CN215028830U - High-efficient cooling device of reation kettle - Google Patents

Abstract

The utility model provides a high-efficient cooling device of reation kettle, including reation kettle body, cooling rack, cooling box I, cooling box II and cooling tube group, reation kettle body top is equipped with the feed inlet, reation kettle body bottom is equipped with the discharge gate, the cooling tube rack has evenly been laid to reation kettle body outer wall, the cooling tube group comprises water cooling pipe and oil cooling pipe, install cooling box I and cooling box II on the upper cooling rack, water cooling pipe water inlet links to each other with cooling box I through the inlet tube, install valve I on the inlet tube, water cooling pipe delivery port links to each other with cooling box I through the outlet pipe; install the motor on the reation kettle body, the (mixing) shaft is installed at reation kettle originally internally, this internal cooling chamber that is equipped with of reation kettle, and many cooling rods are evenly installed to the cooling intracavity, and oil cooling pipe oil inlet links to each other with cooling tank two through advancing oil pipe, advances to install valve two on the oil pipe, and oil cooling pipe oil-out links to each other with cooling tank two through going out oil pipe.

Description

High-efficient cooling device of reation kettle

Technical Field

The utility model belongs to the technical field of reation kettle cooling arrangement, concretely relates to reation kettle's high-efficient cooling device.

Background

The reaction kettle is one of the common devices in the industry, the cooling speed of the reaction kettle has certain influence on the product, the reaction speed in the reaction kettle can change along with the temperature change, when the reaction kettle works, if the reaction kettle is not cooled in place, unreacted materials can be accumulated in the reaction kettle, for example, a publication No. CN204710337U discloses a reaction kettle with a cooling device, which comprises a reaction kettle main body, a spiral stirring blade and a cooling water cavity, a rotating shaft is arranged at the shaft center of the reaction kettle main body, the bottom end of the rotating shaft extends to the bottom of the reaction kettle main body, the rotating shaft is sleeved with the spiral stirring blade, the top end of the rotating shaft extends out of the reaction kettle main body and is connected with a rotating motor, a motor outer cover is arranged outside the rotating motor, a feeding pipe is arranged at the left side of the upper end of the reaction kettle main body, a discharging pipe is arranged at the lower side of the reaction kettle main body, and the spiral stirring blade can stir the reaction materials flying inside the reaction kettle, the cleaning spray head can clean the inner wall of the reaction kettle, the cooling device in the reaction kettle in the prior art only adopts a mode to cool, the requirement of quick cooling cannot be met, water enters the cooling water cavity to be cooled simultaneously, substances are remained in the cooling water cavity when the temperature in the reaction kettle is higher, and the cooling water cavity is difficult to clean, so that the cooling efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems existing in the prior art, the utility model provides a high-efficient cooling device of a reaction kettle.

The utility model provides a following technical scheme:

the utility model provides a reation kettle's high-efficient cooling device, includes reation kettle body, cooling rack, cooler bin one, cooler bin two and cooling tube group, and reation kettle body top is equipped with the feed inlet, and reation kettle body bottom is equipped with the discharge gate, reation kettle body outer wall has evenly laid the cooling tube rack, and the supporting leg is installed at the bottom of the cooling tube rack bottom, and the cooling tube group comprises water cooling pipe and oil cooling pipe, and the water cooling pipe is installed on the cooling tube rack, the cooling rack is installed in reation kettle body one side, the cooling rack divide into two-layerly, installs cooler bin one and cooler bin two on the upper cooling rack, and the water cooling pipe water inlet passes through the inlet tube and links to each other with cooler bin one, installs valve one on the inlet tube, and the water cooling pipe delivery port passes through the outlet pipe and links to each other with cooler bin one.

Further, install the motor on the reation kettle body, the (mixing) shaft is installed at reation kettle originally internally, and (mixing) shaft top and motor bottom link to each other, this internal cooling chamber that is equipped with of reation kettle, and many cooling rods are evenly installed to the cooling intracavity, and oil cooling pipe installs on the cooling rod, and oil cooling pipe oil inlet links to each other with cooling box two through advancing oil pipe, advances to install valve two on the oil pipe, and oil cooling pipe oil-out links to each other with cooling box two through going out oil pipe.

Furthermore, the cooling liquid in the first cooling box is water, and the cooling liquid in the second cooling box is oil.

Furthermore, a circulating cooling groove is formed in the cooling rack and is located below the first cooling box and the second cooling box.

Further, a cooling coil is installed in the circulating cooling tank.

Furthermore, a water tank is further installed on the lower-layer cooling rack, the head end of the cooling coil is connected with the water tank through a first water pipe, and the tail end of the cooling coil is connected with the water tank through a second water pipe.

Furthermore, the first cooling box is connected with the water tank through a third water pipe, and a third valve is installed on the third water pipe.

Furthermore, sensors are installed in the first cooling box and the second cooling box, and the sensors in the first cooling box are electrically connected with the third valve.

The utility model has the advantages that:

1. be equipped with two kinds of cooling device on the reation kettle body, can select different cooling methods, can make two kinds of cooling methods go on simultaneously when needing quick cooling, improve cooling efficiency.

2. And cooling coils are arranged below the first cooling box and the second cooling box, so that the liquid in the first cooling box and the second cooling box can be rapidly cooled and circulated.

3. The sensor senses the use condition of the cooling liquid in the first cooling box and the second cooling box, and the water in the water box can be supplied to the cooling coil and can also be used for supplying the first cooling box.

4. The water cooling pipe is installed on the cooling pipe support, and the oil cooling pipe is installed on the cooling rod, is convenient for pull down the cooling pipe group and washs.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

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

figure 2 is the utility model discloses a reation kettle body cross-sectional view.

Labeled as: 1. supporting legs; 2. a water cooling pipe; 3. cooling the pipe frame; 4. a reaction kettle body; 41. a feed inlet; 42. a cooling chamber; 43. a discharge port; 5. a motor; 6. a water outlet pipe; 7. an oil outlet pipe; 8. a water inlet pipe; 9. a first valve; 10. an oil inlet pipe; 11. a sensor; 12. a first cooling box; 13. a second valve; 14. a second cooling box; 15. a cooling coil; 16. a water pipe II; 17. a first water pipe; 18. a third valve; 19. a water pipe III; 20. a water tank; 21. a cooling rack; 211. a circulating cooling tank; 22. a cooling rod; 23. an oil cooling tube; 24. a stirring shaft.

Detailed Description

As shown in figures 1 and 2, a high-efficiency cooling device of a reaction kettle comprises a reaction kettle body 4, a cooling rack 21, a first cooling box 12, a second cooling box 14 and a cooling pipe group, wherein the cooling liquid in the first cooling box 12 is water, the cooling liquid in the second cooling box 14 is oil, a feed inlet 41 is formed in the top end of the reaction kettle body 4, a discharge outlet 43 is formed in the bottom end of the reaction kettle body 4, a cooling pipe rack 3 is uniformly distributed on the outer wall of the reaction kettle body 1, a supporting leg 1 is installed at the bottom end of the cooling pipe rack 3, the cooling pipe group consists of a water cooling pipe 2 and an oil cooling pipe 23, the water cooling pipe 2 is installed on the cooling pipe rack 3, the cooling rack 21 is installed on one side of the reaction kettle body 4, the cooling rack 21 is divided into two layers, the first cooling box 12 and the second cooling box 14 are installed on the upper cooling rack 21, the water inlet of the water cooling pipe 2 is connected with the first cooling box 12 through a water inlet pipe 8, a first valve 9 is installed on the water inlet pipe 8, the water outlet of the water cooling pipe 2 is connected with a first cooling box 12 through a water outlet pipe 6; install motor 5 on reation kettle body 4, (mixing) shaft 24 installs in reation kettle body 4, (mixing) shaft 24 top and motor 5 bottom link to each other, this internal cooling chamber 42 that is equipped with of reation kettle, evenly install many cooling rods 22 in the cooling chamber 42, oil cooling pipe 23 installs on cooling rod 22, oil cooling pipe 23 oil inlet links to each other with cooling box two 14 through advancing oil pipe 10, advance to install valve two 13 on the oil pipe 10, oil cooling pipe 23 oil-out links to each other with cooling box two 14 through going out oil pipe 7.

The water cooling pipe 2 is arranged on the outer ring of the reaction kettle body 4, water in the cooling box I12 flows into the water cooling pipe 2 through the water inlet pipe 8 to cool the reaction kettle body 4, the water in the water cooling pipe 2 flows back to the cooling box I12 through the water outlet pipe 6 to form water circulation cooling, and can be used in occasions with low requirements on cooling speed, the valve I9 on the water inlet pipe 8 controls the circulation of the water in the cooling box I12, and the water cooling pipe 2 is arranged on the cooling pipe frame 3 and is convenient to disassemble and clean, so that the cooling efficiency is improved; the oil cooling pipe 23 is arranged in the cooling cavity 42 through the cooling rod 22, the oil cooling pipe 23 can be disassembled by assembling and disassembling the cooling rod 22, cooling oil in the cooling box II 14 enters the oil cooling pipe 23 through the oil inlet pipe 10, the cooling oil in the oil cooling pipe 23 returns to the cooling box II 14 through the oil outlet pipe 7 to form oil cooling circulation, the cooling speed of the oil is higher than that of the water due to the fact that the water has larger heat capacity than that of the oil, the oil cooling device can be used for occasions requiring the higher cooling speed, the valve II 13 controls the circulation of the cooling oil in the cooling box II 14, different cooling modes can be used for different occasions, cost is saved, and meanwhile cooling efficiency is improved; if when requiring very high to the cooling rate, then can use two kinds of cooling methods simultaneously to satisfy the preparation requirement, the utility model discloses a theory of operation: if the requirement on the cooling speed of the reaction kettle is not high, opening the first valve 9, enabling the second valve 13 to be in a closed state, enabling water in the first cooling box 12 to return to the first cooling box 12 through the water inlet pipe 8, the water cooling pipe 2 and the water outlet pipe 6 to form water cooling to cool the reaction kettle body 4, if the reaction kettle is fast, opening the second valve 13, enabling the first valve 9 to be in a closed state, enabling cooling oil in the second cooling box 14 to finally flow back to the second cooling box 14 through the oil inlet pipe 10, the oil cooling pipe 23 and the oil outlet pipe 7 to form oil cooling circulation to rapidly cool the reaction kettle body 4, enabling the water outlet pipe 6 and the oil outlet pipe 7 to be vertical water pipes to prevent the water in the first cooling box 12 or the cooling oil in the second cooling box 14 from flowing backwards, and enabling the first valve 9 and the second valve 13 to be opened simultaneously when the cooling speed is fast, the cooling speed is accelerated.

A circulating cooling groove 211 is formed in the cooling rack 21, the circulating cooling groove 211 is located below the first cooling box 12 and the second cooling box 14, a cooling coil 15 is installed in the circulating cooling groove 211, a water tank 20 is further installed on the lower cooling rack 21, the head end of the cooling coil 15 is connected with the water tank 20 through a first water pipe 17, and the tail end of the cooling coil 15 is connected with the water tank 20 through a second water pipe 16; the first cooling box 12 is connected with the water tank 20 through a third water pipe 19, a third valve 18 is installed on the third water pipe 19, the sensors 11 are installed in the first cooling box 12 and the second cooling box 14, and the sensor 11, the controller and the third valve 18 in the first cooling box 12 are electrically connected.

In order to rapidly cool the cooling liquid in the first cooling box 12 and the second cooling box 14, the cooling coil 15 is installed on the cooling rack 21, the water in the water tank 20 returns to the water tank 20 through the first water pipe 17, the cooling coil 15 and the second water pipe 16 to form water cooling, the cooling liquid in the first cooling box 12 and the second cooling box 14 is cooled, the sensor 11 installed in the second cooling box 14 detects the use condition of the cooling oil in the second cooling box 14, and therefore an operator can supply the cooling liquid in time, the sensor 11 in the first cooling box 12 is electrically connected with the third valve 18, when the sensor 11 detects that the cooling liquid in the first cooling box 12 is insufficient, the sensor 11 sends a signal to the controller, and the controller controls the third valve 18 to be opened, so that the water in the water tank 20 is supplied to the first cooling box 12 in time, and the cooling efficiency is effectively improved.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a high-efficient cooling device of reation kettle, includes reation kettle body (4), cooling rack (21), cooling box (12), cooling box two (14) and cooling tube group, and reation kettle body (4) top is equipped with feed inlet (41), and reation kettle body (4) bottom is equipped with discharge gate (43), its characterized in that, cooling tube rack (3) have evenly been laid to reation kettle body (1) outer wall, and supporting leg (1) are installed to cooling tube rack (3) bottom end, and the cooling tube group comprises water cooling pipe (2) and oil cooling pipe (23), and water cooling pipe (2) is installed on cooling tube rack (3), cooling rack (21) are installed in reation kettle body (4) one side, cooling rack (21) divide into two-layerly, install cooling box one (12) and cooling box two (14) on upper cooling rack (21), a water inlet of the water cooling pipe (2) is connected with a first cooling box (12) through a water inlet pipe (8), a first valve (9) is installed on the water inlet pipe (8), and a water outlet of the water cooling pipe (2) is connected with the first cooling box (12) through a water outlet pipe (6);

install motor (5) on reation kettle body (4), install in reation kettle body (4) (mixing) shaft (24), (mixing) shaft (24) top and motor (5) bottom link to each other, be equipped with cooling chamber (42) in reation kettle body (4), evenly install many cooling rod (22) in cooling chamber (42), install on cooling rod (22) oil cooling pipe (23), oil cooling pipe (23) oil inlet links to each other with cooling box two (14) through advancing oil pipe (10), advance and install valve two (13) on oil pipe (10), oil cooling pipe (23) oil-out links to each other with cooling box two (14) through going out oil pipe (7).

2. The efficient cooling device for the reaction kettle according to claim 1, wherein the cooling liquid in the first cooling tank (12) is water, and the cooling liquid in the second cooling tank (14) is oil.

3. The efficient cooling device for the reaction kettle according to claim 1, wherein a circulating cooling groove (211) is arranged on the cooling rack (21), and the circulating cooling groove (211) is positioned below the first cooling box (12) and the second cooling box (14).

4. The cooling apparatus for reactor according to claim 3, wherein a cooling coil (15) is installed in the circulating cooling tank (211).

5. The efficient cooling device for the reaction kettle according to claim 1, wherein a water tank (20) is further installed on the lower cooling rack (21), the head end of the cooling coil (15) is connected with the water tank (20) through a first water pipe (17), and the tail end of the cooling coil (15) is connected with the water tank (20) through a second water pipe (16).

6. The efficient cooling device for the reaction kettle according to claim 1, wherein the first cooling tank (12) is connected with the water tank (20) through a third water pipe (19), and a third valve (18) is arranged on the third water pipe (19).

7. The efficient cooling device for the reaction kettle according to claim 1, wherein the sensor (11) is installed in each of the first cooling box (12) and the second cooling box (14), and the sensor (11) and the valve III (18) in the first cooling box (12) are electrically connected.

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