KR101348683B1 - The fresh air-circulation device for textile drying machine - Google Patents

Abstract

The present invention relates to an apparatus for circulating air into and out of the fiber dryer 1, and is characterized in that it is mounted in communication with the upper part of the dryer 1, and to suck the cold air to the outside. An intake portion 10 having an intake duct 11; An exhaust unit 20 mounted in communication with an upper portion of the dryer 1 and having an exhaust duct 21 to discharge hot air to the outside; An adjustment unit 30 mounted to the intake unit 10 and the exhaust unit 20 and having a control plate 31 and a humidity sensor 35 to adjust the amounts of intake air and exhaust air, respectively; And a blower mounted on the intake duct 11 and the exhaust duct 21 and having blowers 45 and 46 so as to suck / outtake air into and out of the dryer 1 by the motor 41. Apparatus 40; wherein the intake portion 10 and the exhaust portion 20 is mounted to the intake duct 11 and the exhaust duct 21 to cross the heat exchange to prevent condensation in the dryer (1) With the feature of saving energy.
Accordingly, the present invention, the operation of the blower using a motor, as well as the simplification of the device to minimize noise and failure, while adjusting the amount of intake air and exhaust air in a precise balance using the throttle and humidity sensor in the exhaust duct and intake By installing the ducts in the cross section, the suction air can be sucked in a state where the temperature of the suction air is raised to prevent condensation in the dryer, and in particular, the waste heat discharged to the outside due to heat exchange can be recovered, thereby reducing the overall energy. have.

Description

Fresh air-circulation device for textile drying machine

The present invention relates to a device for circulating air into and out of a fiber dryer, and more particularly, by operating a blower using a motor, as well as simplifying the device, minimizing noise and failure, and controlling a throttle and a humidity sensor. By precisely adjusting the amount of intake air and exhaust air, the exhaust duct and the intake duct can be installed in the cross section to prevent the dew condensation in the dryer. It relates to a fresh air circulator of the fiber dryer that can recover the waste heat discharged to the energy saving overall.

In general, in the various processes performed during the production of the fibers, the fibers that are dyed and printed are wetted by the dyeing solution, so that the fibers are quickly dried using a hot air drying apparatus and then transferred to the next process. As a dryer for performing such a processing and drying process, a tenter machine, a coating machine, a shrinkage, and the like are typically used, but a tenter machine is mainly used.

The tenter is a heat setting process, which is a pretreatment process before dyeing the fabric. It is one of the textile processing machines used for the purpose of maintaining the fabric in the best state by performing the drying process, which is a post-treatment process after dyeing treatment, and for heat-heating and smoothing or drying the fabric. In other words, the tenter applies hot air to the fiber fabric and evaporates and removes the moisture contained in the fiber fabric to perform the drying process, smoothes the fiber fabric by hot air drying, and imparts proper stiffness (feel, curvature, etc.). It is a very important textile processing machine to prevent the deformation after the fabric is processed into the product by heat shrink action (heat fixation).

As is well known, a dryer applies hot air generated at a high temperature of 150 ° C. to 230 ° C. to a fabric fabric to be processed, and smoothes or heat shrinks and fixes the wrinkled fabric to dry at an appropriate humidity. Drying time is of great importance as it affects the overall manufacturing process as the performance of the device depends on the drying time. That is, the factors that govern the drying time are largely classified into five factors such as temperature, humidity, air volume, wind speed, and the distance between the nozzle and the treated material.

Here, by controlling the humidity (Humidity) to control the optimum operating humidity in the chamber, the drying time is shortened by keeping the humidity in the drying chamber low. However, in order to minimize the humidity in the continuous dryer, it is necessary to catch a large amount of discharged air and discharge it together with the moisture in the dryer. However, since the heat energy of the dryer is also increased, it is an unsuitable method in terms of energy efficiency. That is, the appropriate humidity needs to be examined from both sides in consideration of the heat amount along with the drying time. Therefore, in recent years, the humidity control device may be installed for the purpose of maintaining the humidity in the dryer. The humidity control device is provided with a control plate for making an inlet passage through which air can be introduced from the outside to one end of the dryer, and controlling (opening / closing) the inflow of air on the passage.

However, there is a problem that the suction air is not introduced from the outside as much as the amount of discharged air in the dryer, and the suction air is concentrated only in one place. In other words, when the cold suction air from the outside is concentrated in one place, condensation occurs because it directly meets the hot air in the dryer. In particular, in winter, condensation is intensified, which leads to defects caused by staining of the processing fabric as well as humidity control in the dryer, and causes serious failures inside.

Moreover, the exhaust air is warmed to a predetermined temperature by the heating system, but the exhaust air is discharged to the outside for humidity control, which causes a serious waste of energy. In addition, since the cold suction air flows into the outside as it is, the heating system needs to be warmed again to a predetermined temperature, which causes enormous losses. Therefore, there is an urgent need for a device capable of efficiently saving energy while preventing dew condensation while precisely adjusting the amount of exhaust air and intake air for precise humidity control.

Accordingly, the present invention is to fundamentally solve the conventional problems as described above, by minimizing the noise and failure as well as the simplification of the device by operating the blower using the motor, using the throttle and the humidity sensor intake air and exhaust Exhaust duct and intake duct are installed crosswise while adjusting the amount of air in a precise balance to prevent condensation inside the dryer by being sucked while the temperature of the intake air is raised. It is an object of the present invention to provide a fresh air circulation device for a fiber dryer that can recover the overall energy.

In order to achieve the above object, the present invention provides a device for circulating air into and out of a fiber dryer: an intake air mounted in communication with an upper part of the dryer and having an intake duct to suck cold air to the outside. part; An exhaust unit mounted in communication with an upper portion of the dryer and having an exhaust duct to exhaust hot air to the outside; A control unit mounted to the intake unit and the exhaust unit, the control unit including a control plate and a humidity sensor to adjust the amounts of the suction air and the discharge air, respectively; And a blower mounted on the intake duct and the exhaust duct, the blower including a blower so as to suck / exhale air into and out of the dryer by a motor. By mounting the ducts cross-exchanged with each other, it is characterized by saving energy with condensation prevention in the dryer.

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It should be understood, however, that the terminology or words of the present specification and claims should not be construed in an ordinary sense or in a dictionary, and that the inventors shall not be limited to the concept of a term It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

As described in the above configuration and operation, the fresh air circulating device of the fiber dryer according to the present invention minimizes the noise and failure as well as the simplification of the device by operating the blower using a motor, and suction using the throttle and humidity sensor Exhaust duct and intake duct are installed alternately while controlling the amount of air and exhaust air in a precise balance to prevent condensation inside the dryer by being sucked while the temperature of the intake air is raised. It is possible to recover the waste heat, which provides the effect of saving the overall energy.

1 and 2 is a block diagram showing a dryer to which the fresh air circulation apparatus according to the present invention is applied.
3 is a block diagram showing an intake portion and an exhaust portion according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing a process of circulating the air in the dryer by a fresh air circulation apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to an apparatus for circulating air into and out of the dryer 1 for fibers, and has an intake unit 10, an exhaust unit 20, an adjusting unit 30, and a blower 40 as main components. To the fresh air circulator of textile dryers. Here, the fiber dryer 1 of the present invention is shown in the drawings limited to 'TENTER MACHINE' as shown in FIG. 1, but can be applied to all other devices for processing fibers with hot air. In addition, the dryer (1) is divided into a gas burner type and a fruit oil type according to the heat source, but only the kind of a simple heat source is distinguished. Not all of them are applicable.

The intake portion 10 according to the present invention is mounted in communication with the upper portion of the dryer 1, and has an intake duct 11 to suck the cold air into the outside. The intake unit 10 supplies fresh (cold) -air to the inside of the dryer 1 as shown in FIG. 1, and the intake duct 11 communicates inside and outside the upper part of the dryer 1. It is provided.

The intake duct 11 is a passage for sucking external cold air to be supplied to the inside of the dryer 1, and is formed to extend to have at least one section from the top of the dryer 1 to the inside. That is, as shown in FIGS. 1 and 2, the intake duct 11 is branched from the blower 40 to be described later on the outside of the dryer 1 so that air is supplied to the inside of the dryer 1 over two sections. To be. Here, the intake duct 11 is formed so as to branch only to both branches, so that the air is supplied to only two sections inside the dryer 1, but if necessary, the number of branches of the intake duct 11 is increased by two or more sections. Air can also be supplied. On the other hand, the reason for supplying air in multiple sections inside the dryer 1 while branching the intake duct 11 will be described in detail with the exhaust unit 20 to be described later.

In addition, the exhaust unit 20 according to the present invention is mounted in communication with the upper portion of the dryer 1, and has an exhaust duct 21 to discharge the hot air to the outside. The exhaust unit 20 discharges a hot air to the outside of the dryer 1 as shown in FIG. 1, and exhausts the exhaust duct 21 that communicates internally and externally to the upper part of the dryer 1. Equipped.

Exhaust duct 21 is a passage for discharging hot air for drying the fibers to the outside of the dryer 1 to the outside, it is formed to extend to have at least one section from the top of the dryer (1). That is, as illustrated in FIGS. 1 and 2, the exhaust duct 21 is branched from the blower 40 to be described later on the outside of the dryer 1 so that air is discharged over two sections inside the dryer 1. To be. Of course, the exhaust duct 21 may also be formed in the same section as the branch water of the intake duct 11 as needed, such as the intake duct 11 to discharge air.

At this time, the intake unit 10 and the exhaust unit 20 according to the present invention is mounted to the intake duct 11 and the exhaust duct 21 to cross the heat exchange to prevent condensation in the dryer (1) and save energy do. The intake duct 11 of the intake unit 10 allows cool air to be supplied to the interior of the dryer 1, and the exhaust duct 21 of the exhaust unit 20 supplies hot air to the inside of the dryer 1 to the outside. Let it drain. That is, since the dryer 1 processes the fiber by drying the fiber with hot air (about 150 ° C. to 230 ° C.) by a heat source, the humidity increases while the moisture contained in the fiber evaporates. Here, if the humidity of the hot air increases in the dryer 1, it is important to lower the humidity of the hot air because the performance of drying the fibers is significantly reduced.

Thus, in order to lower the humidity of the hot air, hot air containing moisture of the dryer 1 should be discharged to the outside, and fresh air must be sucked / supplied from the outside by the amount of the discharged air. Here, the suction air has a room temperature (about 0 ℃ ~ 35 ℃), so that the condensation (water droplets) is generated when the hot discharge air (hot air) and the device meets the interior of the dryer (1). In addition, since the suction air must be heated to be hot air (about 150 ° C. to 230 ° C.) through a heat source, a drying time is increased and energy consumption is increased.

That is, as shown in FIGS. 2 and 3, the intake duct 11 and the exhaust duct 21 are mounted in close contact with each other to cause mutual heat exchange. When the exhaust duct 21 is mounted in close contact with one end of the intake duct 11 as shown in FIG. 2, the heat of the waste hot air air discharged to the exhaust duct 21 is transferred to the air sucked into the intake duct 11 to intake air. Increase the temperature of the air. In this case, as shown in FIG. 3, the intake ducts 11 may be alternately mounted between the plurality of exhaust ducts 21 to increase the heat exchange efficiency. Further, an exchange membrane excellent in heat transfer may be further provided between the intake duct 11 and the exhaust duct 21.

In this way, when the temperature of the intake air is supplied to the inside of the dryer 1, condensation can be prevented, thereby preventing damage to the device, and above all, the heating time of the supplied air is shortened, thereby greatly reducing energy as well as drying time. Can be saved.

In addition, the control unit 30 according to the present invention is mounted to the intake unit 10 and the exhaust unit 20, the control plate 31 and the humidity sensor 35 to adjust the amount of intake air and exhaust air, respectively Equipped. The adjusting unit 30 is electrically connected to the controller as shown in FIG. 1, and includes an adjusting plate 31 and a humidity sensor 35 to precisely adjust the amounts of suction air and discharge air.

The adjusting plate 31 is mounted on the intake duct 11 or the blower 45 to be described later to open and close the valve to adjust the amount of suction air. That is, although the control plate 31 is not shown through a separate drawing, it is connected to the actuator consisting of a cylinder or a motor to adjust the amount of suction air by the electrical signal of the controller. Of course, if necessary, by adjusting the knob 31 or the handle plate 31 may be manually adjusted the amount of suction air.

One or more humidity sensors 35 are mounted in the dryer 1 to generate a signal by measuring the humidity of the hot air, that is, the discharged air. That is, the humidity sensor 35 measures the humidity of the discharged air in real time to generate an electrical signal to the controller to adjust the amount of discharged air by adjusting the rotational speed of the motor 41 to be described later in accordance with the set sequence.

On the other hand, the reason for precisely balancing the amount of intake air and exhaust air is to control the humidity in the dryer 1 as described above. That is, in order to control the humidity of the dryer 1, it can be adjusted through the amount of the discharge air and the suction air. Thus, through the control panel 31 and the humidity sensor 35, it is possible to control the humidity more precisely by the feedback control by the controller, so that not only the performance of the dryer 1 can be responded more comprehensively depending on the material and processing type depending on the fiber. have.

Moreover, the blower 40 which concerns on this invention is mounted on the said intake duct 11 and the exhaust duct 21, and is made to suck | intake / exhale air in and out of the dryer 1 by the motor 41. Moreover, in FIG. Blowers 45 and 46 are provided. The blower 40 is mounted on one end of the intake duct 11 and the exhaust duct 21 as shown in FIGS. 1 and 2 to receive the power from the motor 41 and rotate the blower 45 to intake and discharge air. 46), respectively.

The blowers 45 and 46 are provided with inlets and outlets at one end and the other end of the housing, and have a blade at the center thereof. The inlets of the blower 45 are exposed to the outside and the outlets are the suction ducts 11. It is mounted in communication with one end of the. And the suction port of the blower 46 is mounted in communication with one end of the exhaust duct 21 and the discharge port is mounted to be exposed to the outside. Here, the blades of the blowers 45 and 46 are connected integrally with the rotating shaft connected to the motor 41 to rotate the same. That is, when the motor 41 is operated, the air is sucked in and discharged into and out of the dryer 1 by the blowers 45 and 46.

At this time, the blowers 45 and 46 according to the present invention may be any one of the centrifugal type, the axial flow type, and the quadrilateral type, or may be applied in combination of one or more. The blowers 45 and 46 allow air to be sucked / exhausted into and out of the dryer 1, and are divided into centrifugal type, axial flow type and quadrilateral type according to the blade shape.

Centrifugal type is divided into multi blade type, limit rod type, curved type, blade type, radial type, and perfusion type, and axial type includes propeller type, tube type and vane type. In addition to the cross-flow type and cross-flow type, but the efficiency is low, it is preferable to use the most efficient Sirocco, Airfoil (Arifoil) and Thurbo (Turbo) as widely used for air conditioning. That is, according to the blade shape, the blowers 45 and 46 having various efficiencies are selectively identically provided or differently provided. For example, the blower 45 which sucks air into the dryer 1 from the outside may be mounted in a multi-blade type, and the blower 46 which discharges air in the dryer 1 to the outside may be mounted in a post-curve shape. In any case, a person skilled in the art can install in various types in consideration of the efficiency of inhaling / exhausting air into and out of the dryer 1.

Figure 4 is a cross-sectional view showing a process of circulation of air in the dryer by the air circulation apparatus according to the present invention.

First, when a high humidity (60%) above the humidity (30%) set by the humidity sensor 35 is sensed while drying the fiber fabric with hot air heated by a heat source, the controller interrupts power to the motor 41 to blow the blower. Activate (45) (46). When the blowers 45 and 46 are operated, suction air (about 0 ° C. to 35 ° C.) is sucked into the intake duct 11 as shown in FIG. 4A, and exhaust air (about 150 ° C. heated by the exhaust duct 21 as shown in FIG. 4B). ˜230 ° C.) is exhausted. At this time, the exhaust duct 21 is heated by the exhaust air while the heat is transferred to the intake duct 11 is preheated to a predetermined temperature. That is, while the suction air passes through the intake duct 11, it is supplied into the dryer 1 while being heated to about 50 ° C. to 100 ° C.

In this process, if the humidity is detected by the humidity sensor 35 to 20 to 25%, the controller operates the control panel 31 to adjust (low) only the amount of intake air, and when the humidity reaches 28 to 29%, the motor By reducing the number of revolutions of (41), only the amount of discharged air is adjusted (lower). Here, when the humidity reaches 31 to 32%, the control panel 31 is operated again to adjust (high) only the amount of intake air, thereby performing continuous feedback control to achieve the set humidity (30%). On the other hand, the humidity of 60% higher than the humidity set in the above will be rather exaggerated to explain a series of processes according to the heat exchange with the operation of the motor 41 and the blowers 45, 46, the throttle plate (31) And the feedback control to the humidity sensor 35, it is possible to precisely adjust within the substantially set humidity range (± 5%).

As described above, the present invention minimizes the noise and failure as well as the simplification of the device as the blower is operated using the motor, and the exhaust duct and the intake air while adjusting the amount of the intake air and the exhaust air in a precise balance using the throttle and the humidity sensor. By installing the ducts in the cross section, the suction air can be sucked in a state where the temperature of the suction air is raised to prevent condensation in the dryer, and in particular, the waste heat discharged to the outside due to heat exchange can be recovered, thereby reducing the overall energy. have.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

1: dryer 10: intake section
11: Intake duct 20: Exhaust part
21: exhaust duct 30: control unit
31: control panel 35: humidity sensor
40: blower 41: motor
45, 46: blower

Claims (3)

In the apparatus for circulating air into and out of the fiber dryer (1):
An intake unit 10 mounted in communication with an upper portion of the dryer 1 and having an intake duct 11 to suck cold air into the outside;
An exhaust unit 20 mounted in communication with an upper portion of the dryer 1 and having an exhaust duct 21 to discharge hot air to the outside;
An adjustment unit 30 mounted to the intake unit 10 and the exhaust unit 20 and having a control plate 31 and a humidity sensor 35 to adjust the amounts of intake air and exhaust air, respectively; And
A blower mounted on the intake duct 11 and the exhaust duct 21, and provided with a blower 45 and 46 so as to suck / exhale air into and out of the dryer 1 by the motor 41. 40, including;
The intake part 10 and the exhaust part 20 are mounted to the intake duct 11 and the exhaust duct 21 to cross the heat exchange mutually to prevent condensation in the dryer 1, characterized in that to save energy Fresh Air Circulation Device for Dryer. delete delete

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