CN115876000A - Multidirectional monitoring of temperature and adjustment mechanism of pressure fritting furnace - Google Patents

Abstract

The application discloses multidirectional monitoring of temperature and adjustment mechanism of pressure fritting furnace belongs to fritting furnace technical field, including the supporting seat, the top fixed mounting of supporting seat has the stove outer covering, the inside fixed mounting of stove outer covering has the furnace body, the top fixed mounting of supporting seat has the PLC controller, fixed mounting has the transmission box on the roof in the middle part of stove outer covering, fixed mounting has the drive box on the middle part outer roof of stove outer covering, the screw thread is installed on the actuating lever and is pull the box, the top fixed mounting who pulls the box has the traction frame, the first temperature sensor of inner arc lateral wall top fixed mounting of traction frame, movable mounting has the second temperature sensor on the traction frame, be provided with the angle adjusting part on the traction frame. This application can realize the dynamic monitoring of many temperature sensor multi-angles to the interior temperature of stove outer covering, can obtain more accurate stove outer covering temperature data, is favorable to improving the sintering quality of product, has improved the practicality.

Description

Multidirectional monitoring of temperature and adjustment mechanism of pressure fritting furnace

Technical Field

The application relates to the technical field of sintering furnaces, in particular to a temperature multidirectional monitoring and adjusting mechanism of a pressure sintering furnace.

Background

The sintering furnace is generally divided into a continuous sintering furnace and an intermittent sintering furnace according to the difference of the blank moving modes, wherein the common intermittent sintering furnace comprises a bell jar furnace, a vacuum furnace and the like, and the working cycle of opening the furnace, feeding the blank into the furnace, sintering and discharging sintered parts is carried out according to a certain time interval;

the utility model discloses a grant publication number CN 211177893U's utility model discloses a fritting furnace, it includes outer stove, heating mechanism, mechanism of taking a breath and control mechanism, outer stove includes outer stove main part, supporting seat, furnace gate and hinge, the supporting seat is connected with outer stove main part bottom sprag, and outer stove main part side is located to the furnace gate, hinge mount in outer stove main part top and with furnace gate swing joint, heating mechanism includes heating pipe, heat-conducting plate and support, outer stove main part bottom and top are located to the heating pipe, and the heat-conducting plate covers in the heating pipe surface, the heat-conducting plate top is located to the support, the mechanism of taking a breath includes intake pipe, air pump and blast pipe, the left side of outer stove main part is located to the intake pipe and pierces through the oven wall, and the air pump is installed at outer stove main part top, and air pump and blast pipe are connected, control mechanism includes control box and temperature sensor, the control box is connected with the outer stove side, and temperature sensor hangs inside outer stove main part.

Among the above-mentioned technical scheme, through setting up temperature sensor, the control box, mechanism and exhaust mechanism admit air, the monitoring and the control to the interior temperature of stove have been realized, however, because the heating pipe only sets up on the interior diapire of stove shell, lead to in the heating process, the temperature on stove lower part and upper portion has certain difference, consequently, only set up temperature sensor in the one end of roof in the stove shell, can not be effective accurate carry out real-time supervision to the internal temperature of stove, single temperature data, the data record and the processing operation that probably influence the staff, and then probably influence the sintering quality of product.

Disclosure of Invention

In order to solve the above problems, the present application provides a multidirectional monitoring and adjusting mechanism of temperature of pressure sintering stove, adopts following technical scheme:

a multidirectional temperature monitoring and adjusting mechanism of a pressure sintering furnace comprises a supporting seat, wherein a furnace shell is fixedly mounted at the top of the supporting seat, a furnace body is fixedly mounted inside the furnace shell, a plurality of heating pipes which are distributed in an array manner are fixedly mounted on the inner bottom wall of the furnace shell, the heating pipes are matched with the furnace body, a PLC (programmable logic controller) is fixedly mounted at the top of the supporting seat, and the heating pipes are electrically connected with the PLC;

the furnace shell is characterized in that a transmission box is fixedly arranged on the middle inner top wall of the furnace shell, a driving box is fixedly arranged on the middle outer top wall of the furnace shell and is communicated with the transmission box, two groups of symmetrically-distributed supports are fixedly arranged on the inner top wall of the furnace shell and are respectively positioned at two ends of the transmission box, the number of each group of supports is two, and a driving rod is rotatably arranged between the two supports in the same group;

be provided with the rotation drive assembly with the actuating lever adaptation between drive box and the transmission box, the box is pull in threaded mounting on the actuating lever, the top fixed mounting who pulls the box has the traction frame, and the traction frame is convex structure along the inner wall of stove outer covering, the first temperature sensor of inner arc lateral wall top fixed mounting of traction frame, movable mounting has the second temperature sensor on the traction frame, first temperature sensor and second temperature sensor all with PLC controller electric connection, be provided with the angle adjusting part with the adaptation of second temperature sensor on the traction frame.

Through adopting above-mentioned technical scheme, set up two first temperature sensor and two second temperature sensor at the stove outer covering internalization to carry out angle modulation to the second temperature sensor through angle modulation subassembly, realize the multidirectional temperature monitoring in the heating process, and carry out data record through the PLC controller, can obtain more accurate stove outer covering internal temperature data, be favorable to improving the sintering quality of product.

Further, rotate the drive assembly and install the drive shaft between transmission box both ends inner wall including rotating, and the both ends of drive shaft respectively with two coaxial fixed connection of actuating lever, fixed mounting has first driven gear in the drive shaft, the outer roof of stove outer covering is improved level fixed mounting and is had the motor, and motor and PLC controller electric connection, the motor is located the inside of drive box, fixed mounting has first drive gear on the output shaft of motor, install first chain between first drive gear and the first driven gear.

Through adopting above-mentioned technical scheme, opening of PLC controller control motor stops, and the motor drives first drive gear and rotates, utilizes first chain and first driven gear's transmission, and the drive shaft that drives rotates, and then can drive the actuating lever and rotate.

Furthermore, a supporting block is fixedly installed on the outer top wall of the furnace shell and is rotatably connected with the end part of the output shaft of the motor.

Through adopting above-mentioned technical scheme, the supporting shoe can effectively improve the stability of motor during operation.

Furthermore, two the actuating lever is the symmetric distribution, two the second temperature sensor is the contralateral distribution on the traction frame.

By adopting the technical scheme, the two supports move in the opposite direction or in the opposite direction.

Further, the angle adjusting assembly installs in the second drive gear of drawing the bottom of the box portion including rotating, set up the transmission slewing mechanism with second drive gear adaptation between support and the transmission box, the cavity has been seted up to the inside of traction frame, the inside fixed mounting of traction frame has the baffle, and the baffle extends along the radian direction of the traction frame of traction frame, the second chain is installed around establishing to the both sides of baffle, and second chain and second drive gear meshing, fixed mounting has the pinion rack on the second chain, the one end of pinion rack runs through the outside and the second temperature sensor fixed connection that extend to the traction frame, set up the movable arc groove with second chain movement track adaptation on the lateral wall of traction frame.

Through adopting above-mentioned technical scheme, utilize transmission slewing mechanism to make second drive gear rotate, utilize the transmission of second drive gear and second chain, drive the pinion rack motion, and then can drive second temperature sensor and move along the activity arc groove, realize the change of operating position and direction.

Further, transmission slewing mechanism installs the gag lever post between two supports including rotating, and the gag lever post slides and runs through second drive gear, the fixed spacing strip that is a plurality of annular array distributions that is provided with on the circumference outer wall of gag lever post, set up the spacing groove with spacing strip adaptation on second drive gear's the circumference inner wall, the tip of gag lever post runs through and extends to in the transmission box, fixed mounting has intermeshing's drive gear between gag lever post and the drive shaft.

Through adopting above-mentioned technical scheme, utilize drive gear's effect for the gag lever post can rotate, recycles spacing effect, makes the gag lever post can drive second drive gear and rotates, simultaneously, draws the box translation slip on the gag lever post.

Furthermore, the inside fixed mounting of traction frame has two guide cylinder that are the symmetric distribution, and two guide cylinder are located the both ends of baffle respectively, the both ends of second chain are around establishing on two guide cylinder.

Through adopting above-mentioned technical scheme, the guide cylinder is favorable to improving the smoothness nature of second chain activity.

Furthermore, the bottoms of the two groups of supports are fixedly provided with supporting plates, and the supporting plates are matched with the traction frame.

Through adopting above-mentioned technical scheme, the backup pad can play certain support effect to the traction frame, is favorable to improving the stability of traction frame motion.

Furthermore, the supporting plate is fixedly connected with the inner wall of the furnace shell, and a plurality of hollow grooves distributed in a linear array are formed in one side, close to the inner wall of the furnace shell, of the supporting plate.

Through adopting above-mentioned technical scheme, the fretwork groove of backup pad is convenient for the heat circulation.

Further, with two equal fixed mounting have two spacing lagging that are the symmetric distribution between the support, fixed mounting has two spacing cardboards that are the symmetric distribution on the outer arc lateral wall of traction frame, spacing cardboard is T type structure, and spacing cardboard and spacing lagging adaptation.

Through adopting above-mentioned technical scheme, when the traction frame activity, spacing cardboard extends the activity of spacing lagging, is favorable to improving the stability of traction frame motion.

To sum up, this application includes following beneficial technological effect:

1. according to the temperature monitoring device, under the action of the support, the transmission box, the driving rod, the traction box, the traction frame, the first temperature sensor, the second temperature sensor, the rotation driving assembly and the angle adjusting assembly, dynamic monitoring of the temperature in the furnace shell by multiple temperature sensors in multiple angles is achieved, data recording is conducted through the PLC, more accurate temperature data in the furnace shell can be obtained, the sintering quality of a product is improved, and the practicability is improved;

2. under the action of the supporting plate, the traction frame can be supported to a certain extent, and the motion stability of the traction frame is improved;

3. this application is under the effect of spacing lagging and spacing cardboard, and when the traction frame activity, spacing cardboard extends spacing lagging activity, is favorable to improving the stability of traction frame motion, has improved the practicality.

Drawings

FIG. 1 is a schematic overall structure of the present application;

FIG. 2 is a schematic cross-sectional structural view of the present application;

FIG. 3 is a schematic view of the installation structure of the furnace body and the furnace shell of the present application;

FIG. 4 is a schematic view of the installation structure of the adjusting bracket and the furnace shell of the present application;

FIG. 5 is an enlarged view of A in FIG. 4 of the present application;

FIG. 6 is a schematic view of the mounting structure of the rotary drive assembly of the present application;

FIG. 7 is an enlarged view of B in FIG. 4 of the present application;

FIG. 8 is a schematic view of the mounting structure of the angle adjustment assembly of the present application;

FIG. 9 is an enlarged view of C in FIG. 8 of the present application;

fig. 10 is a schematic view of a mounting structure of a second temperature sensor and a toothed plate of the present application;

fig. 11 is a schematic view of an installation structure of the limiting sleeve plate and the limiting clamping plate.

The reference numbers in the figures illustrate:

1. a supporting base; 2. a furnace shell; 3. a furnace body; 4. heating a tube; 5. a PLC controller; 6. a transmission box; 7. a drive cartridge; 8. a support; 9. a drive rod; 10. a traction box; 11. a traction frame; 12. a first temperature sensor; 13. a second temperature sensor; 14. a drive shaft; 15. a first driven gear; 16. a motor; 17. a first drive gear; 18. a first chain; 19. a support block; 20. a second drive gear; 21. a partition plate; 22. a second chain; 23. a toothed plate; 24. a movable arc groove; 25. a limiting rod; 26. a limiting strip; 27. a limiting groove; 28. a transmission gear; 29. a guide cylinder; 30. a support plate; 31. a limiting sleeve plate; 32. a limiting clamping plate.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application; it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all embodiments, and all other embodiments obtained by those of ordinary skill in the art without any inventive work based on the embodiments in the present application belong to the protection scope of the present application.

In the description of the present application, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present application. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; 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 this application will be understood to be a specific case for those of ordinary skill in the art.

The present application is described in further detail below with reference to figures 1-11.

Referring to fig. 1-11, a multidirectional temperature monitoring and adjusting mechanism for a pressure sintering furnace includes a supporting seat 1, a furnace shell 2 is fixedly installed on the top of the supporting seat 1, a furnace body 3 is fixedly installed inside the furnace shell 2, a plurality of heating pipes 4 distributed in an array are fixedly installed on the inner bottom wall of the furnace shell 2, the heating pipes 4 are adapted to the furnace body 3, a PLC controller 5 is fixedly installed on the top of the supporting seat 1, and the heating pipes 4 are electrically connected with the PLC controller 5;

the middle inner top wall of the furnace shell 2 is fixedly provided with a transmission box 6, the middle outer top wall of the furnace shell 2 is fixedly provided with a driving box 7, the driving box 7 is communicated with the transmission box 6, the inner top wall of the furnace shell 2 is fixedly provided with two groups of symmetrically distributed supports 8, the two groups of supports 8 are respectively positioned at two ends of the transmission box 6, the number of each group of supports 8 is two, and a driving rod 9 is rotatably arranged between the two supports 8 of the same group;

be provided with the rotation drive assembly with actuating lever 9 adaptation between drive box 7 and the transmission box 6, the rotation drive assembly is including rotating the drive shaft 14 of installing between the inner wall of drive box 6 both ends, and the both ends of drive shaft 14 respectively with two coaxial fixed connection of drive lever 9, fixed mounting has first driven gear 15 on the drive shaft 14, outer roof of stove outer covering 2 is improved level fixed mounting has motor 16, and motor 16 and PLC controller 5 electric connection, motor 16 is located the inside of drive box 7, fixed mounting has first drive gear 17 on the output shaft of motor 16, install first chain 18 between first drive gear 17 and the first driven gear 15, start-stop of PLC controller 5 control motor 16, motor 16 drives first drive gear 17 and rotates, utilize the transmission of first chain 18 and first driven gear 15, drive shaft 14 rotates, and then can drive actuating lever 9 and rotate, fixed mounting 19 on outer roof of stove outer covering 2, and supporting shoe 19 and the output shaft end portion rotation connection of motor 16, can effectively improve the stability of motor 16 during operation, and two 9 are the symmetric distribution, and then can make two supports 8 move in opposite directions or show the motion mutually.

The box 10 that pulls is installed to the screw thread on the actuating lever 9, and the top fixed mounting who pulls box 10 has traction frame 11, and traction frame 11 is arc structure along the inner wall of stove outer covering 2, the first temperature sensor 12 of inner arc lateral wall top fixed mounting of traction frame 11, and movable mounting has second temperature sensor 13 on traction frame 11, and first temperature sensor 12 and second temperature sensor 13 all carry out data record with PLC controller 5 electric connection through PLC controller 5.

An angle adjusting component adaptive to the second temperature sensor 13 is arranged on the traction frame 11, the angle adjusting component comprises a second driving gear 20 rotatably arranged at the bottom of the traction box 10, a transmission rotating mechanism adaptive to the second driving gear 20 is arranged between the support 8 and the transmission box 6, the transmission rotating mechanism comprises a limiting rod 25 rotatably arranged between the two supports 8, the limiting rod 25 penetrates through the second driving gear 20 in a sliding manner, a plurality of limiting strips 26 distributed in an annular array manner are fixedly arranged on the circumferential outer wall of the limiting rod 25, a limiting groove 27 adaptive to the limiting strips 26 is formed in the circumferential inner wall of the second driving gear 20, the end part of the limiting rod 25 penetrates and extends into the transmission box 6, mutually meshed transmission gears 28 are fixedly arranged between the limiting rod 25 and the driving shaft 14, the limiting rod 25 can rotate by the action of the transmission gears 28, and then the action of the limiting strips 26 is utilized, so that the limiting rod 25 can drive the second driving gear 20 to rotate, two guide cylinders 29 which are symmetrically distributed are fixedly arranged inside the traction frame 11, the two guide cylinders 29 are respectively positioned at two ends of the partition plate 21, two ends of the second chain 22 are wound on the two guide cylinders 29, which is beneficial to improving the fluency of the movement of the second chain 22, a cavity is arranged inside the traction frame 11, the partition plate 21 is fixedly arranged inside the traction frame 11, the partition plate 21 extends along the radian direction of the traction frame 11, the second chain 22 is wound and arranged at two sides of the partition plate 21, the second chain 22 is meshed with the second driving gear 20, a toothed plate 23 is fixedly arranged on the second chain 22, one end of the toothed plate 23 penetrates through and extends to the outside of the traction frame 11 and is fixedly connected with the second temperature sensor 13, a movable arc groove 24 matched with the movement track of the second chain 22 is arranged on the outer side wall of the traction frame 11, utilize the transmission of second drive gear 20 and second chain 22, drive pinion rack 23 motion, and then can drive second temperature sensor 13 and move along activity arc groove 24, realize realizing the change of operating position and direction, and two second temperature sensor 13 are offside distribution on traction frame 11, can more effectively realize the temperature monitoring of the interior multiposition of stove outer covering 2 when the motion, have improved the practicality.

The bottom parts of the two groups of supports 8 are fixedly provided with the supporting plates 30, the supporting plates 30 are matched with the traction frame 11, a certain supporting effect can be achieved on the traction frame 11, the improvement of the motion stability of the traction frame 11 is facilitated, the supporting plates 30 are fixedly connected with the inner wall of the furnace shell 2, and one side, close to the inner wall of the furnace shell 2, of the supporting plates 30 is provided with a plurality of hollow grooves which are distributed in a linear array mode, so that heat circulation is facilitated; equal fixed mounting has two spacing lagging 31 that are the symmetric distribution between two supports 8 of same set, and fixed mounting has two spacing cardboard 32 that are the symmetric distribution on the outer arc lateral wall of traction frame 11, and spacing cardboard 32 is T type structure, and spacing cardboard 32 and spacing lagging 31 adaptation, and when traction frame 11 activity, spacing cardboard 32 extends spacing lagging 31 activity, is favorable to further improving the stability of traction frame 11 motion.

The implementation principle of the embodiment of the application is as follows: in the heating process of heating pipe 4, through rotating drive assembly, angle adjusting element's effect, make two second temperature sensor 13 can move about along traction frame 11, realize multidirectional temperature monitoring, and simultaneously, traction frame 11 extends the activity of actuating lever 9, can change first temperature sensor 12 and second temperature sensor 13's position, can obtain more temperature monitoring data, intermittent type driving motor 16 reversal, can realize first temperature sensor 12 and second temperature sensor 13's reciprocating motion, finally accomplish the data record through PLC controller 5, can effectively obtain more comprehensive temperature data in the stove outer covering 2, be favorable to improving the sintering quality of product, the practicality has been improved.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a multidirectional monitoring of temperature and adjustment mechanism of pressure fritting furnace, includes supporting seat (1), its characterized in that: the furnace shell (2) is fixedly installed at the top of the supporting seat (1), the furnace body (3) is fixedly installed inside the furnace shell (2), a plurality of heating pipes (4) distributed in an array mode are fixedly installed on the inner bottom wall of the furnace shell (2), the heating pipes (4) are matched with the furnace body (3), the PLC (programmable logic controller) (5) is fixedly installed at the top of the supporting seat (1), and the heating pipes (4) are electrically connected with the PLC (5);

the furnace shell structure is characterized in that a transmission box (6) is fixedly mounted on the middle inner top wall of the furnace shell (2), a driving box (7) is fixedly mounted on the middle outer top wall of the furnace shell (2), the driving box (7) is communicated with the transmission box (6), two groups of symmetrically distributed supports (8) are fixedly mounted on the inner top wall of the furnace shell (2), the two groups of supports (8) are respectively located at two ends of the transmission box (6), the number of each group of supports (8) is two, and a driving rod (9) is rotatably mounted between the two supports (8) of the same group;

be provided with the rotation drive assembly with actuating lever (9) adaptation between drive box (7) and transmission box (6), screw thread installation is gone up in actuating lever (9) pulls box (10), the top fixed mounting who pulls box (10) has traction frame (11), and traction frame (11) are convex structure along the inner wall of stove outer covering (2), the first temperature sensor (12) of inner arc lateral wall top fixed mounting of traction frame (11), movable mounting has second temperature sensor (13) on traction frame (11), first temperature sensor (12) and second temperature sensor (13) all with PLC controller (5) electric connection, be provided with the angle adjusting part with second temperature sensor (13) adaptation on traction frame (11).

2. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 1, characterized in that: rotate drive assembly including rotating drive shaft (14) of installing between transmission box (6) both ends inner wall, and the both ends of drive shaft (14) respectively with two actuating lever (9) coaxial fixed connection, fixed mounting has first driven gear (15) on drive shaft (14), fixed mounting is improved level on the outer roof of stove outer covering (2) has motor (16), and motor (16) and PLC controller (5) electric connection, motor (16) are located the inside of drive box (7), fixed mounting has first drive gear (17) on the output shaft of motor (16), install first chain (18) between first drive gear (17) and first driven gear (15).

3. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 2, characterized in that: and a supporting block (19) is fixedly arranged on the outer top wall of the furnace shell (2), and the supporting block (19) is rotatably connected with the end part of an output shaft of the motor (16).

4. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 2, characterized in that: the two driving rods (9) are symmetrically distributed, and the two second temperature sensors (13) are distributed on the opposite side of the traction frame (11).

5. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 4, characterized in that: the angle adjusting assembly installs in second drive gear (20) of pulling box (10) bottom including rotating, set up the transmission slewing mechanism with second drive gear (20) adaptation between support (8) and transmission box (6), the cavity has been seted up to the inside of traction frame (11), the inside fixed mounting of traction frame (11) has baffle (21), and baffle (21) extend along the radian direction of traction frame (11), the both sides of baffle (21) are around establishing and installing second chain (22), and second chain (22) and second drive gear (20) meshing, fixed mounting has pinion rack (23) on second chain (22), the one end of pinion rack (23) runs through the outside and second temperature sensor (13) fixed connection that extend to traction frame (11), set up movable arc groove (24) with second chain (22) movement track adaptation on the lateral wall of traction frame (11).

6. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 5, characterized in that: the utility model discloses a transmission box, including the transmission slewing mechanism install gag lever post (25) between two supports (8) including rotating, and gag lever post (25) slide and run through second drive gear (20), the fixed spacing strip (26) that are the annular array and distribute that are provided with a plurality ofly on the circumference outer wall of gag lever post (25), offer spacing groove (27) with spacing strip (26) adaptation on the circumference inner wall of second drive gear (20), the tip of gag lever post (25) runs through and extends to in transmission box (6), fixed mounting has intermeshing's drive gear (28) between gag lever post (25) and drive shaft (14).

7. The multidirectional monitoring and adjusting mechanism for the temperature of the pressure sintering furnace according to claim 5, characterized in that: the inside fixed mounting of traction frame (11) has two direction cylinder (29) that are the symmetric distribution, and two direction cylinder (29) are located the both ends of baffle (21) respectively, the both ends of second chain (22) are around establishing on two direction cylinder (29).

8. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 1, characterized in that: the bottom of the two groups of the brackets (8) is fixedly provided with a support plate (30), and the support plate (30) is matched with the traction frame (11).

9. The temperature multidirectional monitoring and adjusting mechanism of the pressure sintering furnace according to claim 8, wherein: the support plate (30) is fixedly connected with the inner wall of the furnace shell (2), and one side of the support plate (30) close to the inner wall of the furnace shell (2) is provided with a plurality of hollow grooves distributed in a linear array.

10. The multidirectional monitoring and adjusting mechanism for the temperature of the pressure sintering furnace according to claim 1, characterized in that: the same two of a set of equal fixed mounting has two spacing lagging (31) that are the symmetric distribution between support (8), fixed mounting has two spacing cardboard (32) that are the symmetric distribution on the outer arc lateral wall of traction frame (11), spacing cardboard (32) are T type structure, and spacing cardboard (32) and spacing lagging (31) adaptation.

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