KR102307301B1 - Damper device for hot air distribution of tenter machine - Google Patents

Abstract

The present invention relates to a damper device for hot air distribution of tenter machine, which comprises: a damper plate rotatably disposed inside a fan casing; and a guide vane fixed inside the fan casing and guiding the hot air without pressure loss by minimizing the collision of the hot air. It is possible to precisely control the air volume of the hot air distributed to upper and lower injection ducts by using the change in the air volume distribution ratio generated according to the separation distance of the damper plate to the guide vane when adjusting the rotation angle of the damper plate. Also, in consideration of conditions such as the type of fabric and the shrinkage rate, it is possible to easily control the distribution ratio of hot air sprayed to upper and lower sides of the textile fabrics. Furthermore, the structure is improved so that the rotation angle of the damper plate can be finely adjusted and precisely controlled according to the pitch interval of a gear unit and the number of gear teeth formed on an outer periphery of the rotation shaft by using a damper shaft and the rotation shaft fastened by the gear meshing method.

Description

DAMPER DEVICE FOR HOT AIR DISTRIBUTION OF TENTER MACHINE

The present invention relates to a damper device for distributing hot air of a tenter machine, and in particular, a damper plate rotatably disposed inside a fan casing and a damper plate fixed inside the fan casing to minimize the collision of hot air and to guide hot air without loss of pressure In order to precisely control the air volume of the hot air distributed to the upper and lower injection ducts by using the change in the air volume distribution ratio generated according to the separation distance of the damper plate to the guide vane when the rotation angle of the damper plate is adjusted. In addition, in consideration of conditions such as the type of fabric and shrinkage rate, the distribution ratio of hot air sprayed to the upper and lower sides of the textile fabric can be easily adjusted. And it relates to a damper device for hot air distribution of a tenter machine whose structure is improved so that the rotation angle of the damper plate can be finely adjusted and precisely controlled according to the number of gear teeth formed on the outer periphery of the rotation shaft.

In general, in the processing process of textile fabrics such as woven fabrics or knitted fabrics, a heat setting process performed as a treatment process before dyeing, a drying process and heat treatment performed as a treatment process after dyeing There is a shrinkage process, etc., and a tenter machine is mainly used as an apparatus for performing this process.

The conventional tenter machine includes: a chamber through which a fabric passes horizontally in the upper space, and a fabric entry port and a fabric outlet port are provided at upstream and downstream ends of the fabric in the transport direction, respectively; a hot air generating duct disposed in the space below the chamber; a heater coupled to one side of the hot air generating duct; a hot air supply duct connected to the other side of the hot air generating duct, extending upward, and having a plurality of hot air outlets opened on the upper side toward one side of the hot air generating duct; a channel-type nozzle body having an inlet end mounted at the hot air outlet of the hot air supply duct and having the other end closed, and upper and lower hot air jet nozzles coupled to a surface of the nozzle body opposite to the fabric fabric and formed with a plurality of nozzle holes; It is installed at the lower end of the hot air supply duct and sucks the air in the chamber through the heater and the hot air generating duct, and blows it into the hot air jet nozzle through the hot air supply duct, so that the hot air is blown into the hot air jet nozzle through the nozzle hole of the fabric fabric. It is configured to include a blower to be sprayed on the upper and lower surfaces of the

The overall length of the chamber is determined according to the feed rate and the processing conditions for processing the fabric. The chamber is configured by connecting a plurality of unit chambers having a length obtained by dividing the entire length into equal parts. The fabric entrance and the fabric outlet are respectively provided in upper and downstream unit chambers installed at upper and lower ends of the unit chambers.

In performing the heat setting process, the drying process, and the shrinking process by the conventional tenter machine, when the blower and the heater are operated while the fabric is transferred, the air inside the chamber is sucked into the hot air generating duct by the blower through the heater, and sucked The heated air is heated by heat exchange while in contact with the heater to generate hot air of about 180°C to 220°C, and the generated hot air is supplied to the inside of the hot air jet nozzle through the hot air supply duct by the blower.

The hot air supplied to the inside of the hot air jet nozzle is sprayed on the upper and lower surfaces of the fabric through a plurality of nozzle holes formed on the nozzle plate of the hot air jet nozzle to perform a heat setting process, a drying process, or a shrinkage process.

As a prior art related to the existing tenter machine hot air supply, as disclosed in Korean Patent Publication No. 10-320004 "Hot air supply system of tenter machine" (registration date: 2001.12.24), it rotates by receiving the driving force of the drive motor. In the hot air supply system of a tenter machine configured to sequentially supply heat heated by a flame generated from a burner assembly to the air conveying duct and the air injection nozzle as a turbofan that is A pair is positioned horizontally spaced apart by a predetermined distance inside the inlet of It is to be fixedly installed on the outside of the right wall plate of the sealing member so that the heat generated in the turbo fan can be ejected directly below the turbo fan.

As another prior art related to the existing tenter machine hot air distribution, as disclosed in Korean Patent Publication No. 10-0613898 "Hot air supply distribution structure of tenter machine" (registration date: August 10, 2006), the upper part of the transferred textile fabric and upper and lower hot air injection ducts that simultaneously spray hot air from the lower portion, an air guide duct connected to one side to guide hot air toward the hot air injection duct, and a circulation fan for forcibly circulating and supplying hot air toward the air guide duct; , a tenter having a duct member for guiding the air recovered in the chamber to the circulation fan side, and a heating member for reheating the air guided through the duct member, wherein the air guide duct is connected to the circulation fan. It is provided with an upper branch duct and a lower branch duct for branching the hot air forcibly transported by the duct and guiding it to the upper and lower hot air blowing ducts, and each branch duct is provided with a guide passage of the same shape and length by an intermediate partition wall. it was made to be accomplished

However, in the process of decomposing the hot air to the upper and lower injection ducts in the existing fan casing, a damper means is provided, and the damper means rotates the damper plate by rotating the drive shaft from the outside of the chamber and the rotation angle of the rotary plate is adjusted. Accordingly, the air volume ratio of the hot air supplied to the upper or lower injection ducts varies. In the process of distributing the hot air from the inside of the fan casing to the upper and lower injection ducts, precise control is achieved by simply rotating the damper plate. It has a difficult drawback.

Korean Patent Publication No. 10-320004 "Hot air supply system of tenter machine" (Registration date: Dec. 24, 2001) Korean Patent Publication No. 10-0613898 "Hot air supply distribution structure of tenter machine" (Registration date: 2006.08.10)

The present invention was created to solve the above problems in consideration of the above problems, and its object is to minimize the collision of the hot air by fixing the damper plate rotatably disposed inside the fan casing and the fan casing to the inside of the fan casing to minimize the pressure loss. It is equipped with guide vanes that can guide An object of the present invention is to provide a damper device for hot air distribution of a tenter machine whose structure is improved so that it can be controlled.

Another object of the present invention is to easily control the distribution ratio of the hot air sprayed to the upper and lower sides of the textile fabric in consideration of conditions such as the type of fabric and the shrinkage rate, and the gear unit is An object of the present invention is to provide a damper device for hot air distribution of a tenter machine whose structure is improved so that the rotation angle of the damper plate can be finely adjusted and precisely controlled according to the pitch interval and the number of gear teeth formed on the outer periphery of the rotation shaft.

The present invention for achieving the above object is an upper and lower injection duct for simultaneously spraying hot air from the upper and lower portions of the textile fabric; a fan casing having a blower fan for forcibly supplying hot air to the upper and lower jetting ducts and having upper and lower guide ducts therein for guiding hot air toward the upper and lower jetting ducts; a guide vane fixed to the inside of the lower guide duct and guiding the hot air toward the lower injection duct; and rotatably provided at the boundary of the upper and lower guide ducts, and distributes the hot air blown from the blowing fan toward the upper and lower guide ducts, and adjusts the air volume distribution ratio of the hot air by adjusting the interval with the guide vanes. It is characterized in that provided with; damper means having a damper plate.

The guide vane is configured in the form of an assembly assembled inside the lower guide duct.

The damper means is rotatably shaft-coupled from the outside of the chamber, and a damper shaft having an adjustment handle provided at one end and a gear portion formed on the outer peripheral surface of the other end is meshed with the gear portion of the damper shaft, and interlocked rotation when the damper shaft is rotated and a rotating shaft for rotating the damper plate.

The damper plate is formed in the form of a plate whose thickness becomes thinner toward the bottom.

An auxiliary guide vane fixed to the inside of the upper guide duct and guiding the hot air forcedly blown from the blowing fan toward the upper injection duct is further provided.

The present invention can precisely and finely adjust the air volume distribution ratio of the hot air supplied to the upper guide duct and the hot air supplied to the lower guide duct by using the distance between the damper plate and the guide vanes of the damper means, as well as the damper means. It has a useful advantage that the operator can easily adjust the ratio of hot air sprayed to the upper and lower sides of the textile fabric by using the

In addition, since the damper means of the present invention is composed of a gear meshing type damper shaft and a rotating shaft, an operator can easily adjust the rotation angle of the damper plate by rotating the control handle in one direction or the other from the outside of the chamber, and gear meshing method By using the damper means, it has the advantage that fine adjustment and precise control are possible according to the pitch interval of the gear part and the number of gear teeth formed on the outer periphery of the rotation shaft.

1 is a block diagram showing the configuration of a damper device for hot air distribution of a tenter machine according to the present invention.
Fig. 2 is a front view of Fig. 1;
Figure 3 is an enlarged view of the present invention guide vane.
4A to 4E are views schematically illustrating a state in which the air volume distribution ratio for each rotation angle of the damper plate of the present invention is varied.
5 is a view showing an auxiliary guide vane provided in the upper guide duct of the present invention.
6 is a view showing a modified example of the damper plate of the present invention.

In describing the present invention, if it is determined that a detailed description of a related known technology or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to the intention or custom of the user. Therefore, the definition should be made based on the content throughout this specification. In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

The damper device for hot air distribution of a tenter machine according to the present invention is described with reference to FIGS. 1 to 5, and includes upper and lower injection ducts 20 and 30 for simultaneously spraying hot air from the upper and lower portions of the textile fabric; A blower fan 50 for forcibly supplying hot air to the upper and lower injection ducts 20 and 30 is disposed therein, and an upper and lower guide duct for guiding hot air toward the upper and lower injection ducts 20 and 30 therein. (110, 120) provided with a fan casing (100) and; a guide vane (250) fixed to the inside of the lower guide duct (120) and guiding the hot air toward the lower injection duct (30); and the upper and lower guide ducts 110 and 120 are rotatably provided, and the hot air blown from the blower fan 50 is distributed to the upper and lower guide ducts 110 and 120 side, and the guide vanes 250 and and a damper means 200 having a damper plate 210 that adjusts the air volume distribution ratio of the hot air by adjusting the interval of the .

1 and 2 , the fan casing 100 is rotationally driven by a driving motor 55 to blow hot air heated from the heater to the upper and lower guide ducts 110 and 120 on the upper side. ) is provided inside.

In addition, the fan casing 100 has an upper guide duct 110 connected to the upper injection duct 20 side in the transverse direction from the upper side of the fan casing 100 on the upper side, and the upper guide duct 110 to the lower side. A lower guide duct 120 connected to the lower injection duct 30 in the transverse direction at a spaced height is provided.

As shown in FIG. 3 , the guide vane 250 is coupled to be fixed inside the lower guide duct 120 and the flow direction of the hot air forcedly blown from the blower fan 50 in the transverse direction In the process of switching, the function of guiding to the lower injection duct 30 side is performed without a pressure loss that is generated when the hot air collides during the direction change of the direction.

The guide vane 250 has a structure that is assembled in the lower guide duct 120 after being pre-fabricated in the form of a semi-finished assembly. As a result, it is possible to shorten the assembly time.

As shown in FIG. 3 , the guide vane 250 is a round curved pipe having a through hole so as to guide the hot air therein toward the lower injection duct 30 through the lower guide duct 120 in the transverse direction. It is formed in the shape, and has a structure in which the width ℓ1 of the entrance side of one side is larger than the width ℓ2 of the exit side of the other side (ℓ1 > ℓ2).

For this reason, the guide vane 250 minimizes the collision of the hot air in the process of converting the direction of the hot air passing through the inside of the lower guide duct 120 from the vertical longitudinal direction to the lower injection duct 30 side in the transverse direction. Although it has the advantage of guiding the hot air without loss, it is not necessarily limited thereto.

In addition, the guide vane 250 and the damper plate 210 are the amount of hot air blown toward the upper and lower guide ducts 110 and 120 according to the separation distance between the inlet of one side of the guide vane 250 and the damper plate 210 . The distribution ratio of is variable.

That is, as the damper plate 210 approaches the inlet side of the guide vane 250, the amount of hot air supplied to the upper guide duct 110 is greater than that of the hot air supplied to the lower guide duct 120. has structural properties.

As shown in FIGS. 1 and 2, the damper means 200 is shaft-coupled rotatably from the outside of the chamber 10, an adjustment handle 230 is provided at one end, and a gear unit 225 is provided on the outer peripheral surface of the other end. The damper shaft 220 on which is formed, is meshed with the gear part 225 of the damper shaft 220, is rotatably coupled to the inside of the fan casing 100, and when the damper shaft 220 rotates It is provided with a rotating shaft 215 for rotating the damper plate 210 by interlocking.

The damper plate 210 rotates interlockingly when the rotation shaft 215 rotates, and as it is formed in a plate shape that becomes thinner toward the bottom, distribution efficiency can be improved without interference with hot air.

The rotation shaft 215 has a gear formed on its outer peripheral surface so as to be engaged with the gear part 225 of the damper shaft 220, and accordingly, the damper shaft 220 and the rotation shaft 215 are worm and worm wheel fastening method. It may have a structure in which it is interlocked and rotated.

As shown in FIG. 5, the upper guide duct 110 is fixed therein, and an auxiliary guide vane 250A for guiding the hot air forcedly blown from the blowing fan 50 toward the upper injection duct 20 side (250A) is further added. can be provided

The auxiliary guide vane (250A) has the advantage of preventing the pressure loss of the hot air generated in the process of changing the flow direction of the hot air passing through the upper guide duct (110).

In the tenter of the present invention having such a configuration, after hot air heated through a heater such as a burner flows into the inside through the lower part of the fan casing 100 , the blowing fan 50 rotates when the driving motor 55 is driven. While being driven, air is forced from the lower part of the fan casing 100 to the upper and lower guide ducts 110 and 120 located on the upper part of the fan casing 100 .

In addition, according to the present invention, while the hot air is branched to the upper and lower guide ducts 110 and 120 side, the air volume ratio of the hot air branched to the upper guide duct 110 and the lower guide duct 120 according to the rotation angle of the damper plate 210 Since it has this variable characteristic, it is possible to easily adjust the air volume injection ratio of the hot air through the upper and lower injection ducts 20 and 30 in consideration of the type of fabric and the shrinkage rate.

At this time, when the operator rotates the control handle 230 from the outside of the chamber 10 in one direction, the damper means 200 rotates in one direction while the damper shaft 220 rotates in one direction and the gear unit 225 is engaged with the gear. The rotation shaft 215 is rotated interlockingly.

The damper shaft 220 can finely adjust the rotation shaft 215 according to the rotation angle of the control handle 230 in a gear meshing meshing method, and the pitch interval of the gear unit 225 and the gear teeth of the rotation shaft 215 . According to the number, the rotation angle of the damper shaft 220 and the rotation shaft 215 can be more finely adjusted.

That is, the rotating shaft 215 interlocked and rotated by the damper shaft 220 rotates the integrally coupled damper plate 210 interlockingly.

At this time, the damper plate 210 can adjust the distribution ratio of the hot air blown toward the upper and lower guide ducts 110 and 120 within the operating range of ±10% from the normal distribution ratio of 50:50, and the gear mesh By using the damper means 200 of the method, fine adjustment and precision control are possible according to the pitch interval of the gear unit 225 and the number of gear teeth formed on the outer periphery of the rotation shaft 215 .

Here, when the damper plate 210 is rotated at an angle exceeding the ±10% distribution ratio range, the injection pressure of the hot air sprayed from the upper and lower sides of the textile fabric is excessively differential, so that the textile fabric sags or rises. , There is a possibility that the textile fabric may be torn by colliding with the nozzles of the lower jetting ducts (20, 30).

4A to 4E are views schematically illustrating a state in which the air volume distribution ratio for each rotation angle of the damper plate 210 of the present invention is varied. It shows sequential rotation in the direction opposite to the moving direction of the clockwise hand toward the direction, and the air volume distribution ratio of the hot air that varies accordingly is schematically expressed by the number of arrows.

In FIG. 4A, the damper plate 210 is in close contact with the inlet side of the guide vane 250 to reduce the area in which the hot air blown from the blower fan 50 is supplied to the lower guide duct 120 side to reduce the guide vane 250. As the hot air passes through the interior of the lower guide duct 120 and blows toward the lower injection duct 30 through the remaining area except for distribution ratio will be higher.

As the end of the damper plate 210 gradually moves away from the inlet side of the guide vane 250 from FIG. 4B to FIG. 4D, the air volume distribution ratio between the upper guide duct 110 and the lower guide duct 120 is Each approaches the same half ratio, and in Fig. 4e, as the damper plate 210 gets closer to the damper shaft 220, compared to the air volume of the hot air passing toward the upper guide duct 110, it passes toward the lower guide duct 120. The ratio of the air volume of the hot air to be produced becomes larger.

Accordingly, for example, when the fabric is of a type in which a lot of sagging occurs during transport in the chamber 10, the distribution ratio of the hot air supplied to the lower guide duct 120 and the lower injection duct 30 is relatively adjusted to the upper guide. The rotation angle of the damper plate 210 may be adjusted to supply hot air at a higher rate than the hot air supplied to the duct 110 and the upper injection duct 20 .

Therefore, in the present invention, using the distance between the damper plate 210 and the guide vane 250 of the damper means 200, the amount of hot air supplied to the upper guide duct 110 and the lower guide duct 120 are supplied to the side. Not only can the air volume distribution ratio of the hot air be precisely and finely adjusted, but by using the damper means 200, the operator can easily adjust the ratio of the hot air sprayed to the upper and lower sides of the textile fabric in consideration of conditions such as the type of fabric and the shrinkage rate. It has a number of useful advantages that can be

In addition, since the damper means 200 of the present invention is composed of a gear meshing type damper shaft 220 and a rotation shaft 215 , the operator rotates the control handle 230 in one direction or the other from the outside of the chamber 10 . Thus, the rotation angle of the damper plate 210 can be easily adjusted, and the pitch interval of the gear unit 225 and the number of gear teeth formed on the outer periphery of the rotation shaft 215 are finely adjusted by using the damper means 200 of the gear meshing method. and precise control.

6 is a view showing a modified example of the damper plate 210 of the present invention. Unlike the previous embodiment, the damper plate 210 has a length that can open and close the entire flow path of the lower guide duct 120. As a result, it has the advantage of being able to adjust the distribution ratio wider than the allowable range of the hot air distribution ratio of the preceding embodiment described above.

A guide vane 250 having a larger volume than the guide vane 250 of the previous embodiment is provided inside the lower guide duct 120, and the auxiliary guide vane 250A is inside the upper guide duct 110. As this is provided, it is possible to reduce the pressure loss when the blowing direction of the hot air blown from the blowing fan 50 is changed.

The guide vane 250 is further provided with a rounded curved blade 255 to guide the hot air therein as the volume increases.

As such, although specific embodiments have been described in the detailed description of the present invention, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the above-described embodiment, but should be defined by the claims and equivalents as well as the claims to be described later.

That is, the present invention described as described above is not limited to the specific preferred embodiments described above, and anyone with ordinary skill in the art to which the invention pertains without departing from the gist of the present invention as claimed in the claims Of course, various modifications are possible, and such modifications are within the scope of the claims.

10: chamber 20, 30: upper, lower injection duct
50: blow fan 55: drive motor
100: fan casing 110,120: upper and lower guide ducts
200: damper means 210: damper plate
215: rotation shaft 220: damper shaft
225: gear unit 230: control handle
250: guide vane 250A: auxiliary guide vane
255 : Blade

Claims (5)

Upper and lower injection ducts 20 and 30 for simultaneously spraying hot air from the upper and lower portions of the textile fabric;
A blower fan 50 for forcibly supplying hot air to the upper and lower jetting ducts 20 and 30 is disposed therein, and an upper and lower guide duct for guiding hot air toward the upper and lower jetting ducts 20 and 30 inside. (110, 120) provided with a fan casing (100) and;
a guide vane (250) fixed to the inside of the lower guide duct (120) and guiding the hot air toward the lower injection duct (30); and
It is rotatably provided at the boundary of the upper and lower guide ducts 110 and 120, and distributes hot air blown from the blowing fan 50 toward the upper and lower guide ducts 110 and 120, and with the guide vane 250. A damper device for hot air distribution of a tenter machine, characterized in that it comprises a; damper means (200) having a damper plate (210) for adjusting the air volume distribution ratio of the hot air by adjusting the interval. The method according to claim 1,
The guide vane 250 is a damper device for hot air distribution of a tenter machine, characterized in that it is configured in the form of an assembly assembled inside the lower guide duct 120 . The method according to claim 1,
The damper means 200 is shaft-coupled rotatably from the outside of the chamber 10, a damper shaft 220 having an adjustment handle 230 provided at one end and a gear unit 225 formed on an outer peripheral surface of the other end;
Ten characterized in that it is engaged with the gear part 225 of the damper shaft 220 and provided with a rotation shaft 215 for rotating the damper plate 210 by interlocking rotation when the damper shaft 220 rotates. A damper device for distribution of hot air in Turkey. The method according to claim 1,
The damper plate 210 is a damper device for hot air distribution of a tenter machine, characterized in that it is formed in the form of a plate that becomes thinner toward the bottom. The method according to claim 1,
The tenter machine, characterized in that it further comprises an auxiliary guide vane (250A) fixed inside the upper guide duct (110) and guiding the hot air forcedly blown from the blowing fan (50) toward the upper injection duct (20). damper device for hot air distribution of

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