CN220724561U - Split type radiator of horizontal medium-temperature medium-pressure steam setting machine - Google Patents

Abstract

The utility model provides a split type radiator of horizontal medium temperature middling pressure steam forming machine, is arranged in first section oven and last section oven on horizontal medium temperature middling pressure steam forming machine, its characterized in that: the split type radiator comprises a radiator A and a radiator B, wherein the radiator A and the radiator B are identical in overall dimension, the width is identical to the height, the length is close to or identical to the width, the radiator A is a two-in two-out radiator, the radiator B is a three-in three-out radiator, the two radiators are arranged side by side in the long direction, the total length is equal to one piece of integral radiator, the arrangement mode is AB type in a first section of oven, and the arrangement mode is BA type in a last section of oven. According to the utility model, the first section of oven and the last section of oven of the horizontal medium-temperature medium-pressure steam setting machine are respectively divided into two sections of original integral radiators, and the normal process temperatures in the first section of oven and the second section of oven can be effectively ensured through different connected media.

Description

Split type radiator of horizontal medium-temperature medium-pressure steam setting machine

Technical Field

The application relates to the technical field of dyeing and finishing setting machine equipment, in particular to a split radiator of a horizontal medium-temperature medium-pressure steam setting machine.

Background

The medium-temperature medium-pressure steam setting machine is an important device in the textile printing and dyeing industry and is used for setting fabrics. The prior medium-temperature medium-pressure steam setting machine, such as the setting machine utilizing medium-temperature medium-pressure steam for heating is disclosed in 2015 in Chinese patent publication No. CN204825358U, and comprises a setting machine body composed of a plurality of sections of machine bodies sequentially arranged from a head to a tail, wherein each section of machine body is provided with a radiator, two sides of the setting machine body are respectively provided with a total air inlet pipe and a total air outlet pipe, an air inlet and an air outlet of each radiator on a second section of machine body to a last section of machine body are respectively connected with the total air inlet pipe and the total air outlet pipe, and the total air outlet pipe is connected with the air inlet of the radiator on a first section of machine body.

In the existing medium-temperature medium-pressure steam setting machine, each section of machine body is internally provided with an integral radiator, and the integral radiator is a three-in and three-out one-piece integral radiator. In the shaping process, the required heat is provided by virtue of a radiator (the machine body comprises an internal radiator also called an oven) to ensure the required process temperature, but in the normal use process, the temperature (generally 85-100 ℃) in a first machine body (also called a first oven) of the shaping machine is lower than the process temperature (160-180 ℃), so that the vaporized oil and steam mixture has the phenomena of dripping water and oil due to lower temperature, and the quality of cloth is seriously influenced; the temperature of the steam-water mixture discharged from the last section of the machine body of the setting machine is generally too high (100 ℃), so that the normal process temperature (180 ℃) is seriously influenced, and the discharge amount of the steam-water mixture is increased.

Therefore, how to raise the steam temperature in the first section of machine body (oven) of the medium-temperature medium-pressure steam shaping machine and ensure the process temperature in the last section of machine body (oven) becomes a problem to be solved urgently by those skilled in the art.

Disclosure of Invention

The application provides a split type radiator of a horizontal medium-temperature medium-pressure steam setting machine, the first section of oven and the last section of oven of the horizontal medium-temperature medium-pressure steam setting machine are respectively split into two, and the normal process temperature in the first section of oven and the second section of oven can be effectively ensured through different connected media.

The horizontal medium-temperature medium-pressure steam setting machine is formed by sequentially arranging a plurality of sections of ovens from a head to a tail, wherein the oven positioned at the head is a first section of oven, and the oven positioned at the tail is a last section of oven.

According to an aspect of the application, an embodiment provides a split type radiator of a horizontal medium temperature and medium pressure steam setting machine, which is used in a first section of oven and a last section of oven on the horizontal medium temperature and medium pressure steam setting machine, and is different from an integral one-piece radiator, and comprises two radiators, namely a radiator A and a radiator B, wherein the radiator A and the radiator B are identical in overall dimension, the width and the height are identical, the length are close to or identical, the radiator A is a two-in and two-out radiator, the radiator B is a three-in and three-out radiator, the two radiators are arranged side by side in the length direction, the total length is equal to the integral radiator of one piece, the arrangement mode is AB type in the first section of oven, and the arrangement mode is BA type in the last section of oven.

In some embodiments, the radiator a and the radiator B are fin type radiator, the fin type radiator comprises a radiator shell, fin tubes, elbows and water collecting tubes, the fin tubes are mutually parallel and are arranged in the radiator shell according to a certain rule, the coleoptera tubes are connected outside the radiator shell through the elbows, the water collecting tubes are connected with the sheath finned tubes, and the water collecting tubes are respectively arranged at the upper end and the lower end of the same side of the radiator frame.

In some embodiments, a flange is attached to the header.

In some embodiments, the finned tube comprises a base tube and fins, both made of a metal that conducts heat well.

In some embodiments, the fin tube specifications of radiator a and radiator B are different.

In some embodiments, the heat sink a and the heat sink B have different numbers of fin tube arrangements.

In some embodiments, after the heat radiator a and the heat radiator B are arranged side by side in the longitudinal direction, a sealing cover plate is arranged between the heat radiator frames of the heat radiator a and the heat radiator B, so that the heat radiator a and the heat radiator B form a whole after being side by side.

According to the split radiator of the horizontal medium-temperature medium-pressure steam setting machine, the steam temperature of the first section of oven is close to the process temperature by adjusting the steam temperatures of the two radiators in the first section of oven, so that the process requirement is met, the process temperature of the last section of oven is ensured, the steam-water mixture temperature is reduced, the steam-water mixture discharge amount is reduced, and the multiple benefits of stabilizing the quality of fabrics, stabilizing the production process, saving energy and reducing emission and saving cost are achieved.

Drawings

Fig. 1 is a side view of a heat sink a according to the present utility model.

Fig. 2 is a side view of a heat sink B according to the present utility model.

FIG. 3 is a schematic illustration of the present utility model in use in a first oven section.

Fig. 4 is a schematic representation of the present utility model in use in a final oven section.

Fig. 5 is a schematic view of the pipe connection in the setting machine according to the present utility model.

In the figure: 1. a heat sink; 1A, a radiator A;1B, a radiator B; 11. a radiator outer frame; 12. a fin tube; 13. an elbow; 14. a water collecting pipe; 15. a flange; 2. and sealing the cover plate.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings by way of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments, and the operational steps involved in the embodiments may be sequentially exchanged or adjusted in a manner apparent to those skilled in the art. Accordingly, the description and drawings are merely for clarity of describing certain embodiments and are not necessarily intended to imply a required composition and/or order.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated.

Single in and single out means that all the pipes on the radiator are connected in series, and only one inlet and one outlet are provided.

The two-in and two-out means that the pipelines on the radiator are divided into two groups, the pipelines in each group are connected in series, two ports are formed on the water collecting pipe, and the two groups of pipelines are connected in parallel.

The three-in and three-out means that the pipelines on the radiator are divided into three groups, the pipelines in each group are connected in series, and the three groups of pipelines are connected in parallel.

Typically, in two-out and three-in three-out radiators, the number of tubes between groups is equal.

In the radiator with steam introduced, the temperature difference between the inlet end and the outlet end is large due to overlong pipeline, and the temperature field of the whole radiator is uneven. The three-in and three-out pipelines are relatively short, the temperature difference between the inlet end and the outlet end is small, and the temperature of the radiator is uniform. The two-in and two-out lie between the two, and are relatively middle.

Examples:

the horizontal medium-temperature medium-pressure steam setting machine is formed by sequentially arranging a plurality of sections of ovens from a head to a tail, wherein the oven positioned at the head is a first section of oven, the oven positioned at the tail is a last section of oven, and the radiators in the rest ovens are three-in three-out one-piece integral radiators except the first section of oven and the last section of oven.

In this embodiment, referring to fig. 2, the difference between the three-in and three-out integral radiator and fig. 2 is that the length of the three-in and three-out integral radiator is longer, i.e. the length of the three-in and three-out integral radiator is almost equal to the length of the radiator a and the radiator B after being arranged side by side in the longitudinal direction. In practice, the three-in three-out one-piece integral radiator has the overall dimensions of 2630-2800mm long, 260mm wide and 1200mm high, the stainless steel base tube of the finned tube has the diameter of 26mm, and after the stainless steel fins are added, the diameter is 50mm, and 78 finned tubes are totally arranged on the three-in three-out one-piece integral radiator, namely, the arrangement mode is 13 multiplied by 6 rows.

Referring to fig. 1, in one embodiment, the split radiator of the horizontal medium-temperature and medium-pressure steam forming machine has an overall dimension of 1265-1350mm long, 260mm wide and 1200mm high, and is a two-in and two-out fin radiator, the stainless steel base tube of the fin tube 12 has a diameter of 25mm, and after adding stainless steel fins, the diameter is 48mm, and 76 fin tubes 12 are arranged on the two-in and two-out one-piece integral radiator, namely, the arrangement mode is 19×4 rows.

Referring to fig. 2, the overall dimensions of the radiator B1B are 1265-1350mm long, 260mm wide and 1200mm high, and are three-in three-out finned radiator, the stainless steel base tube of the finned tube 12 is 26mm in diameter, and after adding stainless steel fins, the diameter is 50mm, and 78 finned tubes 12 are totally arranged on the three-in three-out one-piece type integral radiator, namely, the arrangement mode is 13×6 rows.

Referring to fig. 3 and 4, the split radiator of the horizontal medium-temperature and medium-pressure steam forming machine of the present utility model is used in a first section of oven and a last section of oven on the horizontal medium-temperature and medium-pressure steam forming machine, and after the radiator A1A and the radiator B1B are arranged side by side in a long direction, a sealing cover plate 2 is arranged between the radiator A1A and the radiator B1B.

Referring to fig. 3 and 4 again, in the present embodiment, in the first oven section, two flanges on the radiator A1A are defined as A1 # water outlet and a 2# water inlet, and two flanges on the radiator B1B are defined as a 3# steam inlet and a 4# water outlet; in the last section of oven, two flanges on the radiator B1B are defined as a 6# steam inlet and a 7# water outlet respectively, and two flanges on the radiator A1A are defined as a 8# water outlet and a 9# water inlet.

In use, hot water is introduced into the radiator A1A in the first section of drying oven and the last section of drying oven of the setting machine, steam is introduced into the radiator B1B in the first section of drying oven and the last section of drying oven, and steam is also introduced into the three-in three-out one-piece integral radiator in the middle section of drying oven.

Referring to fig. 5, the radiator B1B with steam introduced and the three-in and three-out one-piece integral radiator are connected by a steam header, and the specific connection mode is that the steam inlet on the 3# steam inlet on the radiator B1B in the first section of oven and the steam inlet on the three-in and three-out one-piece integral radiator in the middle section of oven are connected with the steam header in parallel. The water outlet of the 4# water outlet on the radiator B1B in the first section of oven, the water outlet on the three-in three-out one-piece integral radiator in the middle section of oven and the water outlet of the 7# water outlet on the radiator B1B in the last section of oven are connected in parallel.

The hot water pipe is connected with the 9# water inlet of the radiator A1A in the last section of oven, the 8# water outlet is connected with the water return pipe, the water return pipe is directly connected with the 2# water inlet on the radiator A1A in the first section of oven, then the 1# water outlet is connected with the drain pipe, and the drain pipe is connected with the heating device to form steam again. This forms a reuse water circulation system. In actual use, the process temperature in the first section of oven and the process temperature in the last section of oven of the setting machine can be in the optimal state, so that the speed of the setting machine is ensured.

The foregoing description of the utility model has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the utility model pertains, based on the idea of the utility model.

Claims (7)

1. The utility model provides a split type radiator of horizontal medium temperature middling pressure steam forming machine, is used in first section oven and last section oven on the horizontal medium temperature middling pressure steam forming machine, split type radiator is different from whole one piece formula radiator, its characterized in that: the split type radiator comprises a radiator A and a radiator B, wherein the radiator A and the radiator B are identical in overall dimension, the width is identical to the height, the length is identical, the radiator A is a two-in two-out radiator, the radiator B is a three-in three-out radiator, the two radiators are arranged side by side in the long direction, the total length is equal to one integral radiator, the arrangement mode is AB type in a first section of oven, and the arrangement mode is BA type in a last section of oven.

2. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 1, wherein: the radiator A and the radiator B are fin type radiators, the fin type radiator comprises a radiator shell, fin pipes, elbows and water collecting pipes, the fin pipes are mutually parallel and are arranged in the radiator shell according to a certain rule, the fin pipes are connected outside the radiator shell through the elbows, the water collecting pipes are connected with sheath fin pipes, and the water collecting pipes are respectively arranged at the upper end and the lower end of the same side of the radiator frame.

3. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 2, wherein: and a flange is connected to the water collecting pipe.

4. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 2, wherein: the finned tube comprises a base tube and fins, wherein the base tube and the fins are made of metal with good heat conduction.

5. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 1, wherein: the fin tube specifications of the radiator A and the radiator B are different.

6. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 1, wherein: the fin tubes of the radiator A and the radiator B are arranged in different numbers.

7. The split radiator for the horizontal medium-temperature medium-pressure steam setting machine according to claim 1, wherein: after the radiator A and the radiator B are arranged side by side in the long direction, a sealing cover plate is arranged between radiator frames of the radiator A and the radiator B, so that the radiator A and the radiator B are arranged side by side to form a whole.