CN212253793U - A multistage heat transfer system for taking off production of powder soon - Google Patents

Abstract

The utility model discloses a multistage heat transfer system for taking off production of powder soon, including first heat transfer case, second heat transfer case, third heat transfer case and landing leg, the horizontal fixedly connected with bottom plate in top of landing leg, and the vertical fixedly connected with third heat transfer case in one side of bottom plate top, and the lower extreme fixedly connected with air inlet of third heat transfer case one side, the bottom plate top fixedly connected with second heat transfer case of third heat transfer case one side, the first heat transfer case of bottom plate top fixedly connected with of second heat transfer case one side, and the inside fixedly connected with third pipeline of first heat transfer case, and the other end of third pipeline runs through first heat transfer case one side lower extreme and fixedly connected with discharge gate. The utility model discloses a set up first heat transfer case, second heat transfer case and third heat transfer case on the bottom plate top, utilize tertiary heat transfer for the heat transfer is apart from long, the area is big, effectual etc. and then makes the temperature reduce fast, is convenient for improve work efficiency.

Description

A multistage heat transfer system for taking off production of powder soon

Technical Field

The utility model relates to a quick-release powder production facility technical field specifically is a multistage heat transfer system for quick-release powder production.

Background

Along with the development of society, the rapid development of chemical industry in China makes the preparation of the quick-release powder more intelligent and industrialized, and the quick-release powder can generate a large amount of heat in the production process, so that the heat exchange treatment is needed to be carried out on the quick-release powder to accelerate the working efficiency, but the existing heat exchange system for the quick-release powder production still has many problems or defects:

firstly, the traditional heat exchange system for the quick powder removal production has no multi-stage heat exchange structure when in use, has poor heat exchange efficiency and unsatisfactory effect;

secondly, the traditional heat exchange system for the quick powder removal production has no waste heat recovery structure when in use, so that a large amount of generated heat cannot be well recycled, and resources are wasted;

third, traditional heat transfer system who is used for taking off powder production soon can not dismantle the filter screen fast during the use, and the filter screen is easy to be blockked up by impurity, reduces device air inlet effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a multistage heat transfer system for taking off powder production soon to the problem of the filter screen can not multistage heat transfer, inconvenient waste heat recovery and inconvenient dismantlement fast that proposes in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a multi-stage heat exchange system for quick powder removal production comprises a first heat exchange box, a second heat exchange box, a third heat exchange box and support legs, wherein the top end of each support leg is transversely and fixedly connected with a bottom plate, one side of the top end of the bottom plate is vertically and fixedly connected with the third heat exchange box, a first pipeline is vertically and fixedly connected to the middle position of the top end of the inside of the third heat exchange box, a feed inlet is fixedly connected to the middle position of the top end of the third heat exchange box at the top end of the first pipeline, the top end of the third heat exchange box at one side of the feed inlet is fixedly connected with a heat energy recovery pipe, the lower end of one side of the third heat exchange box is fixedly connected with an air inlet, a filter screen is vertically arranged inside the air inlet, an installation structure is arranged at the top end of the filter screen, the top end of the bottom plate at one side of the third heat exchange box is fixedly connected with the second heat exchange box, the bottom plate top fixedly connected with first heat transfer case of second heat transfer case one side, and the inside fixedly connected with third pipeline of first heat transfer case, third pipeline one end is passed through pipe and second pipeline other end intercommunication, and the other end of third pipeline runs through first heat transfer case one side lower extreme and fixedly connected with discharge gate, the equal fixedly connected with water inlet of intermediate position department on first heat transfer case and second heat transfer case top, and the equal fixedly connected with outlet of intermediate position department of first heat transfer case and second heat transfer case bottom.

Preferably, the bottom of the first heat exchange box and the bottom of the second heat exchange box are fixedly connected with guide plates, and the cross sections of the guide plates and the inclination angle of the horizontal direction are both 20 degrees.

Preferably, the tops of the first heat exchange box, the second heat exchange box and the second heat exchange box are uniformly and transversely fixedly connected with rotating rods, and the surfaces of the rotating rods are uniformly and rotatably connected with flow blocking blades.

Preferably, the interior of the third heat exchange box on the surface of the first pipeline is fixedly connected with a heat conduction rod, and the shape of the heat conduction rod is Y-shaped.

Preferably, mounting hole, installation spring, installation pole, installation piece and sealed piece have been set gradually to mounting structure's inside, sealed piece fixed connection is in air inlet top one side on filter screen top, and the inside both sides of sealed piece have all seted up the mounting hole, the equal fixedly connected with installation piece in air inlet top of sealed piece both sides, and the lower extreme of installation piece one side all runs through have with mounting hole matched with installation pole, the one end on installation pole surface all twines there is the installation spring.

Preferably, the inner parts of the second pipeline and the third pipeline are uniformly and fixedly connected with baffle plates, and the second pipeline and the third pipeline are both in spiral shape and vertically and fixedly connected inside the first heat exchange box and the second heat exchange box.

Compared with the prior art, the beneficial effects of the utility model are that: this a multistage heat transfer system for taking off production of powder soon is rational in infrastructure, has following advantage:

(1) the first heat exchange box, the second heat exchange box and the third heat exchange box are arranged at the top end of the bottom plate, air heat exchange is realized through the third heat exchange box, and cold water heat exchange can be realized through the first heat exchange box and the second heat exchange box, so that the device can realize three-stage heat exchange, the heat exchange distance is long, the area is large, the effect is good, the temperature can be quickly reduced, and the first heat exchange box and the second heat exchange box can ensure that the device can obtain a good cooling effect under the condition of high temperature in summer, the use range of the device is enlarged, and the practicability of the device is improved;

(2) the heat conducting rod is arranged in the third heat exchange box, the filter screen is arranged in the air inlet, the heat of the quick-falling powder in the first pipeline is led out through the heat conducting rod, the Y-shaped heat conducting rod is utilized to enable the mechanical strength of the heat conducting rod to be higher, the contact area between the heat conducting rod and the cold air is increased, the cold air is conveniently and quickly heated, the heat exchange effect is improved, the heated air is discharged through the heat energy recovery pipe and participates in production and utilization again, resources can be saved, the production economy is reduced, meanwhile, the filter screen filters impurities in the air, the situation that the heated air is rich in impurities is avoided, and therefore subsequent production operation is influenced;

(3) the installation structure is arranged on one side of the top end of the air inlet, the installation rod is pulled to move into the installation hole, then the filter screen can be taken out and cleaned from the inside of the air inlet through the sealing block of the worker, the filter screen is prevented from being blocked by impurities, the air inlet effect of the device is reduced, the air heat exchange efficiency is reduced, and the air after heat exchange cannot be well recycled, and the working efficiency of the device is reduced.

Drawings

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

FIG. 2 is a schematic side sectional view of the present invention;

FIG. 3 is a schematic top view of the cross-sectional structure of the present invention;

fig. 4 is an enlarged schematic view of the mounting structure of the present invention.

In the figure: 1. a first heat exchange tank; 2. a water inlet; 3. choked flow leaves; 4. a rotating rod; 5. a second heat exchange tank; 6. a third heat exchange tank; 7. a feed inlet; 8. a heat energy recovery pipe; 9. a heat conducting rod; 10. a first conduit; 11. a mounting structure; 1101. mounting holes; 1102. installing a spring; 1103. mounting a rod; 1104. mounting blocks; 1105. a sealing block; 12. an air inlet; 13. filtering with a screen; 14. a base plate; 15. a support leg; 16. a second conduit; 17. a baffle plate; 18. a water outlet; 19. a baffle; 20. a third pipeline; 21. and (4) a discharge port.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a multi-stage heat exchange system for quick powder removal production comprises a first heat exchange box 1, a second heat exchange box 5, a third heat exchange box 6 and supporting legs 15, wherein the top ends of the supporting legs 15 are transversely and fixedly connected with a bottom plate 14, one side of the top end of the bottom plate 14 is vertically and fixedly connected with the third heat exchange box 6, and a first pipeline 10 is vertically and fixedly connected to the middle position of the top end in the third heat exchange box 6;

the interior of the third heat exchange box 6 on the surface of the first pipeline 10 is fixedly connected with a heat conducting rod 9, and the shape of the heat conducting rod 9 is Y-shaped;

specifically, as shown in fig. 1 and 3, when the mechanism is used, firstly, heat of the quick-falling powder in the first pipeline 10 is led out through the heat conducting rod 9, the mechanical strength of the mechanism is higher by utilizing the "Y" heat conducting rod 9, the contact area between the mechanism and the cold air is increased, the cold air is conveniently and quickly heated, the heat exchange effect is improved, the hot air is discharged through the heat energy recovery pipe 8, and the hot air participates in production and utilization again, so that the recovery and utilization of waste heat are realized;

a feed inlet 7 is fixedly connected to the middle position of the top end of the third heat exchange box 6 at the top end of the first pipeline 10, a heat energy recovery pipe 8 is fixedly connected to the top end of the third heat exchange box 6 at one side of the feed inlet 7, an air inlet 12 is fixedly connected to the lower end of one side of the third heat exchange box 6, a filter screen 13 is vertically arranged inside the air inlet 12, and an installation structure 11 is arranged at the top end of the filter screen 13;

the mounting structure 11 is internally provided with a mounting hole 1101, a mounting spring 1102, a mounting rod 1103, a mounting block 1104 and a sealing block 1105 in sequence, the sealing block 1105 is fixedly connected to one side of the top end of the air inlet 12 at the top end of the filter screen 13, the mounting hole 1101 is formed in each of two sides inside the sealing block 1105, the mounting block 1104 is fixedly connected to each of the top ends of the air inlets 12 at two sides of the sealing block 1105, the mounting rod 1103 matched with the mounting hole 1101 penetrates through the lower end of one side of the mounting block 1104, and the mounting spring 1102 is wound on one end of the surface of the mounting rod 1103;

specifically, as shown in fig. 1, 3 and 4, when the mechanism is used, firstly, the mounting rod 1103 is pulled to move the tension mounting spring 1102 to be completely separated from the mounting hole 1101, and then a worker can take out and clean the filter screen 13 from the inside of the air inlet 12 through the sealing block 1105, so that the filter screen 13 is prevented from being blocked by impurities, and the air inlet effect of the device is reduced;

the top end of the bottom plate 14 at one side of the third heat exchange box 6 is fixedly connected with a second heat exchange box 5, the interior of the second heat exchange box 5 is fixedly connected with a second pipeline 16, one end of the second pipeline 16 is communicated with the bottom end of the first pipeline 10 through a guide pipe, and the top end of the bottom plate 14 at one side of the second heat exchange box 5 is fixedly connected with a first heat exchange box 1;

the top ends of the inner parts of the first heat exchange box 1 and the second heat exchange box 5 are uniformly and transversely fixedly connected with rotating rods 4, and the surfaces of the rotating rods 4 are uniformly and rotatably connected with flow blocking blades 3;

specifically, as shown in fig. 1, 2 and 3, when the mechanism is used, cold water is injected into the first heat exchange box 1 and the second heat exchange box 5 through the water inlet 2, the downward impact force of the water flow is utilized to drive the flow blocking blades 3 to rotate on the rotating rod 4, so that the water flow is scattered, the water flow is more uniformly distributed in the first heat exchange box 1 and the second heat exchange box 5, and the heat exchange efficiency with quick powder removal is improved;

and the inside of the first heat exchange box 1 is fixedly connected with a third pipeline 20;

baffle plates 17 are uniformly and fixedly connected inside the second pipeline 16 and the third pipeline 20, and the second pipeline 16 and the third pipeline 20 are vertically and fixedly connected inside the first heat exchange box 1 and the second heat exchange box 5 in a spiral shape;

specifically, as shown in fig. 1, 2 and 3, when the mechanism is used, firstly, the spiral second pipeline 16 and the spiral third pipeline 20 are arranged, and the baffle plates 17 in the second pipeline 16 and the third pipeline 20 are arranged, so that the flow rate of the quick-release powder is lower, heat exchange with cold water is facilitated, and the heat dissipation effect of the quick-release powder is improved;

one end of a third pipeline 20 is communicated with the other end of the second pipeline 16 through a guide pipe, the other end of the third pipeline 20 penetrates through the lower end of one side of the first heat exchange box 1 and is fixedly connected with a discharge hole 21, a water inlet 2 is fixedly connected to the middle position of the top ends of the first heat exchange box 1 and the second heat exchange box 5, and a water outlet 18 is fixedly connected to the middle position of the bottom ends of the first heat exchange box 1 and the second heat exchange box 5;

the bottom ends of the interior of the first heat exchange box 1 and the interior of the second heat exchange box 5 are fixedly connected with a guide plate 19, and the inclined angles of the cross section of the guide plate 19 and the horizontal direction are both 20 degrees;

specifically, as shown in fig. 1 and 2, when the mechanism is used, the inclined guide plate 19 is first utilized, so that water inside the first heat exchange box 1 and the second heat exchange box 5 is easier to be discharged out of the device through the water discharge port 18.

The working principle is as follows: when the device is used, firstly, after the device is fixed, quick-release powder is blown into the first pipeline 10 through the feed inlet 7, heat of the quick-release powder in the first pipeline 10 is led out through the heat conducting rod 9, cold air is blown into the third heat exchange box 6 through the air inlet 12, impurities in the air are blocked by the filter screen 13, the mechanical strength of the device is higher by utilizing the Y-shaped heat conducting rod 9, the contact area of the device and the cold air is increased, the cold air is conveniently and quickly heated, the heat exchange effect is improved, the hot air is discharged through the heat energy recovery pipe 8, and the hot air participates in production and utilization again;

then the fast-removing powder enters a second pipeline 16, the spiral second pipeline 16 and a baffle plate 17 enable the flow speed of the fast-removing powder to be lower, cold water is injected into the second heat exchange box 5 through a water inlet 2 at the moment, the downward impact force of the water flow drives a flow blocking blade 3 to rotate on a rotating rod 4, the water flow is scattered, the water flow is conveniently and evenly distributed in the second heat exchange box 5, the heat exchange efficiency with the fast-removing powder is improved, then the heated water is drained through a flow guide plate 19, hot water is quickly discharged through a water outlet 18, then the fast-removing powder enters a third pipeline 20, the operation is repeated, the heat exchange effect is better, the fast-removing powder is conveniently and quickly cooled, and then the cooled fast-removing powder is discharged and collected through a discharge port 21;

after the device uses a period, can pull installation pole 1103 for installation pole 1103 removes tensile installation spring 1102 and breaks away from in the mounting hole 1101 completely, then staff's accessible sealed piece 1105 takes out filter screen 13 from air inlet 12 is inside and washs, avoids filter screen 13 to be blockked up by impurity, reduces device air inlet effect.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a multistage heat transfer system for taking off production of powder soon, includes first heat transfer case (1), second heat transfer case (5), third heat transfer case (6) and landing leg (15), its characterized in that: the top end of the supporting leg (15) is transversely and fixedly connected with a bottom plate (14), one side of the top end of the bottom plate (14) is vertically and fixedly connected with a third heat exchange box (6), the middle position of the top end in the third heat exchange box (6) is vertically and fixedly connected with a first pipeline (10), the middle position of the top end of the third heat exchange box (6) on the top end of the first pipeline (10) is fixedly connected with a feed inlet (7), the top end of the third heat exchange box (6) on one side of the feed inlet (7) is fixedly connected with a heat energy recovery pipe (8), the lower end of one side of the third heat exchange box (6) is fixedly connected with an air inlet (12), a filter screen (13) is vertically arranged in the air inlet (12), the top end of the filter screen (13) is provided with an installation structure (11), the top end of the bottom plate (14) on one side of, and a second pipeline (16) is fixedly connected inside the second heat exchange box (5), one end of the second pipeline (16) is communicated with the bottom end of the first pipeline (10) through a guide pipe, the top end of a bottom plate (14) at one side of the second heat exchange box (5) is fixedly connected with a first heat exchange box (1), and a third pipeline (20) is fixedly connected inside the first heat exchange box (1), one end of the third pipeline (20) is communicated with the other end of the second pipeline (16) through a conduit, the other end of the third pipeline (20) penetrates through the lower end of one side of the first heat exchange box (1) and is fixedly connected with a discharge hole (21), the middle positions of the top ends of the first heat exchange box (1) and the second heat exchange box (5) are fixedly connected with a water inlet (2), and the water outlets (18) are fixedly connected to the middle positions of the bottom ends of the first heat exchange box (1) and the second heat exchange box (5).

2. The multistage heat exchange system for the production of quick-release powder of claim 1, which is characterized in that: the equal fixedly connected with guide plate (19) in the bottom of first heat transfer case (1) and second heat transfer case (5) inside, and guide plate (19) cross section is 20 with the inclination of horizontal direction.

3. The multistage heat exchange system for the production of quick-release powder of claim 1, which is characterized in that: the top end inside the first heat exchange box (1) and the second heat exchange box (5) is uniformly and transversely fixedly connected with a rotating rod (4), and the surface of the rotating rod (4) is uniformly and rotatably connected with flow blocking blades (3).

4. The multistage heat exchange system for the production of quick-release powder of claim 1, which is characterized in that: the heat conduction rods (9) are fixedly connected inside the third heat exchange box (6) on the surface of the first pipeline (10), and the heat conduction rods (9) are Y-shaped.

5. The multistage heat exchange system for the production of quick-release powder of claim 1, which is characterized in that: mounting hole (1101), installation spring (1102), installation pole (1103), installation piece (1104) and sealed piece (1105) have set gradually to the inside of mounting structure (11), sealed piece (1105) fixed connection is in air inlet (12) top one side on filter screen (13) top, and inside both sides of sealed piece (1105) have all seted up mounting hole (1101), the equal fixedly connected with installation piece (1104) in air inlet (12) top of sealed piece (1105) both sides, and the lower extreme of installation piece (1104) one side all runs through have with mounting hole (1101) matched with installation pole (1103), installation spring (1102) have all been twined to the one end on installation pole (1103) surface.

6. The multistage heat exchange system for the production of quick-release powder of claim 1, which is characterized in that: baffle plates (17) are uniformly and fixedly connected inside the second pipeline (16) and the third pipeline (20), and the second pipeline (16) and the third pipeline (20) are both in spiral vertical fixed connection inside the first heat exchange box (1) and the second heat exchange box (5).

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