Electric power construction safety protection equipment of putting out a fire
Technical Field
The invention relates to fire extinguishing equipment, in particular to electric power construction safety fire extinguishing protection equipment.
Background
At the power department of some high loads, the conflagration danger takes place easily, and is spacing not have better mode of putting out a fire except setting up power protection, and when the electric leakage took place, the secondary danger is caused easily still to the good still of water fire extinguishing effect, so designed an electric power construction safety protection equipment of putting out a fire.
Disclosure of Invention
The invention mainly solves the technical problem of providing the electric power construction safety fire extinguishing protection equipment, the equipment can extinguish fire, the equipment can recover sand and simultaneously extinguish fire for the second time, the equipment can supplement the sand, and the equipment can ensure stable operation.
In order to solve the technical problem, the invention relates to fire extinguishing equipment, in particular to electric power construction safety fire extinguishing protection equipment which comprises a recovery mechanism, a rotating frame mechanism, a discharging mechanism, a rotary driving mechanism and a vibration supplementing mechanism.
The recovery mechanism is connected with the rotating frame mechanism, the rotating frame mechanism is connected with the discharging mechanism, the rotating frame mechanism is connected with the rotary driving mechanism, the vibration supplementing mechanism is connected with the recovery mechanism, and the vibration supplementing mechanism is connected with the rotating frame mechanism.
As a further optimization of the technical scheme, the recovery mechanism of the electric power construction safety fire extinguishing protection device comprises a sandbox mechanism, an air cavity mechanism, a negative pressure fan mechanism and an air pipe, wherein the sandbox mechanism is connected with the air cavity mechanism, the air cavity mechanism is connected with the negative pressure fan mechanism, and the air cavity mechanism is connected with the air pipe; the sandbox mechanism comprises a sandbox body, a sand outlet opening and an inlet, wherein the sand outlet opening is formed in the sandbox body, and the inlet is formed in the sandbox body; the air cavity mechanism comprises a connecting port, an air cavity body, a bearing seat and a connecting pipe, the connecting port is connected with the air cavity body, the air cavity body is connected with the bearing seat, and the connecting pipe is connected with the air cavity body; the negative pressure fan mechanism comprises a negative pressure blade with a shaft, a coupler and a motor, the negative pressure blade with the shaft is connected with the motor through the coupler, the negative pressure blade with the shaft is connected with a bearing seat through a bearing, the motor is connected with the air cavity body, and the connecting pipe is connected with the air pipe.
As further optimization of the technical scheme, the rotating frame mechanism of the electric power construction safety fire-extinguishing protection device comprises a frame body, a welding machine opening, a bearing seat I, an opening I and a rotating frame mechanism, wherein the welding machine opening is formed in the frame body; the rotating frame mechanism comprises a belt pulley I, a shaft, a lower platform, an upright post, an upper platform and a shaft I, wherein the belt pulley I is connected with the shaft, the shaft is connected with the lower platform, the lower platform is connected with the upright post, the upright post is connected with the upper platform, the upper platform is connected with the shaft I, and the shaft I is connected with a bearing seat I in a bearing mode.
As further optimization of the technical scheme, the discharging mechanism of the electric power construction safety fire extinguishing protection device comprises a supporting leg I, a counterweight door mechanism, a bucket body, a hinged seat I, a hydraulic rod, a hydraulic cylinder and a fixed seat I, wherein the supporting leg I is connected with the bucket body, the counterweight door mechanism is hinged with the bucket body, the bucket body is hinged with the hinged seat I, the hinged seat I is connected with the hydraulic rod, the hydraulic rod is connected with the hydraulic cylinder, the hydraulic cylinder is connected with the fixed seat I, the fixed seat I is connected with a lower platform, and the supporting leg I is connected with the lower platform; the counterweight door mechanism comprises a door body, a counterweight threaded rod, a counterweight with internal threads and a hinge rod, wherein the door body is connected with the counterweight threaded rod, the counterweight threaded rod is connected with the counterweight with internal threads through threads, the hinge rod is connected with the door body, and the hinge rod is hinged with the bucket body.
As further optimization of the technical scheme, the rotary driving mechanism of the electric power construction safety fire extinguishing protection device comprises a driving motor I, a hanging hammer mechanism, a pulley I, a pulley support, a belt, a driving motor belt pulley and a tensioning sliding seat mechanism, wherein the driving motor I is connected with the driving motor belt pulley, the driving motor belt pulley is connected with the belt, the belt is connected with the belt pulley I, the hanging hammer mechanism is in contact fit with the pulley I, the pulley I is connected with the pulley support in a bearing manner, the pulley support is connected with a frame body, the hanging hammer mechanism is in sliding connection with the tensioning sliding seat mechanism, the tensioning sliding seat mechanism is connected with the frame body, and the hanging hammer mechanism is in flexible connection with the belt; the suspension hammer mechanism comprises a suspension hammer body, a balance weight, a steel wire rope, a stepped sliding block A and a tension pulley, wherein the suspension hammer body is connected with the steel wire rope, the balance weight is in contact fit with the suspension hammer body, the steel wire rope is in contact fit with a pulley I, the steel wire rope is connected with the stepped sliding block A, the stepped sliding block A is connected with the tension pulley in a bearing connection mode, and the tension pulley is in flexible connection with a belt; the tensioning sliding seat mechanism comprises a tensioning sliding seat body, a unthreaded hole and a step matching groove I, wherein the unthreaded hole is formed in the tensioning sliding seat body, the step matching groove I is formed in the tensioning sliding seat body, a step sliding block A is connected with the step matching groove I in a sliding mode, and a steel wire rope penetrates through the unthreaded hole.
As a further optimization of the technical scheme, the water pumping pipeline mechanism and the sample storage box mechanism of the electric power construction safety fire extinguishing protection device are made of stainless steel, and the vibration supplementing mechanism comprises a polarizing mechanism, a door opening and closing mechanism, a linkage mechanism and a limiting sliding seat mechanism, wherein the polarizing mechanism is connected with the door opening and closing mechanism, the door opening and closing mechanism is connected with the linkage mechanism, and the linkage mechanism is connected with the limiting sliding seat mechanism; the polarization mechanism comprises a vibration motor, a vibration motor belt pulley, an eccentric wheel, a long shaft, a belt I and an intermediate belt pulley, wherein the vibration motor is connected with the vibration motor belt pulley, the vibration motor belt pulley is connected with the belt I, the belt I is connected with the intermediate belt pulley, the intermediate belt pulley is connected with the long shaft, and the long shaft is connected with the eccentric wheel; the door opening and closing mechanism comprises a slotting I, a door body, a stepped groove, a vibration sliding rod, a vibration spring and a bearing seat II, wherein the slotting I is arranged on the door body, the stepped groove is arranged on the door body, the vibration sliding rod is connected with the door body, the vibration sliding rod is arranged in the stepped groove, the vibration spring is sleeved on the vibration sliding rod, the bearing seat II is connected with the door body, a long shaft is connected with the bearing seat II in a bearing mode, the vibration motor is connected with the door body, and the door body is hinged with the sandbox body; the linkage mechanism comprises a vibration slide bar I, a secondary vibration spring, a secondary step slide block, a linkage rod I and a primary step slide block, the vibration slide bar I is connected with the secondary step slide block, the secondary vibration spring is sleeved on the vibration slide bar I, the secondary step slide block is hinged with the linkage rod I, the linkage rod I is hinged with the primary step slide block, the primary step slide block is matched with the step groove, the primary step slide block is connected with the vibration slide bar in a sliding mode, and the vibration spring abuts against the primary step slide block; spacing sliding seat mechanism includes one-level ladder groove, spacing sliding seat body, sliding opening, and one-level ladder groove is opened on spacing sliding seat body, and the sliding opening is opened on spacing sliding seat body, vibrations slide bar I and sliding opening sliding connection, and second grade ladder slider cooperatees with one-level ladder groove, and second grade vibrations spring supports on the inner wall of spacing sliding seat body.
As a further optimization of the technical scheme, the bucket body of the electric power construction safety fire-extinguishing protection device is made of high manganese steel.
The invention relates to a safety fire-extinguishing protection device for electric power construction, which has the beneficial effects that:
according to the electric power construction safety fire-extinguishing protection equipment, the equipment can extinguish fire, the equipment can recover sand and simultaneously extinguish fire for the second time, the equipment can supplement the sand, and the equipment can guarantee stable operation.
Drawings
The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.
Fig. 1 is a schematic structural diagram of a power construction safety fire extinguishing protection device of the invention.
Fig. 2 is a schematic structural diagram of a recovery mechanism 1 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 3 is a schematic sectional structural view of the recovery mechanism 1 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 4 is a schematic structural diagram of a sandbox mechanism 1-1 of the electric power construction safety fire extinguishing protection device.
Fig. 5 is a schematic structural diagram of a wind cavity mechanism 1-2 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 6 is a schematic sectional structural view of an air chamber mechanism 1-2 of the safety fire-extinguishing protection device for electric power construction.
Fig. 7 is a schematic structural diagram of a negative pressure fan mechanism 1-3 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 8 is a schematic structural diagram of a rotating frame mechanism 2 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 9 is a schematic structural diagram of a rotating frame mechanism 2-5 of the electric power construction safety fire-extinguishing protection device.
Fig. 10 is a schematic structural diagram of a discharging mechanism 3 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 11 is a schematic structural view of a counterweight door mechanism 3-2 of the electric power construction safety fire-extinguishing protection device.
Fig. 12 is a schematic structural diagram of a rotary driving mechanism 4 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 13 is a schematic sectional structure view of the rotary driving mechanism 4 of the electric power construction safety fire-extinguishing protection device of the present invention.
Fig. 14 is a schematic structural diagram of a suspension hammer mechanism 4-2 of the electric power construction safety fire-extinguishing protection device.
Fig. 15 is a schematic structural view of a tensioning sliding seat mechanism 4-7 of the electric power construction safety fire extinguishing protection device.
Fig. 16 is a schematic structural diagram of a vibration supplementing mechanism 5 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 17 is a schematic sectional view of the vibration compensating mechanism 5 of the fire-extinguishing protection device for electric construction safety of the present invention.
Fig. 18 is a schematic structural diagram of a polarization mechanism 5-1 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 19 is a schematic structural diagram of a door opening and closing mechanism 5-2 of the electric power construction safety fire-extinguishing protection device.
Fig. 20 is a schematic structural view of a linkage mechanism 5-3 of the electric power construction safety fire-extinguishing protection device of the invention.
Fig. 21 is a schematic structural view of a limiting sliding seat mechanism 5-4 of the electric power construction safety fire extinguishing protection device of the invention.
In the figure: a recovery mechanism 1; a sandbox mechanism 1-1; 1-1-1 of a sandbox body; a sand outlet opening 1-1-2; 1-1-3 of an inlet; a wind cavity mechanism 1-2; a connecting port 1-2-1; 1-2-2 of the air cavity body; 1-2-3 of a bearing seat; connecting pipes 1-2-4; a negative pressure fan mechanism 1-3; 1-3-1 of negative pressure blades with shafts; 1-3-2 of a coupler; 1-3-3 of a motor; 1-4 of an air duct; a rotating frame mechanism 2; a frame body 2-1; 2-2 of a welding machine port; bearing seat I2-3; opening I2-4; 2-5 of a rotating frame mechanism; pulley I2-5-1; shaft 2-5-2; 2-5-3 of a lower platform; 2-5-4 of a stand column; 2-5-5 parts of an upper platform; axis I2-5-6; a discharging mechanism 3; leg I3-1; a counterweight door mechanism 3-2; a door body 3-2-1; a counterweight threaded rod 3-2-2; 3-2-3 of balance weight with internal thread; hinge rods 3-2-4; 3-3 parts of a bucket body; the hinge seat I3-4; 3-5 of a hydraulic rod; 3-6 parts of a hydraulic cylinder; a fixed seat I3-7; a rotation drive mechanism 4; a driving motor I4-1; a suspension hammer mechanism 4-2; 4-2-1 of a suspension hammer body; 4-2-2 of balance weight; 4-2-3 of a steel wire rope; a step slide block A4-2-4; 4-2-5 of a tension wheel; pulley I4-3; 4-4 of pulley support; 4-5 of a belt; 4-6 of a driving motor belt pulley; tensioning the sliding seat mechanism 4-7; tensioning the sliding seat body 4-7-1; 4-7-2 of a light hole; a step matching groove I4-7-3; a vibration supplementing mechanism 5; a polarization mechanism 5-1; 5-1-1 of a vibration motor; 5-1-2 of a vibration motor belt pulley; 5-1-3 of an eccentric wheel; long axis 5-1-4; belt I5-1-5; 5-1-6 of an intermediate belt pulley; a door opening and closing mechanism 5-2; a groove I5-2-1; a door body 5-2-2; 5-2-3 of a stepped groove; 5-2-4 of a vibration slide bar; 5-2-5 of a vibration spring; bearing seat II 5-2-6; 5-3 of a linkage mechanism; vibrating a sliding rod I5-3-1; 5-3-2 of a secondary vibration spring; 5-3-3 of a secondary step slide block; a linkage rod I5-3-4; 5-3-5 parts of a first-stage stepped sliding block; a limiting sliding seat mechanism 5-4; 5-4-1 of a first-stage stepped groove; a limiting sliding seat body 5-4-2; and 5-4-3 of a slide hole.
Detailed Description
The first embodiment is as follows:
the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, and the present invention relates to a fire extinguishing apparatus, and more specifically, to a power construction safety fire extinguishing protection apparatus, which includes a recovery mechanism 1, a rotating frame mechanism 2, a discharge mechanism 3, a rotary drive mechanism 4, and a vibration replenishment mechanism 5, and which is capable of extinguishing a fire, performing secondary fire extinguishing while recovering sand, replenishing sand, and ensuring stable operation.
The recovery mechanism 1 is connected with the rotating frame mechanism 2, the rotating frame mechanism 2 is connected with the unloading mechanism 3, the rotating frame mechanism 2 is connected with the rotary driving mechanism 4, the vibration supplementing mechanism 5 is connected with the recovery mechanism 1, and the vibration supplementing mechanism 5 is connected with the rotating frame mechanism 2.
The second embodiment is as follows:
the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, and the embodiment further describes the embodiment, where the recovery mechanism 1 includes a sandbox mechanism 1-1, an air cavity mechanism 1-2, a negative pressure fan mechanism 1-3, and an air duct 1-4, the sandbox mechanism 1-1 is connected to the air cavity mechanism 1-2, the air cavity mechanism 1-2 is connected to the negative pressure fan mechanism 1-3, and the air cavity mechanism 1-2 is connected to the air duct 1-4; the sandbox mechanism 1-1 comprises a sandbox body 1-1-1, a sand outlet opening 1-1-2 and an inlet 1-1-3, wherein the sand outlet opening 1-1-2 is formed in the sandbox body 1-1-1, and the inlet 1-1-3 is formed in the sandbox body 1-1-1; the air cavity mechanism 1-2 comprises a connector 1-2-1, an air cavity body 1-2-2, a bearing seat 1-2-3 and a connecting pipe 1-2-4, wherein the connector 1-2-1 is connected with the air cavity body 1-2-2, the air cavity body 1-2-2 is connected with the bearing seat 1-2-3, and the connecting pipe 1-2-4 is connected with the air cavity body 1-2-2; the negative pressure fan mechanism 1-3 comprises a negative pressure blade 1-3-1 with a shaft, a coupler 1-3-2 and a motor 1-3-3, the negative pressure blade 1-3-1 with the shaft is connected with the motor 1-3-3 through the coupler 1-3-2, the negative pressure blade 1-3-1 with the shaft is connected with a bearing seat 1-2-3 through a bearing, the motor 1-3-3 is connected with a wind cavity body 1-2-2, a connecting pipe 1-2-4 is connected with a wind pipe 1-4, the coupler 1-3-2 is driven to rotate by the operation of the motor 1-3-3, the negative pressure blade 1-3-1 with the shaft is driven to rotate by the rotation of the coupler 1-3-2, the negative pressure blade 1-3-1 with the shaft rotates to form negative pressure, the air pipe 1-4 can suck sand poured out during fire extinguishing under the drive of the negative pressure, the sand enters the sandbox body 1-1-1 from the air pipe 1-4 through the air cavity body 1-2-2 under the drive of the negative pressure, and meanwhile air around the air pipe 1-4 can be taken away by the negative pressure, so that open fire loses oxygen required by combustion.
The third concrete implementation mode:
the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, and the embodiment further describes the embodiment, where the rotating frame mechanism 2 includes a frame body 2-1, a welding port 2-2, a bearing seat I2-3, an opening I2-4, and a rotating frame mechanism 2-5, the welding port 2-2 is opened on the frame body 2-1, the bearing seat I2-3 is connected to the frame body 2-1, the opening I2-4 is opened on the frame body 2-1, and the rotating frame mechanism 2-5 is connected to the bearing seat I2-3 by a bearing; the rotating frame mechanism 2-5 comprises a belt pulley I2-5-1, a shaft 2-5-2, a lower platform 2-5-3, an upright post 2-5-4, an upper platform 2-5-5 and a shaft I2-5-6, wherein the belt pulley I2-5-1 is connected with the shaft 2-5-2, the shaft 2-5-2 is connected with the lower platform 2-5-3, the lower platform 2-5-3 is connected with the upright post 2-5-4, the upright post 2-5-4 is connected with the upper platform 2-5-5, the upper platform 2-5-5 is connected with the shaft I2-5-6, and the shaft I2-5-6 is connected with a bearing seat I2-3 in a bearing connection mode.
The fourth concrete implementation mode:
the embodiment is further described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20 and fig. 21, wherein the dumping mechanism 3 comprises a leg I3-1, a counterweight door mechanism 3-2, a bucket body 3-3, an articulated seat I3-4, a hydraulic rod 3-5, a hydraulic cylinder 3-6 and a fixed seat I3-7, the leg I3-1 is connected with the bucket body 3-3, the counterweight door mechanism 3-2 is articulated with the bucket body 3-3, the bucket body 3-3 is articulated with an articulated seat I3-4, the seat I3-4 is connected with the hydraulic rod 3-5, the hydraulic rod 3-5 is connected with the hydraulic cylinder 3-6, the hydraulic cylinder 3-6 is connected with a fixed seat I3-7, the fixed seat I3-7 is connected with a lower platform 2-5-3, and the supporting leg I3-1 is connected with the lower platform 2-5-3; the counterweight door mechanism 3-2 comprises a door body 3-2-1, a counterweight threaded rod 3-2-2, a counterweight 3-2-3 with internal threads and a hinge rod 3-2-4, the door body 3-2-1 is connected with the counterweight threaded rod 3-2-2, the counterweight threaded rod 3-2-2 is connected with the counterweight 3-2-3 with internal threads through threads, the hinge rod 3-2-4 is connected with the door body 3-2-1, the hinge rod 3-2-4 is hinged with the bucket body 3-3, the equipment is placed beside a transformer or an electric wire which is easy to generate open fire under large load, when the open fire occurs, hydraulic oil is injected into the hydraulic cylinder 3-6, and the hydraulic rod 3-5 moves towards the extending direction under the driving of the hydraulic oil, the hydraulic rod 3-5 moves to drive the hinged seat I3-4 to move, the hinged seat I3-4 moves to jack the end, close to the hinged seat I3-4, of the bucket body 3-3 upwards, so that sand stored in the bucket body 3-3 can topple downwards, the door body 3-2-1 can gradually open along with the gravity in the process that the bucket body 3-3 inclines, the sand pours out of the bucket body 3-3, open fire is directly covered, then hydraulic oil is reversely injected into the hydraulic cylinder 3-6, and the bucket body 3-3 can restore to the horizontal position.
The fifth concrete implementation mode:
referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, the present embodiment further illustrates the present embodiment, wherein the rotary driving mechanism 4 includes a driving motor I4-1, a suspending hammer mechanism 4-2, a pulley I4-3, a pulley support 4-4, a belt 4-5, a driving motor pulley 4-6, a sliding tensioning seat mechanism 4-7, a driving motor I4-1 is connected to the driving motor pulley 4-6, the driving motor pulley 4-6 is connected to the belt 4-5, the belt 4-5 is connected to the pulley I2-5-1, the suspending hammer mechanism 4-2 is in contact with the pulley I4-3, the pulley I4-3 is connected with the pulley support 4-4 through a bearing, the pulley support 4-4 is connected with the frame body 2-1, the suspension hammer mechanism 4-2 is connected with the tensioning sliding seat mechanism 4-7 in a sliding manner, the tensioning sliding seat mechanism 4-7 is connected with the frame body 2-1, and the suspension hammer mechanism 4-2 is flexibly connected with the belt 4-5; the suspension hammer mechanism 4-2 comprises a suspension hammer body 4-2-1, a counterweight 4-2-2, a steel wire rope 4-2-3, a step slide block A4-2-4 and a tension pulley 4-2-5, the suspension hammer body 4-2-1 is connected with the steel wire rope 4-2-3, the counterweight 4-2-2 is in contact fit with the suspension hammer body 4-2-1, the steel wire rope 4-2-3 is in contact fit with a pulley I4-3, the steel wire rope 4-2-3 is connected with the step slide block A4-2-4, the step slide block A4-2-4 is connected with the tension pulley 4-2-5 through a bearing, and the tension pulley 4-2-5 is in flexible connection with a belt 4-5, after sand is supplemented, the driving motor I4-1 is operated to drive the driving motor belt pulley 4-6 to rotate, the driving motor belt pulley 4-6 rotates to drive the belt pulley I2-5-1 to rotate through the belt 4-5, the belt pulley I2-5-1 rotates 180 degrees to drive the bucket body 3-3 of supplemented sand to rotate 180 degrees to wait for next use, in the process, as the sand is heavy, in order to prevent the belt 4-5 from slipping, the suspension hammer body 4-2-1 is arranged, under the action of gravity of the suspension hammer body 4-2-1, the steel wire rope 4-2-3 can pull the step slide block A4-2-4, the step slide block A4-2-4 can drive the tension pulley 4-2-5 to tension the belt 4-5, the belt 4-5 is prevented from slipping, and the tension degree can be changed by changing the number of the counter weights 4-2-2; the tensioning sliding seat mechanism 4-7 comprises a tensioning sliding seat body 4-7-1, a unthreaded hole 4-7-2 and a step matching groove I4-7-3, wherein the unthreaded hole 4-7-2 is formed in the tensioning sliding seat body 4-7-1, the step matching groove I4-7-3 is formed in the tensioning sliding seat body 4-7-1, a step sliding block A4-2-4 is connected with the step matching groove I4-7-3 in a sliding mode, and a steel wire rope 4-2-3 penetrates through the unthreaded hole 4-7-2.
The sixth specific implementation mode:
the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, and the embodiment further describes the first embodiment, where the vibration supplementing mechanism 5 includes a polarization mechanism 5-1, a door opening and closing mechanism 5-2, a linkage mechanism 5-3, and a limit sliding seat mechanism 5-4, the polarization mechanism 5-1 is connected with the door opening and closing mechanism 5-2, the door opening and closing mechanism 5-2 is connected with the linkage mechanism 5-3, and the linkage mechanism 5-3 is connected with the limit sliding seat mechanism 5-4; the polarizing mechanism 5-1 comprises a vibration motor 5-1-1, a vibration motor belt pulley 5-1-2, an eccentric wheel 5-1-3, a long shaft 5-1-4, a belt I5-1-5 and an intermediate belt pulley 5-1-6, wherein the vibration motor 5-1-1 is connected with the vibration motor belt pulley 5-1-2, the vibration motor belt pulley 5-1-2 is connected with the belt I5-1-5, the belt I5-1-5 is connected with the intermediate belt pulley 5-1-6, the intermediate belt pulley 5-1-6 is connected with the long shaft 5-1-4, and the long shaft 5-1-4 is connected with the eccentric wheel 5-1-3; the door opening and closing mechanism 5-2 comprises a slot I5-2-1, a door body 5-2-2, a step slot 5-2-3, a vibration slide bar 5-2-4, a vibration spring 5-2-5 and a bearing seat II5-2-6, wherein the slot I5-2-1 is arranged on the door body 5-2-2, the step slot 5-2-3 is arranged on the door body 5-2-2, the vibration slide bar 5-2-4 is connected with the door body 5-2-2, the vibration slide bar 5-2-4 is arranged in the step slot 5-2-3, the vibration spring 5-2-5 is sleeved on the vibration slide bar 5-2-4, the bearing seat II5-2-6 is connected with the door body 5-2-2, the long shaft 5-1-4 is connected with the bearing seat II5-2-6 through a bearing, the vibration motor 5-1-1 is connected with the door body 5-2-2, and the door body 5-2-2 is hinged with the sandbox body 1-1-1; the linkage mechanism 5-3 comprises a vibration slide bar I5-3-1, a secondary vibration spring 5-3-2, a secondary step slide block 5-3-3, a linkage bar I5-3-4 and a primary step slide block 5-3-5, the vibration slide bar I5-3-1 is connected with the secondary step slide block 5-3-3, the secondary vibration spring 5-3-2 is sleeved on the vibration slide bar I5-3-1, the secondary step slide block 5-3-3 is hinged with the linkage bar I5-3-4, the linkage bar I5-3-4 is hinged with the primary step slide block 5-3-5, the primary step slide block 5-3-5 is matched with the step groove 5-2-3, the primary step slide block 5-3-5 is connected with the vibration slide bar 5-2-4 in a sliding way, the vibration spring 5-2-5 abuts against the primary step slide block 5-3-5, the vibration motor 5-1-1 is operated to drive the vibration motor belt pulley 5-1-2 to rotate, the vibration motor belt pulley 5-1-2 rotates to drive the intermediate belt pulley 5-1-6 to rotate through the belt I5-1-5, the intermediate belt pulley 5-1-6 rotates to drive the long shaft 5-1-4 to rotate, the long shaft 5-1-4 rotates to drive the eccentric wheel 5-1-3 to rotate, the eccentric wheel 5-1-3 rotates to form a bias vibration force, the door body 5-2-2 swings downwards under the drive of the bias vibration force, and the primary step slide block 5-3-5 presses the vibration spring 5-2-5 in the swinging process When the first-stage step sliding block 5-3-5 slides, the linkage rod I5-3-4 drives the second-stage step sliding block 5-3-3 to slide, the second-stage step sliding block 5-3-3 slides to compress the second-stage vibration spring 5-3-2, and then the door body 5-2-2 resets under the rebounding of the second-stage vibration spring 5-3-2 and the vibration spring 5-2-5, so that a gap is intermittently formed between the door body 5-2-2 and the sand box body 1-1-1, and sand comes out of the gap and is supplemented into the bucket body 3-3; the limiting sliding seat mechanism 5-4 comprises a primary stepped groove 5-4-1, a limiting sliding seat body 5-4-2 and a sliding hole 5-4-3, wherein the primary stepped groove 5-4-1 is formed in the limiting sliding seat body 5-4-2, the sliding hole 5-4-3 is formed in the limiting sliding seat body 5-4-2, a vibration sliding rod I5-3-1 is connected with the sliding hole 5-4-3 in a sliding mode, a secondary stepped sliding block 5-3-3 is matched with the primary stepped groove 5-4-1, and a secondary vibration spring 5-3-2 abuts against the inner wall of the limiting sliding seat body 5-4-2.
The seventh embodiment:
next, the present embodiment will be described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, and fig. 21, and the first embodiment will be further described, in which the material of the bucket body 3-3 is high manganese steel.
The working principle of the device is as follows: the equipment can extinguish fire, the equipment is placed beside a transformer or an electric wire which is easy to generate open fire under a large load, when the open fire occurs, hydraulic oil is injected into the hydraulic cylinders 3-6, under the drive of oil pressure, the hydraulic rod 3-5 moves towards the extending direction, the hydraulic rod 3-5 moves to drive the hinged seat I3-4 to move, the hinged seat I3-4 moves to jack the end of the bucket body 3-3 close to the hinged seat I3-4 upwards, therefore, the sand stored in the bucket body 3-3 can be poured downwards, and in the process of inclining the bucket body 3-3, the door body 3-2-1 will open gradually with the gravity, the sand will pour out from the bucket body 3-3, the open fire will be covered directly, then, hydraulic oil is reversely injected into the hydraulic cylinder 3-6, and the bucket body 3-3 can restore to the horizontal position; the device can recover sand and simultaneously carry out secondary fire extinguishing, the shaft coupling 1-3-2 is driven to rotate by the operation of the motor 1-3-3, the shaft coupling 1-3-2 can drive the negative pressure blade 1-3-1 with the shaft to rotate, negative pressure can be formed by the rotation of the negative pressure blade 1-3-1 with the shaft, sand poured out during fire extinguishing is pumped back by the air pipe 1-4 under the drive of the negative pressure, the sand enters the sand box body 1-1-1 from the air pipe 1-4 through the air cavity body 1-2-2 under the drive of the negative pressure, and air around the air pipe 1-4 can be taken away by the negative pressure, so that open fire loses oxygen required by combustion; the device can supplement sand, the vibration motor belt pulley 5-1-2 is driven to rotate by the operation of the vibration motor 5-1-1, the vibration motor belt pulley 5-1-2 rotates to drive the intermediate belt pulley 5-1-6 to rotate through the belt I5-1-5, the long shaft 5-1-4 rotates by the rotation of the intermediate belt pulley 5-1-6, the eccentric wheel 5-1-3 rotates to form a bias vibration force, the door body 5-2-2 swings downwards under the drive of the bias vibration force, and the vibration spring 5-2-5 is compressed by the primary step slider 5-3-5 in the swinging process, when the first-stage step sliding block 5-3-5 slides, the linkage rod I5-3-4 drives the second-stage step sliding block 5-3-3 to slide, the second-stage step sliding block 5-3-3 slides to compress the second-stage vibration spring 5-3-2, and then the door body 5-2-2 resets under the rebounding of the second-stage vibration spring 5-3-2 and the vibration spring 5-2-5, so that a gap is intermittently formed between the door body 5-2-2 and the sand box body 1-1-1, and sand comes out of the gap and is supplemented into the bucket body 3-3; the equipment can ensure stable operation, after sand replenishment is finished, the driving motor I4-1 is operated to drive the driving motor belt pulley 4-6 to rotate, the driving motor belt pulley 4-6 rotates to drive the belt pulley I2-5-1 to rotate through the belt 4-5, the belt pulley I2-5-1 rotates 180 degrees to drive the bucket body of replenished sand to rotate 3-3 degrees for waiting for next use, in the process, as the sand is heavy, in order to prevent the belt 4-5 from slipping, the suspension hammer body 4-2-1 is arranged, under the gravity action of the suspension hammer body 4-2-1, the steel wire rope 4-2-3 can pull the step slide block A4-2-4, the step slide block A4-2-4 can drive the tension pulley 4-2-5 to tension the belt 4-5, the belt 4-5 is prevented from slipping, and the degree of tension can be changed by changing the number of the counter weights 4-2-2.
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.