CN213238529U - Oil device direct cooling tower with high treatment efficiency - Google Patents

Abstract

The utility model discloses a direct cooling tower of oil ware that treatment effeciency is high relates to the direct cooling tower technical field of oil ware, and when the high-temperature gas that produces oil gas engineering is cooled off for solving current cooling tower, high-temperature gas generally all moves through the flow velocity of air in the inside of cooling tower to speed is slow excessively when making the high-temperature gas inside the inside motion of cooling tower to the heat exchanger inside heat transfer, thereby causes the problem that cooling efficiency is low excessively. The fixed mount that is provided with in top of base, the fixed straight cold tower body that is provided with in top of mount, the fixed snakelike heat transfer cooling tube that is provided with of inner wall of straight cold tower body, and snakelike heat transfer cooling tube is provided with four, four snakelike heat transfer cooling tube evenly distributed is in the inside top and the below of straight cold tower body, the both ends of snakelike heat transfer cooling tube extend to the outside both sides of straight cold tower body respectively, the fixed outlet duct that is provided with of straight cold tower body top outer wall.

Description

Oil device direct cooling tower with high treatment efficiency

Technical Field

The utility model relates to an oil ware directly cools off tower technical field specifically is an oil ware directly cools off tower that treatment effeciency is high.

Background

In oil gas engineering production, can produce a large amount of high-temperature gas, if high-temperature gas can influence work on next step without cooling, consequently need cool off high-temperature gas, and high-temperature gas generally all uses the cooling tower to cool off through the heat transfer principle.

When an existing cooling tower cools high-temperature gas generated in oil-gas engineering, the high-temperature gas generally moves in the cooling tower through the flowing speed of air, so that the speed of the high-temperature gas moving in the cooling tower to the inside of a heat exchanger for heat exchange is too low, and the cooling efficiency is too low; therefore, the existing requirement is not met, and an oil device direct cooling tower with high treatment efficiency is provided for the requirement.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an oil ware direct cooling tower that treatment effeciency is high to solve the current cooling tower that proposes in the above-mentioned background art when cooling down the high-temperature gas that oil gas engineering produced, high-temperature gas generally all moves through the flow velocity of air in the inside of cooling tower, thereby speed is too slow when making high-temperature gas move to the inside heat transfer that carries on of heat exchanger in the inside of cooling tower, thereby causes the problem that cooling efficiency is low excessively.

In order to achieve the above object, the utility model provides a following technical scheme: an oil device direct cooling tower with high treatment efficiency comprises a base, wherein a fixing frame is fixedly arranged above the base, a direct cooling tower body is fixedly arranged above the fixing frame, a snakelike heat exchange cooling pipe is fixedly arranged on the inner wall of the direct cooling tower body, four snakelike heat exchange cooling pipes are arranged, the four snakelike heat exchange cooling pipes are uniformly distributed above and below the interior of the direct cooling tower body, two ends of each snakelike heat exchange cooling pipe extend to two sides of the exterior of the direct cooling tower body respectively, an air outlet pipe is fixedly arranged on the outer wall of the upper portion of the direct cooling tower body, the interior of the air outlet pipe is communicated with the interior of the direct cooling tower body, an air suction mechanism is arranged outside the air outlet pipe, a water storage tank is arranged on one side of the direct cooling tower body, a water storage tank is arranged on the other side of the direct cooling tower body, and supporting frames are fixedly arranged below, the support frame is fixedly connected with the base.

Preferably, snakelike heat transfer cooling tube is located the outside one end of straight cold tower body one side and the outer wall fixed connection of water storage box, and the inside of snakelike heat transfer cooling tube and the inside of water storage box link up mutually, the fixed outlet pipe that is provided with of one side outer wall of water storage box, the one end of outlet pipe extends to the outside one side of water storage box, and the other end of outlet pipe extends to the inside below of water storage box, the outlet pipe passes through flow divider and the outside one end fixed connection of snakelike heat transfer cooling tube location straight cold tower body opposite side, one side of water storage box is provided with the water pump, and water pump and outlet pipe fixed mounting, the fixed backup pad that is provided with in below of water pump, and the outer wall fixed connection of backup pad.

Preferably, the air suction mechanism consists of a support rod, an air suction box, an air outlet cover, a rotating rod, a fixed rod, a mounting seat, a servo motor and a dust absorption fan, the number of the supporting rods is four, the four supporting rods are all positioned outside the air outlet pipe, the air suction box is fixedly connected above the supporting rods, one end of the air outlet pipe extends into the air suction box, the air outlet cover is fixedly connected above the air suction box, the rotating rod is arranged on the inner wall above the air suction box, two ends of the rotating rod respectively extend to the inside of the air suction box and the upper part of the air outlet cover, four fixing rods are arranged and are positioned outside the air suction box, mount pad fixed connection is in the top of dead lever, servo motor fixed mounting is in the top of mount pad, dust absorption fan fixed connection is located the inside one end of case of breathing in at the dwang.

Preferably, the bracing piece is with the top outer wall fixed connection of direct cooling tower body, the top outer wall fixed connection of dead lever and direct cooling tower body, the mount pad is located the top of the cover of breathing out, servo motor's output extends to the below of mount pad, servo motor's output and the one end that the dwang is located the cover top of breathing out pass through shaft coupling fixed connection, the fixed cover that breathes in that is provided with of one end that the outlet duct is located the incasement portion of breathing in, the top of the cover outer wall of breathing in and the inner wall laminating of the case of breathing in, the ventilation hole has been seted up to the top outer wall of the case of breathing in, and the ventilation hole is provided with a plurality of, the dwang all rotates through the bearing with the.

Preferably, one side of the air outlet cover is fixedly provided with a connecting pipe, the inside of the connecting pipe is mutually communicated with the inside of the air outlet cover, the connecting pipe is positioned between the fixing rods, and the other end of the connecting pipe is fixedly provided with a connecting flange.

Preferably, the fixed inlet tube that is provided with in top of storage water tank one side outer wall, the fixed drain pipe that is provided with in below of storage water tank one side outer wall, the fixed raceway that is provided with in below of storage water tank one side outer wall, the inlet tube is all fixed with flange with the one end of raceway, the sealed lid of one end threaded connection of drain pipe, the fixed intake pipe that is provided with in below of straight cold tower body one side outer wall, the fixed sealed glue that is provided with in junction between snakelike heat transfer cooling tube and the straight cold tower body outer wall.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a set up air suction mechanism, snakelike heat transfer cooling tube and direct cooling tower body, thereby make when cooling high-temperature gas, servo motor can start, servo motor drives the dust absorption fan and rotates, thereby produce suction, suction can enter into the inside of direct cooling tower body through the outlet duct, thereby suction can be with the inside motion of the faster inside to the outlet duct of high-temperature gas of the inside below of direct cooling tower body, thereby make the inside high-temperature gas of direct cooling tower body can be through the passive motion that carries out of suction, when avoiding high-temperature gas to pass through the flow velocity of air and moving, make high-temperature gas be too slow at the inside velocity of motion of direct cooling tower body, and also can avoid high-temperature gas to be detained in the inside of direct cooling tower body, thereby make cooling efficiency higher through air suction mechanism.

2. Through setting up four snakelike heat transfer cooling tubes, and four snakelike heat transfer cooling tube evenly distributed are in the inside top and the below of direct cooling tower body, thereby make high-temperature gas when the inside very fast motion of direct cooling tower body, can make high-temperature gas when the inside upward movement of direct cooling tower body through setting up four snakelike heat transfer cooling tubes, can carry out the heat transfer cooling in proper order through four snakelike heat transfer cooling tubes, avoid causing the cooling to be abundant inadequately because the very fast motion of high-temperature gas and the cooling of an independent snakelike heat transfer cooling tube, thereby through setting up four snakelike heat transfer cooling tubes, make high-temperature gas also can not influence high-temperature gas's cooling effect when cooling heat exchange efficiency is high.

Drawings

FIG. 1 is a schematic view of the overall cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the enlarged structure of the part A of the present invention;

fig. 3 is a schematic top view of the direct cooling tower body and the serpentine heat exchange cooling pipe of the present invention;

in the figure: 1. a base; 2. a direct cooling tower body; 3. a serpentine heat exchange cooling tube; 4. a fixed mount; 5. an air outlet pipe; 6. a suction mechanism; 7. a water storage tank; 8. a water storage tank; 9. a support frame; 10. a water outlet pipe; 11. a tap joint; 12. a water pump; 13. a support plate; 14. an air intake cover; 15. a vent hole; 16. a connecting pipe; 17. a connecting flange; 18. a water inlet pipe; 19. a drain pipe; 20. a water delivery pipe; 21. a sealing cover; 22. an air inlet pipe; 23. sealing glue; 601. a support bar; 602. an air suction box; 603. an air outlet cover; 604. rotating the rod; 605. fixing the rod; 606. a mounting seat; 607. a servo motor; 608. dust collection fan.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, the present invention provides an embodiment: an oil device direct cooling tower with high treatment efficiency comprises a base 1, a fixing frame 4 is fixedly arranged above the base 1, a direct cooling tower body 2 is fixedly arranged above the fixing frame 4, a snakelike heat exchange cooling pipe 3 is fixedly arranged on the inner wall of the direct cooling tower body 2, four snakelike heat exchange cooling pipes 3 are arranged, the four snakelike heat exchange cooling pipes 3 are uniformly distributed above and below the interior of the direct cooling tower body 2, the snakelike heat exchange cooling pipe 3 is made of copper material, two ends of the snakelike heat exchange cooling pipe 3 respectively extend to two sides of the exterior of the direct cooling tower body 2, an air outlet pipe 5 is fixedly arranged on the outer wall of the upper portion of the direct cooling tower body 2, the interior of the air outlet pipe 5 is communicated with the interior of the direct cooling tower body 2, an air suction mechanism 6 is arranged on the exterior of the air outlet pipe 5, a water storage tank 7 is arranged on one side of the direct cooling tower body 2, and, through setting up water storage tank 8 to the cooling water after the heat transfer is stored, later can carry out the water-cooling to external cold water tower with the water of 8 inside water storage tanks through raceway 20, later arrange once more and continue to carry out cooling work to the inside of storage water tank 7 and use, storage water tank 7 all is fixed with support frame 9 with the below of water storage tank 8, support frame 9 and base 1 fixed connection.

Further, one end of the snakelike heat exchange cooling pipe 3, which is positioned outside one side of the direct cooling tower body 2, is fixedly connected with the outer wall of the water storage tank 8, the inside of the snakelike heat exchange cooling pipe 3 is communicated with the inside of the water storage tank 8, a water outlet pipe 10 is fixedly arranged on the outer wall of one side of the water storage tank 7, one end of the water outlet pipe 10 extends to one side of the outside of the water storage tank 7, the other end of the water outlet pipe 10 extends to the lower part of the inside of the water storage tank 7, the water outlet pipe 10 is fixedly connected with one end of the snakelike heat exchange cooling pipe 3 positioned outside the other side of the direct cooling tower body 2 through a shunt joint 11, one side of the water storage tank 7 is provided with a water pump 12, the water pump 12 and the water outlet pipe 10 are fixedly arranged, a supporting plate 13 is fixedly arranged below the water pump 12, the supporting plate 13 is fixedly connected with the outer wall of the water storage tank 7, the water pump 12 is supported and fixed by the support plate 13 by providing the support plate 13.

Further, the air suction mechanism 6 comprises four support rods 601, an air suction box 602, an air outlet cover 603, a rotating rod 604, four fixing rods 605, a mounting seat 606, a servo motor 607 and a dust suction fan 608, wherein the four support rods 601 are arranged outside the air outlet pipe 5, the air suction box 602 is fixedly connected above the support rods 601, one end of the air outlet pipe 5 extends to the inside of the air suction box 602, the air outlet cover 603 is fixedly connected above the air suction box 602, the rotating rod 604 is arranged on the inner wall above the air suction box 602, two ends of the rotating rod 604 respectively extend to the inside of the air suction box 602 and the upper side of the air outlet cover 603, the four fixing rods 605 are arranged outside the air suction box 602, the mounting seat 606 is fixedly connected above the fixing rods 605, the servo motor 607 is fixedly arranged above the mounting seat 606, and a servo controller is fixedly arranged on one side of the servo motor 607, the type of the servo controller is HBS86H, the rotating speed of the servo motor 607 can be adjusted through the servo controller, so that the size of the suction force can be controlled through the rotating speed of the servo motor 607, the moving speed of the high-temperature gas can be controlled through the size of the suction force, and the dust suction fan 608 is fixedly connected to one end of the rotating rod 604, which is positioned in the suction box 602.

Further, bracing piece 601 and the top outer wall fixed connection of direct cooling tower body 2, the top outer wall fixed connection of dead lever 605 and direct cooling tower body 2, mount pad 606 is located the top of breathing out the gas hood 603, servo motor 607's output extends to the below of mount pad 606, shaft coupling fixed connection is passed through with the one end that dwang 604 is located the top of breathing out the gas hood 603, outlet duct 5 is located the fixed cover 14 that breathes in that is provided with of the inside one end of breathing in case 602, the top of the 14 outer walls of breathing in cover and the inner wall laminating of breathing in case 602, ventilation hole 15 has been seted up to the top outer wall of breathing in case 602, and ventilation hole 15 is provided with a plurality of, dwang 604 all rotates through the bearing with the top outer wall of breathing in cover 603 and breathing in case 602 to be connected, through setting up ventilation hole 15, gas after the cooling can.

Further, one side of the gas outlet cover 603 is fixedly provided with a connecting pipe 16, the inside of the connecting pipe 16 is communicated with the inside of the gas outlet cover 603, the connecting pipe 16 is located between the fixing rods 605, the other end of the connecting pipe 16 is fixedly provided with a connecting flange 17, and the connecting pipe 16 is connected with a gas transportation pipeline through the connecting pipe 16, so that cooled gas can be discharged to a place needing to work.

Further, the fixed inlet tube 18 that is provided with in top of 7 one sides outer walls of storage water tank, the fixed drain pipe 19 that is provided with in below of 7 one sides outer walls of storage water tank, the fixed raceway 20 that is provided with in below of 8 one sides outer walls of water storage tank, inlet tube 18 is provided with flange 17 with the one end of raceway 20 is all fixed, the sealed lid 21 of one end threaded connection of drain pipe 19, the fixed intake pipe 22 that is provided with in below of 2 one sides outer walls of straight cold tower body, the fixed sealed glue 23 that is provided with of junction between 3 and the 2 outer walls of straight cold tower body of snakelike heat transfer cooling tube, through setting up sealed glue 23, can avoid the junction gas leakage between 3 of snakelike heat transfer cooling tube.

The working principle is as follows: when the device is used, cooling water is firstly discharged into the water storage tank 7 through the water inlet pipe 18, then a high-temperature gas pipeline is connected with the air inlet pipe 22, the pipeline for transporting cooling gas is connected with the connecting pipe 16 through the connecting flange 17, then the water pump 12 is started, the water in the water storage tank 7 is discharged into the snakelike heat exchange cooling pipe 3 through the water outlet pipe 10 and the flow dividing joint 11 by the water pump 12, and the cooling water is discharged into the water storage tank 8 through the snakelike heat exchange cooling pipe 3, so that the water in the water storage tank 7 can flow in the snakelike heat exchange cooling pipe 3 and then is discharged into the water storage tank 8, meanwhile, the servo motor 607 is started, the rotating speed of the servo motor 607 is adjusted through the servo controller, thereby controlling the size of the suction force, the servo motor 607 can drive the rotating rod 604 to rotate, and the rotating rod 604 can drive the dust suction fan 608, thereby the dust absorption fan 608 generates suction force, the suction force can enter the inside of the direct cooling tower body 2 through the air outlet pipe 5, so that the suction force can suck the high temperature gas inside the direct cooling tower body 2 upwards, the high temperature gas inside the direct cooling tower body 2 can move to the inside of the air outlet pipe 5 rapidly under the action of the suction force, the high temperature gas can respectively pass through the tube gaps of the four serpentine heat exchange cooling tubes 3 during the movement, cooling water flows inside the serpentine heat exchange cooling tubes 3, and the serpentine heat exchange cooling tubes 3 are made of copper materials, so that through the heat exchange principle, the high temperature gas can be subjected to heat exchange cooling through the four serpentine heat exchange cooling tubes 3 when passing through the four serpentine heat exchange cooling tubes 3, and the high temperature gas can be subjected to heat exchange cooling through the four serpentine heat exchange cooling tubes 3 when rapidly moving to the air outlet pipe 5, the cooled gas is discharged to the inside of the gas outlet cover 603 through the vent hole 15, and then discharged to the inside of the gas transport pipeline through the connecting pipe 16, and after the cooling water after heat exchange flows to the inside of the water storage tank 8, the water inside the water storage tank 8 can be discharged to an external cold water tower through the water delivery pipe 20 for water cooling, and then discharged to the inside of the water storage tank 7 again for continuous cooling.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides an oil ware direct cooling tower that treatment effeciency is high, includes base (1), its characterized in that: a fixing frame (4) is fixedly arranged above the base (1), a straight cooling tower body (2) is fixedly arranged above the fixing frame (4), the inner wall of the straight cooling tower body (2) is fixedly provided with a snakelike heat exchange cooling pipe (3), four snakelike heat exchange cooling pipes (3) are arranged, the four snakelike heat exchange cooling pipes (3) are uniformly distributed above and below the inside of the straight cooling tower body (2), two ends of each snakelike heat exchange cooling pipe (3) respectively extend to two sides of the outside of the straight cooling tower body (2), an air outlet pipe (5) is fixedly arranged on the outer wall above the straight cooling tower body (2), the inside of the air outlet pipe (5) is communicated with the inside of the straight cooling tower body (2), an air suction mechanism (6) is arranged outside the air outlet pipe (5), a water storage tank (7) is arranged on one side of the straight cooling tower body (2), the water storage tank (8) is arranged on the other side of the direct cooling tower body (2), support frames (9) are fixedly arranged below the water storage tank (7) and the water storage tank (8), and the support frames (9) are fixedly connected with the base (1).

2. The oil head direct cooling tower with high treatment efficiency as claimed in claim 1, wherein: the serpentine heat exchange cooling pipe (3) is fixedly connected with the outer wall of the water storage tank (8) at one end outside one side of the direct cooling tower body (2), the inside of the serpentine heat exchange cooling pipe (3) is communicated with the inside of the water storage tank (8), a water outlet pipe (10) is fixedly arranged on the outer wall of one side of the water storage tank (7), one end of the water outlet pipe (10) extends to one side outside the water storage tank (7), the other end of the water outlet pipe (10) extends to the lower part inside the water storage tank (7), the water outlet pipe (10) is fixedly connected with one end of the serpentine heat exchange cooling pipe (3) outside the other side of the direct cooling tower body (2) through a shunt joint (11), a water pump (12) is arranged at one side of the water storage tank (7), the water pump (12) and the water outlet pipe (10) are fixedly installed, a support plate (13) is fixedly arranged below, and the supporting plate (13) is fixedly connected with the outer wall of the water storage tank (7).

3. The oil head direct cooling tower with high treatment efficiency as claimed in claim 1, wherein: the air suction mechanism (6) comprises supporting rods (601), an air suction box (602), air outlet covers (603), four rotating rods (604), fixing rods (605), a mounting seat (606), a servo motor (607) and a dust suction fan (608), wherein the number of the supporting rods (601) is four, the four supporting rods (601) are located outside an air outlet pipe (5), the air suction box (602) is fixedly connected above the supporting rods (601), one end of the air outlet pipe (5) extends to the inside of the air suction box (602), the air outlet covers (603) are fixedly connected above the air suction box (602), the rotating rods (604) are arranged on the inner wall above the air suction box (602), the two ends of the rotating rods (604) respectively extend to the inside of the air suction box (602) and the upper side of the air outlet covers (603), the four fixing rods (605) are arranged outside the air suction box (602), the mounting seat (606) is fixedly connected above the fixing rod (605), the servo motor (607) is fixedly mounted above the mounting seat (606), and the dust suction fan (608) is fixedly connected to one end of the rotating rod (604) located inside the air suction box (602).

4. The oil head direct cooling tower with high treatment efficiency as claimed in claim 3, wherein: the supporting rod (601) is fixedly connected with the upper outer wall of the direct cooling tower body (2), the fixed rod (605) is fixedly connected with the upper outer wall of the direct cooling tower body (2), the mounting seat (606) is positioned above the air outlet cover (603), the output end of the servo motor (607) extends to the lower part of the mounting seat (606), the output end of the servo motor (607) is fixedly connected with one end of the rotating rod (604) above the air outlet cover (603) through a coupler, one end of the air outlet pipe (5) positioned in the air suction box (602) is fixedly provided with an air suction cover (14), the upper part of the outer wall of the air suction cover (14) is attached to the inner wall of the air suction box (602), the outer wall of the upper part of the air suction box (602) is provided with a vent hole (15), and ventilation hole (15) are provided with a plurality of, dwang (604) all rotate through the bearing with the top outer wall that goes out air cover (603) and inhale case (602) and be connected.

5. The oil head direct cooling tower with high treatment efficiency as claimed in claim 3, wherein: one side of the air outlet cover (603) is fixedly provided with a connecting pipe (16), the inside of the connecting pipe (16) is communicated with the inside of the air outlet cover (603), the connecting pipe (16) is positioned between the fixing rods (605), and the other end of the connecting pipe (16) is fixedly provided with a connecting flange (17).

6. The oil head direct cooling tower with high treatment efficiency as claimed in claim 1, wherein: the fixed inlet tube (18) that is provided with in top of storage water tank (7) one side outer wall, the fixed drain pipe (19) that is provided with in below of storage water tank (7) one side outer wall, the fixed raceway (20) that is provided with in below of water storage tank (8) one side outer wall, inlet tube (18) and the one end of raceway (20) are all fixed and are provided with flange (17), the sealed lid (21) of one end threaded connection of drain pipe (19), the fixed intake pipe (22) that is provided with in below of straight cold tower body (2) one side outer wall, the fixed sealed glue (23) that is provided with of junction between snakelike heat transfer cooling tube (3) and straight cold tower body (2) outer wall.

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