CN219347457U - Gypsum powder calcines heat transfer device - Google Patents

Abstract

The utility model provides a gypsum powder calcining heat exchange device which comprises a support frame, a shell arranged on the upper end face of the support frame, a heat exchange structure arranged in the shell and used for exchanging heat, and a heat exchange port arranged on one side of the shell, wherein the heat exchange port is connected with a fan, and the heat exchange structure comprises a heat exchange plate, a first inlet end and a second inlet end which are arranged on the upper end face of the shell and connected with the heat exchange plate, and a first outlet end and a second outlet end which are arranged on the lower end face of the shell and connected with the heat exchange plate. The gypsum powder calcining heat exchange device provided by the utility model avoids the problem of large occupied area of the heat exchanger, and finally ensures that the heat exchanger is small in size, reduces the occupied area of the field and maintains the original performance.

Description

Gypsum powder calcines heat transfer device

Technical Field

The utility model belongs to the technical field of gypsum powder calcination, and particularly relates to a gypsum powder calcination heat exchange device.

Background

The steam heat exchanger is a device for heating water or air by taking steam as a heat source, can fully replace a large amount of heat value in the steam for heating water or air, and can intensively convey the heated water or air into various drying and drying devices, and the steam is an ideal heat carrier with wider application in modern industry.

At present, the gas steam boiler needs high-temperature air to exchange with water, and the power of a general gypsum calcining device is larger, so that the heat exchange power of the heat exchanger is also larger, the size of the heat exchanger is overlarge, however, the heat exchanger is influenced by a field, and the size of the heat exchanger needs to be reduced as much as possible.

Therefore, the technical problems that the floor space is limited but the occupied area of the heat exchanger is large are solved.

Disclosure of Invention

The utility model aims to provide a gypsum powder calcination heat exchange device, which solves the problem of large occupied area of a heat exchanger, finally reduces the volume of the heat exchanger, reduces the occupied area of a field and maintains the original heat exchange performance.

The utility model provides a gesso calcines heat transfer device, includes the support frame, sets up the casing of support frame up end still including setting up the inside heat transfer structure that is used for the heat transfer of casing, setting are in the heat exchange port of casing one side, the fan is connected to the heat exchange port.

The heat exchange structure comprises a heat exchange plate arranged in the shell, a first inlet end and a second outlet end which are arranged on the upper end face of the shell and connected with the heat exchange plate, and a first outlet end and a second inlet end which are arranged on the lower end face of the shell and connected with the heat exchange plate.

The adjacent heat exchange plates are connected through pipelines, and the heat exchange plates are provided with a plurality of plates.

The inlet end I is connected with the valve I through the ripple compensator I, and the inlet end II is connected with the water drain valve I through the steam trap I.

The first outlet end is connected with the second valve through the second ripple compensator, and the second outlet end is connected with the second water drain valve through the second steam trap.

The utility model achieves the following remarkable effects:

(1) Through increasing the support frame, support the casing to certain height, make the area of casing significantly reduce.

(2) Through inside setting up the heat exchanger fin, exchange heat with steam through the heat exchanger fin, make steam heat transfer effect better.

(3) Through increasing the fan, steam can cool down the processing when carrying out the heat transfer, makes can cool down fast in the heat transfer process, carries out quick heat transfer.

Drawings

Fig. 1 is an overall construction diagram of the present utility model.

Fig. 2 is a front view of the present utility model.

Fig. 3 is a bottom view of the present utility model.

Wherein, the reference numerals are as follows: 1. a housing; 2. a heat exchange structure; 3. a heat exchange structure; 4. a heat exchange port; 5. a heating sheet; 6. an outlet end II; 7. an inlet end I; 8, 8; a ripple compensator I; 9. a valve I; 10. a second steam trap; 11. a water drain valve II; 12. an inlet end II; 13. a first steam trap; 14. a water drain valve I; 15. a ripple compensator II; 16. a second valve; 17. and an outlet end I.

Detailed Description

In order to more clearly describe the technical characteristics of the present solution, the present solution is described below by means of specific embodiments.

Referring to fig. 1-3, the gypsum powder calcining heat exchange device comprises a support frame 3 and a shell 1 arranged on the upper end face of the support frame 3, and is characterized by further comprising a heat exchange structure 2 arranged in the shell 1 and used for exchanging heat, and a heat exchange port 4 arranged on one side of the shell 1, wherein the heat exchange port 4 is connected with a fan.

The heat exchange structure 2 comprises a heat exchange plate 5 arranged in the shell 1, a first inlet end 7 and a second outlet end 6 which are arranged on the upper end face of the shell 1 and connected with the heat exchange plate 5, and a first outlet end 17 and a second inlet end 12 which are arranged on the lower end face of the shell 1 and connected with the heat exchange plate 5.

The adjacent heat exchange plates 5 are connected through pipelines, and the heat exchange plates 5 are provided with a plurality of plates.

The inlet end 7 is connected with the valve 9 through the ripple compensator 8, and the inlet end 12 is connected with the water drain valve 14 through the steam trap 13.

The first outlet end 17 is connected with the second valve 16 through the second ripple compensator 15, and the second outlet end 6 is connected with the second water drain valve 11 through the second steam trap 10.

The specific working process of the utility model patent comprises the following steps:

the first corrugated compensator 8 and the first valve 9 of the first inlet end 7 are opened, hot gas of the calcining equipment enters the heat exchange plate 5 through the first corrugated compensator 8 and the first valve 9, the first steam trap 13 and the first water drain valve 14 of the second inlet end 12 are opened, cold water enters the heat exchange plate 5, the hot gas is cooled in the heat exchange plate 5, the second corrugated compensator 15 and the second valve 16 of the first outlet end 17 are opened, the hot gas cooled by the cold water exits through the second corrugated compensator 15 and the second valve 16 of the first outlet end 17, the second steam trap 10 and the second water drain valve 11 of the second outlet end 6 are opened, and water generated during the cooling of the cold water is discharged through the second steam trap 10 and the second water drain valve 11 of the second outlet end 6;

hot gas enters the heat exchange plate from the first inlet end 7 and flows out from the first outlet end 17, cold water enters the heat exchange plate from the second inlet end 12 and flows out from the second outlet end 6, and the cold water continuously circulates to cool the hot gas;

when the heat exchange plate 5 is used for exchanging temperature, the fan is turned on, and the fan blows air into the shell through the heat exchange port 4, so that the temperature is reduced more quickly during heat exchange, and the effect is better.

The technical features of the present utility model that are not described in the present utility model may be implemented by or using the prior art, and are not described in detail herein, but the above description is not intended to limit the present utility model, and the present utility model is not limited to the above examples, but is also intended to be within the scope of the present utility model by those skilled in the art.

Claims (5)

1. The utility model provides a gypsum powder calcines heat transfer device, includes support frame (3), sets up casing (1) of support frame (3) up end, its characterized in that is in including setting up inside heat transfer structure (2) that are used for the heat transfer of casing (1), setting are in heat exchange port (4) of casing (1) one side, fan is connected to heat exchange port (4).

2. A gypsum powder calcining heat exchange device according to claim 1, wherein the heat exchange structure (2) comprises a heat exchange plate (5) arranged in the shell (1), a first inlet end (7) and a second outlet end (6) which are arranged on the upper end face of the shell (1) and connected with the heat exchange plate (5), and a first outlet end (17) and a second inlet end (12) which are arranged on the lower end face of the shell (1) and connected with the heat exchange plate (5).

3. A gypsum powder calcination heat exchange apparatus according to claim 2, wherein adjacent heat exchange plates (5) are connected by a pipeline, and the heat exchange plates (5) have a plurality of plates.

4. A gypsum powder calcination heat exchange apparatus according to claim 2, wherein the inlet end 7 is connected to the valve 9 through the bellows compensator 8, and the inlet end 12 is connected to the drain valve 14 through the steam trap 13.

5. A gypsum powder calcination heat exchange apparatus according to claim 2, wherein the first outlet port (17) is connected to the second valve (16) through the second bellows compensator (15), and the second outlet port (6) is connected to the second drain valve (11) through the second steam trap (10).

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