold contraction, then the pushing force is applied to the inner glass block or the outer glass block by the push rod mechanism, the inner glass block and the outer glass block are completely separated under the dual actions of the pulling force generated by cold contraction and the pushing force applied by the push rod mechanism, and the separation integrity is good.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a glass cutting cooling lobe device of the present utility model.

Fig. 2 is a schematic view of a partial structure of a glass cutting and heating splinter device according to the present utility model.

Fig. 3 is a cross-sectional view of fig. 2.

Fig. 4 is a schematic view of a structure of a glass surface subjected to laser cutting according to the present utility model.

Wherein, each reference sign in the figure:

100. a frame; 110. a work table; 111. a blanking hole; 112. a top plate; 113. a bottom plate; 114. a support rod; 120. a horizontal transplanting mechanism; 130. a waste collection vehicle;

200. pressing a cylinder; 201. an inner cavity; 202. a seal ring; 203. perforating; 204. an access port; 21. a cooling mechanism; 210. a gas tank; 220. an air pipe;

300. a push rod mechanism; 310. a mounting frame; 320. a second driving member; 330. a push rod; 340. a pushing block;

400. a lifting mechanism; 410. a vertical frame; 420. a first driving member; 430. a connecting piece;

500. glass; 510. cutting lines; 520. an inner glass block; 530. an outer glass block.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are exemplary and intended to illustrate embodiments of the utility model and should not be construed as limiting the utility model.

In the description of the embodiments of the present utility model, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the embodiments of the present utility model and simplify description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the embodiments of the present utility model, the meaning of "plurality" is two or more, unless explicitly defined otherwise.

In the embodiments of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured" and the like are to be construed broadly and include, for example, either permanently connected, removably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the embodiments of the present utility model will be understood by those of ordinary skill in the art according to specific circumstances.

In one embodiment of the present utility model, referring to fig. 1-4, a glass cutting cooling lobe apparatus is provided that includes a frame 100, a platen 200, a cooling mechanism 21, and a pusher mechanism 300.

Referring to fig. 1 and 4, a workbench 110 is disposed on the frame 100, the workbench 110 is used for horizontally placing the glass 500 after laser cutting, and the surface of the glass 500 is divided into an inner glass block 520 and an outer glass block 530 along a cutting line 510.

Referring to fig. 1, 2 and 3, the pressing cylinder 200 is disposed above the working table 110 and is disposed vertically corresponding to the inner glass block 520, the pressing cylinder 200 is provided with an inner cavity 201 having a lower opening, and the pressing cylinder 200 is used for covering the inner glass block 520 along the cutting line 510.

Referring to fig. 1, 2 and 3, the cooling mechanism 21 is disposed on the frame 100, the cooling mechanism 21 is used for introducing a low-temperature cooling medium into the pressure cylinder 200, the low-temperature cooling medium is used for cooling the inner glass block 520, and the low-temperature cooling medium contacts with the inner glass block 520 to cool the inner glass block 520. When the inner glass block 520 is covered by the pressure cylinder 200 along the cutting line 510, a closed cavity is formed between the pressure cylinder 200 and the inner glass block 520, and at this time, the low-temperature cooling medium introduced into the pressure cylinder 200 is positioned in the closed cavity and cannot diffuse out of the pressure cylinder 200, so that the low-temperature cooling medium is concentrated in the pressure cylinder 200 to cool the inner glass block 520.

Also, referring to fig. 1, 2 and 3, when the pressure cylinder 200 covers the inner glass block 520 along the cutting line 510, the pressure cylinder 200 can isolate the low-temperature cooling medium therein from spreading onto the outer glass block 530, thereby preventing the low-temperature cooling medium from cooling the outer glass block 530 and maximally isolating the influence of the low-temperature cooling medium on the outer glass block 530.

Referring to fig. 1, 2 and 3, the push rod mechanism 300 is disposed above the table 110, and the push rod mechanism 300 is used to apply a pushing force to the inner glass block 520 or the outer glass block 530.

Compared with the prior art, the one or more technical schemes in the glass cutting cooling lobe device provided by the embodiment of the utility model have at least one of the following technical effects:

referring to fig. 1, 2 and 3, the inner glass block 520 and the outer glass block 530, which are separated along the cutting line 510 by laser cutting, are still in a connected state, a low-temperature liquefied low-temperature cooling medium is introduced into the pressure cylinder 200 through the cooling mechanism 21, the low-temperature cooling medium is in contact with the inner glass block 520, the inner glass block 520 is cooled, the inner glass block 520 is rapidly cooled, the inner glass block 520 and the outer glass block 530 are split along the cutting line 510 under the action of a tensile force generated by cold contraction, then a pushing force is applied to the inner glass block 520 or the outer glass block 530 through the pushing rod mechanism 300, and the inner glass block 520 and the outer glass block 530 are completely separated under the dual actions of the tensile force (contraction force) generated by cold contraction force and the pushing rod mechanism 300.

Referring to fig. 4, the shapes of the inner glass pane 520 and the outer glass pane 530 on the glass 500 referred to in the present application may be any shapes, according to actual production requirements. Since the shape of the press cylinder 200 corresponds to the shape of the inner glass block 520, the shape of the press cylinder 200 is changed according to the shape of the inner glass block 520, and is not limited herein. For ease of illustration, a rectangular outer glass pane 530 and a circular inner glass pane 520 are illustrated in this application.

Further, referring to fig. 2 and 3, a sealing ring 202 is disposed at the bottom of the pressure cylinder 200, and when the pressure cylinder 200 covers the inner glass block 520 along the cutting line 510, the sealing ring 202 seals against the inner glass block 520 or the outer glass block 530 along the cutting line 510. The sealing performance of the pressure cylinder 200 in contact with the inner glass block 520 or the outer glass block 530 is improved through the sealing ring 202, so that the performance of the pressure cylinder 200 for isolating the low-temperature cooling medium in the pressure cylinder from spreading to the outer glass block 530 is improved, and the sealing performance is good.

Referring to fig. 2 and 3, the sealing ring 202 may be attached to the bottom of the pressure cylinder 200 by means of adhesion or clamping, and is convenient to install.

In another embodiment of the present utility model, referring to fig. 1, 2 and 3, a lifting mechanism 400 is provided on the frame 100, and the lifting mechanism 400 includes a stand 410 and a first driving member 420. The stand 410 is fixedly arranged on the stand 100, the first driving member 420 is arranged on the stand 410, the pressing cylinder 200 is arranged on the first driving member 420, the first driving member 420 is used for driving the pressing cylinder 200 to move up and down, and the pressing cylinder 200 covers the inner glass block 520 along the cutting line 510 when moving down so as to cover the inner glass block 520 in the pressing cylinder 200.

Further, referring to fig. 2 and 3, the first driving member 420 is a first cylinder, a driving rod of the first cylinder is fixedly connected with the pressing cylinder 200 through a connecting member 430, and the pressing cylinder 200 is driven to move up and down by the telescopic motion of the driving rod of the first cylinder, so that the structure is simple. After the inner glass block 520 is separated from the outer glass block 530, the driving rod of the first cylinder drives the pressing cylinder 200 to move upwards away from the inner glass block 520 and the outer glass block 530, so that the outer glass block 530 is convenient to take off.

In another embodiment of the present utility model, referring to fig. 1, 2 and 3, the pusher mechanism 300 includes a mounting bracket 310, a second driver 320 and a pusher 330. The mounting frame 310 is fixedly arranged on the stand 100 through a vertical frame 410, the second driving piece 320 is arranged on the mounting frame 310, the push rod 330 is arranged on the second driving piece 320, and the push rod 330 movably penetrates through the middle of the pressure cylinder 200. The second driving member 320 is configured to drive the push rod 330 to push the middle portion of the inner glass block 520, so as to apply a pushing force to the inner glass block 520, so that the inner glass block 520 is completely separated from the outer glass block 530, and the structure is simple. After the inner glass block 520 is separated from the outer glass block 530, the second driving member 320 drives the push rod 330 upward so as to remove the outer glass block 530.

Alternatively, in other embodiments, the second driving member 320 is configured to drive the push rod 330 to push the periphery of the outer glass block 530 to apply a pushing force to the outer glass block 530, so that the inner glass block 520 is completely separated from the outer glass block 530, and the structure is simple. Wherein, the push rods 330 may be provided with a plurality of push rods 330, the upper ends of the plurality of push rods 330 are fixedly connected with the second driving member 320 through a connecting frame, and the plurality of push rods 330 are driven by the second driving member 320 to apply thrust to the periphery of the outer glass block 530, so as to uniformly bear force.

Further, referring to fig. 2 and 3, a push block 340 is provided at the bottom of the push rod 330, and specifically, the push block 340 is fixed to the bottom of the push rod 330 by a screw. The push rod 330 pushes the middle part of the inner glass block 520 through the push block 340, increasing the contact area of the inner glass block 520, and reducing the pressure. Wherein the pushing block 340 is an elastic buffer block, and when contacting the inner glass block 520, the inner glass block 520 is not scratched, and hard collision is not generated. The elastic buffer block can be made of silica gel, rubber or the like.

Preferably, referring to fig. 2 and 3, a through hole 203 is formed in the top center of the pressure cylinder 200, and the push rod 330 is tightly inserted into the through hole 203 to prevent the through hole 203 from leaking air. The push rod 330 may be connected with the through hole 203 in a sealing manner through a sealing ring, and the push rod 330 may move up and down relative to the through hole 203 under the driving of the second driving member 320.

Preferably, the material of the pressure cylinder 200 is a heat insulating material, for example: the thermal insulation material may be glass fiber, asbestos, rock wool, silicate, etc., and the novel thermal insulation material, such as aerogel blanket, vacuum panel, etc., is not limited herein.

In other embodiments, the push rod mechanism 300 is connected with the lifting mechanism 400, and after the inner glass block 520 is cooled for a certain time by the low-temperature cooling medium, the push rod mechanism 300 drives the pressure cylinder 200 to press down and apply a pushing force to the inner glass block 520 or the outer glass block 530 through the isolating mechanism 400, so that the inner glass block 520 is completely separated from the outer glass block 530, and the structure is simple. In this case, the push rod mechanism 300 may be a cylinder or other power source.

In another embodiment of the present utility model, referring to fig. 1, 2 and 3, the cooling mechanism 21 is a gas tank 210, the gas tank 210 is provided on the rack 100, the low-temperature cooling medium is a low-temperature liquefied gas, and the low-temperature liquefied gas is stored in the gas tank 210. The outer wall of the pressure cylinder 200 is provided with an inlet 204 communicated with the inner cavity 201 of the pressure cylinder 200, the inlet 204 is connected with the gas tank 210 through a gas pipe 220, and low-temperature liquefied gas is introduced into the pressure cylinder 200 through the gas tank 210. The low-temperature liquefied gas in the gas tank 210 is introduced into the pressure cylinder 200 along the gas pipe 220, and the low-temperature liquefied gas is concentrated in the pressure cylinder 200 to cool the inner glass block 520, so that the inner glass block is rapidly cooled. When the pressure cylinder 200 covers the inner glass block 520 along the cutting line 510, the pressure cylinder 200 can isolate the low-temperature liquefied gas therein from spreading onto the outer glass block 530, thereby preventing the low-temperature liquefied gas from cooling the outer glass block 530 and maximally isolating the influence of the low-temperature liquefied gas on the outer glass block 530.

Referring to fig. 1, 2 and 3, since the temperature of the low-temperature liquefied gas is extremely low, the cooling of the inner glass block 520 by the low-temperature liquefied gas is fast and efficient, and the inner glass block 520 can be cooled to a very low temperature, so that the shrinkage rate of the inner glass block 520 is larger when the inner glass block 520 is contracted, and compared with the prior art in which the glass 500 is cooled by spraying cold water, the separation of the inner glass block 520 and the outer glass block 530 is easier to realize.

The low-temperature liquefied gas is liquid argon, liquid helium, liquid neon, liquid nitrogen, liquid oxygen, liquid hydrogen, liquid methane, liquefied natural gas, or the like, and has an extremely low temperature, and is not limited herein.

Further, the gas tank 210 is provided with a gas valve (not shown), when the gas valve is opened, the low-temperature liquefied gas in the gas tank 210 is introduced into the pressure cylinder 200 along the gas pipe 220, and when the gas valve is closed, the low-temperature liquefied gas in the gas tank 210 cannot be introduced into the pressure cylinder 200.

In another embodiment of the present utility model, referring to fig. 3 and 4, the cooling mechanism 21 is a cold water tank (not shown) provided in the rack 100, the low-temperature cooling medium is cold water (e.g., ice water, etc.), and the cold water is stored in the cold water tank. An inlet 204 is arranged on the outer wall of the pressure cylinder 200, the inlet 204 is connected with the cold water tank through a water pipe, and cold water is introduced into the pressure cylinder 200 through the cold water tank. Cold water in the cold water tank is introduced into the pressure cylinder 200 along the water pipe, and the cold water is concentrated in the pressure cylinder 200 to cool the inner glass block 520, so that the inner glass block is rapidly cooled. When the pressure cylinder 200 covers the inner glass block 520 along the cutting line 510, the pressure cylinder 200 can isolate the inner cold water from spreading onto the outer glass block 530, thereby preventing the cold water from cooling the outer glass block 530 and maximally isolating the influence of the cold water on the outer glass block 530.

In addition, in the prior art, a mode of directly spraying (showering) cold water on the inner glass block 520 is adopted, so that the cold water rapidly flows away from the inner glass block 520 just when the cold water contacts with the inner glass block 520, and the cold water is not fully utilized, so that the energy consumption is high and the cold water consumption is high. In this application, since the pressure cylinder 200 can concentrate the cold water therein, the cold water cannot flow out of the pressure cylinder 200, so that the cold water in the pressure cylinder 200 can be fully utilized to cool the inner glass block 520, the energy consumption is relatively low, the energy is more saved, and the consumption of cold water is relatively low.

Further, the position of the cold water tank is higher than that of the pressure cylinder 200, cold water in the cold water tank flows into the pressure cylinder 200 under the action of gravity, and a power device is not required to be arranged for pumping water, so that the structure is simple. Specifically, a valve body (not shown) is disposed in the water pipe, when the valve body is opened, cold water in the cold water tank is delivered to the pressure cylinder 200 along the water pipe, and when the valve body is closed, the delivery of cold water in the cold water tank to the pressure cylinder 200 is stopped.

Of course, in other embodiments, the cold water tank may be located below the pressure cylinder 200, and a water pipe (not shown) is connected to the water pump, and the cold water in the cold water tank is supplied to the pressure cylinder 200 along the water pipe by the power of the water pump.

Wherein, the cold water tank can be provided with refrigerating mechanism, for example: the mature existing structures such as the refrigerating mechanism in the refrigerator and the condenser tube refrigerating mechanism in the air conditioner can also be used for directly putting ice cubes into cold water in the cold water tank, and the details are not repeated here.

It will be appreciated that in other embodiments, the cryogenic cooling medium may be other cryogenic liquids or cryogenic substances, without limitation.

In another embodiment of the present utility model, referring to fig. 1 and 2, a horizontal transplanting mechanism 120 is provided on the frame 100, the table 110 is provided on the horizontal transplanting mechanism 120, and the horizontal transplanting mechanism 120 is used for driving the table 110 to move between a cooling lobe position and an up-down position. In loading and unloading, the worker removes the outer glass block 530, which is completely broken, and places the glass 500 to be broken on the table 110, thereby facilitating the operation. In cooling the breaking position, the glass 500 is subjected to a cooling breaking process.

The horizontal transplanting mechanism 120 may adopt a screw module, and the screw module drives the workbench 110 to horizontally move, so that the structure is simple.

In another embodiment of the present utility model, referring to fig. 2 and 3, the workbench 110 is provided with a blanking hole 111 for avoiding the inner glass block 520, the workbench 110 can stably support the glass after laser cutting, the glass after laser cutting is convenient for the breaking process, and the inner glass block 520 falls from the blanking hole 111 when the inner glass block 520 is separated from the outer glass block 530.

Further, referring to fig. 2 and 3, the table 110 includes a top plate 112, a bottom plate 113, and a plurality of support rods 114 connected between the top plate 112 and the bottom plate 113. The top plate 112 is provided with a blanking hole 111 for avoiding the inner glass block 520. After the inner glass block 520 is separated from the outer glass block 530, the inner glass block 520 falls onto the bottom plate 113 from the blanking hole 111, and the inner glass block 520 is received, so that the inner glass block 520 is conveniently taken out.

In another embodiment of the present utility model, referring to fig. 1, a waste collection vehicle 130 is disposed below the table 110, and the waste collection vehicle 130 is used for collecting glass scraps falling from the table 110, so as to collect the glass scraps in a concentrated manner.

The rest of the present embodiment is the same as the first embodiment, and the unexplained features in the present embodiment are all explained by the first embodiment, and are not described here again.

The foregoing is a further detailed description of the utility model in connection with the preferred embodiments, and it is not intended that the utility model be limited to the specific embodiments described. For those skilled in the art, the architecture of the utility model can be flexible and changeable without departing from the concept of the utility model, and serial products can be derived. But a few simple derivatives or substitutions should be construed as falling within the scope of the utility model as defined by the appended claims.

Claims (10)

1. A glass cutting cooling splinter device, comprising;

the glass cutting machine comprises a frame, wherein a workbench is arranged on the frame and used for placing glass after laser cutting, and the surface of the glass is divided into an inner glass block and an outer glass block along a cutting line;

the pressing cylinder is arranged above the workbench and corresponds to the inner glass block up and down, and is used for covering the inner glass block along the cutting line;

the cooling mechanism is used for introducing a low-temperature cooling medium into the pressing cylinder, and the low-temperature cooling medium is used for cooling the inner glass block; and

and the push rod mechanism is arranged above the workbench and is used for applying thrust to the inner glass block or the outer glass block.

2. The glass cutting cooling lobe device of claim 1, wherein: the bottom of the pressure cylinder is provided with a sealing ring, and when the pressure cylinder covers the inner glass block along the cutting line, the sealing ring is in sealing contact with the inner glass block or the outer glass block along the cutting line.

3. The glass cutting cooling lobe device of claim 1, wherein: the lifting mechanism is arranged on the frame and comprises a vertical frame and a first driving piece; the stand is arranged on the stand, the first driving piece is arranged on the stand, the pressing cylinder is arranged on the first driving piece, the first driving piece is used for driving the pressing cylinder to move up and down, and the pressing cylinder covers the inner glass block along the cutting line when moving down.

4. The glass cutting cooling lobe device of claim 1, wherein: the push rod mechanism comprises a mounting frame, a second driving piece and a push rod; the mounting frame is arranged on the frame, the second driving piece is arranged on the mounting frame, and the push rod is arranged on the second driving piece; the second driving piece is used for driving the push rod to push the middle part of the inner glass block so as to apply thrust to the inner glass block, or is used for driving the push rod to push the periphery of the outer glass block so as to apply thrust to the outer glass block.

5. The glass cutting cooling lobe device of claim 4, wherein: the bottom of the push rod is provided with a push block.

6. The glass cutting cooling lobe device of any one of claims 1-5, wherein: the cooling mechanism is a gas tank, the low-temperature cooling medium is low-temperature liquefied gas, and the low-temperature liquefied gas is stored in the gas tank; the outer wall of the pressure cylinder is provided with an inlet, the inlet is connected with the gas tank through a gas pipe, and low-temperature liquefied gas is introduced into the pressure cylinder through the gas tank.

7. The glass cutting cooling lobe device of claim 6, wherein: the low-temperature liquefied gas is liquid argon, liquid helium, liquid neon, liquid nitrogen, liquid oxygen, liquid hydrogen, liquid methane or liquefied natural gas.

8. The glass cutting cooling lobe device of any one of claims 1-5, wherein: the horizontal transplanting machine is characterized in that a horizontal transplanting mechanism is arranged on the frame, the workbench is arranged on the horizontal transplanting mechanism, and the horizontal transplanting mechanism is used for driving the workbench to move between a cooling lobe position and an upper and lower material position.

9. The glass cutting cooling lobe device of any one of claims 1-5, wherein: the workbench comprises a top plate, a bottom plate and a plurality of supporting rods connected between the top plate and the bottom plate; the top plate penetrates through a blanking hole provided with a clearance inner glass block.

10. The glass cutting cooling lobe device of any one of claims 1-5, wherein: the cooling mechanism is a cold water tank, the low-temperature cooling medium is cold water, and the cold water is stored in the cold water tank; the outer wall of the pressure cylinder is provided with an inlet, the inlet is connected with the cold water tank through a water pipe, and cold water is introduced into the pressure cylinder through the cold water tank.