CN111993062A - Intelligent production line for fire extinguishing bomb - Google Patents

Abstract

The invention relates to fire extinguishing bomb processing, in particular to an intelligent production line for fire extinguishing bombs, which comprises a device support, a transverse moving mechanism, a clamping mechanism, a welding mechanism and a mouth milling mechanism, wherein the device support comprises side supports, sliding plates, sliding columns I and mounting supports, the two side supports are respectively fixedly connected with the sliding plates between the two sides of the two side supports, the sliding columns I are respectively fixedly connected with the two sliding plates, the mounting supports are fixedly connected between the rear sides of the two sliding plates, the transverse moving mechanism comprises a transverse moving motor, a transverse moving rod and a spiral groove, the transverse moving motor is fixedly connected to the side supports on one side, an output shaft of the transverse moving motor is connected with the transverse moving rod, the spiral groove is arranged on the transverse moving rod, the clamping mechanism comprises a placing bottom plate and inserting nails, the placing bottom plate is connected with the inserting nails through threads.

Description

Intelligent production line for fire extinguishing bomb

Technical Field

The invention relates to processing of fire extinguishing bombs, in particular to an intelligent production line of the fire extinguishing bombs.

Background

For example, the public number CN102451531A discloses a safe and efficient intelligent fire extinguishing bomb which can adjust the launching distance of the fire extinguishing bomb according to the position of a fire, can accurately position and automatically launch in the fire, and comprises a launching device, the fire extinguishing bomb, a controller and a fixed support, wherein the launching device comprises a launching pipe, a transmitter, a bomb positioner, a regulator, a launching frame and a rotating shaft, the fire extinguishing bomb is inserted into the launching pipe of the launching device through the bomb positioner, the regulator can preset the launching distance of the fire extinguishing bomb, the controller arranged in the launching frame of the launching device receives a fire alarm signal from a fire alarm detector at a preset position and controls a corresponding launching device to launch the fire extinguishing bomb to the position of the fire; the disadvantage of this invention is that it is not possible to process the shell of the fire extinguishing bomb in a flowing water manner.

Disclosure of Invention

The invention aims to provide an intelligent production line of fire extinguishing bombs, which can process the shells of the fire extinguishing bombs in a flow manner.

The purpose of the invention is realized by the following technical scheme:

an intelligent production line for fire extinguishing bombs comprises a device support, a transverse moving mechanism, a clamping mechanism, a welding mechanism and a mouth milling mechanism, wherein the device support comprises side supports, two sliding plates, sliding columns I and mounting supports, the two side supports are provided, the sliding plates are fixedly connected between the two sides of the two side supports, the sliding columns I are fixedly connected on the two sliding plates, the mounting supports are fixedly connected between the rear sides of the two sliding plates, the transverse moving mechanism comprises a transverse moving motor, a transverse moving rod and a spiral groove, the transverse moving motor is fixedly connected on the side supports on one side, an output shaft of the transverse moving motor is connected with the transverse moving rod, the spiral groove is arranged on the transverse moving rod, the clamping mechanism comprises a placing bottom plate and inserting nails, the inserting nails are connected on the placing bottom plate through threads, the clamping mechanism is provided with a plurality of placing bottom plates are placed on the two sliding columns I, and the inserting, the welding mechanism is fixedly connected between the middle parts of the two sliding plates, and the mouth milling mechanism is fixedly connected to the mounting bracket.

According to the intelligent production line for the fire extinguishing bomb, the clamping mechanism further comprises a telescopic mechanism I, a friction disk I, a balance weight, permanent magnetic chucks, arc baffles, a holding plate and a positioning bottom plate, the placing bottom plate is fixedly connected with the two telescopic mechanisms I, the two telescopic mechanisms I are fixedly connected with the friction disk I and the balance weight, the telescopic ends of the two telescopic mechanisms I are fixedly connected with the permanent magnetic chucks, the two permanent magnetic chucks are fixedly connected with the three arc baffles, the three arc baffles are rotatably connected with the holding plate, and the lower ends of the two permanent magnetic chucks are fixedly connected with the positioning bottom plate.

As further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb comprises a welding mechanism, a welding mechanism and a welding mechanism, wherein the welding mechanism comprises a support ring, two friction discs II, rotating rings, a sliding groove, a cross column, a threaded cylinder and a locking nut, the support ring is fixedly connected between two side brackets, the support ring is rotatably connected with the two friction discs II, the two friction discs II are fixedly connected with the rotating rings, the two rotating rings are respectively provided with the sliding groove, the support ring is slidably connected with the cross column, the cross column is slidably connected between the two sliding grooves, the cross column is connected with the threaded cylinder and the locking nut through threads, the threaded cylinder is detachably and fixedly connected with a welding head, and the friction discs I and the friction discs; the transverse moving mechanism further comprises a friction wheel I, a connecting key and a sliding friction wheel, the friction wheel I is fixedly connected to an output shaft of the transverse moving motor, the connecting key is fixedly connected to the transverse moving rod, the sliding friction wheel is slidably connected to the connecting key, a compression spring I is fixedly connected between the sliding friction wheel and the transverse moving rod, and the transverse moving rod is rotatably connected to the two side brackets.

As further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb further comprises a control mechanism, the control mechanism comprises a control motor, a sliding column II, a sliding block and a ship-shaped plate, the control motor is fixedly connected to the side brackets on one side, the sliding column II is fixedly connected between the two side brackets, the sliding block is connected to the sliding column II in a sliding mode and is connected to an output shaft of the control motor through threads, and the upper end and the lower end of the sliding block are fixedly connected with the ship-shaped plate.

As the technical scheme is further optimized, the intelligent production line for the fire extinguishing bomb comprises a sliding bottom plate I, pushing sliding blocks I, positioning nails I and pushing columns I, wherein the sliding bottom plate I is fixedly connected between two side brackets, the sliding bottom plate I is connected with a plurality of pushing sliding blocks I in a sliding mode, the pushing sliding blocks I are connected with the positioning nails I through threads, the pushing sliding blocks I are connected with the pushing columns I in a sliding mode, compression springs II are fixedly connected between the pushing columns I and the pushing sliding blocks I, and a ship-shaped plate located on the upper side can be in contact with the lower ends of the pushing columns I.

As further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb comprises a pushing bottom plate, a connecting rod and a shifting fork, wherein the connecting rod is hinged between the pushing bottom plate and the shifting fork, the pushing bottom plate is connected between two side brackets in a sliding mode, the upper ends of a plurality of pushing columns I are in contact with the pushing bottom plate, and the shifting fork is connected to a sliding friction wheel in a rotating mode.

As further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb comprises a sliding bottom plate II, pushing sliding blocks II, positioning nails II and pushing columns II, wherein the sliding bottom plate II is fixedly connected between two side brackets, the sliding bottom plate II is connected with a plurality of pushing sliding blocks II in a sliding mode, the pushing sliding blocks II are connected with the positioning nails II through threads, the pushing columns II are connected with the pushing sliding blocks II in a sliding mode, compression springs III are fixedly connected between the pushing columns II and the pushing sliding blocks II, and a ship-shaped plate located on the lower side can be in contact with the upper ends of the pushing columns II.

As further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb comprises a driving mechanism, a driving motor and a friction wheel II, wherein the driving mechanism comprises a driving support, the driving motor and the friction wheel II, the driving support is connected between two side supports in a sliding mode, a compression spring IV is fixedly connected between the driving support and the side supports, the driving motor is fixedly connected onto the driving support, the friction wheel II is fixedly connected onto an output shaft of the driving motor, and the friction wheel II are in friction transmission.

As a further optimization of the technical scheme, the intelligent production line for the fire extinguishing bomb comprises a telescopic mechanism II, a mouth milling motor and a milling cutter, wherein the telescopic mechanism II is fixedly connected to an installation support, the telescopic end of the telescopic mechanism II is fixedly connected with the mouth milling motor, the milling cutter is detachably and fixedly connected to an output shaft of the mouth milling motor, the clamping mechanism further comprises a limiting mechanism, and the two counter weights are both fixedly connected with the limiting mechanism.

As further optimization of the technical scheme, the fire extinguishing bomb intelligent production line provided by the invention comprises a fire extinguishing bomb shell processed by the fire extinguishing bomb intelligent production line, wherein the fire extinguishing bomb shell comprises a positioning platform I, a notch, a positioning platform II and mounting holes, the positioning platform I is arranged on the left side and the right side of the fire extinguishing bomb shell, the notch is arranged at the upper end of the fire extinguishing bomb shell, the positioning platform II is arranged at the lower end of the fire extinguishing bomb shell, and the mounting holes are formed in the positioning platform II.

The intelligent production line for the fire extinguishing bomb has the beneficial effects that:

the invention relates to an intelligent production line for fire extinguishing bombs, which can process a fire extinguishing bomb shell by a transverse moving mechanism driving a clamping mechanism through a welding mechanism and a mouth milling mechanism in sequence, wherein the clamping mechanism can be detachably placed on the transverse moving mechanism, the clamping mechanism is convenient to place and detach from the transverse moving mechanism, the clamping mechanism clamps the fire extinguishing bomb shell, a control mechanism moves to sequentially push a pushing mechanism I and a pushing mechanism II to move, the pushing mechanism I and the pushing mechanism II are alternately pushed, the power of the transverse moving mechanism is communicated when the pushing mechanism I is pushed, the transverse moving mechanism pushes the clamping mechanism to move, the power of the driving mechanism is communicated with the power of the welding mechanism when the pushing mechanism II is pushed, the welding mechanism welds the fire extinguishing bomb shell, and the fire extinguishing bomb shell is processed through the mouth milling mechanism.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of the overall structure of an intelligent production line of fire extinguishing bombs of the present invention;

FIG. 2 is a schematic diagram of the overall structure of the intelligent production line of fire extinguishing bombs of the present invention;

FIG. 3 is a schematic view of the device support structure of the present invention;

FIG. 4 is a schematic structural view of the traversing mechanism of the present invention;

FIG. 5 is a schematic structural view of a clamping mechanism of the present invention;

FIG. 6 is a first schematic view of the welding mechanism of the present invention;

FIG. 7 is a second schematic structural view of the welding mechanism of the present invention;

FIG. 8 is a schematic structural view of a milling mechanism of the present invention;

FIG. 9 is a schematic view of the control mechanism of the present invention;

FIG. 10 is a schematic view of the structure of a pushing mechanism I of the present invention;

FIG. 11 is a schematic view of the communication mechanism of the present invention;

FIG. 12 is a schematic structural view of a pushing mechanism II of the present invention;

FIG. 13 is a schematic view of the drive mechanism of the present invention;

FIG. 14 is a first schematic view of the shell construction of the fire extinguishing bomb according to the present invention;

FIG. 15 is a second schematic structural view of the shell of the fire extinguishing bomb according to the present invention;

figure 16 is a schematic view of the raw shell construction of the fire extinguishing bomb of the present invention.

In the figure: a device holder 1; side brackets 101; a slide plate 102; a sliding column I103; a mounting bracket 104; a traversing mechanism 2; a traverse motor 201; a traverse bar 202; a friction wheel I203; a connection key 204; a sliding friction wheel 205; a helical groove 206; a clamping mechanism 3; placing a bottom plate 301; the plug pins 302; a telescoping mechanism I303; a friction disc I304; a weight 305; a permanent magnetic chuck 306; a circular arc baffle 307; a hugging plate 308; a positioning base plate 309; a limiting mechanism 3010; a welding mechanism 4; a support ring 401; a friction disc II 402; a rotating ring 403; a slide groove 403; a cross-post 404; a threaded barrel 405; a lock nut 406; a milling opening mechanism 5; a telescoping mechanism II 501; a mill motor 502; a milling cutter 503; a control mechanism 6; controlling the motor 601; a sliding column II 602; a slider 603; a boat-shaped plate 604; a pushing mechanism I7; a sliding bottom plate I701; pushing the sliding block I702; a positioning nail I703; pushing the column I704; a communication mechanism 8; pushing the bottom plate 801; a connecting rod 802; a shift fork 803; a pushing mechanism II 9; a sliding bottom plate II 901; pushing the sliding block II 902; a positioning pin II 903; pushing the column II 904; a drive mechanism 10; a drive bracket 1001; a drive motor 1002; a friction wheel II 1003; a shell 11 of the fire extinguishing bomb; a positioning platform I1101; notches 1102; a positioning platform II 1103; mounting holes 1104.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 16, and an intelligent production line for fire extinguishing bombs comprises a device support 1, a traversing mechanism 2, a clamping mechanism 3, a welding mechanism 4 and a milling mechanism 5, wherein the device support 1 comprises side supports 101, sliding plates 102, sliding columns i 103 and mounting supports 104, the number of the side supports 101 is two, the sliding plates 102 are fixedly connected between two sides of the two side supports 101, the sliding columns i 103 are fixedly connected to the two sliding plates 102, the mounting supports 104 are fixedly connected between the rear sides of the two sliding plates 102, the traversing mechanism 2 comprises a traversing motor 201, a traversing rod 202 and a spiral groove 206, the traversing motor 201 is fixedly connected to the side supports 101 on one side, an output shaft of the traversing motor 201 is connected with the traversing rod 202, the spiral groove 206 is arranged on the traversing rod 202, the clamping mechanism 3 comprises a placing bottom plate 301 and an insert pin 302, the placing bottom plate 301 is connected with the insert pin 302 through a thread, the clamping mechanisms 3 are multiple, the placing bottom plates 301 are placed on the two sliding columns I103, the inserting nails 302 are inserted into the spiral grooves 206, the welding mechanism 4 is fixedly connected between the middle parts of the two sliding plates 102, and the milling mechanism 5 is fixedly connected to the mounting bracket 104; as shown in FIG. 5, a placing bottom plate 301 is placed on two sliding columns I103, the two sliding columns I103 limit the placing bottom plate 301, an inserting nail 302 moves on the placing bottom plate 301 through a thread, the inserting nail 302 is inserted into a spiral groove 206, when a traversing rod 202 rotates under the driving of a traversing motor 201, the traversing rod 202 pushes the inserting nail 302 to move through the spiral groove 206, the inserting nail 302 drives the placing bottom plate 301 to slide, the placing bottom plate 301 slides on the sliding columns I103 and sequentially passes through a welding mechanism 4 and a mouth milling mechanism 5, the welding mechanism 4 welds two hemispherical cavities to form a fire extinguishing bomb shell 11, the mouth milling mechanism 5 processes the fire extinguishing bomb shell 11 to form a notch 1102, and as a plurality of clamping mechanisms 3 are arranged, the plurality of clamping mechanisms 3 are all placed on a device bracket 1 and a traversing mechanism 2 to be convenient for installation and disassembly from the device bracket 1 and the traversing mechanism 2, therefore, a plurality of clamping mechanisms 3 can be placed, the plurality of clamping mechanisms 3 are sequentially processed through the welding mechanism 4 and the milling mechanism 5, and the processed fire extinguishing bomb shell 11 is taken down from the device.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 16, and the embodiment further describes the first embodiment, where the clamping mechanism 3 further includes a telescopic mechanism i 303, a friction disc i 304, a counterweight 305, permanent magnetic suction cups 306, arc baffles 307, a clasping plate 308 and a positioning bottom plate 309, the placing bottom plate 301 is fixedly connected with two telescopic mechanisms i 303, the two telescopic mechanisms i 303 are fixedly connected with the friction disc i 304 and the counterweight 305, the telescopic ends of the two telescopic mechanisms i 303 are fixedly connected with the permanent magnetic suction cups 306, the two permanent magnetic suction cups 306 are fixedly connected with three arc baffles 307, the three arc baffles 307 are rotatably connected with the clasping plate 308, and the lower ends of the two permanent magnetic suction cups 306 are fixedly connected with the positioning bottom plate 309; place two hemisphere cavities respectively on two clamping machine construct 3, two I1101 of locating platform contact with two permanent magnetism sucking discs 306 respectively, permanent magnetism sucking disc 306 can be the permanent magnetism sucking disc among the prior art, also can be the electro-magnet, permanent magnetism sucking disc 306 adsorbs the hemisphere cavity, three circular arc baffle 307 plays the auxiliary stay effect to the hemisphere cavity, two location bottom plates 309 play the support positioning effect to II 1103 of locating platform, hold the board 308 and play the auxiliary stay effect to the hemisphere cavity, start I303 of telescopic machanism, I303 of telescopic machanism and II 501 of telescopic machanism can be pneumatic cylinder or electric putter, also can be other mechanical mechanism that can carry out reciprocating motion, the flexible end of I303 of telescopic machanism promotes two mutual lock of hemisphere cavity and forms fire extinguishing bomb shell 11.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 16, and the embodiment further describes the second embodiment, where the welding mechanism 4 includes a support ring 401, two friction disks ii 402, a rotation ring 403, a sliding groove 403, a cross column 404, a threaded cylinder 405, and a lock nut 406, the support ring 401 is fixedly connected between the two side brackets 101, the support ring 401 is rotatably connected with the two friction disks ii 402, the two friction disks ii 402 are fixedly connected with the rotation ring 403, the two rotation rings 403 are both provided with the sliding groove 403, the support ring 401 is slidably connected with the cross column 404, the cross column 404 is slidably connected between the two sliding grooves 403, the cross column 404 is connected with the threaded cylinder 405 and the lock nut 406 through threads, the threaded cylinder 405 is detachably and fixedly connected with a welding head, and the friction disks i 304 and the friction disks ii 402 are in friction transmission; the transverse moving mechanism 2 further comprises a friction wheel I203, a connecting key 204 and a sliding friction wheel 205, the friction wheel I203 is fixedly connected to an output shaft of the transverse moving motor 201, the connecting key 204 is fixedly connected to the transverse moving rod 202, the sliding friction wheel 205 is slidably connected to the connecting key 204, a compression spring I is fixedly connected between the sliding friction wheel 205 and the transverse moving rod 202, and the transverse moving rod 202 is rotatably connected to the two side brackets 101; enabling the sliding friction wheel 205 and the friction wheel I203 to enter friction transmission, starting the traversing motor 201 in advance, enabling an output shaft of the traversing motor 201 to drive the friction wheel I203 to rotate, enabling the friction wheel I203 to drive the sliding friction wheel 205 to rotate, enabling the sliding friction wheel 205 to drive the connecting key 204 to rotate, enabling the connecting key 204 to drive the traversing rod 202 to rotate, and enabling the traversing rod 202 to drive the clamping mechanism 3 to move transversely; as shown in fig. 2, when the boat-shaped plate 604 on the upper side no longer presses the pushing column i 704, the boat-shaped plate 604 on the lower side moves to a designated position and pushes the pushing column ii 904 to contact and push the pushing column ii 904 to move downwards, the pushing column ii 904 moves downwards, the driving bracket 1001 drives the driving motor 1002 to move downwards, the driving motor 1002 is started in advance, the output shaft of the driving motor 1002 drives the friction wheel ii 1003 to rotate, the friction wheel ii 1003 moves downwards to drive the friction disc ii 402 to rotate, the friction disc ii 402 drives the rotating ring 403 to rotate, the cross column 404 starts to slide in the sliding groove 403, due to the existence of the positioning platform ii 1103 on the shell 11 of the fire extinguishing bomb, the sliding groove 403 needs to be arranged, as shown in fig. 7, the upper end of the sliding groove 403 has a flat arrangement, so as to ensure that the welding head can pass through the positioning platform ii 1103, the welding head can still be in welding contact with the two hemispherical cavities to ensure the welding effect, as shown in fig. 7, the extending length of the welding head can be adjusted by rotating the threaded cylinder 405, so that different use requirements are met; it should be noted that when the clamping mechanism 3 moves to the welding mechanism 4 side, the friction disc i 304 and the friction disc ii 402 enter into friction transmission, and the transmission ratio between the friction disc i 304 and the friction disc ii 402 is one, so that when the friction disc ii 402 drives the friction disc i 304 to rotate, the rotating ring 403 also rotates one circle when the shell 11 of the fire extinguishing bomb moves one circle, and when the welding head moves to the position of the positioning platform ii 1103, the sliding groove 403 also moves to a flat section.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 16, the intelligent production line of fire extinguishing bomb further includes a control mechanism 6, the control mechanism 6 includes a control motor 601, a sliding column ii 602, a sliding block 603 and a boat-shaped plate 604, the control motor 601 is fixedly connected to the side brackets 101 on one side, the sliding column ii 602 is fixedly connected between the two side brackets 101, the sliding column ii 602 is slidably connected to a sliding block 603, the sliding block 603 is connected to the output shaft of the control motor 601 through a screw, and the boat-shaped plate 604 is fixedly connected to the upper and lower ends of the sliding block 603; starting the control motor 601, driving the sliding block 603 to move transversely through the rotation of the output shaft of the control motor 601 through the threads, and driving the two boat-shaped plates 604 to move by the sliding block 603; as shown in fig. 2, the boat-shaped plate 604 on the upper side can contact with the pushing column i 704 and push the pushing column i 704 to move upwards, the pushing column i 704 pushes the pushing bottom plate 801 to slide upwards, the pushing bottom plate 801 drives the connecting rod 802 and the shifting fork 803 to move, and the shifting fork 803 pushes the sliding friction wheel 205 to slide backwards, so that the sliding friction wheel 205 and the friction wheel i 203 enter into friction transmission.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-16, wherein the pushing mechanism i 7 includes a sliding bottom plate i 701, a pushing slider i 702, a positioning pin i 703 and a pushing post i 704, the sliding bottom plate i 701 is fixedly connected between the two side brackets 101, the sliding bottom plate i 701 is slidably connected with a plurality of pushing sliders i 702, the plurality of pushing sliders i 702 are all connected with the positioning pin i 703 through threads, the pushing slider i 702 is slidably connected with the pushing post i 704, a compression spring ii is fixedly connected between the pushing post i 704 and the pushing slider i 702, the boat-shaped plate 604 on the upper side can be in contact with the lower ends of the plurality of pushing posts i 704, when the boat-shaped plate 604 on the upper side no longer presses the pushing post 704 i, the clamping mechanism 3 does not move any more, the length of the boat-shaped plate 604 is set according to the use requirement, the plurality of clamping mechanisms 3 are set at intervals according to the length of the boat-shaped plate 604 and the rotation speed of the traverse motor 201, when each clamping mechanism 3 moves to the welding mechanism 4 side, the ship-shaped plate 604 on the upper side just no longer extrudes the pushing column I704, the position of the pushing slide block I702 can be adjusted, the pushing slide block I702 can be set according to the number of the clamping mechanisms 3, and the number of times that a batch of clamping mechanisms 3 stop when moving, namely the number of the clamping mechanisms 3, is controlled.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 16, and further described with reference to the fifth embodiment, the communication mechanism 8 includes a pushing bottom plate 801, a connecting rod 802 and a shifting fork 803, the connecting rod 802 is hinged between the pushing bottom plate 801 and the shifting fork 803, the pushing bottom plate 801 is slidably connected between the two side brackets 101, the upper ends of a plurality of pushing columns i 704 are all in contact with the pushing bottom plate 801, and the shifting fork 803 is rotatably connected to the sliding friction wheel 205.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 16, and the sixth embodiment is further described in the present embodiment, where the pushing mechanism ii 9 includes a sliding bottom plate ii 901, a pushing slider ii 902, a positioning pin ii 903, and a pushing column ii 904, the sliding bottom plate ii 901 is fixedly connected between the two side brackets 101, the sliding bottom plate ii 901 is slidably connected with a plurality of pushing sliders ii 902, the plurality of pushing sliders ii 902 are all connected with the positioning pin ii 903 through a thread, the plurality of pushing sliders ii 902 are all slidably connected with the pushing column ii 904, the pushing column ii 904 and the pushing slider ii 902 are fixedly connected with a compression spring iii, and the ship plate 604 located on the lower side can contact with the upper ends of the plurality of pushing columns ii 904.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 16, and the seventh embodiment is further described in the present embodiment, where the driving mechanism 10 includes a driving bracket 1001, a driving motor 1002, and a friction wheel ii 1003, the driving bracket 1001 is slidably connected between the two side brackets 101, a compression spring iv is fixedly connected between the driving bracket 1001 and the side brackets 101, the driving bracket 1001 is fixedly connected with the driving motor 1002, an output shaft of the driving motor 1002 is fixedly connected with the friction wheel ii 1003, and the friction wheel ii 1003 and the friction disc ii 402 are in friction transmission.

The specific implementation method nine:

the following describes the present embodiment with reference to fig. 1 to 16, and the eighth embodiment is further described in the present embodiment, where the mouth milling mechanism 5 includes a telescopic mechanism ii 501, a mouth milling motor 502, and a milling cutter 503, the telescopic mechanism ii 501 is fixedly connected to the mounting bracket 104, the telescopic end of the telescopic mechanism ii 501 is fixedly connected to the mouth milling motor 502, and the output shaft of the mouth milling motor 502 is detachably and fixedly connected to the milling cutter 503; as shown in fig. 14, after the fire extinguishing bomb shell 11 is formed by the two hemispherical cavities, the clamping mechanism 3 drives the fire extinguishing bomb shell 11 to pass through the mouth milling mechanism 5, the telescopic mechanism ii 501 is started, the telescopic end of the telescopic mechanism ii 501 can adjust the horizontal height of the mouth milling motor 502, the mouth milling motor 502 is started to drive the milling cutter 503 to rotate, the milling cutter 503 processes the fire extinguishing bomb shell 11 to form a notch 1102, the clamping mechanism 3 further comprises a limiting mechanism 3010, and the two balance weights 305 are both fixedly connected with the limiting mechanism 3010.

The detailed implementation mode is ten:

the following describes the present embodiment with reference to fig. 1 to 16, and the present embodiment further describes an embodiment nine, where the fire extinguishing bomb housing 11 processed by the fire extinguishing bomb intelligent production line includes a positioning platform i 1101, a notch 1102, a positioning platform ii 1103 and an installation hole 1104, the positioning platform i 1101 is disposed on both left and right sides of the fire extinguishing bomb housing 11, the notch 1102 is disposed on the upper end of the fire extinguishing bomb housing 11, the positioning platform ii 1103 is disposed on the lower end of the fire extinguishing bomb housing 11, and the installation hole 1104 is disposed on the positioning platform ii 1103; when the fire extinguishing bomb shell 11 is used, the fire extinguishing bomb shell 11 needing to be processed is respectively placed on the two clamping mechanisms 3, as shown in fig. 16, a hemisphere cavity which is not processed is shown in fig. 16, the fire extinguishing bomb shell 11 is formed by buckling and processing the two hemisphere cavities, a positioning platform I1101 and a positioning platform II 1103 are arranged on the hemisphere cavity, and the positioning platform I1101 and the positioning platform II 1103 can be integrally cast during casting of the hemisphere cavity or can be separately processed and formed after casting of the hemisphere cavity is completed; as shown in fig. 14 and 15, a notch 1102 and a mounting hole 1104 are arranged on the fire extinguishing bomb shell 11, a plastic baffle is arranged in the notch 1102, a fire extinguishing agent, an explosive and a lead wire are added into the fire extinguishing bomb shell 11 through the notch 1102 and the mounting hole 1104, a cover plate is connected with the mounting hole 1104 through threads, the fire extinguishing bomb shell 11 is closed, when fire occurs, the lead wire is ignited, the lead wire ignites the explosive, the explosive explodes to burst the plastic baffle arranged in the notch 1102 and spray out the fire extinguishing agent, and due to the existence of the notch 1102, the fire extinguishing agent is sprayed out linearly, so that the fire extinguishing area is larger than that of circular spraying in the prior art, and meanwhile, the fire extinguishing agent can be sprayed out quickly.

The invention relates to an intelligent production line of fire extinguishing bombs, which has the working principle that:

when the fire extinguishing bomb shell 11 is used, the fire extinguishing bomb shell 11 needing to be processed is respectively placed on the two clamping mechanisms 3, as shown in fig. 16, a hemisphere cavity which is not processed is shown in fig. 16, the fire extinguishing bomb shell 11 is formed by buckling and processing the two hemisphere cavities, a positioning platform I1101 and a positioning platform II 1103 are arranged on the hemisphere cavity, and the positioning platform I1101 and the positioning platform II 1103 can be integrally cast during casting of the hemisphere cavity or can be separately processed and formed after casting of the hemisphere cavity is completed; the two hemispherical cavities are respectively placed on the two clamping mechanisms 3, the two positioning platforms I1101 are respectively contacted with the two permanent magnetic suckers 306, the permanent magnetic suckers 306 can be permanent magnetic suckers in the prior art and can also be electromagnets, the permanent magnetic suckers 306 adsorb the hemispherical cavities, the three arc baffles 307 play a role in auxiliary supporting the hemispherical cavities, the two positioning bottom plates 309 play a role in supporting and positioning the positioning platforms II 1103, the holding plates 308 play a role in auxiliary supporting the hemispherical cavities, the telescopic mechanism I303 is started, the telescopic mechanism I303 and the telescopic mechanism II 501 can be hydraulic cylinders or electric push rods or other mechanical mechanisms capable of reciprocating, and the telescopic end of the telescopic mechanism I303 pushes the two hemispherical cavities to be mutually buckled to form the fire extinguishing bomb shell 11; as shown in FIG. 5, a placing bottom plate 301 is placed on two sliding columns I103, the two sliding columns I103 limit the placing bottom plate 301, an inserting nail 302 moves on the placing bottom plate 301 through a thread, the inserting nail 302 is inserted into a spiral groove 206, when a traversing rod 202 rotates under the driving of a traversing motor 201, the traversing rod 202 pushes the inserting nail 302 to move through the spiral groove 206, the inserting nail 302 drives the placing bottom plate 301 to slide, the placing bottom plate 301 slides on the sliding columns I103 and sequentially passes through a welding mechanism 4 and a mouth milling mechanism 5, the welding mechanism 4 welds two hemispherical cavities to form a fire extinguishing bomb shell 11, the mouth milling mechanism 5 processes the fire extinguishing bomb shell 11 to form a notch 1102, and as a plurality of clamping mechanisms 3 are arranged, the plurality of clamping mechanisms 3 are all placed on a device bracket 1 and a traversing mechanism 2 to be convenient for installation and disassembly from the device bracket 1 and the traversing mechanism 2, therefore, a plurality of clamping mechanisms 3 can be placed, the plurality of clamping mechanisms 3 are sequentially processed through the welding mechanism 4 and the milling mechanism 5, and the processed fire extinguishing bomb shell 11 is taken down from the device; starting the control motor 601, driving the sliding block 603 to move transversely through the rotation of the output shaft of the control motor 601 through the threads, and driving the two boat-shaped plates 604 to move by the sliding block 603; as shown in fig. 2, the ship-shaped plate 604 on the upper side can contact with the pushing column i 704 and push the pushing column i 704 to move upward, the pushing column i 704 pushes the pushing bottom plate 801 to slide upward, the pushing bottom plate 801 drives the connecting rod 802 and the shifting fork 803 to move, the shifting fork 803 pushes the sliding friction wheel 205 to slide backward, so that the sliding friction wheel 205 and the friction wheel i 203 enter friction transmission, the traversing motor 201 is started in advance, the output shaft of the traversing motor 201 drives the friction wheel i 203 to rotate, the friction wheel i 203 drives the sliding friction wheel 205 to rotate, the sliding friction wheel 205 drives the connection key 204 to rotate, the connection key 204 drives the traversing rod 202 to rotate, and the traversing rod 202 drives the clamping mechanism 3 to move laterally; when the ship-shaped plate 604 on the upper side does not extrude the pushing columns I704 any more, the clamping mechanisms 3 do not move any more, the length of the ship-shaped plate 604 is set according to the use requirement, the intervals of the plurality of clamping mechanisms 3 when being placed are set according to the length of the ship-shaped plate 604 and the rotating speed of the traverse motor 201, so that when each clamping mechanism 3 moves to the side of the welding mechanism 4, the ship-shaped plate 604 on the upper side does not extrude the pushing columns I704 any more, the position of the pushing sliding block I702 can be adjusted, the pushing sliding block I702 can be set according to the number of the clamping mechanisms 3, and the stopping times of a batch of clamping mechanisms 3 during movement, namely the number of the clamping mechanisms 3, are controlled; as shown in fig. 2, when the boat-shaped plate 604 on the upper side no longer presses the pushing column i 704, the boat-shaped plate 604 on the lower side moves to a designated position and pushes the pushing column ii 904 to contact and push the pushing column ii 904 to move downwards, the pushing column ii 904 moves downwards, the driving bracket 1001 drives the driving motor 1002 to move downwards, the driving motor 1002 is started in advance, the output shaft of the driving motor 1002 drives the friction wheel ii 1003 to rotate, the friction wheel ii 1003 moves downwards to drive the friction disc ii 402 to rotate, the friction disc ii 402 drives the rotating ring 403 to rotate, the cross column 404 starts to slide in the sliding groove 403, due to the existence of the positioning platform ii 1103 on the shell 11 of the fire extinguishing bomb, the sliding groove 403 needs to be arranged, as shown in fig. 7, the upper end of the sliding groove 403 has a flat arrangement, so as to ensure that the welding head can pass through the positioning platform ii 1103, the welding head can still be in welding contact with the two hemispherical cavities to ensure the welding effect, as shown in fig. 7, the extending length of the welding head can be adjusted by rotating the threaded cylinder 405, so that different use requirements are met; it should be noted that when the clamping mechanism 3 moves to the welding mechanism 4 side, the friction disc i 304 and the friction disc ii 402 enter into friction transmission, the transmission ratio between the friction disc i 304 and the friction disc ii 402 is one, so that when the friction disc ii 402 drives the friction disc i 304 to rotate, the rotating ring 403 also rotates for one circle when the shell 11 of the fire extinguishing bomb moves for one circle, and when the welding head moves to the location platform ii 1103, the sliding groove 403 also moves to a flat section; the pushing sliding block II 902 is adjusted according to the number of the clamping mechanisms 3, and when attention needs to be paid, the ship-shaped plate 604 on the lower side is set to be in a corresponding length, so that the ship-shaped plate 604 on the lower side is guaranteed to move downwards when pushing the pushing column II 904 every time, the welding mechanism 4 only welds one circle when welding is carried out, and then the ship-shaped plate 604 on the lower side does not extrude the pushing column II 904 any more; as shown in fig. 14, after the fire extinguishing bomb shell 11 is formed by the two hemispherical cavities, the clamping mechanism 3 drives the fire extinguishing bomb shell 11 to pass through the mouth milling mechanism 5, the telescopic mechanism ii 501 is started, the telescopic end of the telescopic mechanism ii 501 can adjust the horizontal height of the mouth milling motor 502, the mouth milling motor 502 is started to drive the milling cutter 503 to rotate, and the milling cutter 503 processes the fire extinguishing bomb shell 11 to form a notch 1102; before the clamping mechanism 3 moves to the milling cutter 503, the limiting mechanism 3010 can be a hydraulic cylinder or an electric push rod, due to the existence of the counterweight 305, after passing through the welding mechanism 4, the counterweight 305 drives the clamping mechanism 3 to rotate and reset, the limiting mechanism 3010 is in contact with the mounting bracket 104, a limiting sliding plate is arranged on the mounting bracket 104, or a boss is not shown in the drawing, a sliding rail is fixedly connected to the telescopic end of the clasping mechanism 3010, a sliding groove is arranged on the sliding rail, the sliding groove is in contact with the limiting sliding plate, the limiting sliding plate is in sliding connection in the sliding groove, the rotation of the clamping mechanism 3 is limited again, and the situation that the clamping mechanism 3 cannot deflect when passing through the milling cutter; the slide rail and the limiting slide plate are transversely arranged; as shown in fig. 14 and 15, a notch 1102 and a mounting hole 1104 are arranged on the fire extinguishing bomb shell 11, a plastic baffle is arranged in the notch 1102, a fire extinguishing agent, an explosive and a lead wire are added into the fire extinguishing bomb shell 11 through the notch 1102 and the mounting hole 1104, a cover plate is connected with the mounting hole 1104 through threads, the fire extinguishing bomb shell 11 is closed, when fire occurs, the lead wire is ignited, the lead wire ignites the explosive, the explosive explodes to burst the plastic baffle arranged in the notch 1102 and spray out the fire extinguishing agent, and due to the existence of the notch 1102, the fire extinguishing agent is sprayed out linearly, so that the fire extinguishing area is larger than that of circular spraying in the prior art, and meanwhile, the fire extinguishing agent can be sprayed out quickly.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides an intelligent production line of fire extinguishing bomb, includes device support (1), sideslip mechanism (2), clamping machine structure (3), welding mechanism (4) and mills a mouthful mechanism (5), its characterized in that: the device support (1) comprises side supports (101), sliding plates (102), sliding columns I (103) and mounting supports (104), the number of the side supports (101) is two, the sliding plates (102) are fixedly connected between two sides of the two side supports (101), the sliding columns I (103) are fixedly connected to the two sliding plates (102), the mounting supports (104) are fixedly connected between the rear sides of the two sliding plates (102), a transverse moving mechanism (2) comprises a transverse moving motor (201), a transverse moving rod (202) and a spiral groove (206), the transverse moving motor (201) is fixedly connected to the side supports (101) on one side, an output shaft of the transverse moving motor (201) is connected with the transverse moving rod (202), the spiral groove (206) is arranged on the transverse moving rod (202), a clamping mechanism (3) comprises a placing bottom plate (301) and inserting nails (302), the placing bottom plate (301) is connected with the inserting nails (302) through threads, clamping machine constructs (3) and is provided with a plurality ofly, and a plurality ofly place bottom plate (301) and all place on two slip post I (103), and in a plurality of nail (302) of inserting all inserted helical groove (206), fixedly connected with welding mechanism (4) between the middle part of two slide (102), fixedly connected with mills a mouthful mechanism (5) on installing support (104).

2. The intelligent production line of fire extinguishing bomb according to claim 1, characterized in that: clamping machine constructs (3) still includes telescopic machanism I (303), friction disc I (304), counter weight (305), permanent magnet chuck (306), circular arc baffle (307), hold board (308) and location bottom plate (309), place two telescopic machanism I (303) of fixedly connected with on bottom plate (301), equal fixedly connected with friction disc I (304) and counter weight (305) on two telescopic machanism I (303), equal fixedly connected with permanent magnet chuck (306) are served in the flexible of two telescopic machanism I (303), three circular arc baffle (307) of equal fixedly connected with on two permanent magnet chucks (306), all rotate on three circular arc baffle (307) and be connected with and hold board (308) tightly, the equal fixedly connected with location bottom plate (309) of lower extreme of two permanent magnet chucks (306).

3. The intelligent production line of fire extinguishing bomb according to claim 2, characterized in that: the welding mechanism (4) comprises a support ring (401), a friction disc II (402), a rotating ring (403), a sliding groove (403), a cross column (404), a threaded cylinder (405) and a locking nut (406), the support ring (401) is fixedly connected between the two side supports (101), the support ring (401) is rotatably connected with two friction discs II (402), the two friction discs II (402) are fixedly connected with rotating rings (403), the two rotating rings (403) are respectively provided with a sliding groove (403), the support ring (401) is slidably connected with a cross column (404), the cross column (404) is slidably connected between the two sliding grooves (403), the cross column (404) is connected with a threaded cylinder (405) and a locking nut (406) through threads, the threaded cylinder (405) is detachably and fixedly connected with a welding head, and the friction discs I (304) and the friction discs II (402) are in friction transmission; the transverse moving mechanism (2) further comprises a friction wheel I (203), a connecting key (204) and a sliding friction wheel (205), the friction wheel I (203) is fixedly connected to an output shaft of the transverse moving motor (201), the connecting key (204) is fixedly connected to the transverse moving rod (202), the sliding friction wheel (205) is slidably connected to the connecting key (204), a compression spring I is fixedly connected between the sliding friction wheel (205) and the transverse moving rod (202), and the transverse moving rod (202) is rotatably connected to the two side brackets (101).

4. The intelligent production line of fire extinguishing bomb according to claim 3, characterized in that: fire extinguishing bomb intelligent production line still includes control mechanism (6), control mechanism (6) are including control motor (601), slip post II (602), sliding block (603) and ship template (604), control motor (601) fixed connection is on the collateral branch frame (101) of one side, slip post II (602) fixed connection is between two collateral branch frames (101), sliding connection has sliding block (603) on slip post II (602), sliding block (603) are on the output shaft of control motor (601) through threaded connection, the equal fixedly connected with ship template (604) in upper and lower both ends of sliding block (603).

5. The intelligent production line of fire extinguishing bomb according to claim 4, characterized in that: pushing mechanism I (7) are including sliding bottom I (701), promote slider I (702), location nail I (703) and promote post I (704), sliding bottom I (701) fixed connection is between two side supports (101), sliding bottom I (701) go up sliding connection has a plurality of sliders I (702) that promote, all there is location nail I (703) through threaded connection on a plurality of sliders I (702) that promote, sliding connection has promotion post I (704) on promoting slider I (702), promote fixedly connected with compression spring II between post I (704) and the slider I (702) that promotes, ship template (604) that are located the upside can contact with a plurality of lower extremes that promote post I (704).

6. The intelligent production line of fire extinguishing bomb according to claim 5, characterized in that: the communicating mechanism (8) comprises a pushing bottom plate (801), a connecting rod (802) and a shifting fork (803), the connecting rod (802) is hinged between the pushing bottom plate (801) and the shifting fork (803), the pushing bottom plate (801) is connected between the two side supports (101) in a sliding mode, the upper ends of a plurality of pushing columns I (704) are in contact with the pushing bottom plate (801), and the shifting fork (803) is connected to the sliding friction wheel (205) in a rotating mode.

7. The intelligent production line of fire extinguishing bomb according to claim 4, characterized in that: pushing mechanism II (9) are including sliding bottom II (901), promote slider II (902), location nail II (903) and promote post II (904), sliding bottom II (901) fixed connection is between two collateral branch framves (101), sliding bottom II (901) go up sliding connection has a plurality of sliders II (902) that promote, all there are location nail II (903) on a plurality of sliders II (902) that promote through threaded connection, equal sliding connection has promotion post II (904) on a plurality of sliders II (902) that promote, it has compression spring III to promote between post II (904) and the slider II (902) that promote, ship template (604) that are located the downside can contact with the upper end of a plurality of pushing posts II (904).

8. The intelligent production line of fire extinguishing bomb according to claim 7, characterized in that: the driving mechanism (10) comprises a driving support (1001), a driving motor (1002) and a friction wheel II (1003), the driving support (1001) is connected between the two side supports (101) in a sliding mode, a compression spring IV is fixedly connected between the driving support (1001) and the side supports (101), the driving support (1001) is fixedly connected with the driving motor (1002), the output shaft of the driving motor (1002) is fixedly connected with the friction wheel II (1003), and the friction wheel II (1003) and the friction disc II (402) are in friction transmission.

9. The intelligent production line of fire extinguishing bomb according to any one of claims 2-8, characterised in that: mill a mouthful mechanism (5) and include telescopic machanism II (501), mill a mouthful motor (502) and milling cutter (503), telescopic machanism II (501) fixed connection is on installing support (104), telescopic machanism II (501) serve fixedly connected with and mill a mouthful motor (502) on the flexible, mill and to dismantle fixedly connected with milling cutter (503) on the output shaft of mouthful motor (502), clamping mechanism (3) still include stop gear (3010), equal fixedly connected with stop gear (3010) on two counter weights (305).

10. The intelligent production line of fire extinguishing bomb according to any one of claims 1-8, characterised in that: fire extinguishing bomb shell (11) of fire extinguishing bomb intelligent production line processing includes locating platform I (1101), notch (1102), locating platform II (1103) and mounting hole (1104), and the left and right sides of fire extinguishing bomb shell (11) all is provided with locating platform I (1101), and the upper end of fire extinguishing bomb shell (11) is provided with notch (1102), and the lower extreme of fire extinguishing bomb shell (11) is provided with locating platform II (1103), is provided with mounting hole (1104) on locating platform II (1103).

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