CN215463079U - Recovery unit of synthetic ammonia steam condensate - Google Patents

Abstract

The utility model provides a recovery device of synthetic ammonia steam condensate, which comprises a bottom plate, wherein vertical plates are symmetrically fixed at the top of the bottom plate, a hot air pipe is fixed at one side of the two vertical plates close to each other, a cold air pipe is fixed inside the hot air pipe, a plurality of partition plates are sleeved outside the cold air pipe, the partition plates are staggered from top to bottom, and a switch mechanism is arranged at the bottom of the hot air pipe. The motor enables the second sliding plate to do reciprocating linear motion through the rotary disc, the rotary rod and the T-shaped shaft, the second sliding plate enables the motion directions of the first sliding plate and the second sliding plate to be opposite through the rack and the gear, compared with an electric push rod, the motor is longer in service life, more convenient to maintain and lower in manufacturing cost, the first through holes and the second through holes in the first sliding plate and the second sliding plate are staggered mutually, the interior of the hot air pipe is isolated from the outside, hot air cannot leak when condensate is taken out, continuous condensation of the hot air is not influenced, and the motor is convenient and efficient.

Description

Recovery unit of synthetic ammonia steam condensate

Technical Field

The utility model relates to the technical field of condensate production, in particular to a recovery device for synthetic ammonia vapor condensate.

Background

Condensation is the condensation of a gas or liquid when it is cold, for example, water vapor turns into water when it is cold and water turns into ice when it is cold. The lower the temperature, the faster the condensation rate and the better the effect. In chemical production, water or air which is easy to obtain and low in cost is generally used as a condensing medium, and after the condensation operation, the temperature of the water or the air is increased, and if the water or the air is directly discharged, thermal pollution is caused. Condensation and evaporation are two physical processes that work in opposition.

The liquid of current synthetic ammonia vapor condensate is inconvenient to be collected, can make steam have certain loss from liquid outlet when collecting, perhaps need suspend the entering of steam earlier, then open the liquid outlet and collect, and is very inconvenient, and efficiency is lower.

Therefore, it is necessary to provide a recycling device for the condensate of synthetic ammonia vapor to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides the device for recovering the condensate of the synthetic ammonia steam, which can prevent hot gas from leaking when the condensate is taken out by driving the switch mechanism through the driving mechanism, so that the hot gas continuously circulates in the hot gas pipe, the continuous condensation of the hot gas is not influenced, and the device is convenient and efficient.

The utility model provides a recovery device of synthetic ammonia steam condensate, which comprises a bottom plate, wherein vertical plates are symmetrically fixed on the top of the bottom plate, a hot air pipe is fixed on one side of each vertical plate, which is close to each other, a cold air pipe is fixed inside the hot air pipe, a plurality of partition plates are sleeved outside the cold air pipe, the partition plates are staggered from top to bottom, a switch mechanism is arranged at the bottom of the hot air pipe, a driving mechanism is fixed on the top of the bottom plate, a cold air inlet and a cold air outlet are respectively fixed on one sides, which are far away from each other, of the two vertical plates, the cold air inlet and the cold air outlet are communicated with the cold air pipe, and a first air pipe and a second air pipe are fixedly communicated with the top of the hot air pipe.

Preferably, the switch mechanism comprises a first sliding plate, a first through hole, a second sliding plate, a second through hole, a ball, a water pipe, a gear, a rack, a first groove, a second groove, a third groove and a fourth groove, the bottom of the hot air pipe is fixedly communicated with the water pipe, the inner wall of the water pipe is provided with the first groove, the third groove and the fourth groove, the first sliding plate and the second sliding plate are connected in the first groove in a sliding mode, the first through hole is formed in the first sliding plate, the second through hole is formed in the second sliding plate, the gear connected with the inner wall of the first groove in a rotating mode is arranged between the first sliding plate and the second sliding plate, the rack is fixed on one side, close to the gear, of the first sliding plate and the second sliding plate, and the rack is connected with the gear in a meshing mode.

Preferably, actuating mechanism includes mounting panel, motor, strengthening rib, carousel, rotary rod, T type axle and fifth recess, the top of bottom plate is fixed with the mounting panel, one side of mounting panel is fixed with the motor, the output shaft of motor is fixed with the carousel, one side off-centre of carousel is fixed with the rotary rod, the second recess has been seted up to the inner wall of first recess, second recess sliding connection has T type axle, and the one end and the second slide fixed connection of T type axle, the vertical fifth recess of having seted up in one side that the second slide was kept away from to T type axle, the one end and the fifth recess sliding connection of rotary rod.

Preferably, balls are movably embedded in one sides of the first sliding plate and the second sliding plate, which are far away from the gear.

Preferably, reinforcing ribs are symmetrically fixed between the motor and the mounting plate.

Preferably, a collecting box is fixed on the top of the bottom plate and is positioned below the water pipe.

Preferably, support columns are symmetrically fixed to the bottom of the bottom plate, and locking wheels are fixed to the bottoms of the support columns.

Preferably, the inner wall of the bottom of the hot air pipe is inclined towards the water pipe.

Compared with the related art, the recovery device of the synthetic ammonia vapor condensate provided by the utility model has the following beneficial effects:

the utility model provides a recovery device of synthetic ammonia vapor condensate, which comprises the following steps:

1. the motor drives the rotating rod to do circular motion through the turntable, the rotating rod enables the second sliding plate to do reciprocating linear motion through the T-shaped shaft, the second sliding plate enables the motion directions of the first sliding plate and the second sliding plate to be opposite through the rack and the gear, and compared with an electric push rod, the motor is longer in service life, more convenient to maintain and lower in manufacturing cost;

2. when first through-hole on first slide removed the water delivery space to the water pipe, first through-hole on the second slide is located first recess, water removes between first slide and the second slide, later when first through-hole on first slide removes to first recess in, first through-hole on the second slide is located the water delivery space of water pipe, water just can fall, and the hot trachea is inside to be kept apart with the external world, thereby can realize taking out can not spill steam when the condensate, make steam continue circulation in the hot trachea, do not influence the continuation condensation of steam, and is convenient and efficient.

Drawings

FIG. 1 is a schematic sectional view of the present invention;

FIG. 2 is an enlarged schematic view of the structure at the position A of the present invention;

FIG. 3 is a side sectional view of the first and second slide plates of the present invention;

FIG. 4 is a schematic side view of the present invention.

Reference numbers in the figures: 1. locking wheels; 2. a support pillar; 3. a base plate; 4. a vertical plate; 5. a drive mechanism; 51. mounting a plate; 52. a motor; 53. reinforcing ribs; 54. a turntable; 55. rotating the rod; 56. a T-shaped shaft; 57. a fifth groove; 6. a switch mechanism; 61. a first slide plate; 62. a first through hole; 63. a second slide plate; 64. a second through hole; 65. a ball bearing; 66. a water pipe; 67. a gear; 68. a rack; 69. a first groove; 610. a second groove; 611. a third groove; 612. a fourth groove; 7. a cold air inlet; 8. a first air pipe; 9. a partition plate; 10. a cold air pipe; 11. a second air pipe; 12. a cold air discharge port; 13. a collection box; 14. a hot air pipe.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

Referring to fig. 1, the recovery device for the condensate of synthetic ammonia steam in the figure comprises a bottom plate 3, wherein vertical plates 4 are symmetrically fixed on the top of the bottom plate 3, a hot air pipe 14 is fixed on one side of the two vertical plates 4 close to each other, a cold air pipe 10 is fixed inside the hot air pipe 14, a plurality of partition plates 9 are sleeved outside the cold air pipe 10, the partition plates 9 are staggered from top to bottom, a switch mechanism 6 is arranged at the bottom of the hot air pipe 14, a driving mechanism 5 is fixed on the top of the bottom plate 3, a cold air inlet 7 and a cold air outlet 12 are respectively fixed on one side of the two vertical plates 4 far from each other, the cold air inlet 7 and the cold air outlet 12 are both communicated with the cold air pipe 10, a first air pipe 8 and a second air pipe 11 are fixedly communicated with the top of the hot air pipe 14, cold air enters from the cold air inlet 7 and is discharged from the cold air outlet through the cold air pipe 10, the hot gas enters from the first gas pipe 8 and is discharged from the second gas pipe 11, and the hot gas is condensed into liquid when meeting the cold gas pipe 10, and then the switch mechanism 6 is driven by the driving mechanism 5, so that the hot gas cannot flow out along with the liquid when the liquid is discharged.

Referring to fig. 2, the switch mechanism 6 includes a first sliding plate 61, a first through hole 62, a second sliding plate 63, a second through hole 64, a ball 65, a water pipe 66, a gear 67, a rack 68, a first groove 69, a second groove 610, a third groove 611, and a fourth groove 612, the middle of the bottom of the hot air pipe 14 is fixedly communicated with the water pipe 66, the inner wall of the water pipe 66 is provided with the first groove 69, the third groove 611, and the fourth groove 612, the first groove 69 is slidably connected with the first sliding plate 61 and the second sliding plate 63, the first sliding plate 61 is provided with the first through hole 62, the second sliding plate 63 is provided with the second through hole 64, the gear 67 rotatably connected with the inner wall of the first groove 69 is arranged between the first sliding plate 61 and the second sliding plate 63, the rack 68 is fixed on one side of the first sliding plate 61 and the second sliding plate 63 close to the gear 67, and the rack 68 is engaged with the gear 67, the second slide plate 63 makes the first slide plate 61 and the second slide plate 63 move in opposite directions through the rack 68 and the gear 67, so that when the first through hole 62 of the first slide plate 61 moves to the water delivery space of the water pipe 66, the second through hole 64 of the second slide plate 63 is located in the first groove 69, water moves between the first slide plate 61 and the second slide plate 63, and then when the first through hole 62 of the first slide plate 61 moves to the first groove 69, the second through hole 64 of the second slide plate 63 is located in the water delivery space of the water pipe 66, water falls down, and the inside of the hot air pipe 10 is isolated from the outside.

Referring to fig. 2, 3 and 4, the driving mechanism 5 includes a mounting plate 51, a motor 52, a reinforcing rib 53, a rotating disc 54, a rotating rod 55, a T-shaped shaft 56 and a fifth groove 57, the mounting plate 51 is fixed on the top of the base plate 3, the motor 52 is fixed on one side of the mounting plate 51, the rotating disc 54 is fixed on an output shaft of the motor 52, the rotating rod 55 is eccentrically fixed on one side of the rotating disc 54, a second groove 610 is formed on an inner wall of the first groove 69, the T-shaped shaft 56 is slidably connected to the second groove 610, one end of the T-shaped shaft 56 is fixedly connected to the second sliding plate 63, a fifth groove 57 is vertically formed on one side of the T-shaped shaft 56 away from the second sliding plate 63, one end of the rotating rod 55 is slidably connected to the fifth groove 57, the motor 52 drives the rotating rod 55 to perform a circular motion through the rotating disc 54, the rotating rod 55 makes the T-shaped shaft 56 perform a reciprocating linear motion through the third sliding groove 57 on the T-shaped shaft 56, thereby driving the second sliding plate 63 to make a reciprocating linear motion.

Referring to fig. 1, 2 and 4, balls 65 are movably embedded in one side of the first sliding plate 61 and the second sliding plate 63, which is far away from the gear 67, to improve the sliding stability of the first sliding plate 61 and the second sliding plate 63, reinforcing ribs 53 are symmetrically fixed between the motor 52 and the mounting plate 51 to improve the stability of the motor 52, a collection box 13 is fixed at the top of the bottom plate 3, the collection box 13 is located below the water pipe 66, support columns 2 are symmetrically fixed at the bottom of the bottom plate 3, locking wheels 1 are fixed at the bottom of the support columns 2 to improve the mobility of the whole device, and the inner wall of the bottom of the hot air pipe 14 is inclined towards the water pipe 66, so that the liquid can be conveniently taken out from the water pipe 66.

The working principle is as follows: cold air enters from the cold air inlet 7, is discharged from the cold air outlet through the cold air pipe 10, hot air enters from the first air pipe 8 and is discharged from the second air pipe 11, the hot air is condensed into liquid when meeting the cold air pipe 10 during the cold air, then the liquid is gathered to the water pipe 66, the motor 52 is started, the motor 52 drives the rotating rod 55 to do circular motion through the rotating disc 54, the rotating rod 55 enables the T-shaped shaft 56 to do reciprocating linear motion through the third chute 57 on the T-shaped shaft 56, so as to drive the second sliding plate 63 to do reciprocating linear motion, the first sliding plate 61 and the second sliding plate 63 are meshed with the gear 67 through the rack 68, so that the motion directions of the first sliding plate 61 and the second sliding plate 63 are opposite, when the first through hole 62 on the first sliding plate 61 moves to the water conveying space of the water pipe 66, the second through hole 64 on the second sliding plate 63 is positioned in the fourth groove 612, water moves to the first sliding plate 61 and the second sliding plate 63, when the first through hole 62 of the first sliding plate 61 is moved into the third groove 611, the second through hole 64 of the second sliding plate 63 is located in the water delivery space of the water pipe 66, and the water falls into the collecting tank 13.

The circuits and controls involved in the present invention are prior art and will not be described in detail herein.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The recovery device of the condensate of the synthetic ammonia vapor comprises a bottom plate (3) and is characterized in that, vertical plates (4) are symmetrically fixed at the top of the bottom plate (3), a hot air pipe (14) is fixed at one side of the two vertical plates (4) which are close to each other, a cold air pipe (10) is fixed in the hot air pipe (14), a plurality of clapboards (9) are sleeved outside the cold air pipe (10), the clapboards (9) are staggered up and down, a switch mechanism (6) is arranged at the bottom of the hot air pipe (14), a driving mechanism (5) is fixed at the top of the bottom plate (3), a cold air inlet (7) and a cold air outlet (12) are respectively fixed at one sides of the two vertical plates (4) which are far away from each other, the cold air inlet (7) and the cold air outlet (12) are both communicated with the cold air pipe (10), the top of the hot air pipe (14) is fixedly communicated with a first air pipe (8) and a second air pipe (11).

2. The recycling device for the condensate of synthetic ammonia vapor according to claim 1, wherein the switch mechanism (6) comprises a first sliding plate (61), a first through hole (62), a second sliding plate (63), a second through hole (64), a ball (65), a water pipe (66), a gear (67), a rack (68), a first groove (69), a second groove (610), a third groove (611) and a fourth groove (612), the water pipe (66) is fixedly communicated with the middle of the bottom of the hot air pipe (14), the inner wall of the water pipe (66) is provided with the first groove (69), the third groove (611) and the fourth groove (612), the first sliding plate (61) and the second sliding plate (63) are connected in the first groove (69) in a sliding manner, the first through hole (62) is provided on the first sliding plate (61), the second through hole (64) is provided on the second sliding plate (63), a gear (67) rotatably connected with the inner wall of the first groove (69) is arranged between the first sliding plate (61) and the second sliding plate (63), a rack (68) is fixed on one side of the first sliding plate (61) and the second sliding plate (63) close to the gear (67), and the rack (68) is meshed with the gear (67).

3. The recycling device for the condensate of synthetic ammonia vapor according to claim 2, characterized in that the driving mechanism (5) comprises a mounting plate (51), a motor (52), a reinforcing rib (53), a turntable (54), a rotating rod (55), a T-shaped shaft (56) and a fifth groove (57), the mounting plate (51) is fixed on the top of the bottom plate (3), the motor (52) is fixed on one side of the mounting plate (51), the turntable (54) is fixed on the output shaft of the motor (52), the rotating rod (55) is eccentrically fixed on one side of the turntable (54), the second groove (610) is opened on the inner wall of the first groove (69), the T-shaped shaft (56) is slidably connected with the second groove (610), one end of the T-shaped shaft (56) is fixedly connected with the second sliding plate (63), the fifth groove (57) is vertically opened on the side of the T-shaped shaft (56) far away from the second sliding plate (63), one end of the rotating rod (55) is connected with the fifth groove (57) in a sliding mode.

4. A recovery device for ammonia synthesis vapor condensate as claimed in claim 2, characterized in that the first slide plate (61) and the second slide plate (63) are movably embedded with balls (65) on the side remote from the gear (67).

5. A recovery device for ammonia vapour condensate according to claim 3, characterised in that reinforcing ribs (53) are symmetrically fixed between the motor (52) and the mounting plate (51).

6. A recovery device for synthesis ammonia vapor condensate according to claim 1, characterized in that a collection tank (13) is fixed on top of the floor (3) and the collection tank (13) is located below the water pipes (66).

7. A recovery device for ammonia synthesis vapor condensate as claimed in claim 1, characterized in that the bottom of the base plate (3) is symmetrically fixed with supporting columns (2), and the bottom of the supporting columns (2) is fixed with locking wheels (1).

8. A recovery device for ammonia synthesis vapor condensate as claimed in claim 2, characterized in that the bottom inner wall of the hot gas pipe (14) is inclined towards the water pipe (66).

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