CN113262584A

CN113262584A - Safety recovery equipment for gas leakage

Info

Publication number: CN113262584A
Application number: CN202110710006.8A
Authority: CN
Inventors: 张文举
Original assignee: Individual
Current assignee: Lichuan Jiannan Natural Gas Supply Center
Priority date: 2021-06-25
Filing date: 2021-06-25
Publication date: 2021-08-17
Anticipated expiration: 2041-06-25
Also published as: CN113262584B

Abstract

The invention relates to a safety recovery device, in particular to a gas leakage safety recovery device which comprises a filtering recovery mechanism, a double pressurizing mechanism and a waste heat recovery mechanism, wherein the device can filter and guide leaked gas, can fully combust and treat the gas, can heat water by utilizing the heat energy generated by combustion to generate power, can supplement the pressure of water vapor, and is connected with the double pressurizing mechanism which is connected with the waste heat recovery mechanism.

Description

Safety recovery equipment for gas leakage

Technical Field

The invention relates to a safety recovery device, in particular to a gas leakage safety recovery device.

Background

At the pipeline interface of the fuel gas conveyed in large flow, if leakage occurs, serious potential safety hazard is caused, the existing equipment is simply utilized for recovery and storage during recovery, and explosion danger exists;

the Chinese patent with the publication number of CN112283580A comprises a device body, wherein the device body comprises a base, a connecting pipeline is fixedly installed at the top end of the base, a storage box body is fixedly installed at the top end of the base, and a temperature control mechanism is arranged at one end of the storage box body. According to the invention, the fixing frame, the mainboard processing controller, the protection box, the temperature detection sensor, the water tank, the electromagnetic valve, the first water pump, the circulating water pipe, the temperature control bin, the second water pump, the cooler and the water inlet pipe are arranged, when the waste gas and fuel gas are collected in the storage box body, the mainboard processing controller controls the temperature detection sensor to detect the temperature in the storage box body, when the temperature is too high, the mainboard processing controller controls the electromagnetic valve and the first water pump to pump water from the water tank and convey the pumped water to the temperature control bin arranged in the storage box body through the circulating water pipe, the size of the stored fuel gas is limited, and the stored fuel gas cannot be recycled without limitation, so that when the leakage cannot be controlled, a huge potential safety hazard exists;

therefore, the safe recovery device for the fuel gas leakage is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the gas leakage safety recovery equipment, the equipment can filter and guide the leaked gas, the equipment can fully combust the gas, the equipment can utilize the heat energy of combustion to heat water to generate electricity, and the equipment can supplement the pressure of water vapor.

In order to solve the technical problems, the invention relates to a safety recovery device, in particular to a gas leakage safety recovery device which comprises a filtering recovery mechanism, a double pressurizing mechanism and a waste heat recovery mechanism, wherein the device can filter and guide leaked gas, can fully combust the gas, can utilize the heat energy of combustion to heat water to generate electricity, and can supplement the pressure of water vapor.

The filtering and recovering mechanism is connected with the double pressurizing mechanism, and the double pressurizing mechanism is connected with the waste heat recovering mechanism.

As a further optimization of the technical scheme, the filtering and recycling mechanism of the safe recycling device for the fuel gas leakage comprises a filtering cage seat, filtering holes, a belt pulley, a bearing seat, a shaft with a bulge, a spring, a stepped shaft, a sliding bearing seat, a coupling, a motor, a servo motor, a sliding rod, a lead screw, a supporting seat, a built-in impeller, a slot, a piston and a channel, wherein the filtering cage seat is provided with a plurality of filtering holes, the filtering cage seat is connected with the belt pulley, the filtering cage seat is rotatably connected with the bearing seat, the shaft with the bulge is slidably connected with the filtering cage seat, the spring is sleeved on the shaft with the bulge, the shaft with the bulge is connected with the stepped shaft, the spring is sleeved on the shaft with the bulge, two ends of the spring are respectively connected with the filtering cage seat and the stepped shaft, the stepped shaft is rotatably connected with the sliding bearing seat, the stepped shaft is connected with the motor through the coupling, the motor is connected with the sliding bearing seat, the servo motor is connected with the supporting seat, the supporting seat is connected with the bearing seat, the slide bar is connected with the supporting seat, the slide bar is connected with the bearing seat, the lead screw is connected with the servo motor, the lead screw is in threaded connection with the sliding bearing seat, the sliding bearing seat is in sliding connection with the slide bar, the built-in impeller is arranged in the filtering cage seat, the groove is formed in the filtering cage seat, the piston is in sliding connection with the filtering cage seat, the piston is connected with the protruding shaft, and the channel is arranged on the bearing seat.

As a further optimization of the technical scheme, the double-pressurizing mechanism of the fuel gas leakage safety recovery device comprises a belt, a connecting channel, an air supplementing pipe, an air box, an air inlet and a secondary air box, go out the tuber pipe, some firearm, threaded nozzle, belt pulley I, the one-level impeller that accelerates of band shaft, the impeller is accelerated to the second grade, the belt is connected with belt pulley I friction, the belt is connected with belt pulley friction, the connection way is linked together with the benefit tuber pipe, the connection way sets up on bellows, the benefit tuber pipe links to each other with bellows, the air intake sets up on the second grade bellows, the second grade bellows links to each other with bellows, the second grade bellows links to each other and communicates with the play tuber pipe, threaded nozzle and belt pulley I threaded connection, threaded nozzle links to each other with bellows, belt pulley I links to each other with the one-level impeller that accelerates of band shaft, the one-level impeller that accelerates of band shaft rotates with bellows to be connected, the one-level impeller that accelerates of band shaft links to each other with the impeller that accelerates of second grade.

As a further optimization of the technical scheme, the waste heat recovery mechanism of the fuel gas leakage safety recovery device comprises a combustion chamber, a separation seat, a box body, an air outlet pipe, a penetration channel, a connecting pipe, a power conversion box, a magnetic induction line providing seat, an air exhaust channel, a water inlet pipe, a driven belt shaft impeller, an air outlet one-way valve, a water inlet check valve, a cutting coil, an L-shaped hole, a flow channel and a flame outlet, wherein the combustion chamber is connected with the separation seat, the combustion chamber is connected with the box body, the box body is connected and communicated with the air outlet pipe, the air outlet pipe is connected and communicated with the connecting pipe, the connecting pipe is provided with the penetration channel, the connecting pipe is connected and communicated with the power conversion box, the power conversion box is connected and communicated with the air exhaust channel, the water inlet pipe is connected and communicated with the box body, the driven belt shaft impeller is rotatably connected with the power conversion box, the air outlet pipe penetrates into the connecting pipe from the penetration channel, the air outlet one-way valve is arranged in the air outlet pipe, the water inlet one-way valve is arranged in the water inlet pipe, the driven shaft impeller is connected with the cutting coil, the cutting coil is rotatably connected with the magnetic induction line providing seat, the separating seat is symmetrically provided with a plurality of L-shaped holes with different lengths, the flow channel is formed by enclosing a combustion chamber and the separating seat, and the flame outlet is arranged on the combustion chamber.

As a further optimization of the technical scheme, the slotting of the gas leakage safety recovery equipment is intermittently communicated with the channel when the filtering cage seat rotates.

As a further optimization of the technical scheme, the separation seat of the gas leakage safety recovery device is aligned to the center of the threaded nozzle.

The gas leakage safety recovery equipment has the beneficial effects that:

according to the gas leakage safety recovery equipment, the leaked gas can be filtered and guided by the equipment, the gas can be sufficiently combusted by the equipment, the equipment can be used for heating water by utilizing the combusted heat energy to generate power, and the pressure of water vapor can be supplemented by the equipment.

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 gas leakage safety recovery device of the invention.

Fig. 2 is a schematic structural diagram of a gas leakage safety recovery device of the invention.

Fig. 3 is a schematic structural diagram three of the gas leakage safety recovery device of the present invention.

Fig. 4 is a first structural schematic diagram of the filtering and recycling mechanism 1 of the gas leakage safety recycling device of the invention.

Fig. 5 is a schematic structural diagram of a filtering and recycling mechanism 1 of the gas leakage safety recycling device of the invention.

Fig. 6 is a third schematic structural diagram of the filtering and recycling mechanism 1 of the gas leakage safety recycling device of the invention.

Fig. 7 is a first structural schematic diagram of a double pressurizing mechanism 2 of the gas leakage safety recovery device of the invention.

Fig. 8 is a schematic structural diagram of a double pressurizing mechanism 2 of the gas leakage safety recovery device of the invention.

Fig. 9 is a third schematic structural view of a double pressurizing mechanism 2 of the gas leakage safety recovery device of the invention.

Fig. 10 is a fourth schematic structural view of the double pressurizing mechanism 2 of the gas leakage safety recovery device of the invention.

Fig. 11 is a first structural schematic diagram of the waste heat recovery mechanism 3 of the gas leakage safety recovery device of the invention.

Fig. 12 is a schematic structural diagram of a waste heat recovery mechanism 3 of the gas leakage safety recovery device of the invention.

Fig. 13 is a third schematic structural diagram of the waste heat recovery mechanism 3 of the gas leakage safety recovery device of the present invention.

Fig. 14 is a fourth schematic structural diagram of the waste heat recovery mechanism 3 of the gas leakage safety recovery device of the present invention.

Fig. 15 is a fifth schematic structural diagram of the waste heat recovery mechanism 3 of the fuel gas leakage safety recovery device of the present invention.

In the figure: a filtration recovery mechanism 1; 1-1 parts of a filtering cage seat; 1-2 of filtering holes; 1-3 of belt pulleys; 1-4 of a bearing seat; 1-5 parts of a shaft with a bulge; 1-6 of a spring; 1-7 of a stepped shaft; 1-8 of a sliding bearing seat; 1-9 of a coupler; 1-10 of a motor; 1-11 of a servo motor; 1-12 slide bars; 1-13 parts of a screw rod; 1-14 parts of a supporting seat; 1-15 of built-in impeller; 1-16 of slotting; pistons 1-17; channels 1-18; a double pressurizing mechanism 2; 2-1 of a belt; 2-2 of connecting channel; 2-3 of air supply pipe; 2-4 of an air box; 2-5 of an air inlet; 2-6 of a secondary air box; 2-7 of an air outlet pipe; 2-8 parts of an igniter; 2-9 parts of a threaded nozzle; pulley I2-10; a first-stage accelerating impeller 2-11 with a shaft; 2-12 of a second-stage accelerating impeller; a waste heat recovery mechanism 3; a combustion chamber 3-1; a separation seat 3-2; 3-3 of a box body; 3-4 parts of an air outlet pipe; penetrating into a channel 3-5; connecting pipes 3-6; 3-7 of a power conversion box; magnetic induction line providing seats 3-8; 3-9 of an exhaust channel; 3-10 parts of a water inlet pipe; passive belt shaft impellers 3-11; 3-12 parts of an air outlet one-way valve; 3-13 of a water inlet one-way valve; 3-14 parts of cutting coils; l-shaped holes 3-15; 3-16 of a flow channel; and 3-17 flame outlets.

Detailed Description

The first embodiment is as follows:

the present 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, and fig. 15, and the present invention relates to a safety recovery device for gas leakage, and more specifically, to a safety recovery device for gas leakage, which includes a filtration recovery mechanism 1, a double pressurization mechanism 2, and a waste heat recovery mechanism 3, and is capable of filtering and guiding leaked gas, sufficiently combusting the gas, heating water by using the heat energy of combustion to generate electricity, and replenishing the pressure of water vapor.

The filtering and recovering mechanism 1 is connected with the double pressurizing mechanism 2, and the double pressurizing mechanism 2 is connected with the waste heat recovering mechanism 3.

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, and the embodiment further describes the embodiment, where the filtration recovery mechanism 1 includes a filtration cage base 1-1, filtration holes 1-2, a belt pulley 1-3, a bearing base 1-4, a shaft with protrusions 1-5, a spring 1-6, a stepped shaft 1-7, a sliding bearing base 1-8, a coupling 1-9, a motor 1-10, a servo motor 1-11, a sliding rod 1-12, a screw rod 1-13, a support base 1-14, a built-in impeller 1-15, a slot 1-16, a piston 1-17, and a channel 1-18, the filtration cage base 1-1 is provided with a plurality of filtration holes 1-2, the filtering cage seat 1-1 is connected with the belt pulley 1-3, the filtering cage seat 1-1 is rotationally connected with the bearing seat 1-4, the shaft with the projection 1-5 is slidably connected with the filtering cage seat 1-1, the spring 1-6 is sleeved on the shaft with the projection 1-5, the shaft with the projection 1-5 is connected with the stepped shaft 1-7, the spring 1-6 is sleeved on the shaft with the projection 1-5, two ends of the spring 1-6 are respectively connected with the filtering cage seat 1-1 and the stepped shaft 1-7, the stepped shaft 1-7 is rotationally connected with the sliding bearing seat 1-8, the stepped shaft 1-7 is connected with the motor 1-10 through the shaft coupling 1-9, the motor 1-10 is connected with the sliding bearing seat 1-8, the servo motor 1-11 is connected with the supporting seat 1-14, the support seat 1-14 is connected with the bearing seat 1-4, the slide bar 1-12 is connected with the support seat 1-14, the slide bar 1-12 is connected with the bearing seat 1-4, the lead screw 1-13 is connected with the servo motor 1-11, the lead screw 1-13 is connected with the slide bearing seat 1-8 by screw thread, the slide bearing seat 1-8 is connected with the slide bar 1-12 by sliding, the built-in impeller 1-15 is arranged in the filtration cage seat 1-1, the open slot 1-16 is arranged on the filtration cage seat 1-1, the piston 1-17 is connected with the filtration cage seat 1-1 by sliding, the piston 1-17 is connected with the shaft 1-5 with the bulge, and the channel 1-18 is arranged on the bearing seat 1-4.

The third 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, the present embodiment further illustrates the present embodiment, in which the double pressurizing mechanism 2 includes a belt 2-1, a connecting passage 2-2, an air supply pipe 2-3, an air box 2-4, an air inlet 2-5, a secondary air box 2-6, an air outlet pipe 2-7, an igniter 2-8, a threaded nozzle 2-9, a pulley I2-10, a primary accelerating impeller 2-11 with a shaft, a secondary accelerating impeller 2-12, the belt 2-1 is frictionally connected with the pulley I2-10, the belt 2-1 is frictionally connected with the pulley 1-3, the connecting passage 2-2 is communicated with the air supply pipe 2-3, the connecting channel 2-2 is arranged on the air box 2-4, the air supplementing pipe 2-3 is connected with the air box 2-4, the air inlet 2-5 is arranged on the second-stage air box 2-6, the second-stage air box 2-6 is connected with the air box 2-4, the second-stage air box 2-6 is connected and communicated with the air outlet pipe 2-7, the threaded nozzle 2-9 is in threaded connection with the belt pulley I2-10, the threaded nozzle 2-9 is connected with the air box 2-4, the belt pulley I2-10 is connected with the first-stage accelerating impeller 2-11 with a shaft, the first-stage accelerating impeller 2-11 with the shaft is in rotary connection with the air box 2-4, the first-stage accelerating impeller 2-11 with the shaft is connected with the second-stage accelerating impeller 2-12, the connecting channel 2-2 is communicated with the channel 1-18, if gas leakage occurs, the motor 1-10 runs to drive the shaft coupling 1-9 to rotate, the shaft coupling 1-9 can drive the stepped shaft 1-7 to rotate, the stepped shaft 1-7 can drive the shaft with the bulge 1-5 to rotate, the shaft with the bulge 1-5 can drive the filtering cage base 1-1 to rotate, the filtering cage base 1-1 can drive the built-in impeller 1-15 to rotate, the built-in impeller 1-15 rotates to form downward airflow, so that the externally leaked fuel gas is filtered by the filtering hole 1-2 and then sucked into the filtering cage base 1-1, the gas can rapidly enter the channel 1-18 with certain pressure along with the continuous connection of the slot 1-16 and the channel 1-18, the intermittent connection can avoid backflow, and the filtering cage base 1-1 can drive the belt pulley 1-3 to rotate during rotation, the belt pulley 1-3 can drive the belt pulley I2-10 to rotate through the belt 2-1, the belt pulley I2-10 can drive the belt shaft primary accelerating impeller 2-11 to rotate, the belt shaft primary accelerating impeller 2-11 can rotate to form gas flowing from the connecting channel 2-2 to the direction of the threaded nozzle 2-9 to help gas flow to the igniter 2-8, the air supplementing pipe 2-3 can supplement incoming air and gas to be mixed to provide sufficient oxygen, and the sufficient combustion is carried out through the ignition of the igniter 2-8.

The fourth concrete implementation mode:

the following describes the present embodiment 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, and the present embodiment further describes the present embodiment, where the waste heat recovery mechanism 3 includes a combustion chamber 3-1, a separation seat 3-2, a tank 3-3, an outlet pipe 3-4, a penetration passage 3-5, a connection pipe 3-6, a power conversion box 3-7, a magnetic induction line providing seat 3-8, an exhaust passage 3-9, an inlet pipe 3-10, a passive axial impeller 3-11, an outlet check valve 3-12, an inlet check valve 3-13, a cutting coil 3-14, an L-shaped hole 3-15, a flow passage 3-16, and a flame outlet 3-17, the combustion chamber 3-1 is connected to the separation seat 3-2, the combustion chamber 3-1 is connected with the box body 3-3, the box body 3-3 is connected and communicated with an air outlet pipe 3-4, the air outlet pipe 3-4 is connected and communicated with a connecting pipe 3-6, a penetration channel 3-5 is arranged on the connecting pipe 3-6, the connecting pipe 3-6 is connected and communicated with a power conversion box 3-7, the power conversion box 3-7 is connected with a magnetic induction line providing seat 3-8, the power conversion box 3-7 is connected and communicated with an air exhaust channel 3-9, a water inlet pipe 3-10 is connected and communicated with the box body 3-3, a driven shaft impeller 3-11 is rotationally connected with the power conversion box 3-7, an air outlet pipe 2-7 penetrates into the connecting pipe 3-6 from the penetration channel 3-5, an air outlet one-way valve 3-12 is arranged in the air outlet pipe 3-4, the water inlet one-way valve 3-13 is arranged in the water inlet pipe 3-10, the driven shaft impeller 3-11 is connected with the cutting coil 3-14, the cutting coil 3-14 is rotationally connected with the magnetic induction line providing seat 3-8, the separating seat 3-2 is symmetrically provided with a plurality of L-shaped holes 3-15 with different lengths, the flow passage 3-16 is formed by enclosing the combustion chamber 3-1 and the separating seat 3-2, the flame outlet 3-17 is arranged on the combustion chamber 3-1, the device uses the water inlet pipe 3-10 to be externally connected with a pipeline capable of continuously supplementing water, the fire sprayed by the threaded nozzle 2-9 is shunted to the flow passage 3-16 at the two sides when touching the separating seat 3-2, the box body 3-3 is heated, and a part of the fire is upwards sprayed from the L-shaped holes 3-15 to heat the box body 3-3, the heat efficiency is improved, water in the box body 3-3 can form steam after being heated, the steam can rush out the air outlet one-way valve 3-12 after accumulating pressure to drive the driven impeller with shaft 3-11 to rotate, the first-stage accelerating impeller with shaft 2-11 can drive the second-stage accelerating impeller 2-12 to rotate, so that the air is introduced into the secondary air box 2-6 from the air inlet 2-5 and then blown into the connecting pipe 3-6 from the air outlet pipe 2-7 and blown upwards, the sprayed water vapor is pressurized, so that the rotating speed of the driven shaft-provided impeller 3-11 is increased, the driven shaft-provided impeller 3-11 can drive the cutting coils 3-14 to rotate, the cutting coils 3-14 can cut the magnetic induction lines of the magnetic induction line providing seats 3-8, electric energy is formed, and waste of heat energy is prevented.

The fifth concrete implementation mode:

the embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 and 15, and will be further explained in the following, wherein the slots 1-16 are intermittently connected to the passages 1-18 as the filter cage holder 1-1 rotates.

The sixth specific implementation mode:

the following describes the present embodiment 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, and fig. 15, and the present embodiment further describes the present embodiment in which the partition seat 3-2 is aligned with the center of the threaded nozzle 2-9.

The working principle of the device is as follows: the device can filter and guide leaked fuel gas, the device can fully combust and treat the fuel gas, if the fuel gas is leaked, the motor 1-10 operates to drive the coupler 1-9 to rotate, the coupler 1-9 can drive the stepped shaft 1-7 to rotate, the stepped shaft 1-7 can drive the shaft 1-5 with the bulge to rotate, the shaft 1-5 with the bulge can drive the filtering cage seat 1-1 to rotate, the filtering cage seat 1-1 can drive the built-in impeller 1-15 to rotate, the built-in impeller 1-15 can rotate to form downward airflow, so that the externally leaked fuel gas is filtered by the filtering hole 1-2 and then is sucked into the filtering cage seat 1-1, and the gas can rapidly enter the channel 1-18 with certain pressure along with the continuous connection of the groove 1-16 and the channel 1-18, the intermittent connection has the advantages that backflow can be avoided, the filter cage seat 1-1 can drive the belt pulley 1-3 to rotate when rotating, the belt pulley 1-3 can drive the belt pulley I2-10 to rotate through the belt 2-1, the belt pulley I2-10 can drive the belt shaft primary acceleration impeller 2-11 to rotate, the belt shaft primary acceleration impeller 2-11 can rotate to form gas flow from the connecting channel 2-2 to the threaded nozzle 2-9 to help gas to flow to the igniter 2-8, the air supplementing pipe 2-3 can supplement air and gas to be mixed, sufficient oxygen is provided, and sufficient combustion is carried out through ignition of the igniter 2-8; the equipment can utilize combustion heat energy to heat water to generate electricity, the equipment can supplement the pressure of water vapor, the equipment uses a forward water pipe 3-10 to be externally connected with a pipeline which can continuously supplement water, fire sprayed by a threaded nozzle 2-9 can be shunted to enter flow channels 3-16 at two sides when touching a separation seat 3-2, a box body 3-3 is heated, a part of fire is sprayed upwards from an L-shaped hole 3-15 to heat the box body 3-3, the heat efficiency is improved, water in the box body 3-3 can form water vapor after being heated, the water vapor is sprayed upwards to drive a driven shaft impeller 3-11 to rotate after accumulating the pressure, a shaft-contained primary accelerating impeller 2-11 rotates to drive a secondary accelerating impeller 2-12 to rotate, so that air is introduced into a secondary air box 2-6 from an air inlet 2-5 and then blown into an air outlet pipe 2-7 The connecting pipe 3-6 is blown upwards, so that the sprayed water vapor performs pressure compensation, the rotating speed of the driven shaft-provided impeller 3-11 is improved, the driven shaft-provided impeller 3-11 can drive the cutting coil 3-14 to rotate, the cutting coil 3-14 can cut the magnetic induction line of the magnetic induction line providing seat 3-8, electric energy is formed, and waste of heat energy is prevented.

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

1. The utility model provides a gas leakage safety recovery device, includes that filtration retrieves mechanism (1), double pressurization mechanism (2), waste heat recovery mechanism (3), its characterized in that: the filtering and recovering mechanism (1) is connected with the double pressurizing mechanism (2), and the double pressurizing mechanism (2) is connected with the waste heat recovering mechanism (3).

2. The gas leakage safety recovery device according to claim 1, wherein: the filtering and recycling mechanism (1) comprises a filtering cage seat (1-1), filtering holes (1-2), belt pulleys (1-3), bearing seats (1-4), shafts with protrusions (1-5), springs (1-6), stepped shafts (1-7), sliding bearing seats (1-8), couplers (1-9), motors (1-10), servo motors (1-11), sliding rods (1-12), lead screws (1-13), supporting seats (1-14), built-in impellers (1-15), slots (1-16), pistons (1-17) and channels (1-18), a plurality of filtering holes (1-2) are formed in the filtering cage seat (1-1), the filtering cage seat (1-1) is connected with the belt pulleys (1-3), the filtering cage seat (1-1) is rotationally connected with the bearing seat (1-4), the shaft (1-5) with the bulge is slidably connected with the filtering cage seat (1-1), the spring (1-6) is sleeved on the shaft (1-5) with the bulge, the shaft (1-5) with the bulge is connected with the stepped shaft (1-7), the spring (1-6) is sleeved on the shaft (1-5) with the bulge, two ends of the spring (1-6) are respectively connected with the filtering cage seat (1-1) and the stepped shaft (1-7), the stepped shaft (1-7) is rotationally connected with the sliding bearing seat (1-8), the stepped shaft (1-7) is connected with the motor (1-10) through the coupler (1-9), the motor (1-10) is connected with the sliding bearing seat (1-8), the servo motor (1-11) is connected with the supporting seat (1-14), the support seat (1-14) is connected with the bearing seat (1-4), the slide rod (1-12) is connected with the support seat (1-14), the slide rod (1-12) is connected with the bearing seat (1-4), the lead screw (1-13) is connected with the servo motor (1-11), the lead screw (1-13) is in threaded connection with the slide bearing seat (1-8), the slide bearing seat (1-8) is in sliding connection with the slide rod (1-12), the built-in impeller (1-15) is arranged in the filtering cage seat (1-1), the notch (1-16) is arranged on the filtering cage seat (1-1), the piston (1-17) is in sliding connection with the filtering cage seat (1-1), the piston (1-17) is connected with the shaft (1-5) with the bulge, and the channel (1-18) is arranged on the bearing seat (1-4).

3. The gas leakage safety recovery device according to claim 2, wherein: the double-pressurization mechanism (2) comprises a belt (2-1), a connecting channel (2-2), an air supplementing pipe (2-3), an air box (2-4), an air inlet (2-5), a secondary air box (2-6), an air outlet pipe (2-7), an igniter (2-8), a threaded nozzle (2-9), a belt pulley I (2-10), a primary accelerating impeller (2-11) with a shaft and a secondary accelerating impeller (2-12), the belt (2-1) is in friction connection with the belt pulley I (2-10), the belt (2-1) is in friction connection with the belt pulley (1-3), the connecting channel (2-2) is communicated with the air supplementing pipe (2-3), the connecting channel (2-2) is arranged on the air box (2-4), the air supplementing pipe (2-3) is connected with the air box (2-4), the air inlet (2-5) is arranged on the secondary air box (2-6), the secondary air box (2-6) is connected with the air box (2-4), the secondary air box (2-6) is connected and communicated with the air outlet pipe (2-7), the threaded nozzle (2-9) is in threaded connection with the belt pulley I (2-10), the threaded nozzle (2-9) is connected with the air box (2-4), the belt pulley I (2-10) is connected with the primary acceleration impeller (2-11) with the shaft, the primary acceleration impeller (2-11) with the shaft is rotationally connected with the air box (2-4), the primary acceleration impeller (2-11) with the shaft is connected with the secondary acceleration impeller (2-12), and the connecting channel (2-2) is communicated with the channel (1-18).

4. The gas leakage safety recovery device according to claim 1, wherein: the waste heat recovery mechanism (3) comprises a combustion chamber (3-1), a separation seat (3-2), a box body (3-3), an air outlet pipe (3-4), a penetration channel (3-5), a connecting pipe (3-6), a power conversion box (3-7), a magnetic induction line providing seat (3-8), an air exhaust channel (3-9), a water inlet pipe (3-10), a driven shaft-mounted impeller (3-11), an air outlet one-way valve (3-12), a water inlet one-way valve (3-13), a cutting coil (3-14), an L-shaped hole (3-15), a flow channel (3-16) and a flame outlet (3-17), wherein the combustion chamber (3-1) is connected with the separation seat (3-2), and the combustion chamber (3-1) is connected with the box body (3-3), the box body (3-3) is connected and communicated with the air outlet pipe (3-4), the air outlet pipe (3-4) is connected and communicated with the connecting pipe (3-6), the connecting pipe (3-6) is provided with a penetration channel (3-5), the connecting pipe (3-6) is connected and communicated with the power conversion box (3-7), the power conversion box (3-7) is connected with the magnetic induction line providing seat (3-8), the power conversion box (3-7) is connected and communicated with the air exhaust channel (3-9), the water inlet pipe (3-10) is connected and communicated with the box body (3-3), the driven shaft impeller (3-11) is rotationally connected with the power conversion box (3-7), the air outlet pipe (2-7) penetrates into the connecting pipe (3-6) from the penetration channel (3-5), the air outlet one-way valve (3-12) is arranged in the air outlet pipe (3-4), the water inlet one-way valve (3-13) is arranged in the water inlet pipe (3-10), the driven shaft impeller (3-11) is connected with the cutting coil (3-14), the cutting coil (3-14) is rotatably connected with the magnetic induction line providing seat (3-8), a plurality of L-shaped holes (3-15) with different lengths are symmetrically arranged on the separating seat (3-2), the flow channel (3-16) is formed by enclosing a combustion chamber (3-1) and the separating seat (3-2), and the flame outlet (3-17) is arranged on the combustion chamber (3-1).

5. The gas leakage safety recovery device according to claim 2, wherein: the slots (1-16) are intermittently communicated with the channels (1-18) when the filtering cage seat (1-1) rotates.

6. The gas leakage safety recovery device according to claim 3 or 4, wherein: the separating seat (3-2) is aligned with the center of the threaded nozzle (2-9).