CN211806792U - Fireproof window filler module forming machine - Google Patents

Abstract

The utility model discloses a fireproof window filler module forming machine, which comprises a frame, a workbench, a blanking mechanism, a feeding channel, a die cavity adjusting mechanism and a material pressing mechanism; the workbench is arranged on the frame; a die cavity is arranged on the workbench; the feeding channel is arranged on the workbench; a blanking mechanism is connected above one end of the feeding channel; the other end of the feeding channel is connected to the die cavity; a material pressing mechanism is arranged above the die cavity in a reciprocating manner up and down; the bottom of the die cavity is vertically movably provided with a die cavity adjusting mechanism; a material pushing mechanism is horizontally and reciprocally arranged in the feeding channel; a cleaning scraper is arranged at the bottom of the material pushing mechanism; the utility model discloses the technical scheme who takes has solved the refractory powder and has been difficult for resulting in the problem that packing efficiency is low by the compaction in the fire window, and produces the problem that the raise dust leads to the influence environment easily at the refractory material of powder at the pay-off.

Description

Fireproof window filler module forming machine

Technical Field

The utility model relates to a fire window processing equipment technical field, concretely relates to fire window packs module make-up machine.

Background

A fire window is a window that, in conjunction with a frame, meets the requirements of fire stability and fire integrity over a period of time. Most of the existing fireproof windows adopt aluminum alloy profiles as frame materials, and because the profiles have cavities, the heat-resistant and fireproof performances of the fireproof window frame can be improved in a mode of filling fireproof materials in the cavities. At present, most of filling materials such as heavy filling materials, steel linings, liquid silica gel and the like are filled in a cavity of a bridge-cut aluminum alloy non-heat-insulation fireproof window. The above materials have the advantages of applicability and the disadvantages of the above materials which are difficult to overcome. The heavy filling material has good strength, but the heat insulation performance of the heavy filling material is too poor, the whole weight is increased, particularly, the bearing capacity of a window sash on hardware and a window closer is tested after the weight is increased, the quality of the heavy filling materials on the market is uneven, and the corrosion problem of aluminum alloy is not considered at all for some heavy filling materials, so that some filling materials cause serious corrosion to the aluminum alloy window in a short time. Although the strength of the added steel lining is good, the weight of the steel lining is particularly heavy, and the steel lining is easy to bend after meeting high temperature, so that secondary damage is caused to the aluminum alloy fireproof door and window, and the specified fireproof time cannot be achieved under the condition of fire. The liquid silica gel has good filling performance, but the state is jelly shape, has no structural strength, and can not effectively support the fireproof glass of the fireproof door and window.

In order to improve the filling effect, various refractory powder materials can be filled into the cavity; but the problem of low filling efficiency is caused by the fact that the refractory powder is not easy to compact in the fireproof window, and the problem of environmental influence caused by dust easily generated during feeding of the refractory material of the powder is solved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a fire window filler module make-up machine solves the fire-resistant powder and is difficult for being leaded to the problem that packing efficiency is low by the compaction in the fire window, and produces the problem that the raise dust leads to the influence environment easily at the refractory material of powder at the pay-off.

In order to solve the technical problem, the utility model adopts the following technical scheme: a fireproof window filler module forming machine comprises a frame, a workbench, a blanking mechanism, a feeding channel, a die cavity adjusting mechanism and a pressing mechanism; the workbench is arranged on the frame; a die cavity is arranged on the workbench; the feeding channel is arranged on the workbench; a blanking mechanism is connected above one end of the feeding channel; the other end of the feeding channel is connected to the die cavity; a material pressing mechanism is arranged above the die cavity in a reciprocating manner up and down; the bottom of the die cavity is vertically movably provided with a die cavity adjusting mechanism; a material pushing mechanism is horizontally and reciprocally arranged in the feeding channel; a cleaning scraper is arranged at the bottom of the material pushing mechanism;

the blanking mechanism comprises a blanking hopper and a stirring mechanism arranged in the blanking hopper; the stirring mechanism comprises a motor and a stirring rod; the motor drives the stirring rod to rotate in the blanking hopper; the discharge hole of the discharging hopper is communicated with the feeding channel;

the blanking hopper is also provided with a dust guard; the dust guard comprises a fixed plate and a movable plate; an accommodating cavity is formed in the fixing plate; the movable plate is movably accommodated in the accommodating cavity;

a first lantern ring is arranged on one side edge of the fixing plate; a second lantern ring is arranged on one side edge of the movable plate; the stirring rod penetrates through the first sleeve ring and the second sleeve ring; the movable plate is rotatably arranged at the upper end of the blanking hopper around the stirring rod;

the edges of two sides of the upper surface of the cleaning scraper are provided with cut angles; soft cleaning bristles are arranged on the lower surface of the cleaning scraper; the cleaning bristles are contacted with the bottom of the feeding channel;

the die cavity adjusting mechanism comprises a hydraulic telescopic component and a resisting block; the hydraulic telescopic component drives the abutting block to slide up and down in the die cavity to form a die cavity with adjustable depth;

the hydraulic telescopic assembly comprises a supporting plate, a first hydraulic cylinder, a first telescopic rod and a connecting plate; the support plate is erected on the machine frame below the workbench; the first hydraulic cylinder is arranged on the support plate; one end of the first telescopic rod is connected to the first hydraulic cylinder, and the other end of the first telescopic rod is connected to the connecting plate; the connecting plate is connected with the abutting block;

the material pressing mechanism comprises a hydraulic driving mechanism and a pressing block; the hydraulic driving mechanism comprises a second hydraulic cylinder and a second telescopic rod; the second telescopic rod is connected with the pressing block and driven to reciprocate above the die cavity; the pressing block is matched with the die cavity;

the two sides of the pressing block are horizontally provided with connecting lugs in an extending manner; the connecting lug is provided with a limiting hole; a positioning screw rod is movably arranged in the limiting hole up and down; the positioning screw rod is fixed through a nut;

a positioning groove is arranged on the surface of the workbench corresponding to the positioning screw rod; a damping sleeve is detachably arranged in the positioning groove; the outer wall of the damping sleeve is connected with the inner wall of the positioning groove through threads.

Compared with the prior art, the beneficial effects of the utility model are one of following at least:

1. before the powdery refractory material is filled into a window frame, the powdery refractory material is firstly pressed into a refractory block with certain volume and density by a module forming machine, and then the refractory block is filled into the window frame, so that the refractory material can be quickly and compactly stacked in the window frame, the filling efficiency of the refractory material in the window frame is improved, meanwhile, the powdery refractory material is firstly fixed into a certain shape instead of scattered powder, the dust generated during the conveying and filling of the refractory material is reduced, and the air environment quality around equipment is maintained;

2. the blanking mechanism is used for blanking the feeding channel quantitatively, the powder refractory material in the feeding channel is pushed into the die cavity through the material pushing mechanism, and then the die cavity is extruded by the material pressing mechanism to form a refractory block with a certain shape;

3. the die cavity adjusting mechanism arranged at the bottom of the die cavity can adjust the depth in the die cavity so as to adjust the thickness of the refractory block as required; meanwhile, the die cavity adjusting mechanism also records the function of outputting the refractory blocks, and after the refractory blocks are molded in the die cavity, the die cavity adjusting mechanism moves upwards to push out the refractory blocks and then send the refractory blocks to a filling station;

4. the cleaning scraper blade arranged at the bottom of the material pushing mechanism 7 is beneficial to scraping and pushing the powder refractory material to move to the filling station, is beneficial to reducing the leakage of the powder refractory material, and is beneficial to improving the feeding effect.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic diagram of a dust-proof plate structure.

Fig. 3 is a schematic view of the structure of a feeding channel.

Fig. 4 is a schematic structural view of a mold cavity adjusting mechanism.

Fig. 5 is a schematic structural view of the pressing mechanism.

In the drawings: 1. a frame; 2. a work table; 3. a blanking mechanism; 301. feeding a hopper; 302. a motor; 303. a stirring rod; 4. a feed channel; 5. a mold cavity adjusting mechanism; 501. a resisting block; 502. a support plate; 503. a first hydraulic cylinder; 504. a first telescopic rod; 505. a connecting plate; 6. a material pressing mechanism; 601. briquetting; 602. a second hydraulic cylinder; 603. a second telescopic rod; 604. connecting lugs; 605. positioning a screw rod; 7. a material pushing mechanism; 8. a cleaning blade; 9. a dust-proof plate; 901. a fixing plate; 902. a movable plate; 903. an accommodating chamber; 904. a first collar; 905. a second collar; 10. cleaning the bristles; 11. positioning a groove; 12. shock attenuation cover.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1: as shown in fig. 1 to 5, a fire window filler module forming machine comprises a frame 1, a workbench 2, a blanking mechanism 3, a feeding channel 4, a mold cavity adjusting mechanism 5 and a pressing mechanism 6; the workbench 2 is arranged on the frame 1; a die cavity is arranged on the workbench 2; the feeding channel 4 is arranged on the workbench 2; a blanking mechanism 3 is connected above one end of the feeding channel 4; the other end of the feeding channel 4 is connected to a die cavity; a material pressing mechanism 6 is arranged above the die cavity in a reciprocating manner up and down; the bottom of the die cavity is vertically movably provided with a die cavity adjusting mechanism 5; a material pushing mechanism 7 is horizontally and reciprocally arranged in the feeding channel 4; a cleaning scraper 8 is arranged at the bottom of the material pushing mechanism 7; before the powdery refractory material is filled into a window frame, the powdery refractory material is firstly pressed into a refractory block with certain volume and density by a module forming machine, and then the refractory block is filled into the window frame, so that the refractory material can be quickly and compactly stacked in the window frame, the filling efficiency of the refractory material in the window frame is improved, meanwhile, the powdery refractory material is firstly fixed into a certain shape instead of scattered powder, the dust generated during the conveying and filling of the refractory material is reduced, and the air environment quality around equipment is maintained; the blanking mechanism 3 is used for blanking the feeding channel 4 quantitatively, powder refractory materials in the feeding channel 4 are pushed into the die cavity through the material pushing mechanism 7, and then the die cavity is extruded by the material pressing mechanism 6 to form a refractory block with a certain shape; the die cavity adjusting mechanism 5 arranged at the bottom of the die cavity can adjust the depth in the die cavity so as to adjust the thickness of the refractory block as required; meanwhile, the die cavity adjusting mechanism 5 also records the function of outputting the refractory blocks, and after the refractory blocks are molded in the die cavity, the die cavity adjusting mechanism 5 moves upwards to push out the refractory blocks and then sends the refractory blocks to a filling station; the cleaning scraper blade 8 arranged at the bottom of the material pushing mechanism 7 is beneficial to scraping and pushing the powder refractory material to move to the filling station, is beneficial to reducing the leakage of the powder refractory material, and is beneficial to improving the feeding effect.

The blanking mechanism 3 comprises a blanking hopper 301 and a stirring mechanism arranged in the blanking hopper 301; the stirring mechanism comprises a motor 302 and a stirring rod 303; the motor 302 drives the stirring rod 303 to rotate in the blanking hopper 301; the discharge hole of the discharge hopper 301 is communicated with the feeding channel 4; in this embodiment, the motor 302 of the stirring mechanism is disposed above the lower hopper 301, and drives the stirring rod 303 to stir in the lower hopper 301, which is beneficial to avoiding agglomeration of the powder material in the lower hopper 301; in this embodiment, the discharge hopper 301 is a conventional quantitative discharge hopper 301, and in this embodiment, any reasonable connection manner such as hose connection may be adopted as the connection manner between the discharge port of the discharge hopper 301 and the interior of the feeding channel 4.

The blanking hopper 301 is also provided with a dust guard 9; the dust guard 9 comprises a fixed plate 901 and a movable plate 902; an accommodating cavity 903 is formed in the fixing plate 901; the movable plate 902 is movably accommodated in the accommodating cavity 903; the dust guard plate 9 arranged at the upper end of the blanking hopper 301 is beneficial to blocking the raised dust generated by blanking and stirring in the blanking hopper 301, and is beneficial to improving the cleanness of the processing environment; in this embodiment, the fixed plate 901 and the movable plate 902 are both semicircular, the radius of the fixed plate 901 is larger than that of the movable plate 902, the fixed plate 901 is fixedly arranged at the upper end of the blanking hopper 301, the movable plate 902 is rotatably arranged and movably housed in the housing cavity 903, and after the movable plate 902 is rotated out of the housing cavity 903, the movable plate 902 and the fixed plate 901 can be spliced together to form the dust-proof plate 9 matched with the upper end of the blanking hopper 301; when the movable plate 902 is received in the receiving cavity 903, one plate of the dust-proof plate 9 is opened for blanking; in this embodiment, the upper end of the discharging hopper 301 is provided with a circle of sliding grooves corresponding to the movable plate 902, and the arc-shaped edge of the movable plate 902 can be slidably arranged in the sliding grooves, thereby being beneficial to improving the stability of the rotation of the movable part.

A first collar 904 is arranged at the edge of one side of the fixing plate 901; a second collar 905 is arranged on one side edge of the movable plate 902; the stirring rod 303 passes through a first collar 904 and a second collar 905; the movable plate 902 is rotatably arranged at the upper end of the lower hopper 301 around the stirring rod 303; a first arc-shaped groove is formed in one side edge of the fixed plate 901, the first lantern ring 904 is fixedly installed in the arc-shaped groove, a second arc-shaped groove is formed in one side edge of the movable plate 902, and the second lantern ring 905 is fixedly installed in the second arc-shaped groove and installed in a conventional fixing and installing mode; the rotation axis of the stirring mechanism can pass through the first sleeve ring 904 and the second sleeve ring 905, which is beneficial to avoiding influencing the normal rotation of the rotation axis, the movable plate 902 rotates on the blanking hopper 301 by taking the rotation axis as the axis, and the movable plate 902 is rotationally arranged, which is beneficial to flexible retraction and extraction.

The edges of two sides of the upper surface of the cleaning scraper 8 are provided with cut angles; soft cleaning bristles 10 are arranged on the lower surface of the cleaning scraper 8; the cleaning bristles 10 are in contact with the bottom of the feeding channel 4; the corner cut is beneficial to improving the material scraping effect; the edges of the two sides of the cleaning scraper 8 extend out from the two sides of the bottom of the material pushing mechanism 7, so that when the material pushing mechanism 7 is pushed out and retracted, the bottom of the feeding channel 4 can be scraped by the material scraping part positioned at the front end in the moving direction, scattered powder can be cleaned, and the cleanness of the interior of the feeding channel 4 can be improved; the soft cleaning bristles 10 on the lower surface of the scraping plate are in contact with the bottom of the feeding channel 4, so that the cleaning effect of powder scattered at the bottom of the feeding channel 4 can be improved when the pushing part reciprocates in the feeding channel 4, and the cleaning bristles 10 are made of soft materials, and the normal reciprocating motion of the pushing part is not influenced after the cleaning bristles 10 are extruded to a certain extent.

The die cavity adjusting mechanism 5 comprises a hydraulic telescopic component and a resisting block 501; the hydraulic telescopic component drives the abutting block 501 to slide up and down in the die cavity to form a die cavity with adjustable depth; in this embodiment, the cross section of the resisting block 501 is matched with the cross section of the mold cavity, and two side walls of the resisting block 501 are closely and slidably connected with the inner side wall of the mold cavity; the depth of the die cavity is adjusted by adjusting the height of the abutting block 501, so that the fireproof speed is high, and the window frame is suitable for window frames with different thicknesses; when the hydraulic telescopic mechanism ejects the abutting block 501 upwards, the refractory block pressed and formed in the die cavity is also ejected out of the die cavity, and then the refractory block enters the filling station for filling.

The hydraulic telescopic assembly comprises a supporting plate 502, a first hydraulic cylinder 503, a first telescopic rod 504 and a connecting plate 505; the supporting plate 502 is erected on the frame 1 below the workbench 2; the first hydraulic cylinder 503 is mounted on the support plate 502; the first telescopic rod 504 is connected to the first hydraulic cylinder 503 at one end and connected to the connecting plate 505 at the other end; the connecting plate 505 is connected with the abutting block 501; in this embodiment, the first hydraulic cylinder 503 is a conventional hydraulic cylinder, and the first hydraulic cylinder 503 is connected with a pipeline connected with an oil tank, and a hydraulic cylinder with a reasonable model can be selected as required; the first hydraulic cylinder 503 is fixedly mounted on the support plate 502 by means of bolts and nuts, and any other reasonable conventional mounting manner can be adopted; in this embodiment, the connection manner of the first telescopic rod 504 and the first hydraulic cylinder 503 is a conventional manner, and the connection manner of the first telescopic rod 504 and the connection plate 505 is a conventional fixed connection manner; the first hydraulic cylinder 503 drives the first telescopic rod 504 to reciprocate up and down below the workbench 2, so as to drive the connecting plate 505 to reciprocate up and down, so as to drive the abutting block 501 to reciprocate up and down; the supporting plate 502 can be fixed on the frame 1 by welding. The resisting block 501 and the connecting plate 505 are also fixed by conventional fixing connection means, such as bolts, nuts, etc. In this embodiment, the rack 1 on one side of the supporting plate 502 is further provided with a detection device, the detection device comprises two inductive sensors arranged up and down, and the inductive sensors in this embodiment are of the type LJ18a 3-8-Z/EX; the inductive sensor can detect that the telescopic rod is stretched and retracted when the first telescopic rod 504 detects the stretching and retracting of the telescopic rod, and transmits an electric signal to the control system to start other machining mechanisms to work in a matched mode, so that automatic and assembly line machining is completed. In this embodiment, the control system selects the conventional PCL programming system.

The material pressing mechanism 6 comprises a hydraulic driving mechanism and a pressing block 601; the hydraulic driving mechanism comprises a second hydraulic cylinder 602 and a second telescopic rod 603; the second telescopic rod 603 is connected with the pressing block 601 and driven to reciprocate above the die cavity; the pressing block 601 is matched with the die cavity; in this embodiment, the second hydraulic cylinder 602 is fixedly mounted on the worktable 2 through a support frame; one end of the second telescopic rod 603 is connected to the second hydraulic cylinder 602, and the other end is connected to the pressing block 601; in this embodiment, the second hydraulic cylinder 602 is a conventional hydraulic cylinder, and the second hydraulic cylinder 602 is connected to a pipeline (not shown in the figure) connected to an oil tank, and a hydraulic cylinder with a reasonable model can be selected as required; in this embodiment, the connection manner of the second telescopic rod 603 and the second hydraulic cylinder 602 is a conventional manner, and the connection manner of the second telescopic rod 603 and the pressing block 601 is a conventional fixed connection manner, such as welding or bolt and nut fixed connection; the second hydraulic cylinder 602 drives the telescopic rod to reciprocate up and down above the workbench 2, so as to drive the pressing block 601 to reciprocate up and down, so that the pressing block 601 is pressed and lifted towards the material receiving die cavity, the refractory powder in the material receiving die cavity is tamped, a refractory module with a certain fixed shape is formed, the window frame can be conveniently filled into the die cavity, the density of the refractory material in the window frame is improved, and the refractory performance is improved.

The two sides of the pressing block 601 are horizontally provided with connecting lugs 604 in an extending mode; the connecting lug 604 is provided with a limiting hole; a positioning screw 605 is movably arranged in the limiting hole up and down; the positioning screw 605 is fixed by a nut; the limiting holes formed in the connecting lugs 604 are used for penetrating through the positioning screws 605, the downward extending height of the positioning screws 605 can be adjusted after the positioning screws 605 penetrate through the limiting holes, the height of the positioning screws 605 is fixed through nuts, when the pressing block 601 is pressed downwards to the end point, the lower end of the positioning screws 605 can be abutted against the working platform, the pressing block 601 is prevented from further moving downwards, the pressing stroke of the pressing block 601 is limited, and the height of the positioning screws 605 can be adjusted adaptively according to material borrowing die cavities with different depths, so that the downward pressing displacement of the pressing block 601 can be adjusted adaptively; the pressing stability and uniformity of the pressing block 601 can be improved by the limitation of the positioning screw 605. In this embodiment, a detection mechanism is also arranged on one side of the pressing mechanism 6, and the structure and principle of the detection mechanism are the same as those of the detection mechanism on one side of the die cavity adjusting mechanism 5.

A positioning groove 11 is arranged on the surface of the workbench 2 corresponding to the positioning screw 605; a damping sleeve 12 is detachably arranged in the positioning groove 11; the outer wall of the shock absorption sleeve 12 is connected with the inner wall of the positioning groove 11 through threads; in this embodiment, by providing the positioning groove 11 on the working platform, the positioning screw 605 is positioned by being inserted into the positioning groove 11, which is beneficial to improving the stability of the positioning screw 605 after abutting; a damping sleeve 12 is arranged in the positioning groove 11, so that the impact of the positioning screw 605 on the working platform can be buffered; after the positioning screw 605 impacts one end of the bottom of the damping sleeve 12, the bottom of the damping sleeve 12 is abraded, and the damping sleeve 12 is screwed out through threads to be replaced; in this embodiment, the damping sleeve 12 is made of conventional rubber; any other conventional and reasonable buffer material can be selected according to the requirement.

Although the invention has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this invention. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a fire window filler module make-up machine which characterized in that: comprises a frame (1), a workbench (2), a blanking mechanism (3), a feeding channel (4), a die cavity adjusting mechanism (5) and a pressing mechanism (6); the workbench (2) is arranged on the rack (1); a die cavity is arranged on the workbench (2); the feeding channel (4) is arranged on the workbench (2); a blanking mechanism (3) is connected above one end of the feeding channel (4); the other end of the feeding channel (4) is connected to the die cavity; a material pressing mechanism (6) reciprocates up and down above the die cavity; the bottom of the die cavity is vertically movably provided with a die cavity adjusting mechanism (5); a material pushing mechanism (7) is horizontally and reciprocally arranged in the feeding channel (4); and a cleaning scraper blade (8) is arranged at the bottom of the material pushing mechanism (7).

2. The fire protection window packing module forming machine of claim 1, wherein: the blanking mechanism (3) comprises a blanking hopper (301) and a stirring mechanism arranged in the blanking hopper (301); the stirring mechanism comprises a motor (302) and a stirring rod (303); the motor (302) drives the stirring rod (303) to rotate in the blanking hopper (301); and a discharge hole of the discharging hopper (301) is communicated with the feeding channel (4).

3. A fire window filler module forming machine as claimed in claim 2, wherein: the blanking hopper (301) is also provided with a dust guard (9); the dust guard (9) comprises a fixed plate (901) and a movable plate (902); an accommodating cavity (903) is formed in the fixing plate (901); the movable plate (902) is movably stored in the containing cavity (903).

4. A fire window filler module forming machine as claimed in claim 3, wherein: a first lantern ring (904) is arranged at the edge of one side of the fixing plate (901); a second lantern ring (905) is arranged on the edge of one side of the movable plate (902); the stirring rod (303) penetrates through a first collar (904) and a second collar (905); the movable plate (902) is rotatably arranged at the upper end of the blanking hopper (301) around the stirring rod (303).

5. The fire protection window packing module forming machine of claim 1, wherein: the edges of two sides of the upper surface of the cleaning scraper (8) are provided with cut angles; soft cleaning bristles (10) are arranged on the lower surface of the cleaning scraper (8); the cleaning brush bristles (10) are in contact with the bottom of the feeding channel (4).

6. The fire protection window packing module forming machine of claim 1, wherein: the die cavity adjusting mechanism (5) comprises a hydraulic telescopic component and a resisting block (501); the hydraulic telescopic component drives the abutting block (501) to slide up and down in the die cavity to form the die cavity with adjustable depth.

7. The fire protection window packing module forming machine of claim 6, wherein: the hydraulic telescopic assembly comprises a supporting plate (502), a first hydraulic cylinder (503), a first telescopic rod (504) and a connecting plate (505); the supporting plate (502) is erected on the rack (1) below the workbench (2); the first hydraulic cylinder (503) is mounted on a support plate (502); one end of the first telescopic rod (504) is connected to the first hydraulic cylinder (503) and the other end is connected to the connecting plate (505); the connecting plate (505) is connected with the abutting block (501).

8. The fire protection window packing module forming machine of claim 1, wherein: the pressing mechanism (6) comprises a hydraulic driving mechanism and a pressing block (601); the hydraulic driving mechanism comprises a second hydraulic cylinder (602) and a second telescopic rod (603); the second telescopic rod (603) is connected with the pressing block (601) and driven to reciprocate above the die cavity; the compact (601) is adapted to a mold cavity.

9. The fire protection window packing module forming machine of claim 8, wherein: two sides of the pressing block (601) are horizontally provided with connecting lugs (604) in an extending mode; the connecting lug (604) is provided with a limiting hole; a positioning screw rod (605) is movably arranged in the limiting hole up and down; the positioning screw (605) is fixed through a nut.

10. A fire window filler module forming machine as claimed in claim 9, wherein: a positioning groove (11) is arranged on the surface of the workbench (2) corresponding to the positioning screw rod (605); a damping sleeve (12) is detachably arranged in the positioning groove (11); the outer wall of the damping sleeve (12) is connected with the inner wall of the positioning groove (11) through threads.

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