CN213804385U - Heat cycle supply system - Google Patents

Abstract

The utility model provides a thermal cycle supply system, include: the device comprises a thermal circulation ventilation pipeline arranged at the bottom of a steamer box body, wherein a plurality of groups of first circulating fans are arranged above the thermal circulation ventilation pipeline, and each group of first circulating fans is provided with a first air duct pipeline communicated with the thermal circulation ventilation pipeline; the second circulating fans are arranged on two sides of the steamer box body and form a second air duct pipeline communicated with the thermal circulation ventilation pipeline; and the combustion furnace is communicated with the steamer box body and is respectively communicated with the first air duct pipeline and the thermal circulation ventilation pipeline in the steamer box body. The utility model provides a to the ageing effect of fabric among the prior art than poor and the higher problem of electric energy consumption.

Description

Heat cycle supply system

Technical Field

The utility model relates to a rapid steamer technical field, more specifically relate to a thermal cycle supply system.

Background

The steamer is suitable for steaming, fixing and baking after printing of various natural fibers, synthetic fibers, chemical fibers and blended woven fabrics, knitted fabrics and non-woven fabrics, is suitable for various processes and dyes, and is suitable for the gram weight range of the fabrics of 50-800 g/m². During the steaming process, the fabric is subjected to saturated steamingAfter steam, the temperature is rapidly raised, at the moment, the condensed water can dissolve the dye and the chemical reagent in the color paste, sometimes, the chemical reaction can occur, the color paste penetrates into the fiber and diffuses into the fiber, and the purpose of color fixation is achieved.

Generally speaking, a plurality of groups of heat exchangers are arranged in a box body of the steamer, and heat of media in the heat exchangers is extracted through circulating fans below the heat exchangers so as to achieve the purpose of heating the inside of the box body of the steamer. However, the temperature in the box body of the steamer is raised through the heat exchanger, so that the steaming effect of the steamer on fabrics is not good enough, and the waste of electric energy is caused due to the extremely large power consumption of the heat exchanger.

In view of the above, it is desirable to provide a heat cycle supply device for a steamer to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to disclose a thermal cycle supply system to solve among the prior art to the evaporation effect of fabric than poor and the higher problem of electric energy consumption.

To achieve the above object, the present invention provides a thermal cycle supply system, including:

the device comprises a thermal circulation ventilation pipeline arranged at the bottom of a steamer box body, wherein a plurality of groups of first circulating fans are arranged above the thermal circulation ventilation pipeline, and each group of first circulating fans is provided with a first air duct pipeline communicated with the thermal circulation ventilation pipeline;

the second circulating fans are arranged on two sides of the steamer box body and form a second air duct pipeline communicated with the thermal circulation ventilation pipeline;

and the combustion furnace is communicated with the steamer box body and is respectively communicated with the first air duct pipeline and the thermal circulation ventilation pipeline in the steamer box body.

As a further improvement, first circulating fan forms from bottom to top and follows first wind channel pipeline flow direction the air current in the rapid steamer box, second circulating fan forms from bottom to top and follows the flow direction of second wind channel pipeline the air current in the rapid steamer box.

As a further improvement of the utility model, the air inlet end of the combustion furnace is communicated with the steamer box body, the air outlet end of the combustion furnace is communicated with the thermal cycle ventilation pipeline.

As a further improvement, the first air duct pipeline is hugged closely the front inner wall and the back inner wall of the rapid steamer box body are arranged, just the first air duct pipeline is formed with two branch pipelines that vertically extend to the rapid steamer box body top and have the preset distance with the rapid steamer box body top.

As a further improvement, the lateral inner wall of the steamer box is hugged closely to the second air channel pipeline and is arranged, just the second air channel pipeline is formed with two branch pipelines that vertically extend to the steamer box top and have the preset clearance with the steamer box top.

As a further improvement, the front outer wall and the back outer wall of the steamer box are uniformly provided with an oil exhaust fan for exhausting oil smoke in the steamer box.

As a further improvement of the present invention, the combustion furnace includes a combustion chamber housing, a combustion cylinder is disposed in the combustion chamber housing along a first direction, the combustion cylinder is attached to an inner side of the combustion chamber housing, a burner extends into the combustion cylinder along the first direction, and a free end of the combustion cylinder is opposite to a blade disposed with a third circulation fan;

and a blocking plate is arranged between the free end of the combustion cylinder and the third circulating fan and used for changing the flowing direction of hot gas scattered into the combustion chamber from the combustion cylinder.

As a further improvement, the inlet end of the combustion chamber housing is just right the side wall of the combustion cylinder, the outlet end of the combustion chamber housing is communicated with the air pipe of the third circulating fan.

As a further improvement of the utility model, the transverse section configuration of barrier plate is triangle-shaped, just the triangle top of barrier plate is just right the free end of a combustion section of thick bamboo is arranged.

As a further improvement, the blade is connected with and runs through along the first direction the connecting axle of combustion chamber casing, just the connecting axle is arranged on being located the bearing frame in the combustion chamber casing outside, the base has been arranged to the end of bearing frame, it is used for the drive to have arranged on the base blade pivoted driving motor.

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

the thermal cycle supply system that this application reveals provides circulation steam to the rapid steamer through the burning furnace that is linked together with first wind channel pipeline and thermal cycle ventilation pipeline in the rapid steamer box respectively to through arranging the hot circulation fan of multiunit above the thermal cycle ventilation pipeline with the steam that the burning furnace provided in the heat dissipation to the rapid steamer box via first wind channel pipeline, and through arranging the second circulation fan in the rapid steamer box both sides with steam in the rapid steamer box via second wind channel pipeline. So set up, can carry out heat treatment through the fabric of thermal cycle supply system in to the rapid steamer box effectively to not only improve the effect of carrying out the rapid steamer to fabric in the rapid steamer box and carry out the steaming process, need not to consume too much electric energy in order to reduce the consumption of electric energy source moreover.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a thermal cycle supply system according to the present invention;

fig. 2 is a schematic side view of a thermal cycle supply system according to the present invention;

FIG. 3 is a schematic view of a connection structure of an oil discharge fan and a box body of a steamer;

FIG. 4 is an enlarged view of the structure at Q of FIG. 2;

FIG. 5 is a schematic view of a combustion furnace of the steamer of the present invention;

fig. 6 is a top view of fig. 5.

Detailed Description

The present invention is described in detail with reference to the embodiments shown in the drawings, but it should be understood that these embodiments are not intended to limit the present invention, and those skilled in the art should understand that the functions, methods, or structural equivalents or substitutions made by these embodiments are within the scope of the present invention.

It will be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," "positive," "negative," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing and simplifying the description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be considered as limiting the present disclosure.

Please refer to fig. 1 to 6 for a specific embodiment of a thermal cycle supply system according to an embodiment of the present invention.

Referring to fig. 1 and 2, an embodiment of the present invention provides a thermal cycle supply system, including: a thermal circulation ventilation pipeline 301 arranged at the bottom of the steamer box body 10, a plurality of groups of first circulating fans 302 are arranged above the thermal circulation ventilation pipeline 301, and a first air duct pipeline 303 communicated with the thermal circulation ventilation pipeline 301 is formed on each group of first circulating fans 302; a second circulating fan 304 arranged at both sides of the steamer body 10, the second circulating fan 304 being formed with a second air duct line 305 communicating with the thermal circulation ventilation line 301; the combustion furnace 50 is communicated with the steamer box body 10, and the combustion furnace 50 is respectively communicated with a first air duct pipeline 303 and a thermal circulation ventilation pipeline 301 in the steamer box body 10. Wherein, the inlet end 501 of the combustion furnace 50 is communicated with the steamer box 10, and the outlet end 502 of the combustion furnace 50 is communicated with the thermal cycle ventilation pipeline 301. The target side of the steamer box 10 is provided with an air inlet 502 'communicated with the air outlet 502 of the combustion furnace 50 and an air outlet 501' communicated with the air inlet 501 of the combustion furnace 50. Wherein the inlet 502 'of the target side of the steamer body 10 is generally lower in vertical height than the outlet 501'. The target side of the digester enclosure 10 may be the front 10a or the back 10b of the digester enclosure 10.

Specifically, the first air duct 303 is closely attached to the inner walls of the front 10a and the back 10b of the steamer case 10, and the first air duct 303 is formed with two branch ducts 303' longitudinally extending to the top of the steamer case and having a predetermined distance d1 with the top of the steamer case. The first circulation fan 302 forms an air flow H flowing from bottom to top along the first air duct 303 into the steamer body 10. The air flow H forms a branch air flow H1 and a branch air flow H2 via two branch lines 303' to circulate into the steamer tank 10. The second air duct 305 is closely attached to the inner wall of the lateral side of the steamer body 10, and the second air duct 305 is formed with two branch pipes 305' which longitudinally extend to the top of the steamer body and have a predetermined gap 2031 with the top of the steamer body. The second circulation fan 304 forms an airflow M flowing from bottom to top along the second air duct 305 into the steamer body 10. The air flow M is sequentially formed into an air flow M1 and an air flow M2 via two branch lines 305' to be circulated into the steamer tank 10.

The first air duct pipe 303 is provided with a first opening 3031, and the thermal circulation ventilation pipe 301 is communicated with the first air duct pipe 303 through the first opening 3031. Second open 3051 is opened to second air duct 305, and thermal cycle ventilation pipeline 301 is communicated with second air duct 305 through second open 3051.

It should be noted that, the setting of the size of the preset gap 2031 formed between the air outlet ends of the two branch pipes 305 'of the second air duct pipe 305 and the top of the box body of the steamer can ensure that the air flowing out of the two branch pipes 305' can effectively flow into the box body 10 of the steamer, and the specific size can be set according to the actual working condition, which is not described in detail. The setting of the preset distance d1 formed between the air outlet ends of the two branch pipes 303 'of the first air duct pipe 303 and the top of the steamer can be set according to actual working conditions as long as it can ensure that the air flowing out of the two branch pipes 303' effectively flows into the steamer case 10, which will not be described in detail. Wherein the outlet ends of the two branch pipes 305 'are generally higher than the outlet ends of the two branch pipes 303'.

It can be understood that the hot gas N1 generated by the combustion furnace 50 flows into the air inlet 502 'of the steamer body 10 through the air outlet 502 thereof to circulate into the thermal circulation ventilation pipeline 301, the hot gas N1 circulating into the thermal circulation ventilation pipeline 301 circulates into the first air channel pipeline 303 through the first opening 3031, and the gas H circulating into the first air channel pipeline 303 forms the branch gas flow H1 and the branch gas flow H2 through the two branch pipelines 303' to circulate into the steamer body 10. Meanwhile, the hot air N1 in the thermal circulation ventilation pipeline 301 is communicated to the second air duct pipeline 305 through the second opening 3051, and the air M in the second air duct pipeline 305 is communicated to the steamer body 10 through two branch pipelines 305' to form a branch air flow M1 and a branch air flow M2. Thus, the gas N2 flowing through the first air duct 303 and the second air duct 305 into the steamer case 10 flows into the combustion furnace 50.

As can be seen, the thermal circulation supply system of the present embodiment provides circulating hot air to the steamer through the combustion furnace 50 respectively communicating with the first air duct 303 and the thermal circulation ventilation duct 301 in the steamer body 10, and dissipates the hot air provided by the combustion furnace into the steamer body 10 through the first air duct 303 by the first circulating fans 302 arranged above the thermal circulation ventilation duct 301, and dissipates the hot air into the steamer body 10 through the second air duct 305 by the second circulating fans 304 arranged at both sides of the steamer body 10. So set up, can carry out heat treatment through the fabric of thermal cycle supply system in to the rapid steamer box effectively to improve the effect of carrying out the rapid steamer to fabric in the rapid steamer box and carry out the steaming treatment effectively, need not to consume too much electric energy in order to reduce the consumption of electric energy source moreover.

In the present embodiment, as described with reference to fig. 1 and 3, the oil discharge fans 306 are disposed on the outer walls of the front 10a and the back 10b of the steamer case 10, and the oil discharge fans 306 draw the oil smoke in the steamer case 10 in the direction of R1 and discharge the oil smoke out of the steamer case 10 in the direction of R2. The oil drain fans 306 can be configured in two and are located near the inlet end 103 and the outlet end 103' of the digester tank, respectively. Wherein, the air entering the steamer body 10 from the feeding end 103 (the air is lower than the temperature of the air in the steamer body 10) can effectively reduce the temperature in the steamer body 10, so as to improve the steaming quality of the fabrics in the steamer body 10. The oil discharge fan 306 can be configured to be a plurality of, and a plurality of oil discharge fan steam ager boxes 10 are arranged uniformly in the length direction. Of course, the number of the oil exhaust fans 306 may be configured according to actual working condition requirements, and is not limited to the range defined in this embodiment.

In any of the above embodiments, as described with reference to fig. 4 to 6, the combustion furnace 50 includes a combustion chamber housing 500, and a combustion cylinder 503 attached to the inside of the combustion chamber housing 500 is disposed in the combustion chamber housing 500 along a first direction, specifically, the bottom of the combustion cylinder 503 is attached to the inside of the combustion chamber housing 500. The combustor casing 500 is penetrated with a burner 504 extending into the combustion can 503 in a first direction to generate a flame 5041 in the combustion can 503 by igniting the burner 504. The free end 5031 of the combustion canister 503 faces the blade on which the third circulator 505 is disposed. A blocking plate 506 is disposed between the free end 5031 of the combustion cylinder 503 and the third circulation fan 505 for changing the flowing direction of the hot gas dissipated from the combustion cylinder 503 into the combustion chamber 500'.

It is to be understood that the combustion furnace 50 emits hot gas of the flame generated in the combustion cylinder 503 into the combustion chamber 500' by igniting the burner 504. Since the blocking plate 506 is disposed between the free end 5031 of the combustion canister 503 and the third circulation fan 505, the hot gas emitted from the combustion canister 503 is blocked by the blocking plate 506 and flows into the duct 5051 of the third circulation fan 505 along the peripheral direction of the blocking plate 506, so as to prevent the hot gas emitted from the combustion canister 503 from flowing directly to the blades of the third circulation fan 505 to damage the blades. So, the problem that circulating fan blade was burnt to the steam that the combustion chamber gived off among the prior art can be solved to this embodiment.

Further, the first-direction cross section of the blocking plate 506 is configured to be triangular, and the triangular tip of the blocking plate 506 is disposed facing the free end 5031 of the combustion canister 503. In this way, the hot gas emitted from the combustion cylinder 503 can flow along the triangular oblique surface of the blocking plate 506 toward the air duct 5051 of the third circulation fan 505, so as to prevent the hot gas from directly flowing to the blades of the third circulation fan 505 and causing damage to the blades.

Specifically, a connecting shaft 507 penetrating through the combustion chamber housing 500 in the first direction is connected to the blade of the third circulation fan 505, the connecting shaft 507 is disposed on a bearing housing 508 located outside the combustion chamber housing 500, a base 509 is disposed at a distal end of the bearing housing 508, and a driving motor 510 for driving the blade to rotate is disposed on the base 509. Accordingly, the driving motor 510 drives the third circulation fan 505 to operate, so that the hot air N1 in the combustion chamber 500 ' is blown into the hot circulation ventilation pipeline 301 at the bottom of the steamer body 10, and is emitted into the steamer body 10 through the two branch pipelines 303 ' and 305 ', and the gas N2 in the steamer body 10 flows into the combustion furnace 50, so that the hot circulation gas is supplied to the steamer body in the next step.

A plurality of gas outlet holes 5032 for circulating the heating gas into the combustion chamber 500' are uniformly arranged on the side wall of the combustion cylinder 503. The air inlet end 501 of the combustion chamber shell 500 faces the side wall of the combustion cylinder 503, and the air outlet end 502 of the combustion chamber shell 500 is communicated with the air pipe 5051 of the third circulating fan 505. With such an arrangement, after the hot air in the combustion cylinder 503 flows out through the plurality of air outlet holes 5032, the hot air can be mixed with the gas N2 entering the combustion chamber 500' from the air inlet end 501, so as to cool the hot air flowing out through the plurality of air outlet holes 5032 by the gas N2, and thus, when the cooled hot air flows to the third circulating fan 505, the blades of the third circulating fan 505 are not burned, and the purpose of further protecting the blades of the third circulating fan 505 is achieved.

In addition, the combustion chamber housing 500 is provided with a service hole 511, so that a maintenance person can perform maintenance on various components (such as the combustion cylinder 503, the third circulating fan 505, the blocking plate 506, etc.) in the combustion chamber 500' through the service hole 511, thereby improving the service life of the combustion furnace 50.

The first direction in the present embodiment is a direction perpendicular to the paper surface in fig. 1, and the vertical direction is a direction perpendicular to the steamer case in fig. 1.

The embodiment of the utility model provides a still provide a rapid steamer, include: a steamer box body; and a thermal cycle supply system as in any one of the embodiments above. The specific scheme of the heat cycle supply system according to this embodiment refers to the content of the heat cycle supply system according to any one of the above embodiments, and details thereof are not repeated.

The steamer of the present embodiment supplies circulating hot air to the steamer through the combustion furnace 50 in the thermal circulation supply system, which is respectively communicated with the first air duct 303 and the thermal circulation ventilation pipeline 301 in the steamer body 10, and dissipates the hot air supplied from the combustion furnace into the steamer body 10 through the first air duct 303 by a plurality of sets of first circulation fans 302 arranged above the thermal circulation ventilation pipeline 301, and dissipates the hot air into the steamer body 10 through the second air duct 305 by the second circulation fans 304 arranged at both sides of the steamer body 10. With the arrangement, the fabric in the box body of the rapid steamer can be effectively heated through the heat circulation supply system, so that the effect of steaming the fabric in the box body of the rapid steamer is effectively improved, and the consumption of electric energy sources is reduced without consuming excessive electric energy.

The above list of details is only for the practical implementation of the present invention, and they are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the technical spirit of the present invention should be included in the scope of the present invention.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. A thermal cycler supply system, comprising:

the device comprises a thermal circulation ventilation pipeline arranged at the bottom of a steamer box body, wherein a plurality of groups of first circulating fans are arranged above the thermal circulation ventilation pipeline, and each group of first circulating fans is provided with a first air duct pipeline communicated with the thermal circulation ventilation pipeline;

the second circulating fans are arranged on two sides of the steamer box body and form a second air duct pipeline communicated with the thermal circulation ventilation pipeline;

and the combustion furnace is communicated with the steamer box body and is respectively communicated with the first air duct pipeline and the thermal circulation ventilation pipeline in the steamer box body.

2. The thermal cycle supply system of claim 1,

the first circulating fan forms airflow from bottom to top and flows to the inside of the steamer body along the first air duct pipeline, and the second circulating fan forms airflow from bottom to top and flows to the inside of the steamer body along the second air duct pipeline.

3. The thermal cycle supply system of claim 2,

the gas inlet end of the combustion furnace is communicated with the steamer box body, and the gas outlet end of the combustion furnace is communicated with the thermal cycle ventilation pipeline.

4. The thermal cycle supply system of claim 1,

the first air channel pipeline is tightly attached to the front inner wall and the back inner wall of the steamer box body and is provided with two branch pipelines which longitudinally extend to the top of the steamer box body and have a preset distance with the top of the steamer box body.

5. The thermal cycle supply system of claim 1,

the second air duct pipeline is arranged close to the inner wall of the side face of the steamer box body, and two branch pipelines which longitudinally extend to the top of the steamer box body and have a preset gap with the top of the steamer box body are formed on the second air duct pipeline.

6. The thermal cycle supply system according to any one of claims 1 to 5,

and oil exhaust fans for exhausting oil smoke in the steamer box body are uniformly arranged on the outer wall of the front side and the outer wall of the back side of the steamer box body.

7. The thermal cycle supply system according to any one of claims 1 to 5,

the combustion furnace comprises a combustion chamber shell, a combustion cylinder which is attached to the inner side of the combustion chamber shell is arranged in the combustion chamber shell along a first direction, a combustor which extends into the combustion cylinder penetrates through the combustion chamber shell along the first direction, and the free end of the combustion cylinder is opposite to a blade of a third circulating fan;

and a blocking plate is arranged between the free end of the combustion cylinder and the third circulating fan and used for changing the flowing direction of hot gas scattered into the combustion chamber from the combustion cylinder.

8. The thermal cycle supply system of claim 7,

the air inlet end of the combustion chamber shell is over against the side wall of the combustion cylinder, and the air outlet end of the combustion chamber shell is communicated with an air pipe of the third circulating fan.

9. The thermal cycle supply system of claim 7,

the transverse section of the blocking plate is configured to be triangular, and the triangular top of the blocking plate is arranged right opposite to the free end of the combustion cylinder.

10. The thermal cycle supply system of claim 7,

the blade is connected with and runs through along the first direction the connecting axle of combustion chamber casing, just the connecting axle is arranged on being located the bearing frame in the combustion chamber casing outside, the base has been arranged to the end of bearing frame, it is used for the drive to arrange on the base blade pivoted driving motor.

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