阅读说明：本技术 一种石油焦煅烧用蒸汽循环利用装置 (Steam recycling device for petroleum coke calcination ) 是由 欧阳霞 于 2021-10-20 设计创作，主要内容包括：本发明涉及蒸汽循环利用技术领域,具体涉及一种石油焦煅烧用蒸汽循环利用装置,包括有固定底箱、支撑底座、炼化炉、固定圆架、定位底座、盖子、启动按钮、停止按钮、冷却机构和储气机构,固定底箱底部连接有支撑底座,固定底箱内底部右侧连接有定位底座,固定底箱后侧内壁的右侧连接有固定圆架,固定圆架内壁连接有炼化炉,炼化炉顶部带有可取下的炉盖。石油焦在炼化炉内煅烧时所产生的蒸汽通过进气管排入冷却箱与密闭盖之间,冷却模组对蒸汽进行冷却,进而冷却后的蒸汽通过导气异型管排入储气炉内,打开第一球形电磁阀能够将蒸汽排出,过滤底网能够对蒸汽进行过滤,从而达到了方便工作人员对蒸汽进行循环利用,不浪费水资源的效果。(The invention relates to the technical field of steam recycling, in particular to a steam recycling device for petroleum coke calcination, which comprises a fixed bottom box, a supporting base, a refining furnace, a fixed round frame, a positioning base, a cover, a starting button, a stopping button, a cooling mechanism and a gas storage mechanism, wherein the bottom of the fixed bottom box is connected with the supporting base, the right side of the bottom in the fixed bottom box is connected with the positioning base, the right side of the inner wall of the rear side of the fixed bottom box is connected with the fixed round frame, the inner wall of the fixed round frame is connected with the refining furnace, and the top of the refining furnace is provided with a detachable furnace cover. Steam generated when petroleum coke is calcined in the refining furnace is discharged into the space between the cooling box and the closed cover through the air inlet pipe, the cooling module cools the steam, the cooled steam is discharged into the air storage furnace through the air guide special pipe, the first spherical electromagnetic valve is opened to discharge the steam, and the filtering bottom net can filter the steam, so that the effect of facilitating cyclic utilization of the steam by workers and not wasting water resources is achieved.)

1. A steam recycling device for petroleum coke calcination comprises a fixed bottom box (1) and a supporting base (2), wherein the bottom of the fixed bottom box (1) is connected with the supporting base (2), and the steam recycling device is characterized by further comprising a refining furnace (3), a fixed round frame (4), a positioning base (5), a cover (60), a starting button (61), a stopping button (62), a cooling mechanism (7) and a gas storage mechanism (8), wherein the refining furnace (3) is arranged on the right side of the inner wall of the fixed bottom box (1) through the fixed round frame (4), the bottom of the refining furnace (3) is supported by the positioning base (5), the positioning base (5) is connected above the supporting base (2), the front side surface of the supporting base (2) is movably connected with the cover (60), the starting button (61) and the stopping button (62) are arranged on the supporting base (2) on the inner side of the cover (60), the cooling mechanism (7) is arranged on one side in the fixed bottom box (1), one side of a cooling mechanism (7) at the bottom in the fixed bottom box (1) is provided with a gas storage mechanism (8), a flue gas channel of the refining furnace (3) is communicated with the cooling mechanism (7), and a gas outlet channel of the cooling mechanism (7) is communicated with the gas storage mechanism (8);

the cooling mechanism (7) comprises a cooling box (71), a closed cover (72), a sealing outer sleeve (73), an air inlet pipe (74), a fixed cross plate (75), a fixed short shaft (76), an air guide roller (77), a cooling module (78) and a temperature sensor (79), wherein the bottom of the fixed bottom box (1) is connected with the cooling box (71), the outer ring at the front part of the cooling box (71) is connected with the sealing outer sleeve (73), one side of the sealing outer sleeve (73) is connected with the closed cover (72), the cooling box (71) and the closed cover (72) form the sealed cooling box, the air inlet pipe (74) is communicated between the cooling box (71) and the refining furnace (3), the fixed cross plate (75) is connected to the outer side of the cooling box (71), the fixed short shaft (76) is rotatably connected with the fixed short shaft (76), one end of the fixed short shaft (76) penetrates through the rear side wall of the cooling box (71), the fixed short shaft (76) is rotatably connected with the rear side wall of the cooling box (71), an air guide roller (77) is connected to a fixed short shaft (76) on the inner wall of the cooling box (71), a cooling module (78) is connected to the closed cover (72), a temperature sensor (79) is arranged on the cooling module (78), the cooling module (78) is communicated with an air outlet of the closed cover (72), and the closed cover (72) is communicated with the air storage mechanism (8).

2. The steam recycling device for petroleum coke calcination, according to claim 1, characterized in that the gas storage mechanism (8) comprises an installation base (80), a gas storage furnace (81), gas guide special-shaped pipes (82), a filter bottom net (83), gas outlet pipes (85) and first spherical electromagnetic valves (86), the installation base (80) is connected to the front side of the bottom cooling mechanism (7) in the fixed bottom box (1), the gas storage furnace (81) is connected to the top of the installation base (80), the gas guide special-shaped pipes (82) are communicated between the gas storage furnace (81) and the gas outlet of the closed cover (72), the filter bottom net (83) is connected to the lower portion of the inner wall of the gas storage furnace (81), the gas outlet pipes (85) are communicated to the bottom of the gas storage furnace, the gas outlet pipes (85) penetrate through the installation base (80), and the first spherical electromagnetic valves (86) are connected to the gas outlet pipes (85).

3. The steam recycling device for petroleum coke calcination, as claimed in claim 2, further comprising a filtering mechanism (9), wherein the filtering mechanism (9) is arranged in the cooling tank (71), the filtering mechanism (9) comprises an air guide turbine (91), an inner toothed ring (92), a filtering bottom box (93), a groove plate (94), a fixed cross bar (95), a spiral plate (96), a flat belt (97), a first driven gear (98), a fixed bottom block (99), a first positioning guide pillar (910), a limiting roller (911), a first return spring (912) and a positioning guide rail (913), the air guide turbine (91) is connected to a fixed short shaft (76) at the front side of the air guide roller (77), the inner toothed ring (92) is connected to the inner wall of the closed cover (72), the four filtering bottom boxes (93) are uniformly connected to the inner wall of the air guide roller (77) at intervals along the circumferential direction, one side of the bottoms of the four filtering bottom boxes (93), which is far away from the air guide roller (77), is hinged with one groove plate (94), the side wall of each filtering bottom box (93) is rotatably connected with two fixed cross rods (95), the fixed cross rod (95) at the inner side of each filtering bottom box (93) is connected with a spiral plate (96), the fixed cross rod (95) extending to the outer wall of each filtering bottom box (93) is provided with a belt pulley, the belt pulleys of the fixed cross rods (95) in the same group are connected through a flat belt (97), the front side of the fixed cross rod (95) at one side close to the hinge point of the groove plate (94) is connected with a first driven gear (98), four first driven gears (98) are all meshed with the inner toothed ring (92), one side of each filtering bottom box (93) far away from the first driven gear (98) is connected with a fixed bottom block (99), the fixed bottom block (99) is connected with two first positioning guide columns (910), the first positioning guide columns (910) are movably connected with the groove plate (94), and a first reset spring (912) is connected between the fixed bottom block (99) and the groove plate (94), one side, far away from the hinge point, of the groove plate (94) is connected with a limiting roller (911), the rear side face of the closed cover (72) is connected with a positioning guide rail (913), and the positioning guide rail (913) is in contact with the limiting roller (911).

4. The steam recycling device for petroleum coke calcination, according to claim 3, characterized in that the device further comprises an adsorption mechanism (10), the adsorption mechanism (10) is connected between the cooling box (71) and the air guide roller (77), the adsorption mechanism (10) comprises a limiting top plate (101), a fixed short plate (102), an outer toothed ring (103), a fixed top box (104), a movable slider (105), a second positioning guide post (106), a second return spring (107), a rotary air pipe (108), an adsorption screen cylinder (109), a waste residue collection frame (1010), a scraping plate (1011), a flexible hose (1012), an air suction pump (1013), a dust cover (1014), a second driven gear (1015) and a pressure sensor (1016), the front side surface of the air guide roller (77) is connected with four limiting top plates (101) through the fixed short plates (102) along the circumferential direction, one side of the outer surface of the air guide roller (77), which is far away from the inner toothed ring (92), is connected with the outer toothed ring (103), the top of the cooling box (71) is connected with a fixed top box (104), two second positioning guide columns (106) are connected in a cavity inside the front part of the fixed top box (104), the two second positioning guide columns (106) are connected with a movable sliding block (105) in a sliding mode, a second reset spring (107) is connected between the top of the movable sliding block (105) and the inner wall of the fixed top box (104), the middle part of the movable sliding block (105) is connected with a rotary air pipe (108) in a rotating mode, the middle part of the rotary air pipe (108) is connected with an adsorption sieve tube (109), one side, close to the refining furnace (3), of the rotary air pipe (108) is connected with a waste residue collecting frame (1010) in a rotating mode, a scraping plate (1011) is connected in the waste residue collecting frame (1010), the scraping plate (1011) is in contact with the adsorption sieve tube (109), the top of the fixed top box (104) is connected with an air extracting pump (1013), and an air outlet of the air pump (1013) is connected with a dust cover (1014), an air outlet of the air pump (1013) is connected with a telescopic hose (1012), the telescopic hose (1012) is rotatably connected with a rotary air pipe (108), the rear part of the rotary air pipe (108) is connected with a second driven gear (1015), the second driven gear (1015) is meshed with an outer gear ring (103), the bottom of a cavity in the front part of the fixed top box (104) is connected with a pressure sensor (1016), and the pressure sensor (1016) is contacted with a movable slider (105).

5. The steam recycling device for petroleum coke calcination, according to claim 4, characterized in that the device further comprises a buffer mechanism (11), the air guide special pipe (82) is provided with the buffer mechanism (11), the buffer mechanism (11) is connected with the gas storage furnace (81), the buffer mechanism (11) comprises a return pipe (111), a limit vertical plate (112), a buffer cylinder (113), a second spherical solenoid valve (114), a second air pressure sensor (115), an electric push rod (116), a lifting bottom block (117), a first flow-limiting guide plate (118), a connecting vertical rod (119), a limit horizontal plate (1110), an L-shaped vertical rod (1111), a second flow-limiting guide plate (1112), a third positioning guide post (1113), a third return spring (1114) and a first air pressure sensor (1115), the buffer cylinder (113) is communicated with the upper side of the air guide special pipe (82), the upper portion of the buffer cylinder (113) is communicated with the upper portion of the gas storage furnace (81) through the return pipe (111), a limiting vertical plate (112) is connected between the outer wall of the air guide special pipe (82) and the outer wall of the return pipe (111), a second spherical electromagnetic valve (114) is connected on the air guide special pipe (82), the second spherical electromagnetic valve (114) respectively controls the air guide special pipe (82) and a buffer cylinder (113), a second air pressure sensor (115) is embedded in the upper arm of the buffer cylinder (113), an electric push rod (116) is connected on the inner wall of the left side of the fixed bottom box (1), a lifting bottom block (117) is connected on an expansion link of the electric push rod (116), a first current-limiting guide plate (118) is connected on the lower part in the limiting vertical plate (112) in a sliding manner, the first current-limiting guide plate (118) is fixedly connected with the lifting bottom block (117), the first current-limiting guide plate (118) is connected with the air guide special pipe (82) in a sliding manner, two connecting vertical rods (119) are symmetrically connected on the left and right of the top of the first current-limiting guide plate (118), a limiting transverse plate (1110) is connected between the top ends of the two connecting vertical rods (119), upper portion bilateral symmetry in spacing riser (112) is connected with two third positioning guide pillar (1113), slidingtype connection has second current-limiting baffle (1112) between two third positioning guide pillar (1113), second current-limiting baffle (1112) bottom bilateral symmetry is connected with two L type montants (1111), contact with L type montant (1111) after spacing diaphragm (1110) the downstream, it has one third reset spring (1114) all to overlap on two third positioning guide pillar (1113), third reset spring (1114) one end is connected with second current-limiting baffle (1112), the other one end of third reset spring (1114) and spacing riser (112) inner wall connection, gas storage furnace (81) upper portion is connected with first baroceptor (1115).

6. The petroleum coke calcination steam recycling device as claimed in claim 5, characterized in that it further comprises a shunting mechanism (12), the right side of the outer wall of the fixed bottom box (1) close to the gas storage furnace (81) is provided with the shunting mechanism (12), the shunting mechanism (12) is connected with the gas outlet pipe (85), the shunting mechanism (12) comprises a fixed bottom frame (121) and a shunting bottom cylinder (122), spacing funnel (123), sieve trachea (124) and play liquid hose (125), the right side that fixed under casing (1) outer wall is close to gas storage furnace (81) is connected with fixed chassis (121), fixed chassis (121) in-connection has a reposition of redundant personnel end section of thick bamboo (122), reposition of redundant personnel end section of thick bamboo (122) is linked together with outlet duct (85), reposition of redundant personnel end section of thick bamboo (122) inner wall upside is connected with spacing funnel (123), reposition of redundant personnel end section of thick bamboo (122) top pipe connection has trachea (124) of sieving, reposition of redundant personnel end section of thick bamboo (122) bottom is connected with play liquid hose (125).

7. The steam recycling device for petroleum coke calcination as claimed in claim 6, wherein the cooling module (78) comprises a hollow circular block and a plurality of condensing pipes, the hollow circular block is connected to the middle part of the rear side surface of the closed cover (72), and the plurality of condensing pipes are connected to the hollow circular block.

8. The petroleum coke calcination steam recycling device as claimed in claim 7, further comprising an electric cabinet (6), wherein the electric cabinet (6) is mounted at the lower part of the left front side of the fixed bottom box (1), the electric cabinet (6) internally comprises a switching power supply, a power supply module and a control module, the switching power supply supplies power to the steam recycling device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the starting button (61), the stopping button (62), the first air pressure sensor (1115), the second air pressure sensor (115), the pressure sensor (1016) and the temperature sensor (79) are all electrically connected with the control module, and the cooling module (78), the electric push rod (116), the first spherical electromagnetic valve (86), the second spherical electromagnetic valve (114) and the air suction pump (1013) are all connected with the control module through peripheral circuits.

Technical Field

The invention relates to the technical field of steam recycling, in particular to a steam recycling device for petroleum coke calcination.

Background

In order to reduce the hydrogen content of petroleum coke reworked products and improve the graphitization degree of the petroleum coke, thereby improving the high-temperature strength and the heat resistance of a graphite electrode and improving the conductivity of the graphite electrode, the petroleum coke needs to be calcined, more steam is generated during calcination, in order to more reasonably apply the steam, the steam generated during the calcination of the petroleum coke needs to be recycled, and when the steam generated during the calcination of the petroleum coke is recycled, the steam needs to be cooled, at present, a cooling method of water spray mixing is generally adopted to recycle the steam generated during the calcination of the petroleum coke, but the recycling of the steam generated during the calcination of the petroleum coke by the method causes the waste of water resources, and a large amount of particles and distilled water are stored in the steam, and the impurities and distilled water are difficult to be treated by the cooling method of water spray mixing, the purity of the steam is easily reduced, and the subsequent use is influenced.

Therefore, the steam recycling device for petroleum coke calcination needs to be designed, which can recycle steam, does not waste water resources, can treat impurities and distilled water, and does not affect subsequent use, so as to solve the problem of the prior art.

Disclosure of Invention

In order to overcome the steam that produces when adopting the cooling method of water spray mixing to petroleum coke calcination to retrieve cyclic utilization and can cause the waste of water resource, be difficult to handle impurity and distilled water, easily lead to the purity of steam to reduce, influence follow-up shortcoming, technical problem: the steam recycling device for petroleum coke calcination is convenient for workers to recycle steam, does not waste water resources, and does not influence subsequent use.

The technical scheme is as follows: a steam recycling device for petroleum coke calcination comprises a fixed bottom box and a supporting base, wherein the bottom of the fixed bottom box is connected with the supporting base, the steam recycling device also comprises a refining furnace, a fixed round frame, a positioning base, a cover, a starting button, a stopping button, a cooling mechanism and a gas storage mechanism, the refining furnace is arranged on the right side of the inner wall of the fixed bottom box through the fixed round frame, the bottom of the refining furnace is supported by the positioning base, the positioning base is connected above the supporting base, the front side surface of the supporting base is movably connected with the cover, the starting button and the stopping button are arranged on the supporting base on the inner side of the cover, the cooling mechanism is arranged on one side in the fixed bottom box, the gas storage mechanism is arranged on one side of the cooling mechanism on the bottom in the fixed bottom box, a flue gas channel of the refining furnace is communicated with the cooling mechanism, and a gas outlet channel of the cooling mechanism is communicated with the gas storage mechanism;

cooling body is including the cooler bin, airtight lid, sealed overcoat, the intake pipe, fixed cross plate, fixed minor axis, the air guide cylinder, cooling module and temperature sensor, the left rear side of bottom is connected with the cooler bin in the fixed under casing, the cooler bin front side is uncovered formula setting, the cooler bin front portion is connected with sealed overcoat, sealed overcoat front portion is connected with airtight lid, the intercommunication has the intake pipe between cooler bin and the refining furnace, the cooler bin outside is connected with fixed cross plate, the rotary type is connected with fixed minor axis in the fixed cross plate, cooler bin trailing flank is passed to fixed minor axis one end, fixed minor axis is connected with cooler bin trailing flank rotary type, fixed minor axis surface rear side is connected with the air guide cylinder, the air guide cylinder is located the cooler bin, airtight in-connection has the cooling module, the rear side upper portion of cooling module is connected with temperature sensor.

Optionally, the gas storage mechanism comprises an installation base, a gas storage furnace, a gas guide special pipe, a filter bottom net, a gas outlet pipe and a first spherical electromagnetic valve, the left front side of the bottom in the fixed bottom box is connected with the installation base, the top of the installation base is connected with the gas storage furnace, the gas guide special pipe is connected between the gas storage furnace and the airtight cover, the lower portion of the inner wall of the gas storage furnace is connected with the filter bottom net, the bottom of the gas storage furnace is connected with the gas outlet pipe, the gas outlet pipe penetrates through the installation base, the first spherical electromagnetic valve is connected onto the gas outlet pipe, and the first spherical electromagnetic valve is connected with the installation base.

Optionally, the device also comprises a filtering mechanism, the filtering mechanism is connected between the cooling box, the air guide roller and the fixed short shaft, the filtering mechanism comprises an air guide turbine, an inner toothed ring, a filtering bottom box, a groove plate, fixed cross rods, a spiral plate, a flat belt, a first driven gear, a fixed bottom block, a first positioning guide pillar, a limiting roller, a first reset spring and a positioning guide rail, the front side of the outer surface of the fixed short shaft is connected with the air guide turbine, the inner wall of the closed cover is connected with the inner toothed ring, the inner wall of the air guide roller is uniformly connected with four filtering bottom boxes at intervals along the circumferential direction, the four filtering bottom boxes are respectively connected with a groove plate in a rotating manner through a rotating shaft, the inner walls of the rear sides of the four filtering bottom boxes are respectively connected with a group of fixed cross rods in a rotating manner, two fixed cross rods form a group, the front ends of the four groups of fixed cross rods respectively penetrate through the four filtering bottom boxes, the middle parts of the outer surfaces of the eight fixed cross rods are respectively connected with a spiral plate, eight spiral plates are respectively positioned in four filtering bottom boxes, the front sides of four groups of fixed cross rods are all sleeved with a flat belt through belt pulleys, the front side of one fixed cross rod in each group is connected with a first driven gear, the four first driven gears are all meshed with an inner toothed ring, four filtering bottom boxes are all connected with a fixed bottom block, the fixed bottom block is connected with one side of the filtering bottom box, which is far away from a groove plate, the four fixed bottom blocks are all connected with a group of first positioning guide posts, two first positioning guide posts are in a group, the four groups of first positioning guide posts are respectively connected with four groove plates in a sliding mode, eight first positioning guide posts are all sleeved with a first reset spring, one end of the first reset spring is connected with the fixed bottom block, the other end of the first reset spring is connected with the groove plate, the front side of the groove plate is rotatably connected with a limiting roller through a rotating shaft, and the rear side surface of the sealing cover is connected with a positioning guide rail, the positioning guide rail is contacted with the limiting idler wheel.

Optionally, the cooling device also comprises an adsorption mechanism, the adsorption mechanism is connected between the cooling box and the air guide roller, the adsorption mechanism comprises a limit top plate, a fixed short plate, an outer toothed ring, a fixed top box, a movable sliding block, a second positioning guide pillar, a second reset spring, a rotary air pipe, an adsorption screen drum, a waste residue collecting frame, a scraping plate, a telescopic hose, an air suction pump, a dust cover, a second driven gear and a pressure sensor, four groups of fixed short plates are uniformly connected to the front side surface of the air guide roller along the circumferential direction at intervals, two fixed short plates form a group, the four groups of fixed short plates are respectively connected with one limit top plate, the outer toothed ring is connected to the rear side of the outer surface of the air guide roller, the top of the cooling box is connected with the fixed top box, the front part of the fixed top box is bilaterally and symmetrically connected with two second positioning guide pillars, the movable sliding block is connected between the two second positioning guide pillars, and a second reset spring is connected between the top of the movable block and the inner wall of the fixed top box, the movable sliding block middle part rotary type is connected with rotatory trachea, rotatory trachea middle part is connected with the absorption screen drum, the anterior rotary type of rotatory trachea is connected with the waste residue and collects the frame, the right part in the waste residue collection frame is connected with scrapes the flitch, scrape the flitch and adsorb the screen drum contact, fixed roof box top front side is connected with the aspiration pump, the air outlet department of aspiration pump front side is connected with the dust cover, the air outlet department of aspiration pump rear side is connected with the bellows, the bellows rotates with rotatory trachea to be connected, rotatory trachea rear portion is connected with the second driven gear, second driven gear and outer ring gear meshing, the front side sub-unit connection in the fixed roof box has pressure sensor.

Optionally, the gas storage device also comprises a buffer mechanism, the fixed bottom box, the sealing cover and the gas guide special pipe are connected with the buffer mechanism, the buffer mechanism is also fixedly connected with the gas storage furnace, the buffer mechanism comprises a return pipe, a limiting vertical plate, a buffer cylinder, a second spherical electromagnetic valve, a second air pressure sensor, an electric push rod, a lifting bottom block, a first current-limiting guide plate, a connecting vertical rod, a limiting horizontal plate, an L-shaped vertical rod, a second current-limiting guide plate, a third positioning guide pillar, a third reset spring and a first air pressure sensor, the gas outlet at the upper side of the gas guide special pipe is connected with the buffer cylinder, the buffer cylinder is fixedly connected with the gas guide special pipe, the return pipe is connected between the upper part of the buffer cylinder and the upper part of the gas storage furnace, the limiting vertical plate is connected between the outer wall of the gas guide special pipe and the outer wall of the return pipe, the second spherical electromagnetic valve is connected with the front side surface of the sealing cover, the front side of the upper part of the buffer cylinder is connected with a second air pressure sensor, the inner wall of the left side of the fixed bottom box is connected with an electric push rod, a telescopic rod of the electric push rod is connected with a lifting bottom block, the lower part in a limiting vertical plate is connected with a first current-limiting guide plate in a sliding way, the first current-limiting guide plate is fixedly connected with the lifting bottom block, the first current-limiting guide plate is connected with an air guide special pipe in a sliding way, the top part of the first current-limiting guide plate is connected with two connecting vertical rods in a bilateral symmetry way, a limiting transverse plate is connected between the top ends of the two connecting vertical rods, the upper part in the limiting vertical plate is connected with two third positioning guide columns in a bilateral symmetry way, a second current-limiting guide plate is connected between the two third positioning guide columns in a sliding way, the bottom part of the second current-limiting guide plate is connected with two L-shaped vertical rods in a bilateral symmetry way, the limiting transverse plate can be contacted with the L-shaped vertical rods after moving downwards, the two third positioning guide columns are both sleeved with a third return spring, one end of the third return spring is connected with the second current-limiting guide plate, the other end of the third return spring is connected with the inner wall of the limiting vertical plate, and the front side of the upper part of the gas storage furnace is connected with a first air pressure sensor.

Optionally, still including reposition of redundant personnel mechanism, be connected with reposition of redundant personnel mechanism on the fixed under casing, reposition of redundant personnel mechanism is including fixed chassis, reposition of redundant personnel end section of thick bamboo, spacing funnel, sieve trachea and liquid outlet hose, and the sub-unit connection of the right front side of fixed under casing has fixed chassis, and fixed chassis in-connection has a reposition of redundant personnel end section of thick bamboo, and a reposition of redundant personnel end section of thick bamboo is connected with the outlet duct, and a reposition of redundant personnel end section of thick bamboo is linked together with the outlet duct, and a reposition of redundant personnel end section of thick bamboo inner wall upside is connected with spacing funnel, and a reposition of redundant personnel end section of thick bamboo top is connected with the trachea that sieves, and a reposition of redundant personnel end section of thick bamboo bottom is connected with liquid outlet hose.

Optionally, the steam recycling device further comprises an electric cabinet, the electric cabinet is mounted at the lower portion of the left front side of the fixed bottom box, a switching power supply, a power supply module and a control module are arranged in the electric cabinet, the switching power supply supplies power to the steam recycling device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the start button, the stop button, the first air pressure sensor, the second air pressure sensor, the pressure sensor and the temperature sensor are electrically connected with the control module, and the cooling module, the electric push rod, the first spherical electromagnetic valve, the second spherical electromagnetic valve and the air pump are connected with the control module through a peripheral circuit.

Optionally, the cooling module comprises a hollow circular block and a plurality of condenser pipes, the hollow circular block is connected to the middle of the rear side face of the sealing cover, and the plurality of condenser pipes are connected to the inside of the hollow circular block.

The beneficial effects are that:

1. steam generated when petroleum coke is calcined in the refining furnace is discharged into the space between the cooling box and the closed cover through the air inlet pipe, the cooling module cools the steam, the cooled steam is discharged into the air storage furnace through the air guide special pipe, the first spherical electromagnetic valve is opened to discharge the steam, and the filtering bottom net can filter the steam, so that the effect of facilitating cyclic utilization of the steam by workers and not wasting water resources is achieved.

2. Steam gets into in filtering the under casing, and steam makes the air guide cylinder begin the reversal, and then fixed horizontal pole also drives the spiral plate reversal, and the spiral plate reversal adsorbs the small impurity in the steam, so, can avoid having impurity in the steam to follow-up use of not influencing.

3. Steam passes through in the outlet duct discharges the reposition of redundant personnel end section of thick bamboo, and spacing funnel shelters from the distilled water in to steam, and the distilled water is also just discharged from going out the liquid hose, and steam is discharged from the trachea of sieving to make steam and distilled water shunt.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

FIG. 3 is a schematic view of a first partial body structure according to the present invention.

FIG. 4 is a schematic view of a second partial body structure according to the present invention.

Fig. 5 is a schematic perspective view of the cooling mechanism of the present invention.

Fig. 6 is a schematic perspective view of the gas storage mechanism of the present invention.

Fig. 7 is a perspective view of a third embodiment of the present invention.

Fig. 8 is a schematic view of a first partial body construction of a filter mechanism of the present invention.

Fig. 9 is a schematic view of a second partial body construction of the filter mechanism of the present invention.

Fig. 10 is a perspective view of a third portion of the filter mechanism of the present invention.

Fig. 11 is a perspective view of a fourth portion of the filter mechanism of the present invention.

Fig. 12 is a schematic view of a first partial bulk structure of the adsorption mechanism of the present invention.

Fig. 13 is a schematic view of a second partial body structure of the adsorption mechanism of the present invention.

Fig. 14 is a perspective view of a third part of the adsorption mechanism of the present invention.

Fig. 15 is an enlarged schematic view of part a of the present invention.

Fig. 16 is a schematic diagram of a first partial body structure of the cache mechanism of the present invention.

Fig. 17 is a schematic diagram of a second partial body structure of the cache mechanism of the present invention.

Fig. 18 is a perspective view of a third part of the buffer mechanism of the present invention.

Fig. 19 is a perspective view of a fourth portion of the buffer mechanism of the present invention.

Fig. 20 is an enlarged view of part B of the present invention.

Fig. 21 is a partial perspective view of the shunt mechanism of the present invention.

FIG. 22 is a block circuit diagram of the present invention.

Fig. 23 is a schematic circuit diagram of the present invention.

The meaning of the reference symbols in the figures: 1-fixed bottom box, 2-supporting base, 3-refining furnace, 4-fixed round frame, 5-positioning base, 6-electric control box, 60-cover, 61-start button, 62-stop button, 7-cooling mechanism, 71-cooling box, 72-sealing cover, 73-sealing jacket, 74-air inlet pipe, 75-fixed cross plate, 76-fixed short shaft, 77-air guide roller, 78-cooling module, 79-temperature sensor, 8-air storage mechanism, 80-installation base, 81-air storage furnace, 82-air guide special pipe, 83-filtering bottom net, 85-air outlet pipe, 86-first spherical electromagnetic valve, 9-filtering mechanism, 91-air guide turbine, 92-inner toothed ring, 93-filtering bottom box, 94-grooved plate, 95-fixed cross bar, 96-spiral plate, 97-flat belt, 98-first driven gear, 99-fixed bottom block, 910-first positioning guide post, 911-limiting roller, 912-first return spring, 913-positioning guide rail, 10-adsorption mechanism, 101-limiting top plate, 102-fixed short plate, 103-external toothed ring, 104-fixed top box, 105-movable slide block, 106-second positioning guide post, 107-second return spring, 108-rotary air pipe, 109-adsorption screen drum, 1010-waste residue collection frame, 1011-scraping plate, 1012-telescopic hose, 1013-air pump, 1014-dust cover, 1015-second driven gear, 1016-pressure sensor, 11-a buffer mechanism, 111-a return pipe, 112-a limiting vertical plate, 113-a buffer cylinder, 114-a second spherical electromagnetic valve, 115-a second air pressure sensor, 116-an electric push rod, 117-a lifting bottom block, 118-a first flow-limiting guide plate, 119-a connecting vertical rod, 1110-a limiting horizontal plate, 1111-an L-shaped vertical rod, 1112-a second flow-limiting guide plate, 1113-a third positioning guide column, 1114-a third reset spring, 1115-a first air pressure sensor, 12-a shunt mechanism, 121-a fixed bottom frame, 122-a shunt bottom cylinder, 123-a limiting funnel, 124-a sieving air pipe and 125-a liquid outlet hose.

Detailed Description

The invention is further illustrated by the following specific examples in which, unless otherwise explicitly stated and limited, terms such as: the arrangement, installation, connection are to be understood broadly, for example, they may be fixed, detachable, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

A steam recycling device for petroleum coke calcination is disclosed, as shown in figures 1-7, and comprises a fixed bottom box 1, a supporting base 2, a refining furnace 3, a fixed round frame 4, a positioning base 5, a cover 60, a starting button 61, a stopping button 62, a cooling mechanism 7 and a gas storage mechanism 8, wherein the bottom of the fixed bottom box 1 is connected with the supporting base 2, the right side of the bottom in the fixed bottom box 1 is connected with the positioning base 5, the right side of the inner wall of the rear side of the fixed bottom box 1 is connected with the fixed round frame 4, the inner wall of the fixed round frame 4 is connected with the refining furnace 3, the top of the refining furnace 3 is provided with a detachable furnace cover, and the furnace cover can be connected with a clamping component of the refining furnace 3 through a buckle, a bolt, a sealing ring and the like; the opening is opened on the right side of 1 top of fixed bottom case, the opening is used for taking out and putting back the bell on the refining furnace 3, the refining furnace 3 is used for splendid attire petroleum coke, refining furnace 3 bottom and 5 top fixed connection of location base, it is connected with lid 60 through the pivot rotary type to support 2 leading flank right parts of base, it is connected with start button 61 to support 2 leading flank right parts of base, it is connected with stop button 62 to support 2 leading flank right parts of base, stop button 62 is located start button 61 right side, lid 60 is used for hiding start button 61 and stop button 62, be connected with cooling mechanism 7 between fixed bottom case 1 and the refining furnace 3, cooling mechanism 7 is used for cooling the steam that produces when the petroleum coke is calcined, be connected with gas storage mechanism 8 between fixed bottom case 1 and the cooling mechanism 7, gas storage mechanism 8 is used for storing steam.

The cooling mechanism 7 comprises a cooling box 71, a closed cover 72, a sealing outer sleeve 73, an air inlet pipe 74, a fixed cross plate 75, a fixed short shaft 76, an air guide roller 77, a cooling module 78 and a temperature sensor 79, wherein the left rear side of the bottom in the fixed bottom box 1 is connected with the cooling box 71, the front side of the cooling box 71 is arranged in an open manner, the front part of the cooling box 71 is connected with the sealing outer sleeve 73, the front part of the sealing outer sleeve 73 is connected with the closed cover 72, the air inlet pipe 74 is connected between the upper side of the right part of the cooling box 71 and the upper side of the left part of the refining furnace 3, the outer side of the cooling box 71 is connected with the fixed cross plate 75, the fixed short shaft 76 is rotatably connected with the fixed cross plate 75, one end of the fixed short shaft 76 penetrates through the rear side surface of the cooling box 71, the fixed short shaft 76 is rotatably connected with the rear side surface of the cooling box 71, the air guide roller 77 is positioned in the cooling box 71, the cooling module 78 is connected in the closed cover 72, cooling module 78 comprises a hollow ring piece and many condenser pipes, and the hollow ring piece is connected at airtight lid 72 trailing flank middle part, and the hollow ring piece is used for connecting the annular condenser pipe, and the inlet tube and the outlet pipe of condenser pipe all run through fixed under casing 1 leading flank, and cooling module 78's hollow ring piece trailing flank upper portion is connected with temperature sensor 79, and temperature sensor 79 is used for detecting the height of the interior temperature of cooler bin 71.

The gas storage mechanism 8 comprises an installation base 80, a gas storage furnace 81, a gas guide special pipe 82, a filtering bottom net 83, a gas outlet pipe 85 and a first spherical electromagnetic valve 86, the left front side of the bottom in the fixed bottom box 1 is connected with the installation base 80, the top of the installation base 80 is connected with the gas storage furnace 81, the gas storage furnace 81 is used for storing steam, the gas guide special pipe 82 is connected between the gas storage furnace 81 and the sealing cover 72, the lower part of the inner wall of the gas storage furnace 81 is connected with the filtering bottom net 83, the filtering bottom net 83 is used for filtering the steam, the bottom of the gas storage furnace is connected with the gas outlet pipe 85, the gas outlet pipe 85 penetrates through the installation base 80, the gas outlet pipe 85 is connected with the first spherical electromagnetic valve 86, and the first spherical electromagnetic valve 86 is connected with the installation base 80.

The worker presses a power supply main switch to electrify the device, the refining furnace 3 starts to work, a furnace cover at the top of the refining furnace 3 is taken out through an opening at the top of the fixed bottom box 1, then petroleum coke burnt to 500 ℃ is poured into the refining furnace 3, then the furnace cover of the refining furnace 3 is covered, the petroleum coke is electrically heated in the refining furnace 3 by self and a spiral heating pipe arranged in the refining furnace 3 to carry out coking reaction, an air inlet pipe is arranged on the side surface, the interior is ventilated by a high-pressure fan, the pressure in the refining furnace 3 is increased by a large amount of gas generated by the coking reaction, steam is discharged into a cavity between the cooling box 71 and the closed cover 72 through an air inlet pipe 74, the steam blowing air guide roller 77 starts to rotate reversely, the temperature sensor 79 detects that the steam entering temperature is higher than the rated value in the control module, the temperature sensor 79 sends out a signal, the control module receives a signal to control the cooling module 78 to work, the cooling module 78 cools the steam, because the temperature of the steam is high, the cooled steam cannot be liquefied, when the steam continuously enters the cooling box 71, the pressure in the cooling box 71 is increased, the cooled steam is discharged into the gas storage furnace 81 through the gas guide special pipe 82, after all the petroleum coke is combusted, the steam is not discharged between the cooling box 71 and the closed cover 72, the gas guide roller 77 stops reversing, the temperature sensor 79 detects that the temperature is less than a rated value in the control module, the temperature sensor 79 sends a signal again, the control module receives a signal to control the cooling module 78 to stop, when the steam is required to be used, the gas outlet pipe 85 can be externally connected, the start button 61 is pressed once, the start button 61 sends a signal, the control module receives a signal to control the first spherical electromagnetic valve 86 to be opened, the steam is discharged through the air outlet pipe 85, after the steam is not needed to be used, the stop button 62 is pressed once, the stop button 62 sends out a signal, and the control module receives the signal to control the first spherical electromagnetic valve 86 to be closed.

Example 2

Based on embodiment 1, as shown in fig. 6 to 20, the steam-assisted steam boiler further comprises a filtering mechanism 9, the filtering mechanism 9 is connected between the cooling box 71, the air guide roller 77 and the fixed stub shaft 76, the filtering mechanism 9 is used for adsorbing micro impurities in the steam, the filtering mechanism 9 comprises an air guide turbine 91, an inner toothed ring 92, a filtering bottom box 93, a trough plate 94, a fixed cross rod 95, a spiral plate 96, a flat belt 97, a first driven gear 98, a fixed bottom block 99, a first positioning guide pillar 910, a limit roller 911, a first return spring 912 and a positioning guide rail 913, the front side of the outer surface of the fixed stub shaft 76 is connected with the air guide turbine 91, the air guide turbine 91 is used for accelerating the flow rate of the steam, the inner wall of the sealing cover 72 is connected with the inner toothed ring 92, the inner wall of the air guide roller 77 is connected with four filtering bottom boxes 93 at regular intervals along the circumferential direction, one side of the filtering bottom boxes 93 close to the fixed stub shaft 76 is in a grid shape, four filtering bottom boxes 93 are respectively connected with a groove plate 94 in a rotating mode through rotating shafts, the groove plates 94 and grids of the filtering bottom boxes 93 are alternately arranged, the groove plates 94 can block the filtering bottom boxes 93, the inner walls of the rear sides of the four filtering bottom boxes 93 are respectively connected with a group of fixed cross rods 95 in a rotating mode, two fixed cross rods 95 are in a group, the front ends of four groups of fixed cross rods 95 respectively penetrate through the four filtering bottom boxes 93, the middle parts of the outer surfaces of the eight fixed cross rods 95 are respectively connected with a spiral plate 96, the outer sides of the spiral plates 96 are provided with sponge, the eight spiral plates 96 are respectively positioned in the four filtering bottom boxes 93, the spiral plates 96 are used for adsorbing impurities in steam, the front sides of the four groups of fixed cross rods 95 are respectively sleeved with a flat belt 97 through belt pulleys, the front side of one fixed cross rod 95 in each group is respectively connected with a first driven gear 98, the four first driven gears 98 are respectively meshed with inner gear rings 92, the four filtering bottom boxes 93 are respectively connected with a fixed bottom block 99, fixed bottom block 99 is connected in the one side that the cell-plate 94 is kept away from to filter bottom case 93, all be connected with a set of first positioning guide pillar 910 on four fixed bottom blocks 99, two first positioning guide pillars 910 are a set of, four sets of first positioning guide pillars 910 are sliding connection with four cell-plates 94 respectively, all the cover has a first reset spring 912 on eight first positioning guide pillars 910, first reset spring 912 one end is connected with fixed bottom block 99, the first reset spring 912 other end is connected with cell-plate 94, the cell-plate 94 front side is connected with spacing gyro wheel 911 through the pivot rotary type, airtight lid 72 trailing flank is connected with location guide 913, location guide 913 and spacing gyro wheel 911 contact cooperation, location guide 913 is used for leading to cell-plate 94.

When the limiting roller 911 is located at the arc-shaped position of the positioning guide rail 913, the first return spring 912 is in a compression state, and the limiting roller 911 drives the trough plate 94 to cover the filtering bottom box 93, so that the filtering bottom box 93 is blocked. When steam is discharged between the cooling box 71 and the sealing cover 72, the steam enters the filtering bottom box 93 blocked by the groove plates 94, the air guide roller 77 starts to rotate reversely by the steam, the air guide roller 77 rotates reversely to drive the filtering bottom box 93 to rotate reversely, the filtering bottom box 93 rotates reversely to drive the groove plates 94 to rotate reversely, the groove plates 94 rotate reversely to drive the limiting rollers 911 to rotate reversely, the limiting rollers 911 rotate reversely along the positioning guide rails 913, meanwhile, the filtering bottom box 93 rotates reversely to drive the first driven gear 98 to rotate reversely along the inner toothed ring 92, due to the action of the inner toothed ring 92, the first driven gear 98 can rotate when rotating reversely along the inner toothed ring 92, when the first driven gear 98 rotates, the fixed cross rod 95 connected with the first driven gear 98 is driven to rotate, the fixed cross rod 95 connected with the first driven gear 98 rotates to drive the flat belt 97 to rotate, the flat belt 97 rotates to drive the other fixed cross rod 95 to rotate, and the fixed cross rod 95 rotates to drive the spiral plate 96 to rotate, the reversal of spiral plate 96 causes the air current to form the swirl, and the small impurity in spiral plate 96 sponge material is to steam adsorbs, so, can avoid having impurity in the steam. When the limiting roller 911 extruded by the arc-shaped part of the positioning guide rail 913 rotates reversely to the straight rod part of the positioning guide rail 913, the first return spring 912 drives the groove plate 94 and the limiting roller 911 to move, the limiting roller 911 is continuously contacted with the positioning guide rail 913, at this time, the groove plate 94 rotates around the rotating shaft on the filtering bottom box 93 to open, the groove plate 94 does not block the filtering bottom box 93, the filtered steam is discharged into the gas storage furnace 81 through the gas guide special pipe 82, the gas guide roller 77 rotates reversely to drive the fixed short shaft 76 to rotate reversely, the fixed short shaft 76 rotates reversely to drive the gas guide turbine 91 to rotate reversely, and the gas guide turbine 91 rotates reversely to accelerate the steam flow rate.

The device also comprises an adsorption mechanism 10, the adsorption mechanism 10 is connected between the cooling box 71 and the air guide roller 77, the adsorption mechanism 10 is used for adsorbing impurities on the spiral plate 96, the adsorption mechanism 10 comprises a limit top plate 101, a fixed short plate 102, an outer toothed ring 103, a fixed top box 104, a movable slider 105, a second positioning guide post 106, a second reset spring 107, a rotary air pipe 108, an adsorption screen drum 109, a waste residue collection frame 1010, a scraping plate 1011, a telescopic hose 1012, an air suction pump 1013, a dust cover 1014, a second driven gear 1015 and a pressure sensor 1016, four groups of fixed short plates 102 are uniformly connected to the front side of the air guide roller 77 at intervals along the circumferential direction, two fixed short plates 102 are in one group, one limit top plate 101 is connected to each group of the four groups of fixed short plates 102, the rear side of the outer surface of the air guide roller 77 is connected with the outer toothed ring 103, the top of the cooling box 71 is connected with a fixed top box 104, two second positioning guide posts 106 are symmetrically connected to the left and right of the front of the fixed top box 104, a movable sliding block 105 is connected between the two second positioning guide pillars 106 in a sliding manner, a second return spring 107 is connected between the top of the movable sliding block 105 and the inner wall of the fixed top box 104, a rotary air pipe 108 is rotatably connected to the middle of the movable sliding block 105, an adsorption screen cylinder 109 is connected to the middle of the rotary air pipe 108, the adsorption screen cylinder 109 is used for adsorbing and collecting impurities, a waste residue collection frame 1010 is rotatably connected to the front of the rotary air pipe 108, the waste residue collection frame 1010 is used for collecting impurities, a scraping plate 1011 is connected to the right part in the waste residue collection frame 1010, the scraping plate 1011 is in contact with the adsorption screen cylinder 109, the scraping plate 1011 can scrape the impurities on the adsorption screen cylinder 109, an air suction pump 1013 is connected to the front of the top of the fixed top box 104, a dust cover 1014 is connected to an air outlet on the front side of the air suction pump 1013, a flexible hose is connected to an air outlet on the rear side of the 1012, and the flexible hose 1012 is rotatably connected to the rotary air pipe 108, a second driven gear 1015 is connected to the rear of the rotary air pipe 108, the second driven gear 1015 meshes with the outer ring gear 103, and a pressure sensor 1016 is connected to the lower front portion of the inside of the fixed top box 104.

When the air guide roller 77 starts to rotate reversely, the air guide roller 77 rotates reversely to drive the outer gear ring 103 to rotate reversely, the outer gear ring 103 rotates reversely to be meshed with the second driven gear 1015, the outer gear ring 103 drives the second driven gear 1015 to rotate forwardly, the second driven gear 1015 rotates forwardly to drive the rotary air pipe 108 to rotate forwardly, the rotary air pipe 108 rotates forwardly to drive the adsorption screen drum 109 to rotate forwardly, the movable slider 105 is in contact with the pressure sensor 1016, the pressure sensor 1016 sends out a signal, the control module receives the signal to control the air pump 1013 to work, the air pump 1013 enables the rotary air pipe 108 to suck air to the upper filtering bottom box 93 through the telescopic hose 1012, the pressure in the rotary air pipe 108 is reduced, further, the gas in the filtering bottom box 93 and the impurities of the spiral plate 96 are adsorbed, the adsorption screen drum 109 rotates forwardly and simultaneously filters and adheres the impurities on the spiral plate 96 to the wall of the adsorption screen drum 109, the adsorption screen drum 109 rotates forwardly to be in contact with the scraper 1011 to scrape the impurities on the waste residue collection frame 1010 on the adsorption screen drum 109, the air guide roller 77 continuously rotates reversely to enable the outer toothed ring 103 to be separated from the second driven gear 1015, the rotary air pipe 108 stops driving the adsorption screen drum 109 to rotate forwardly, meanwhile, the air guide roller 77 also drives the limit top plate 101 to rotate reversely, the limit top plate 101 rotates reversely to be in contact with the movable sliding block 105, the movable sliding block 105 is driven by the limit top plate 101 to move upwards, the second reset spring 107 is compressed, the movable sliding block 105 moves upwards to be separated from the pressure sensor 1016, the pressure sensor 1016 sends out a signal again, the control module receives the signal to control the air suction pump 1013 to stop, and similarly, the air guide roller 77 continuously rotates reversely to enable the limit top plate 101 to be separated from the movable sliding block 105, due to the action of the second reset spring 107, the movable sliding block 105 moves downwards to reset, the outer toothed ring 103 is in contact with the second driven gear 1015, and filtered impurities can be adsorbed and collected.

The steam storage device also comprises a buffer mechanism 11, the fixed bottom box 1, a sealing cover 72 and the air guide special pipe 82 are connected with the buffer mechanism 11, the buffer mechanism 11 is also fixedly connected with the air storage furnace 81, the buffer mechanism 11 is used for buffering steam, the buffer mechanism 11 comprises a return pipe 111, a limit vertical plate 112, a buffer cylinder 113, a second spherical electromagnetic valve 114, a second air pressure sensor 115, an electric push rod 116, a lifting bottom block 117, a first flow-limiting guide plate 118, a connecting vertical rod 119, a limit horizontal plate 1110, an L-shaped vertical rod 1111, a second flow-limiting guide plate 1112, a third positioning guide pillar 1113, a third reset spring 1114 and a first air pressure sensor 1115, the buffer cylinder 113 is connected with an air outlet at the upper side of the air guide special pipe 82, the buffer cylinder 113 is fixedly connected with the air guide special pipe 82, the return pipe 111 is connected between the upper part of the buffer cylinder 113 and the upper part of the air storage furnace 81, the limit vertical plate 112 is connected between the outer wall of the air guide pipe 82 and the return pipe 111, the air guide special pipe 82 is connected with a second spherical electromagnetic valve 114, the second spherical electromagnetic valve 114 is connected with the front side surface of the closed cover 72, the front side of the upper part of the buffer cylinder 113 is connected with a second air pressure sensor 115, the second air pressure sensor 115 is used for detecting the air pressure in the buffer cylinder 113, the inner wall of the left side of the fixed bottom box 1 is connected with an electric push rod 116, the telescopic rod of the electric push rod 116 is connected with a lifting bottom block 117, the lower part in the limit vertical plate 112 is connected with a first current-limiting guide plate 118 in a sliding way, the first current-limiting guide plate 118 is fixedly connected with the lifting bottom block 117, the first current-limiting guide plate 118 is connected with the air guide special pipe 82 in a sliding way, the first current-limiting guide plate 118 is used for blocking the air guide special pipe 82, the top of the first current-limiting guide plate 118 is connected with two connecting vertical rods 119 in a bilateral symmetry way, a limit transverse plate 1110 is connected between the top ends of the two connecting vertical rods 119, the upper part in the limit vertical plate 112 is connected with two third positioning guide posts 1113 in a bilateral symmetry way, second current-limiting guide plate 1112 is connected between two third positioning guide pillars 1113 in a sliding manner, two L-shaped vertical rods 1111 are symmetrically connected to the bottom of second current-limiting guide plate 1112 in a left-right manner, limiting transverse plate 1110 can be in contact with L-shaped vertical rods 1111 after moving downwards, a third return spring 1114 is sleeved on each of the two third positioning guide pillars 1113, one end of each third return spring 1114 is connected with the second current-limiting guide plate 1112, the other end of each third return spring 1114 is connected with the inner wall of a limiting vertical plate 112, a first air pressure sensor 1115 is connected to the front side of the upper portion of the gas storage furnace 81, and the first air pressure sensor 1115 is used for detecting the air pressure in the gas storage furnace 81.

When steam is discharged into the gas storage furnace 81 through the gas guide special pipe 82, the first gas pressure sensor 1115 monitors the gas pressure in the gas storage furnace 81, the first gas pressure sensor 1115 detects that the gas pressure in the gas storage furnace 81 is higher than a rated value in the control module, the first gas pressure sensor 1115 sends a signal, the control module receives the signal to control the extension of the telescopic rod of the electric push rod 116 to extend for 2 seconds, the telescopic rod of the electric push rod 116 extends to drive the lifting bottom block 117 to move downwards, the lifting bottom block 117 moves downwards to drive the first current-limiting guide plate 118 to move downwards, the gas guide special pipe 82 is blocked after the first current-limiting guide plate 118 moves downwards, the first current-limiting guide plate 118 moves downwards to drive the connecting vertical rod 119 to move downwards, the connecting vertical rod 119 moves downwards to drive the limiting transverse plate 1110 to move downwards, and after 2 seconds, the control module controls the electric push rod 116 to stop, and receives the signal to further control the second spherical electromagnetic valve 114 to operate, the second spherical electromagnetic valve 114 operates to enable the air guide special pipe 82 to be communicated with the buffer cylinder 113, steam is discharged into the buffer cylinder 113, a worker can discharge and utilize the steam in the air storage furnace 81 through an external exhaust pipe of the air outlet pipe 85, meanwhile, the second air pressure sensor 115 monitors the air pressure in the buffer cylinder 113, the second air pressure sensor 115 detects that the air pressure in the buffer cylinder 113 is higher than a rated value in the control module, the second air pressure sensor 115 sends a signal, the control module receives the signal to control the extension rod of the electric push rod 116 to extend for 2 seconds, the extension rod of the electric push rod 116 continues to extend to drive the lifting bottom block 117 to continue to move downwards, the connecting vertical rod 119 also continues to drive the limiting transverse plate 1110 to move downwards, the limiting transverse plate 1110 moves downwards to be in contact with the L-shaped vertical rod 1111, the limiting transverse plate 1110 continues to move downwards to drive the L-shaped vertical rod 1111 to move downwards, the L-shaped vertical rod 1111 moves downwards to drive the second flow-limiting guide plate 1112 to move downwards, the third return spring 1114 is compressed, the second flow-limiting guide plate 1112 does not block the return pipe 111 after moving downwards, after 2 seconds, the control module controls the electric push rod 116 to stop, steam in the buffer cylinder 113 is discharged into the gas storage furnace 81 through the return pipe 111, when the first air pressure sensor 1115 detects that the air pressure in the gas storage furnace 81 is lower than a rated value in the control module, the first air pressure sensor 1115 sends a signal again, the control module receives the signal to control the telescopic rod of the electric push rod 116 to shorten for 4 seconds, the telescopic rod of the electric push rod 116 shortens to drive the lifting bottom block 117 to move upwards for resetting, the lifting bottom block 117 moves upwards for resetting to drive the first flow-limiting guide plate 118 to move upwards for resetting without blocking the gas guide special pipe 82, the first flow-limiting guide plate 118 moves upwards for resetting to drive the connecting vertical rod 119 and the limiting horizontal plate 1110 to move upwards for resetting, under the action of the third return spring 1114, the second guide plate 1112 can move upwards for resetting to block the return pipe 111, and the control module receives the signal and controls the second spherical electromagnetic valve 114 to work, the second spherical electromagnetic valve 114 operates to enable the air guide special pipe 82 to be communicated with the air storage furnace 81, and after 4 seconds, the control module controls the electric push rod 116 to stop, so that dangers caused by overlarge air pressure in the air storage furnace 81 and the buffer cylinder 113 can be avoided.

Example 3

On the basis of embodiment 1 and embodiment 2, as shown in fig. 1 and fig. 21, the steam-water separator further comprises a flow dividing mechanism 12, the flow dividing mechanism 12 is connected to the fixed bottom box 1, the flow dividing mechanism 12 is used for dividing steam and distilled water, the flow dividing mechanism 12 comprises a fixed bottom frame 121, a flow dividing bottom cylinder 122, a limiting funnel 123, a sieving air pipe 124 and a liquid outlet hose 125, the lower portion of the right front side of the fixed bottom box 1 is connected with the fixed bottom frame 121, the flow dividing bottom cylinder 122 is connected to the air outlet pipe 85, the flow dividing bottom cylinder 122 is communicated with the air outlet pipe 85, the limiting funnel 123 is connected to the upper side of the inner wall of the flow dividing bottom cylinder 122, the top of the flow dividing bottom cylinder 122 is connected to the sieving air pipe 124, and the bottom of the flow dividing bottom cylinder 122 is connected to the liquid outlet hose 125.

When the staff need use steam, the external blast pipe of trachea 124 will sieve, will go out the external drain pipe of liquid hose 125, press start button 61 once, start button 61 signals, the first spherical solenoid valve 86 of control module received signal control is opened, steam just also discharges into in the reposition of redundant personnel end section of thick bamboo 122 through outlet duct 85, spacing funnel 123 shelters from the distilled water in the steam, distilled water just also discharges from liquid hose 125, and steam is discharged from trachea 124 that sieves, need not to use after the steam, press stop button 62 once, stop button 62 signals, the first spherical solenoid valve 86 of control module received signal control is closed, so, can make steam and distilled water shunt.

As shown in fig. 2, 22 and 23, the steam recycling device further comprises an electric cabinet 6, wherein the electric cabinet 6 is installed at the lower portion of the left front side of the fixed bottom case 1, a switching power supply, a power supply module and a control module are included in the electric cabinet 6, the switching power supply supplies power to the steam recycling device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the start button 61, the stop button 62, the first air pressure sensor 1115, the second air pressure sensor 115, the pressure sensor 1016 and the temperature sensor 79 are all electrically connected with the control module, and the cooling module 78, the electric push rod 116, the first spherical solenoid valve 86, the second spherical solenoid valve 114 and the air pump 1013 are all connected with the control module through peripheral circuits.

While the disclosure has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that various other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.