CN110585755A

CN110585755A - Industrial steam rapid condensation recovery device

Info

Publication number: CN110585755A
Application number: CN201910885549.6A
Authority: CN
Inventors: 方星
Original assignee: Pujiang Liding Environmental Protection Equipment Co Ltd
Current assignee: Pujiang Liding Environmental Protection Equipment Co Ltd
Priority date: 2019-09-19
Filing date: 2019-09-19
Publication date: 2019-12-20
Also published as: JP2021045734A

Abstract

The invention discloses a rapid condensation and recovery device for industrial steam, which comprises a heat insulation box and a water tank, wherein a water storage cavity is arranged in the water tank, ice water is stored in the water storage cavity, a condensation cavity is arranged in the heat insulation box, aerosol particles are stored in the condensation cavity, the steam and the aerosol particles are mixed to facilitate the condensation of the steam, a connecting pipe is fixedly connected between the heat insulation box and the upper end surface of the water tank, and a connecting passage is arranged in the connecting pipe in a run-through manner.

Description

Industrial steam rapid condensation recovery device

Technical Field

The invention relates to the field of steam recovery, in particular to a rapid condensation and recovery device for industrial steam.

Background

The industrial steam generated in some industrial production can cause air pollution if directly discharged into the air, and the industrial steam contains a large amount of energy, which can cause energy waste and can recycle the industrial steam, but some industrial steam is formed by mixing a plurality of gases, directly recycles the industrial steam, has low efficiency and high consumption cost.

Disclosure of Invention

The technical problem is as follows:

the industrial steam discharged into the air can cause pollution, and can waste energy, and the recovery efficiency and the consumption cost of the mixed industrial steam are low.

In order to solve the above problems, the present embodiment provides a rapid condensation and recovery device for industrial steam, which comprises a heat insulation box and a water tank, wherein a water storage cavity is arranged in the water tank, ice water is stored in the water storage cavity, a condensation cavity is arranged in the heat insulation box, aerosol particles are stored in the condensation cavity, steam and aerosol particles are mixed to facilitate steam condensation, a connecting pipe is fixedly connected between the heat insulation box and the upper end surface of the water tank, a connecting passage is arranged in the connecting pipe in a through manner, the steam in the water storage cavity can enter the condensation cavity through the connecting passage, the left end of the water tank is connected with an air inlet device, industrial steam can be discharged into the water storage cavity through the air inlet device, an absorption device is arranged in the water storage cavity, the absorption device is communicated with the air inlet device, and industrial steam flows into the absorption device through the air inlet device, and then fully mixing the industrial steam and the ice water through an absorption device and rapidly cooling the industrial steam, dissolving water-soluble steam in water for recycling, overflowing the water-insoluble steam out of the ice water and storing the water-insoluble steam in the water storage cavity, wherein a crystallization device is arranged in the condensation cavity, and the crystallization device can reduce the air pressure in the condensation cavity, so that the water-insoluble and cooled steam in the water storage cavity can be sucked into the condensation cavity, and further the steam in the condensation cavity is mixed with aerosol particles, and further the steam can be rapidly condensed and recycled. Preferably, a water inlet pipe is fixedly connected to the left end of the water tank, a water inlet channel is arranged in the water inlet pipe in a left-right through mode, ice water can be added into the water storage cavity through the water inlet channel, a water inlet valve with an opening facing the water storage cavity is fixedly arranged in the water inlet channel, a water outlet pipe is fixedly connected to the lower end of the water tank, a water outlet channel is arranged in the water outlet pipe in a vertical through mode, the ice water in the water storage cavity can be discharged through the water outlet channel, a water outlet valve with an opening deviating from the water storage cavity is fixedly arranged in the water outlet channel, the water outlet valve is powered on, the ice water in the water storage cavity can be discharged through the water outlet channel at the moment, the water inlet valve is powered on, and the ice water can be added.

Beneficially, air inlet unit includes the fixed pipe that links firmly in the water tank left end, fixed intraductal guide chute that is equipped with the opening left that is equipped with, slidable is equipped with the slip piston in the guide chute, the logical groove that is equipped with that link up about in the slip piston, the slip piston right-hand member has linked firmly the slip pipe, the slip pipe with sliding connection between the fixed pipe, the slip pipe right-hand member extends to in the water storage chamber and connect in absorbing device, the intraductal air inlet passage that is equipped with that link up of slip about, the air inlet passage left side be linked together in the logical groove, the air inlet passage right side be linked together in absorbing device, industrial steam passes through the guide chute gets into the logical groove and in the air inlet passage, and then get into in the absorbing device.

Preferably, the fixed rods are connected to the right inner wall of the sliding guide groove in a vertically symmetrical manner, the fixed rods are connected to the sliding piston in a sliding manner, racks are fixedly arranged in one end faces of the fixed rods, which are close to a symmetrical center, connecting gears are arranged in the sliding guide groove in a vertically symmetrical and rotatable manner, the connecting gears are meshed with the racks, connecting shafts are fixedly connected to the connecting gears, the connecting shafts are rotatably connected between the front inner wall and the rear inner wall of the sliding guide groove, baffles are rotatably arranged at the front sides of the connecting gears and are fixedly connected to the connecting shafts, two compression springs are fixedly connected between the right end of the sliding piston and the right inner wall of the sliding guide groove, when no industrial steam passes through the through groove, the baffles close the through groove, when the industrial steam in the sliding guide groove flows, the sliding piston is pushed to slide, meanwhile, the sliding piston and the fixed rod relatively slide and compress the compression spring, the rack drives the connecting gear to rotate, the connecting shaft drives the baffle to rotate and open the through groove, the through groove and the guide chute are communicated, when no industrial steam flows in the guide chute, the sliding piston is pushed to slide left under the action of the elastic force of the compression spring, and then the rack, the rack and the connecting shaft drive the baffle to rotate and close the through groove again.

Advantageously, the absorption device comprises a rotating pipe rotatably disposed in the water storage chamber, the rotating pipe is provided with an air guide hole with a left opening, the right end of the sliding pipe extends into the air guide hole and is in threaded connection with the rotating pipe, a through hole with a downward opening is formed in the inner wall of the lower side of the air guide hole, a connecting rod is rotatably connected to the circumferential surface of the rotating pipe, a cavity is formed in the connecting rod and can be communicated with the through hole, air exchange pipes are fixedly connected to the upper end and the left and right ends of the connecting rod, an air exchange chamber with an opening facing the connecting rod is formed in the air exchange pipe and is communicated with the cavity, an air exchange hole is formed in the air exchange pipe, ice water in the water storage chamber cannot enter the air exchange chamber, industrial steam in the air exchange chamber can enter the water storage chamber, the sliding pipe slides rightwards, and then the through hole is communicated with the cavity, industrial steam enters the air guide hole through the through groove and the air inlet channel, then enters the cavity through the through hole, further enters the ventilation cavity, further enters the water storage cavity through the ventilation pipe, is fully mixed with ice water and is cooled, at the moment, steam which can be dissolved in water is dissolved in water for recycling, and water-insoluble steam overflows the ice water and is stored in the water storage cavity.

Preferably, a cantilever shaft is fixedly connected to the right end of the rotating pipeline, the cantilever shaft is rotatably connected to the inner wall of the right side of the water storage cavity, and the rotating pipeline, the connecting rod and the ventilation pipe can be supported by the cantilever shaft.

Beneficially, the crystallization device comprises a transmission cavity arranged in the inner wall of the lower side of the condensation cavity, a sliding gear is rotatably and slidably arranged in the transmission cavity, a motor shaft is fixedly connected with the inner spline of the sliding gear, a motor is fixedly arranged in the inner wall of the upper side of the transmission cavity, the upper end of the motor shaft is in power connection with the motor, a fixed gear is rotatably arranged on the right side of the sliding gear and can be meshed with the sliding gear, a screw rod is fixedly connected to the upper end of the fixed gear, a guide hole is arranged in the inner wall of the upper side of the transmission cavity, the inner wall of the upper side of the guide hole is communicated with the condensation cavity, a sliding rod is slidably arranged in the guide hole, a threaded hole is vertically communicated in the sliding rod, the upper end of the screw rod extends into the threaded hole and is in threaded connection with the sliding rod, aerosol particles are stored on the upper side of the sliding plate, when the sliding gear is meshed with the fixed gear, the motor is started, the sliding gear is driven to rotate through the motor shaft, the fixed gear is driven to rotate, the sliding rod is driven to descend through the screw rod, the sliding plate is driven to descend, the air pressure in the condensation cavity is reduced, water-insoluble steam in the water storage cavity is sucked into the condensation cavity, and the steam and the aerosol particles are mixed and quickly condensed.

Preferably, the upper end of the sliding gear is rotatably connected with a fixed block, an electromagnetic spring is fixedly connected between the upper end of the fixed block and the inner wall of the upper side of the transmission cavity, a contact switch is fixedly connected on the inner wall of the lower side of the condensation cavity, the contact switch is electrically connected with the electromagnetic spring, and when the sliding plate slides downwards and contacts with the contact switch, the electromagnetic spring is electrified to drive the fixed block and the sliding gear to slide upwards, so that the sliding gear is disengaged from the fixed gear.

Beneficially, a driving gear is rotatably arranged at the lower side of the sliding gear, a driven gear is arranged at the right end of the driving gear in a meshed manner, a fixed shaft is fixedly connected in the driven gear, a sliding shaft is slidably and rotatably arranged at the upper side of the fixed shaft, a spline hole with a downward opening is arranged in the sliding shaft, the upper end of the fixed shaft extends into the spline hole and is in spline connection with the sliding shaft, the sliding shaft and the screw rod can rotate relatively, the upper end of the sliding shaft is rotatably connected to the sliding plate, a gear cavity is arranged in the sliding plate, a pinion is rotatably arranged in the gear cavity and is fixedly connected to the sliding shaft, large gears are symmetrically arranged at the left end and the right end of the pinion in a meshed manner, a fan shaft is fixedly connected in the large gears, and fan cavities with upward openings are symmetrically arranged, the fan shaft upper end extends to the fan intracavity and has linked firmly the fan, the fan upside has set firmly the filter screen, and steam and aerosol granule can not pass through the filter screen gets into the fan intracavity, start the motor, and then pass through the motor shaft drives the driving gear rotates, and then drives driven gear rotates, and then passes through the fixed axle drives the sliding shaft rotates, can drive when the sliding plate slides the sliding shaft slides, simultaneously the sliding shaft rotates and drives pinion rotates, and then drives gear wheel rotates, and then passes through the fan shaft drives the fan rotates, and then can blow the aerosol granule in the condensation intracavity makes steam can fully contact with the aerosol granule.

The invention has the beneficial effects that: the industrial steam and the ice water are mixed at first, heat exchange is carried out on the industrial steam for cooling, some water-soluble gas can be dissolved by the ice water, and the water-insoluble gas is condensed into crystals in a pressure reduction mode for recycling.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic diagram of the overall structure of an industrial steam rapid condensation and recovery device according to the present invention;

FIG. 2 is an enlarged schematic view of "A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-3, for the sake of convenience, the orientations described hereinafter being defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a rapid condensation and recovery device for industrial steam, which is mainly applied to the condensation and recovery of industrial steam mixed with various gases, and the invention is further explained by combining the attached drawings of the invention:

the invention relates to an industrial steam rapid condensation and recovery device, which comprises a heat insulation box 11 and a water tank 51, wherein a water storage cavity 50 is arranged in the water tank 51, ice water is stored in the water storage cavity 50, a condensation cavity 30 is arranged in the heat insulation box 11, aerosol particles are stored in the condensation cavity 30, steam and the aerosol particles are mixed to facilitate steam condensation, a connecting pipe 53 is fixedly connected between the heat insulation box 11 and the upper end surface of the water tank 51, a connecting passage 52 is arranged in the connecting pipe 53 in a through manner, steam in the water storage cavity 50 can enter the condensation cavity 30 through the connecting passage 52, the left end of the water tank 51 is connected with an air inlet device 100, industrial steam can be discharged into the water storage cavity 50 through the air inlet device 100, an absorption device 101 is arranged in the water storage cavity 50, the absorption device 101 is communicated with the air inlet device 100, and industrial steam flows into the absorption device 101 through the air inlet device 100, and then, the industrial steam and the ice water are fully mixed through the absorption device 101, the industrial steam is rapidly cooled, the water-soluble steam is dissolved in the water for recycling, the water-insoluble steam overflows the ice water and is stored in the water storage cavity 50, the crystallization device 102 is arranged in the condensation cavity 30, the air pressure in the condensation cavity 30 can be reduced through the crystallization device 102, the water-insoluble and cooled steam in the water storage cavity 50 can be sucked into the condensation cavity 30, the steam in the condensation cavity 30 is mixed with aerosol particles, and the steam can be rapidly condensed and recycled.

Beneficially, a water inlet pipe 47 is fixedly connected to the left end of the water tank 51, a water inlet channel 49 is arranged in the water inlet pipe 47 in a left-right through manner, ice water can be added into the water storage cavity 50 through the water inlet channel 49, a water inlet valve 48 with an opening facing the water storage cavity 50 is fixedly arranged in the water inlet channel 49, a water outlet pipe 43 is fixedly connected to the lower end of the water tank 51, a water outlet channel 41 is arranged in the water outlet pipe 43 in a vertical through manner, the ice water in the water storage cavity 50 can be discharged through the water outlet channel 41, a water outlet valve 42 with an opening deviating from the water storage cavity 50 is fixedly arranged in the water outlet channel 41, the water outlet valve 42 is electrified, the ice water in the water storage cavity 50 can be discharged through the water outlet channel 41 at this time, the water inlet valve 48 is electrified, and the ice water can be added into the.

According to an embodiment, the air intake apparatus 100 is described in detail below, the air intake apparatus 100 includes a fixed pipe 58 fixedly connected to a left end of the water tank 51, a guide chute 60 with a leftward opening is disposed in the fixed pipe 58, a sliding piston 67 is slidably disposed in the guide chute 60, a through groove 59 is disposed in the sliding piston 67 and penetrates left and right, a sliding pipe 57 is fixedly connected to a right end of the sliding piston 67, the sliding pipe 57 and the fixed pipe 58 are slidably connected, a right end of the sliding pipe 57 extends into the water storage cavity 50 and is connected to the absorption device 101, an air intake channel 56 is disposed in the sliding pipe 57 and penetrates left and right, a left side of the air intake channel 56 is communicated with the through groove 59, a right side of the air intake channel 56 is communicated with the absorption device 101, industrial steam enters the through the guide chute 60 into the through groove 59 and the air intake channel 56, and into the absorption device 101.

Beneficially, the fixed rod 65 is fixed on the inner wall of the right side of the sliding chute 60 in an up-down symmetrical manner, the fixed rod 65 is connected to the sliding piston 67 in a sliding manner, a rack 64 is fixedly arranged in one end face of the fixed rod 65 close to the center of symmetry, a connecting gear 63 is arranged in the through groove 59 in an up-down symmetrical manner and in a rotatable manner, the connecting gear 63 is meshed with the rack 64, a connecting shaft 62 is fixedly connected in the connecting gear 63, the connecting shaft 62 is rotatably connected between the front inner wall and the rear inner wall of the through groove 59, a baffle 61 is rotatably arranged on the front side of the connecting gear 63, the baffle 61 is fixedly connected to the connecting shaft 62, two compression springs 66 are fixedly connected between the right end of the sliding piston 67 and the inner wall of the right side of the sliding chute 60, when no industrial steam passes through the through groove 59, the, promote sliding piston 67 slides rightwards, and then drives sliding tube 57 slides rightwards, simultaneously sliding piston 67 with relative slip and compression between the dead lever 65 compression spring 66 passes through simultaneously rack 64 drives connecting gear 63 rotates, and then passes through connecting axle 62 drives baffle 61 rotates and opens logical groove 59, the intercommunication this moment logical groove 59 with lead spout 60, when do not have the industry steam to flow in the lead spout 60, push under compression spring 66's spring action sliding piston 67 slides to the left, and then passes through rack 64 connecting axle 62 drives baffle 61 rotates and recloses logical groove 59.

According to the embodiment, the details of the absorption device 101 are described below, the absorption device 101 includes a rotating pipe 44 rotatably disposed in the water storage cavity 50, the rotating pipe 44 is provided with a left-opening air guide hole 39 therein, the right end of the sliding pipe 57 extends into the air guide hole 39 and is in threaded connection with the rotating pipe 44, a downward-opening through hole 40 is disposed in the inner wall of the lower side of the air guide hole 39 and is communicated with the inner wall, a connecting rod 54 is rotatably connected to the circumferential surface of the rotating pipe 44, a cavity 55 is disposed in the connecting rod 54, the cavity 55 is capable of being communicated with the through hole 40, air exchanging pipes 45 are fixedly connected to the upper end and the left and right ends of the connecting rod 54, an air exchanging cavity 46 opening toward the connecting rod 54 is disposed in the air exchanging cavity 46 and is communicated with the cavity 55, air exchanging holes are disposed in the air exchanging pipes 45, ice water in the water storage cavity 50, the industrial steam in the air exchange cavity 46 can enter the water storage cavity 50, the sliding pipe 57 slides rightwards and drives the rotating pipeline 44 to rotate, so that the through hole 40 is communicated with the cavity 55, the industrial steam enters the air guide hole 39 through the through groove 59 and the air inlet channel 56, then enters the cavity 55 through the through hole 40, then enters the air exchange cavity 46, further enters the water storage cavity 50 through the air exchange pipe 45, is fully mixed with ice water and is cooled, the steam which can be dissolved in water is dissolved in the water for recycling, and the water-insoluble steam overflows the ice water and is stored in the water storage cavity 50.

Advantageously, a cantilever shaft 38 is attached to the right end of the rotating pipe 44, the cantilever shaft 38 is rotatably connected to the right inner wall of the water storage chamber 50, and the rotating pipe 44, the connecting rod 54 and the ventilation pipe 45 can be supported by the cantilever shaft 38.

According to the embodiment, the crystallization device 102 is described in detail below, the crystallization device 102 includes a transmission cavity 20 disposed in a lower inner wall of the condensation cavity 30, a sliding gear 17 is rotatably and slidably disposed in the transmission cavity 20, a motor shaft 18 is splined in the sliding gear 17, a motor 23 is fixedly disposed in an upper inner wall of the transmission cavity 20, an upper end of the motor shaft 18 is connected to the motor 23, a fixed gear 14 is rotatably disposed on a right side of the sliding gear 17, the fixed gear 14 is capable of meshing with the sliding gear 17, a screw 13 is fixedly connected to an upper end of the fixed gear 14, a guide hole 12 is disposed in an upper inner wall of the transmission cavity 20, the upper inner wall of the guide hole 12 is communicated with the condensation cavity 30, a sliding rod 37 is slidably disposed in the guide hole 12, and a threaded hole 68 is vertically communicated in the sliding rod 37, the upper end of the screw 13 extends into the threaded hole 68 and is in threaded connection with the sliding rod 37, the upper end of the sliding rod 37 extends into the condensation chamber 30 and is fixedly connected with a sliding plate 25, aerosol particles are stored on the sliding plate 25, when the sliding gear 17 is meshed with the fixed gear 14, the motor 23 is started, the sliding gear 17 is driven to rotate by the motor shaft 18, the fixed gear 14 is driven to rotate, the sliding rod 37 is driven to descend by the screw 13, the sliding plate 25 is driven to descend, the air pressure in the condensation chamber 30 is reduced, water-insoluble steam in the water storage chamber 50 is sucked into the condensation chamber 30, and the steam and the aerosol particles are mixed and quickly condensed.

Advantageously, a fixed block 21 is rotatably connected to the upper end of the sliding gear 17, an electromagnetic spring 22 is fixedly connected between the upper end of the fixed block 21 and the inner wall of the upper side of the transmission chamber 20, a contact switch 24 is fixedly connected to the inner wall of the lower side of the condensation chamber 30, the contact switch 24 is electrically connected to the electromagnetic spring 22, and when the sliding plate 25 slides down and contacts the contact switch 24, the electromagnetic spring 22 is energized to drive the fixed block 21 and the sliding gear 17 to slide up, so that the sliding gear 17 is disengaged from the fixed gear 14.

Beneficially, a driving gear 19 is rotatably provided at the lower side of the sliding gear 17, a driven gear 16 is provided at the right end of the driving gear 19 in a meshed manner, the driven gear 16 is fixedly connected with a fixed shaft 15, a sliding shaft 36 is slidably and rotatably provided at the upper side of the fixed shaft 15, a spline hole 35 with a downward opening is provided in the sliding shaft 36, the upper end of the fixed shaft 15 extends into the spline hole 35 and is in splined connection with the sliding shaft 36, the sliding shaft 36 and the screw 13 can rotate relatively, the upper end of the sliding shaft 36 is rotatably connected to the sliding plate 25, a gear cavity 28 is provided in the sliding plate 25, a pinion 27 is rotatably provided in the gear cavity 28, the pinion 27 is fixedly connected to the sliding shaft 36, large gears 34 are symmetrically provided at the left and right ends of the pinion 27 in a meshed manner, and a fan shaft 33 is fixedly connected in the, a fan cavity 31 with an upward opening is symmetrically arranged at the left and the right in the sliding plate 25, the upper end of the fan shaft 33 extends into the fan cavity 31 and is fixedly connected with the fan 26, a filter screen 29 is fixedly arranged on the upper side of the fan 26, steam and aerosol particles cannot enter the fan cavity 31 through the filter screen 29, the motor 23 is started, thereby driving the driving gear 19 to rotate through the motor shaft 18, and further driving the driven gear 16 to rotate, the fixed shaft 15 further drives the sliding shaft 36 to rotate, the sliding plate 25 slides to drive the sliding shaft 36 to slide, and simultaneously the sliding shaft 36 rotates and drives the pinion 27 to rotate, thereby driving the bull gear 34 to rotate, and further driving the fan 26 to rotate through the fan shaft 33, thereby blowing the aerosol particles in the condensation chamber 30 to allow the vapor to fully contact the aerosol particles.

The following detailed description of the steps of the industrial steam rapid condensation recycling device in the present disclosure is provided with reference to fig. 1 to 3:

initially, the sliding piston 67 is at the left limit position, the shutter 61 closes the through slot 59, the compression spring 66 is in the normal state, the through hole 40 is opened downward and is not communicated with the cavity 55, the water inlet valve 48 and the water outlet valve 42 are in the closed state, the sliding plate 25 is at the upper limit position, the electromagnetic spring 22 is in the non-energized state, and the sliding gear 17 is engaged with the fixed gear 14.

When the steam generator is used, the water inlet valve 48 is electrified, ice water is added into the water storage cavity 50 through the water inlet channel 49 until the liquid level of water in the water storage cavity 50 is higher than the ventilation pipe 45, at the moment, industrial steam passes through the guide chute 60 and pushes the sliding piston 67 to slide rightwards, so that the sliding pipe 57 is driven to slide rightwards, at the same time, the sliding piston 67 and the fixed rod 65 slide relatively and compress the compression spring 66, at the same time, the connecting gear 63 is driven to rotate through the rack 64, the baffle 61 is driven to rotate through the connecting shaft 62 and the through groove 59 is opened, at the moment, the through groove 59 is communicated with the guide chute 60, at the moment, the industrial steam in the guide chute 60 enters the air guide hole 39 through the through groove 59 and the air inlet channel 56, at the same time, the sliding pipe 57 slides and drives the rotating pipeline 44 to rotate, so that the through hole 40 is communicated with, and then enters the water storage cavity 50 through the air exchange pipe 45, is fully mixed with the ice water and is cooled, at the moment, steam which can be dissolved in water is dissolved in the water for recycling, and the steam which is not dissolved in water overflows the ice water and is stored in the water storage cavity 50.

At this time, the motor 23 is started, and then the sliding gear 17 is driven to rotate by the motor shaft 18, and then the fixed gear 14 is driven to rotate, and then the sliding rod 37 is driven to descend by the screw 13, and then the sliding plate 25 is driven to descend, and then the air pressure in the condensation chamber 30 is reduced, and further the water-insoluble steam in the water storage chamber 50 is sucked into the condensation chamber 30, and at the same time, the motor shaft 18 rotates and drives the driving gear 19 to rotate, and further drives the driven gear 16 to rotate, and further drives the sliding shaft 36 to rotate by the fixed shaft 15, the sliding shaft 36 can be driven to slide when the sliding plate 25 slides, and simultaneously the sliding shaft 36 rotates and drives the pinion 27 to rotate, and further drives the bull gear 34 to rotate, and further drives the fan 26 to rotate by the fan shaft 33, and further can blow the aerosol particles in the condensation chamber 30, so that the steam can, the electromagnetic spring 22 is energized to slide the fixed block 21 and the slide gear 17, thereby disengaging the slide gear 17 from the fixed gear 14.

When the temperature of the ice water in the water storage cavity 50 rises to be close to the boiling point, the introduction of the industrial steam into the guide chute 60 is stopped, the sliding piston 67 is driven to slide leftwards under the action of the elastic force of the compression spring 66, the baffle 61 is driven to rotate through the rack 64, the connecting gear 63 and the connecting shaft 62 and the through groove 59 is closed, meanwhile, the sliding pipe 57 slides leftwards and drives the rotating pipeline 44 to rotate, the through hole 40 is not communicated with the cavity 55, the water outlet valve 42 is electrified, the water in the water storage cavity 50 is discharged through the water outlet channel 41, the connecting pipe 53 can be separated from the heat insulation box 11, crystals condensed in the condensation cavity 30 are taken out, aerosol particles in the condensation cavity 30 are replaced, and finally the device is restored to the initial state.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. A rapid condensation and recovery device for industrial steam comprises a heat insulation box and a water tank; a water storage cavity is arranged in the water tank, ice water is stored in the water storage cavity, a condensation cavity is arranged in the heat insulation box, aerosol particles are stored in the condensation cavity, steam and the aerosol particles are mixed to facilitate steam condensation, a connecting pipe is fixedly connected between the heat insulation box and the upper end face of the water tank, a connecting channel is arranged in the connecting pipe in a run-through mode, and the steam in the water storage cavity can enter the condensation cavity through the connecting channel; the left end of the water tank is connected with an air inlet device, and industrial steam can be discharged into the water storage cavity through the air inlet device; an absorption device is arranged in the water storage cavity and is communicated with the air inlet device, industrial steam flows into the absorption device through the air inlet device, the industrial steam and ice water are fully mixed through the absorption device, the industrial steam is rapidly cooled, water-soluble steam is dissolved in water for recovery, and water-insoluble steam overflows the ice water and is stored in the water storage cavity; the condensation cavity is internally provided with a crystallization device, the crystallization device can reduce the air pressure in the condensation cavity, so that the steam which is insoluble in water and cooled in the water storage cavity can be sucked into the condensation cavity, the steam in the condensation cavity is mixed with aerosol particles, and the steam can be rapidly condensed and recycled.

2. The rapid industrial steam condensation and recovery device as claimed in claim 1, wherein: the left end of the water tank is fixedly connected with a water inlet pipe, a water inlet channel is arranged in the water inlet pipe in a left-right through mode, ice water can be added into the water storage cavity through the water inlet channel, and a water inlet valve with an opening facing the water storage cavity is fixedly arranged in the water inlet channel; the water tank is characterized in that a water outlet pipe is fixedly connected to the lower end of the water tank, a water outlet channel is arranged in the water outlet pipe in a vertically through mode, ice water in the water storage cavity can be discharged through the water outlet channel, and a water outlet valve with an opening deviating from the water storage cavity is fixedly arranged in the water outlet channel.

3. The rapid industrial steam condensation and recovery device as claimed in claim 1, wherein: the air inlet device comprises a fixed pipe fixedly connected with the left end of the water tank, a guide chute with a leftward opening is arranged in the fixed pipe, a sliding piston is slidably arranged in the guide chute, a through groove is formed in the sliding piston in a left-right through manner, a sliding pipe is fixedly connected with the right end of the sliding piston, and the sliding pipe is slidably connected with the fixed pipe; the right end of the sliding pipe extends into the water storage cavity and is connected with the absorption device, an air inlet channel is arranged in the sliding pipe in a left-right through mode, the left side of the air inlet channel is communicated with the through groove, and the right side of the air inlet channel is communicated with the absorption device.

4. The rapid industrial steam condensation and recovery device as claimed in claim 3, wherein: the inner wall of the right side of the guide chute is fixedly connected with fixed rods in an up-down symmetrical manner, the fixed rods are connected to the sliding piston in a sliding manner, racks are fixedly arranged in one end face, close to a symmetrical center, of the fixed rods, connecting gears are arranged in the through grooves in an up-down symmetrical manner and can rotate, the connecting gears are meshed with the racks, connecting shafts are fixedly connected in the connecting gears, the connecting shafts are rotatably connected between the front inner wall and the rear inner wall of the through grooves, baffles are rotatably arranged on the front sides of the connecting gears, and the baffles are fixedly; two compression springs are fixedly connected between the right end of the sliding piston and the inner wall of the right side of the guide chute.

5. The rapid industrial steam condensation and recovery device as claimed in claim 4, wherein: the absorption device comprises a rotary pipeline which is rotatably arranged in the water storage cavity, an air guide hole with a leftward opening is arranged in the rotary pipeline, the right end of the sliding pipe extends into the air guide hole and is in threaded connection with the rotary pipeline, a through hole with a downward opening is formed in the inner wall of the lower side of the air guide hole in a communicated manner, a connecting rod is rotatably connected to the circumferential surface of the rotary pipeline, a cavity is arranged in the connecting rod, and the cavity can be communicated with the through hole; the upper end, the left end and the right end of the connecting rod are fixedly connected with air exchange pipes, air exchange cavities with openings facing the connecting rod are arranged in the air exchange pipes, the air exchange cavities are communicated with cavities, air exchange holes are formed in the air exchange pipes, ice water in the water storage cavity cannot enter the air exchange cavities, and industrial steam in the air exchange cavities can enter the water storage cavity.

6. The rapid industrial steam condensing and recycling device according to claim 5, wherein: the right end of the rotating pipeline is fixedly connected with a cantilever shaft, and the cantilever shaft is rotatably connected to the inner wall of the right side of the water storage cavity.

7. The rapid industrial steam condensation and recovery device as claimed in claim 1, wherein: the crystallization device comprises a transmission cavity arranged in the inner wall of the lower side of the condensation cavity, a sliding gear is rotatably and slidably arranged in the transmission cavity, a motor shaft is connected with an internal spline of the sliding gear, a motor is fixedly arranged in the inner wall of the upper side of the transmission cavity, and the upper end of the motor shaft is in power connection with the motor; the right side of the sliding gear is rotatably provided with a fixed gear which can be meshed with the sliding gear, the upper end of the fixed gear is fixedly connected with a screw, the inner wall of the upper side of the transmission cavity is internally provided with a guide hole, and the inner wall of the upper side of the guide hole is communicated with the condensation cavity; the aerosol condensation device is characterized in that a sliding rod is slidably arranged in the guide hole, a threaded hole is formed in the sliding rod in a vertically through mode, the upper end of the screw rod extends into the threaded hole and is in threaded connection with the sliding rod, the upper end of the sliding rod extends into the condensation cavity and is fixedly connected with a sliding plate, and aerosol particles are stored on the upper side of the sliding plate.

8. The rapid industrial steam condensing and recycling device according to claim 7, wherein: the sliding gear upper end is rotated and is connected with the fixed block, the fixed block upper end with the electromagnetic spring has been linked firmly between the transmission chamber upside inner wall, contact switch has been linked firmly on the chamber downside inner wall that condenses, contact switch electric connection in the electromagnetic spring.

9. The rapid industrial steam condensing and recycling device according to claim 8, wherein: the lower side of the sliding gear is rotatably provided with a driving gear, the right end of the driving gear is meshed with a driven gear, a fixed shaft is fixedly connected in the driven gear, the upper side of the fixed shaft is slidably and rotatably provided with a sliding shaft, a spline hole with a downward opening is formed in the sliding shaft, the upper end of the fixed shaft extends into the spline hole and is in spline connection with the sliding shaft, and the sliding shaft and the screw rod can rotate relatively; the upper end of the sliding shaft is rotatably connected with the sliding plate, a gear cavity is arranged in the sliding plate, a pinion is rotatably arranged in the gear cavity and fixedly connected with the sliding shaft, the left end and the right end of the pinion are symmetrically provided with big gears in a meshed mode, a fan shaft is fixedly connected in the big gears, fan cavities with upward openings are symmetrically arranged in the sliding plate in a left-right mode, and the upper end of the fan shaft extends into the fan cavities and is fixedly connected with a fan; the upper side of the fan is fixedly provided with a filter screen, and steam and aerosol particles cannot enter the fan cavity through the filter screen.