CN116161857A - Energy-saving foam glass foaming kiln - Google Patents

Abstract

The invention discloses an energy-saving foam glass foaming kiln, which relates to the technical field of foaming kilns and comprises the following components: the kiln comprises two supporting plates, wherein the top of the two supporting plates is fixedly connected with a kiln body shell, one side of the top of the kiln body shell is fixedly connected with a preheating assembly, a plurality of transmission wheels are rotatably connected between the two supporting plates through a rotating shaft, a transmission belt is connected between a plurality of transmission wheels in a transmission manner, and the top of the transmission belt is fixedly connected with a plurality of mounting plates; this scheme is through setting up vibrating assembly, and the extrusion piece cooperates the second spring to drive the slide bar and is reciprocating motion, and the slide bar drives the laminating piece through the connecting plate and knocks the shaping template and shake, and the vibration can make the material in the shaping template fill more compact even to improve the quality of finished product, simultaneously, when the shaping template gets into the cooling zone, vibrating assembly knocks the shaping template and shakes, makes fashioned foam glass and shaping template separation, reduces the separation degree of difficulty of finished product and shaping template.

Description

Energy-saving foam glass foaming kiln

Technical Field

The invention relates to the technical field of foaming kilns, in particular to an energy-saving foam glass foaming kiln.

Background

The foam glass is a porous inorganic nonmetallic material which takes waste flat glass and bottle glass as raw materials and is formed by high-temperature foaming, and has the characteristics of fire resistance, water resistance, innocuity, corrosion resistance, moth resistance, aging resistance, radioactivity resistance, insulation, magnetic wave resistance, static resistance, high mechanical strength and good cohesiveness with various slurries, and the foam glass generally needs to enter a foaming kiln for firing.

Chinese patent application No.: the invention patent of cn201210571938.X discloses a foam glass production system comprising a raw material cleaning system, a raw material ball milling system, a heating system and an annealing system for sequentially processing raw materials, wherein the raw material cleaning system comprises: a feeding device, a drying and dedusting device, a crushing device, a magnetic impurity removing device and a storage bin which are used for sequentially carrying out corresponding treatment on foam glass raw materials; the raw material ball milling system comprises: ball mill; a raw material conveying device; a storage and transportation distribution device; the heating system includes: a heating furnace; a first track; a mould box transfer trolley and a foam glass transfer trolley; a transfer rail; a finished product raw material bin positioned above the conveying track; the annealing system includes: annealing furnace; kiln car; a second track; kiln car traction device; a third rail interfacing with the first rail; a fourth track connecting the second track and the third track; kiln car transfer car (buggy). The production system has reasonable structural design and high production efficiency, and can ensure the high quality of the product, but in the actual use process, raw materials are not preheated before entering the kiln body for heating, so that the temperature difference of the raw materials is easy to cause larger influence on the firing quality.

Disclosure of Invention

The invention aims to provide an energy-saving foam glass foaming kiln which can realize the function of preheating raw materials before the raw materials enter the kiln body for heating.

The technical aim of the invention is realized by the following technical scheme: an energy efficient foam glass foaming kiln comprising: the kiln comprises two supporting plates, kiln body shells are fixedly connected to the tops of the two supporting plates, a preheating assembly is fixedly connected to one side of the tops of the kiln body shells, a plurality of transmission wheels are connected between the two supporting plates in a rotating mode through a rotating shaft, a transmission belt is connected between a plurality of transmission wheels in a transmission mode, a plurality of mounting plates are fixedly connected to the tops of the transmission belts, a forming template is fixedly connected to the center of the tops of the mounting plates, vibration assemblies are arranged on two sides of the forming template, a buffer collecting assembly is arranged on one side of each of the two supporting plates, two separation doors are arranged in the kiln body shells and divide the kiln body shells into a residual heat area, a heating area and a cooling area, a first motor is fixedly connected to one side of each supporting plate, and one end of an output shaft of the first motor is fixedly connected with one side of one transmission wheel;

wherein, vibration subassembly includes a plurality of mounting brackets, sliding connection has the slide bar between mounting bracket and the mounting panel top fixed connection and the adjacent two mounting brackets, slide bar one end fixedly connected with connecting plate, one side fixedly connected with laminating piece that the connecting plate deviates from the slide bar, laminating piece one side laminates with shaping template one side mutually, laminating piece cross section shape is the hemisphere, the laminating piece is flexible plastic mat.

Further, slide bar one side fixedly connected with limiting plate, limiting plate one side is laminated mutually with one of them mounting bracket one side, slide bar surface cover is equipped with the second spring, second spring both ends respectively with limiting plate one side and mounting bracket one side fixed connection.

Further, the one end fixedly connected with removal wheel that the connecting plate was kept away from to the slide bar, a plurality of extrusion pieces of inboard both ends equal fixedly connected with of backup pad, extrusion piece is laminated mutually with removing the wheel, extrusion piece cross section shape is trapezoidal.

Further, the preheating component comprises a connecting pipe, one end of the connecting pipe is fixedly communicated with the heating area, the other end of the connecting pipe extends to the residual heat area and is connected with an air outlet box, the middle part of the connecting pipe is fixedly connected with an air extracting pump, and a plurality of partition plates are rotatably connected in the air outlet box through connecting shafts and bearings.

Further, the connecting axle one end surface fixedly connected with drive gear, drive gear bottom meshing has the drive rack, drive rack sliding connection is in play bellows one side, drive rack one end threaded connection has reciprocating screw, reciprocating screw one end is connected with play bellows inner wall one side rotation, play bellows one side fixed mounting has the second motor, second motor output shaft one end extends to out the bellows inside and with reciprocating screw one end fixed connection through the pivot.

Further, two first sliding grooves are fixedly formed in one side of the transmission rack, a first sliding block is connected in the first sliding groove in a sliding mode, and one end of the first sliding block is fixedly connected with one side of the inner wall of the air outlet box.

Further, the buffering collection subassembly includes the collecting box, the collecting box both sides all laminate with the backup pad is inboard mutually, the cavity has been seted up to the collecting box bottom, sliding connection has the sliding plate in the cavity, the sliding plate both sides laminate mutually with the cavity inner wall, the equal fixedly connected with pinch roller in sliding plate bottom both sides, the laminating of pinch roller bottom has the stripper plate, stripper plate cross section shape is trapezoidal, stripper plate sliding connection is in cavity inner wall bottom, sliding plate top central point puts fixedly connected with slide bar, slide bar one end extends to the collecting box inside and fixedly connected with buffer plate.

Further, the bottom of the extrusion plate is fixedly connected with a second sliding block, a second sliding groove is formed in the bottom of the inner wall of the cavity, and the second sliding block is slidably connected in the second sliding groove.

Further, squeeze board one side fixedly connected with telescopic link, the telescopic link other end and cavity inner wall one side fixed connection, telescopic link surface cover is equipped with first spring, first spring both ends respectively with cavity inner wall one side and squeeze board one side fixed connection.

Further, heating device has all been set firmly to kiln body shell both sides, heating device is located the zone of heating, kiln body shell top fixedly connected with combustion-supporting fan, combustion-supporting fan one side fixedly connected with combustion-supporting pipe, the combustion-supporting pipe other end is linked together with the zone of heating, combustion-supporting fan opposite side fixedly connected with blowing pipe, the blowing pipe other end is linked together with the cooling zone.

Compared with the prior art, the beneficial effect of this scheme is as follows:

1. according to the scheme, the vibration assembly is arranged, the first motor drives the transmission belt to operate, the transmission drive drives the molding template to move through the mounting plate, meanwhile, the mounting plate drives the sliding rod to move through the mounting frame, the sliding rod drives the moving wheel to move, the moving wheel periodically contacts with the extrusion block in the moving process, the extrusion block is matched with the second spring to drive the sliding rod to reciprocate, the sliding rod drives the attaching block to knock the molding template through the connecting plate, the vibration can enable the material in the molding template to be filled more tightly and uniformly, so that the quality of a finished product is improved, meanwhile, when the molding template enters the cooling area, the vibration assembly knocks the molding template, so that molded foam glass is separated from the molding template, and the separation difficulty of a finished product and the molding template is reduced;

2. according to the scheme, the preheating assembly is arranged, hot gas in the heating area enters the preheating area through the air extracting pump, the connecting pipe and the air box to preheat materials, the second motor drives the reciprocating screw rod to rotate, the reciprocating screw rod drives the transmission rack to reciprocate, the transmission rack drives the transmission gear to reciprocate, the transmission gear drives the partition plate to reciprocate through the connecting shaft, so that the air outlet direction is periodically changed, raw materials which do not enter the heating area can be comprehensively preheated, the raw materials are prevented from directly entering the heating area, the burning effect of foam glass is prevented from being influenced by overlarge temperature difference, the burning effect of a kiln body is improved, meanwhile, the full utilization of redundant heat in the heating area is realized, and the cost is saved;

3. this scheme is through setting up buffering collection subassembly, the finished product falls into on the buffer board, the buffer board receives the impact back and drives the slide bar and move down, the slide bar drives the slide bar and moves down, the slide bar drives the extrusion wheel and moves down, the extrusion wheel drives the extrusion board and moves to one side, the extrusion board drives the telescopic link and moves, the extrusion board drives first spring shrink, reduce the collision kinetic energy of finished product, afterwards, the finished product falls into the buffering swash plate surface after the buffer board buffering, the finished product falls into the collecting box after buffering many times, can reduce the impact force that the finished product received, guarantee the yields of finished product.

Drawings

FIG. 1 is a schematic perspective view of a structure for embodying the present invention;

FIG. 2 is a schematic elevational cross-sectional structure for embodying the present invention;

FIG. 3 is an enlarged schematic view of the portion A of FIG. 2 for embodying the present invention;

FIG. 4 is a schematic top view cross-sectional structure for embodying the present invention;

FIG. 5 is an enlarged schematic view of the portion B of FIG. 4 for embodying the present invention;

FIG. 6 is a schematic perspective exploded view of a preheating assembly for embodying the present invention;

fig. 7 is an enlarged schematic view of the portion C of fig. 6 for embodying the present invention.

In the figure: 1. a kiln body shell; 2. a heating device; 3. a support plate; 4. a combustion fan; 5. a combustion-supporting tube; 6. a preheating assembly; 601. an air extracting pump; 602. a connecting pipe; 603. a wind outlet box; 604. a partition plate; 605. a second motor; 606. a connecting shaft; 607. a transmission gear; 608. a drive rack; 609. a first slider; 610. a first chute; 611. a reciprocating screw; 7. a transmission belt; 8. a buffer collection assembly; 801. a collection box; 802. a buffer sloping plate; 803. a telescopic rod; 804. a first spring; 805. a second chute; 806. a second slider; 807. an extrusion plate; 808. a pressing wheel; 809. a cavity; 810. a sliding plate; 811. a slide bar; 812. a buffer plate; 9. a vibration assembly; 901. extruding a block; 902. a bonding block; 903. a connecting plate; 904. a second spring; 905. a limiting plate; 906. a mounting frame; 907. a slide bar; 908. a moving wheel; 10. a first motor; 11. a blowing pipe; 12. a transfer wheel; 13. forming a template; 14. a mounting plate; 15. a partition door.

Description of the embodiments

The invention will now be further described by way of specific examples with reference to the accompanying drawings, which are given by way of illustration only and not by way of limitation.

Examples

An energy-saving foam glass foaming kiln, as shown in fig. 1-7, comprises: the kiln comprises two supporting plates 3, kiln body shells 1 are fixedly connected to the tops of the two supporting plates 3, a preheating assembly 6 is fixedly connected to one side of the tops of the kiln body shells 1, a plurality of transmission wheels 12 are rotatably connected between the two supporting plates 3 through a rotating shaft, a transmission belt 7 is connected between the transmission wheels, a plurality of mounting plates 14 are fixedly connected to the tops of the transmission belts 7, a forming template 13 is fixedly connected to the center of the tops of the mounting plates 14, vibrating assemblies 9 are arranged on two sides of the forming template 13, a buffer collecting assembly 8 is arranged on one side of the two supporting plates 3, two separation doors 15 are arranged in the kiln body shells 1, the kiln body shells 1 are divided into a residual heat zone, a heating zone and a cooling zone by the separation doors 15, a first motor 10 is fixedly connected to one side of the supporting plates 3, one end of an output shaft of the first motor 10 is fixedly connected with one side of one transmission wheel 12, heating devices 2 are fixedly arranged on two sides of the kiln body shells 1, heating devices 2 are located in the heating zone, a combustion-supporting fan 4 is fixedly connected to the tops of the kiln body shells 1, a combustion-supporting fan 5 is fixedly connected to one side of the combustion-supporting fan 4, the other side of the combustion-supporting fan 5 is fixedly connected to the other side of the combustion-supporting fan 5, the other side of the combustion-supporting fan is fixedly connected to the other side of the combustion-supporting fan 11, and the other side of the combustion-supporting fan 11 is fixedly connected to the other side of the blow pipe 11.

Wherein, vibration subassembly 9 includes a plurality of mounting brackets 906, mounting bracket 906 and mounting panel 14 top fixed connection, and sliding connection has slide bar 907 between two adjacent mounting brackets 906, slide bar 907 one end fixedly connected with connecting plate 903, one side fixedly connected with laminating piece 902 of connecting plate 903 departure slide bar 907, laminating piece 902 one side is laminated with shaping template 13 one side mutually, laminating piece 902 cross section shape is the hemisphere, laminating piece 902 is flexible plastic mat, slide bar 907 one side fixedly connected with limiting plate 905, limiting plate 905 one side is laminated with one of them mounting bracket 906 one side mutually, slide bar 907 surface cover is equipped with second spring 904, second spring 904 both ends respectively with limiting plate 905 one side and mounting bracket 906 one side fixed connection, the one end fixedly connected with movable wheel 908 that the connecting plate 903 was kept away from to the slide bar, the inboard both ends of backup pad 3 are a plurality of extrusion pieces 901, extrusion piece 901 is laminated with movable wheel 908 mutually, extrusion piece 901 cross section shape is trapezoidal.

In practical application, through setting up vibration subassembly 9, first motor 10 drives the conveyer belt 14 through transmission wheel 12 and moves, the conveyer belt 7 passes through mounting panel 14 and drives shaping template 13 and remove, simultaneously, mounting panel 14 drives slide bar 907 and drives and remove round 908, remove round 908 and move the periodic and extrusion piece 901 contact of in-process, extrusion piece 901 cooperates second spring 904 to drive slide bar 907 and makes reciprocating motion, slide bar 907 drives laminating piece 902 and knocks out vibration to shaping template 13, the vibration can make the more compact even of material filling in the shaping template 13, thereby improve the quality of finished product, simultaneously, when shaping template gets into the cooling zone, vibration subassembly 9 knocks out vibration to shaping template 13, make fashioned foam glass and shaping template 13 separation, reduce the separation degree of difficulty of finished product and shaping template 13.

Examples

The energy-saving foam glass foaming kiln is different from the embodiment 1 in that, as shown in fig. 1-2 and fig. 6-7, the preheating component 6 comprises a connecting pipe 602, one end of the connecting pipe 602 is fixedly communicated with a heating area, the other end of the connecting pipe 602 extends to a residual heat area and is connected with an air outlet box 603, an air pump 601 is fixedly connected to the middle part of the connecting pipe 602, a plurality of separation plates 604 are rotatably connected to the air outlet box 603 through a connecting shaft 606 and a bearing, a transmission gear 607 is fixedly connected to the outer surface of one end of the connecting shaft 606, a transmission rack 608 is meshed to the bottom of the transmission gear 607, the transmission rack 608 is slidably connected to one side of the air outlet box 603, one end of the transmission rack 608 is in threaded connection with a reciprocating screw 611, one end of the reciprocating screw 611 is rotatably connected to one side of the air outlet box 603, one side of the air outlet box 603 is fixedly provided with a second motor 605, one end of an output shaft of the second motor 605 extends to the inside of the air outlet box 603 through a rotating shaft and is fixedly connected with one end of the reciprocating screw 611, one side of the reciprocating screw 608 is fixedly provided with two first sliding grooves 610, one side of the first sliding grooves 610 are fixedly connected with one side of the sliding blocks 609, one side of the sliding blocks 609 is fixedly connected with one side of the inner wall 603.

In practical application, through setting up preheating assembly 6, the steam of zone of heating gets into preheating zone through connecting pipe 602 and preheats the material, and second motor 605 drives drive rack 608 reciprocating motion through reciprocating lead screw 611, and drive rack 608 drives baffle 604 through drive gear 607 and reciprocate the deflection for the play gas direction periodicity changes, can carry out all-round preheating to the raw and other materials that do not get into the zone of heating, has realized simultaneously to the make full use of the unnecessary heat in the zone of heating, has saved the cost.

Examples

The energy-saving foam glass foaming kiln is different from embodiment 1 in that, as shown in fig. 2 and 3, buffer collecting assembly 8 includes collecting box 801, collecting box 801 both sides all laminate with backup pad 3 inboard mutually, cavity 809 has been seted up to collecting box 801 bottom, sliding connection has slide plate 810 in cavity 809, slide plate 810 both sides laminate with cavity 809 inner wall mutually, slide plate 810 bottom both sides all fixedly connected with pinch roller 808, pinch roller 808 bottom laminating has pinch plate 807, pinch plate 807 cross section shape is trapezoidal, pinch plate 807 sliding connection is in cavity 809 inner wall bottom, slide plate 810 top central point puts fixedly connected with slide bar 811, slide bar 811 one end extends to collecting box 801 inside and fixedly connected with buffer plate 812, collecting box 801 inside all is fixedly connected with buffering 802, pinch plate 807 bottom fixedly connected with second slider, cavity 809 inner wall bottom has seted up second spout 805, second slider 806 sliding connection is in first spout 805, pinch plate 803 and a telescopic connection is equipped with a telescopic spring 803 and a telescopic connection profile 803, one side telescopic connection is equipped with a telescopic connection with inner wall 803 and a telescopic connection 803.

In practical application, through setting up buffering collection subassembly 8, the finished product falls into on the buffer board 812, and the buffer board 812 receives the impact back and drives slide bar 811 and move down, and slide bar 811 passes through slide plate 810 and drives extrusion wheel 808 and move down, and extrusion wheel 808 passes through extrusion plate 807 and drives first spring 804 shrink, reduces the collision kinetic energy of finished product, can reduce the impact force that the finished product received.

The working principle is that in the use, the staff puts into shaping template 13 with the material after grinding, first motor 10 drives transmission wheel 12 through the output shaft and rotates, transmission wheel 12 drives transmission belt 7 operation, transmission belt 7 moves and drives mounting panel 14 and remove, mounting panel 14 drives shaping template 13 and removes, simultaneously mounting panel 14 drives mounting bracket 906 and removes, mounting bracket 906 drives slide bar 907 drives and removes wheel 908 and remove wheel 908 and contact, the extrusion piece 901 drives and removes wheel 908 and remove the wheel 908 in the periodicity of removal in-process, simultaneously second spring 904 drives through slide bar 907 and removes wheel 908 and reset, make slide bar 907 do reciprocating motion, slide bar 907 drives connecting plate 903 and do reciprocating motion, connecting plate 903 drives laminating piece 902 and knocks moulding template 13 and vibrate, the vibration can make the material filling in the shaping template 13 more compact even.

Meanwhile, hot gas in the heating area enters the preheating area through the air pump 601, the connecting pipe 602 and the bellows to preheat materials, the second motor 605 drives the reciprocating screw 611 to rotate, the reciprocating screw 611 drives the transmission rack 608 to reciprocate, the transmission rack 608 drives the transmission gear 607 to reciprocate, and the transmission gear 607 drives the partition plate 604 to reciprocate through the connecting shaft 606, so that the air outlet direction periodically changes.

Meanwhile, the conveying belt 7 drives the forming template 13 to move from the preheating zone to the heating zone and then to enter the cooling zone, in the process, the partition door 15 is periodically closed, statistics is carried out, the combustion fan 4 is used for introducing air to the heating zone through the combustion pipe 5, combustion heating is assisted, the heating speed is improved, the other side blowing pipe 11 is used for blowing and radiating finished products in the cooling zone, cooling is assisted, when the finished products enter the cooling zone, the vibrating assembly 9 knocks the forming template 13 again, formed foam glass is separated from the forming template 13 and falls into the collecting box 801, the finished products fall into the buffer plate 812, the buffer plate 812 is subjected to impact force and then drives the sliding rod 811 to move downwards, the sliding rod 811 drives the sliding plate 810 to move downwards, the sliding plate 810 drives the extrusion wheel 808 to move downwards, the extrusion wheel 808 drives the extrusion plate 807 to move to one side, the extrusion plate 807 drives the telescopic rod 803 to move, the extrusion plate 807 drives the first spring 804 to shrink, the collision kinetic energy of the finished products is reduced, after the finished products are buffered by the buffer plate 812 and then fall into the surface of the buffer sloping plate 802, and the finished products fall into the collecting box 801 after multiple buffering.

The present embodiment is only for explanation of the present invention and is not to be construed as limiting the present invention, and modifications to the present embodiment, which may not creatively contribute to the present invention as required by those skilled in the art after reading the present specification, are all protected by patent laws within the scope of claims of the present invention.

Claims (10)

1. An energy-efficient foam glass foaming kiln, characterized by comprising: the kiln comprises two support plates (3), a kiln body housing (1) is fixedly connected to the tops of the two support plates (3), a preheating assembly (6) is fixedly connected to one side of the top of the kiln body housing (1), a plurality of transmission wheels (12) are rotatably connected between the two support plates (3) through a rotating shaft, a transmission belt (7) is connected between the plurality of transmission wheels in a transmission mode, a plurality of mounting plates (14) are fixedly connected to the tops of the transmission belts (7), a forming template (13) is fixedly connected to the center of the tops of the mounting plates (14), vibrating assemblies (9) are arranged on two sides of the forming template (13), a buffering collecting assembly (8) is arranged on one side of the two support plates (3), two separation doors (15) are arranged in the kiln body housing (1), the separation doors (15) divide the kiln body housing (1) into a residual heat zone, a heating zone and a cooling zone, a first motor (10) is fixedly connected to one side of the support plates (3), and one end of an output shaft of the first motor (10) is fixedly connected to one side of the transmission wheels (12).

Wherein, vibration subassembly (9) include a plurality of mounting brackets (906), mounting bracket (906) and mounting panel (14) top fixed connection, and sliding connection has slide bar (907) between two adjacent mounting brackets (906), slide bar (907) one end fixedly connected with connecting plate (903), one side fixedly connected with laminating piece (902) that connecting plate (903) deviate from slide bar (907), laminating piece (902) one side is laminated mutually with shaping template (13) one side, laminating piece (902) cross section shape is the hemisphere, laminating piece (902) are flexible plastic mat.

2. The energy-saving foam glass foaming kiln according to claim 1, wherein a limiting plate (905) is fixedly connected to one side of the sliding rod (907), one side of the limiting plate (905) is attached to one side of one of the mounting frames (906), a second spring (904) is sleeved on the outer surface of the sliding rod (907), and two ends of the second spring (904) are fixedly connected with one side of the limiting plate (905) and one side of the mounting frame (906) respectively.

3. The energy-saving foam glass foaming kiln according to claim 1, wherein one end of the sliding rod (907) far away from the connecting plate (903) is fixedly connected with a movable wheel (908), two ends of the inner side of the supporting plate (3) are fixedly connected with a plurality of extrusion blocks (901), the extrusion blocks (901) are attached to the movable wheel (908), and the cross section of each extrusion block (901) is trapezoid.

4. An energy-saving foam glass foaming kiln according to claim 1, characterized in that the preheating component (6) comprises a connecting pipe (602), one end of the connecting pipe (602) is fixedly communicated with the heating zone, the other end of the connecting pipe (602) extends to the residual heating zone and is connected with an air outlet box (603), an air pump (601) is fixedly connected to the middle part of the connecting pipe (602), and a plurality of partition boards (604) are rotatably connected with a bearing in the air outlet box (603) through a connecting shaft (606).

5. The energy-saving foam glass foaming kiln according to claim 4, wherein a transmission gear (607) is fixedly connected to the outer surface of one end of the connecting shaft (606), a transmission rack (608) is meshed to the bottom of the transmission gear (607), the transmission rack (608) is slidably connected to one side of the air outlet box (603), a reciprocating screw (611) is screwed to one end of the transmission rack (608), one end of the reciprocating screw (611) is rotatably connected with one side of the inner wall of the air outlet box (603), a second motor (605) is fixedly installed on one side of the air outlet box (603), and one end of an output shaft of the second motor (605) extends into the air outlet box (603) through a rotating shaft and is fixedly connected with one end of the reciprocating screw (611).

6. The energy-saving foam glass foaming kiln according to claim 5, wherein two first sliding grooves (610) are fixedly formed in one side of the transmission rack (608), a first sliding block (609) is connected in a sliding manner in the first sliding grooves (610), and one end of the first sliding block (609) is fixedly connected with one side of the inner wall of the air outlet box (603).

7. The energy-saving foam glass foaming kiln according to claim 1, wherein the buffering collection component (8) comprises a collection box (801), two sides of the collection box (801) are attached to the inner side of a supporting plate (3), a cavity (809) is formed in the bottom of the collection box (801), a sliding plate (810) is connected in a sliding mode in the cavity (809), two sides of the sliding plate (810) are attached to the inner wall of the cavity (809), two sides of the bottom of the sliding plate (810) are fixedly connected with extrusion wheels (808), the extrusion wheels (808) are attached to the bottom of the extrusion plate (807), the cross section of the extrusion plate (807) is trapezoid, the extrusion plate (807) is connected to the bottom of the inner wall of the cavity (809) in a sliding mode, a sliding rod (811) is fixedly connected to the center position of the top of the sliding plate (810), one end of the sliding rod (811) extends to the inside the collection box (801) and is fixedly connected with a buffering plate (812), and the periphery of the inside of the collection box (801) is fixedly connected to a buffering plate (802).

8. The energy-saving foam glass foaming kiln according to claim 7, wherein a second sliding block (806) is fixedly connected to the bottom of the extrusion plate (807), a second sliding groove (805) is formed in the bottom of the inner wall of the cavity (809), and the second sliding block (806) is slidably connected to the second sliding groove (805).

9. The energy-saving foam glass foaming kiln according to claim 7, wherein one side of the extrusion plate (807) is fixedly connected with a telescopic rod (803), the other end of the telescopic rod (803) is fixedly connected with one side of the inner wall of the cavity (809), a first spring (804) is sleeved on the outer surface of the telescopic rod (803), and two ends of the first spring (804) are respectively fixedly connected with one side of the inner wall of the cavity (809) and one side of the extrusion plate (807).

10. The energy-saving foam glass foaming kiln according to claim 1, wherein heating devices (2) are fixedly arranged on two sides of the kiln body shell (1), the heating devices (2) are located in heating areas, a combustion-supporting fan (4) is fixedly connected to the top of the kiln body shell (1), a combustion-supporting pipe (5) is fixedly connected to one side of the combustion-supporting fan (4), the other end of the combustion-supporting pipe (5) is communicated with the heating areas, a blowing pipe (11) is fixedly connected to the other side of the combustion-supporting fan (4), and the other end of the blowing pipe (11) is communicated with cooling areas.

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