CN211233887U - Combined transmission structure of walking beam type high-temperature sintering furnace - Google Patents

Abstract

The utility model relates to the technical field of sintering furnaces, in particular to a combined transmission structure of a walking beam type high-temperature sintering furnace, which comprises a sintering chamber, wherein a feed inlet is formed in the left side of the sintering chamber, a discharge outlet is formed in the right side of the sintering chamber, a first dust suction pipe is arranged at the top of the sintering chamber, and a plurality of second dust suction pipes are horizontally and transversely arranged in the front of the first dust suction pipe at equal intervals; the utility model discloses walking beam formula high temperature sintering furnace's combination transmission structure, first damping spring through setting up, second damping spring, balance support board and shock attenuation support column isotructure, effectual better shock attenuation effect has been played this transmission band, the shock attenuation performance of this transmission band has been promoted, the effectual powdery material that prevents on the transmission band is fallen or shakes because the vibrations power is shaken and is scattered, the device's work efficiency has been improved, the convenience is to the recovery of material, the relatively poor problem of transmission band shock attenuation effect in traditional sintering furnace has been solved.

Description

Combined transmission structure of walking beam type high-temperature sintering furnace

Technical Field

The utility model relates to a fritting furnace technical field specifically is a walking beam formula high temperature fritting furnace's combination transmission structure.

Background

Sintering furnaces refer to specialized equipment that allows powder compacts to be sintered to achieve desired physical, mechanical properties, and microstructures. The sintering furnace is used for drying slurry on a silicon wafer, removing organic components in the slurry and completing sintering of an aluminum back surface field and a grid line, and most of the existing sintering furnaces convey materials to be sintered to the sintering furnace by utilizing a conveying belt to carry out high-temperature heating.

However, most of the materials are powdery, and the transmission belt of the conventional sintering furnace can vibrate to a certain extent due to the operation of the whole sintering furnace in the transmission process, so that the powdery materials on the transmission belt are shaken down or dispersed by the vibration force, which is not beneficial to subsequent processing treatment, and therefore, a combined transmission structure of the walking beam type high-temperature sintering furnace with better damping performance needs to be designed.

SUMMERY OF THE UTILITY MODEL

The not enough to prior art, the utility model provides a walking beam formula high temperature sintering furnace's combination transmission structure possesses the good advantage of shock attenuation nature, has solved the relatively poor problem of transmission band shock attenuation effect in traditional sintering furnace.

The utility model provides a walking beam formula high temperature sintering furnace's combined transmission structure, includes the sintering chamber, the feed inlet has been seted up in the left side of sintering chamber, the discharge gate has been seted up on the right side of sintering chamber, the top of sintering chamber is provided with first dust absorption pipe, the front of first dust absorption pipe is provided with a plurality of second dust absorption pipes along horizontal equidistance, the position that is close to the feed inlet in sintering chamber left side is provided with the drive case, the position that the sintering chamber inner chamber is close to the bottom is provided with the transmission band, the bottom of sintering chamber is along horizontal equidistance fixedly connected with many supporting legss of horizontal.

The utility model discloses walking beam formula high temperature sintering furnace's combination transmission structure, wherein the inner chamber of transmission band is provided with a plurality of support cylinder along horizontal equidistance, the front and the back of transmission band left and right sides support cylinder all are connected with the bracing piece through the bearing, and this structure can utilize support cylinder to make the transmission band more stable and balanced, utilizes the bearing to make the bracing piece better be connected with support cylinder simultaneously.

The utility model discloses walking beam formula high temperature sintering furnace's combination transmission structure, wherein the position that four spinal branch vaulting poles are close to the bottom has all cup jointed first damping spring, the bottom of transmission band is provided with the balance support board, the equal fixedly connected with solid fixed ring in four corners department of balance support board, four gu fixed ring cup joints first damping spring's top on four spinal branch vaulting poles respectively, this structure can utilize first damping spring and bracing piece to have played preliminary cushioning effect to the transmission band, makes this transmission band more firm simultaneously.

The utility model discloses combination transmission structure of walking beam formula high temperature fritting furnace, wherein the top of balance support board is provided with many auxiliary drum along horizontal equidistance of level, the balance support board bottom is provided with many shock attenuation support columns along horizontal equidistance of level, the shock attenuation support column includes outer pole and interior pole, interior pole is pegged graft in the outer pole, the bottom of interior pole is provided with second damping spring, and this structure can utilize interior pole and second damping spring effectually carry out the shock attenuation to this transmission band.

The utility model discloses combination transmission structure of walking beam formula high temperature fritting furnace, wherein the equal fixedly connected with baffle in the front and the back of balance support board, be provided with between baffle and the balance support board and connect the silo, connect the front and the back that the silo is located the transmission band, this structure can utilize to connect the effectual unrestrained material powder of catching from the transmission band of silo.

The utility model discloses walking beam formula high temperature sintering furnace's combination transmission structure wherein is provided with drive gear on the bracing piece at transmission band left side back, and this drive gear meshes with the epaxial drive gear of motor output, and this structure can utilize driving motor and drive gear to make this transmission band can transmit.

Compared with the prior art, the beneficial effects of the utility model are as follows:

the utility model discloses combination transmission structure of walking beam formula high temperature fritting furnace, first damping spring through setting up, second damping spring, balance support board and shock attenuation support column isotructure, effectually play better shock attenuation effect to this transmission band, the shock attenuation performance of this transmission band has been promoted, the effectual powdery material that prevents on the transmission band is fallen or shakes and scatters because the vibrations power is shaken, the work efficiency of the device is improved, utilize the silo that connects of transmission band both sides simultaneously, the effect of protection has been played, prevent that the material from dropping because other reasons, the convenient recovery to the material, the relatively poor problem of transmission band shock attenuation effect in traditional fritting furnace has been solved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic overall side view and sectional structure of the present invention;

FIG. 2 is a schematic top view of the balance support plate of the present invention;

FIG. 3 is a schematic side view of the conveyor belt of the present invention;

fig. 4 is a schematic view of the overhead structure of the conveyor belt of the present invention;

fig. 5 is an enlarged schematic view of a portion a of fig. 1 according to the present invention;

fig. 6 is an enlarged schematic structural diagram of fig. 1 at B according to the present invention.

In the figure: 01. a sintering chamber; 02. a feed inlet; 03. a discharge port; 04. a first dust suction pipe; 05. a second dust suction pipe; 06. a drive box; 07. a support bar; 08. a conveyor belt; 09. supporting legs; 10. a balance support plate; 11. a support roller; 12. a first damping spring; 13. an auxiliary drum; 14. a baffle plate; 15. a shock-absorbing support column; 16. a material receiving groove; 17. a fixing ring; 18. a bearing; 19. a second damping spring; 20. an outer rod; 21. an inner rod.

Detailed Description

In the following description, numerous implementation details are set forth in order to provide a more thorough understanding of the present invention. It should be understood, however, that these implementation details should not be used to limit the invention. That is, in some embodiments of the invention, details of these implementations are not necessary. In addition, some conventional structures and components are shown in simplified schematic form in the drawings.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for description purposes, not specifically referring to the order or sequence, and are not intended to limit the present invention, but only to distinguish the components or operations described in the same technical terms, and are not to be construed as indicating or implying any relative importance or implicit indication of the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Please refer to fig. 1-6, the utility model discloses a combination transmission structure of walking beam formula high temperature sintering stove, including sintering chamber 01, feed inlet 02 has been seted up in sintering chamber 01's left side, discharge gate 03 has been seted up on sintering chamber 01's right side, sintering chamber 01's top is provided with first dust absorption pipe 04, first dust absorption pipe 04 openly is provided with a plurality of second dust absorption pipes 05 along horizontal equidistance, the position that sintering chamber 01 left side is close to feed inlet 02 is provided with drive box 06, the position that sintering chamber 01 inner chamber is close to the bottom is provided with transmission band 08, sintering chamber 01's bottom is along horizontal equidistance fixedly connected with many supporting legss 09.

The inner cavity of transmission band 08 is provided with a plurality of support cylinder 11 along horizontal equidistance, and the transmission band 08 left and right sides supports the front and the back of cylinder 11 and all is connected with bracing piece 07 through bearing 18, and this structure can utilize support cylinder 11 to make transmission band 08 more stable and balanced, utilizes bearing 18 to make bracing piece 07 better be connected with support cylinder 11 simultaneously.

First damping spring 12 has all been cup jointed in the position that four spinal branch vaulting poles 07 are close to the bottom, transmission band 08's bottom is provided with balance support plate 10, the solid fixed ring 17 of the equal fixedly connected with in four corners department of balance support plate 10, four solid fixed ring 17 cup joint respectively on four spinal branch vaulting poles 07 first damping spring 12's top, this structure can utilize first damping spring 12 and bracing piece 07 to have played preliminary cushioning effect to transmission band 08, make this transmission band 08 more firm simultaneously.

The top of balance support plate 10 is provided with many auxiliary drum 13 along the horizontal equidistance of level, and balance support plate 10 bottom is provided with many shock absorber support columns 15 along the horizontal equidistance of level, and shock absorber support columns 15 includes outer pole 20 and interior pole 21, and this interior pole 21 is pegged graft in outer pole 20, and the bottom of interior pole 21 is provided with second damping spring 19, and this structure can utilize interior pole 21 and the effectual shock attenuation of this transmission band 08 of second damping spring.

The front and the back of the balance support plate 10 are fixedly connected with a baffle plate 14, a material receiving groove 16 is arranged between the baffle plate 14 and the balance support plate 10, the material receiving groove 16 is positioned on the front and the back of the transmission belt 08, and the structure can effectively receive the scattered material powder from the transmission belt 08 by using the material receiving groove 16.

The driving gear is arranged on the supporting rod 07 at the back of the left side of the transmission belt 08 and meshed with the driving gear on the output shaft of the motor, and the transmission belt 08 can be transmitted by using the driving motor and the driving gear.

When using the utility model discloses the time: firstly, materials are placed on a conveying belt 08 from a feeding hole 02, a driving motor, a sintering chamber 01 switch and a first dust absorption pipe 04 switch are turned on at the same time, the materials are conveyed into the sintering chamber 01 through the conveying belt 08 to be heated at high temperature, waste gas and dust of the materials are absorbed by a second dust absorption pipe 05, and the heated materials are conveyed out through a discharging hole 03;

when the vibration force that the device produced transmits transmission band 08, transmission band 08 at first utilized the first damping spring 12 on four spinal branch vaulting poles 07 to carry out the shock attenuation, and the vibration force of transmission band 08 bottom transmits balancing support plate 10 earlier simultaneously, and balancing support plate 10 transmits the vibration force to interior pole 21 again, and interior pole 21 then transmits the vibration force to second damping spring 19, cushions the vibration force, utilizes a plurality of shock attenuation support columns 15 in balancing support plate 10 bottom effectual the vibrations that the material received on the transmission band 08 of having reduced.

The above description is only an embodiment of the present invention, and is not intended to limit the present invention. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (6)

1. The utility model provides a walking beam formula high temperature sintering furnace's combination transmission structure, includes sintering chamber (01), its characterized in that: feed inlet (02) have been seted up in the left side of sintering chamber (01), discharge gate (03) have been seted up on the right side of sintering chamber (01), the top of sintering chamber (01) is provided with first dust absorption pipe (04), the front of first dust absorption pipe (04) is provided with a plurality of second dust absorption pipes (05) along horizontal equidistance, the position that is close to feed inlet (02) in sintering chamber (01) left side is provided with drive box (06), the position that is close to the bottom in sintering chamber (01) inner chamber is provided with transmission band (08), many supporting legss (09) of horizontal equidistance fixedly connected with are followed to the bottom in sintering chamber (01).

2. The combined conveying structure of the walking-beam high-temperature sintering furnace according to claim 1, characterized in that: the inner chamber of transmission band (08) is provided with a plurality of support cylinder (11) along horizontal equidistance, the front and the back that transmission band (08) left and right sides supported cylinder (11) all are connected with bracing piece (07) through bearing (18).

3. The combined conveying structure of the walking-beam high-temperature sintering furnace according to claim 2, characterized in that: four bracing piece (07) are close to the position of bottom and all have cup jointed first damping spring (12), the bottom of transmission band (08) is provided with balance support plate (10), the equal fixedly connected with of four corners department of balance support plate (10) is solid fixed ring (17), four gu fixed ring (17) cup joint respectively on four bracing pieces (07) the top of first damping spring (12).

4. The combined conveying structure of the walking-beam high-temperature sintering furnace according to claim 3, characterized in that: the top of backup pad (10) is provided with many auxiliary drum (13) along horizontal equidistance, backup pad (10) bottom is provided with many shock attenuation support column (15) along horizontal equidistance, shock attenuation support column (15) include outer pole (20) and interior pole (21), and this interior pole (21) are pegged graft in outer pole (20), the bottom of interior pole (21) is provided with second damping spring (19).

5. The combined conveying structure of the walking-beam high-temperature sintering furnace according to claim 4, characterized in that: the front and the back of the balance support plate (10) are fixedly connected with baffle plates (14), a material receiving groove (16) is arranged between the baffle plates (14) and the balance support plate (10), and the material receiving groove (16) is located on the front and the back of the conveying belt (08).

6. The combined conveying structure of the walking-beam high-temperature sintering furnace according to claim 1, characterized in that: and a driving gear is arranged on the supporting rod (07) at the back of the left side of the transmission belt (08) and is meshed with the driving gear on the output shaft of the motor.

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