KR100613898B1 - Hot air distribution structure of tenter machine - Google Patents

Abstract

The present invention relates to a hot air supply distribution structure of a tenter, in which the hot air injection and the supply amount of the hot air branched to the hot air injection duct side of the upper and lower in the hot air injection to both sides of the fiber fabric to be transported can be uniformly distributed. This is to improve the quality of the fiber fabric.

The present invention for realizing this, the upper and lower hot air spraying duct for simultaneously injecting hot air from the upper and lower portions of the fiber fabric to be transported, and the air guide duct installed in communication on one side to guide the hot air to the hot air spraying duct side; A circulation fan for forcibly circulating and supplying hot air to the air guide duct side, 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; In the tenter, the air duct is provided with an upper branch duct and a lower branch duct for guiding the hot air forced by the circulation fan to the upper and lower hot air spraying duct, respectively, each branch duct The intermediate partition walls are characterized by guiding passages of the same shape and length.

Tenter, textile fabric, hot air, spraying, supply, distribution

Description

Hot air supply distribution structure of tenter machine {HOT AIR DISTRIBUTION STRUCTURE OF TENTER MACHINE}

1 is an internal structure diagram of a conventional general tenter.

2 is an internal structure diagram of a tenter according to an embodiment of the present invention.

Figure 3 is an enlarged detail of the main portion of the tenter according to an embodiment of the present invention.

Figure 4 is a state diagram provided with a distribution control plate according to an embodiment of the present invention.

5 is a rear view of the tenter according to another embodiment of the present invention.

6 is a cross-sectional view taken along the line A-A of FIG.

FIG. 7 is a sectional view taken along the line B-B in FIG. 5; FIG.

<Explanation of symbols for the main parts of the drawings>

100: chamber 101: burner

102: duct member 103: circulation fan

104: drive motor 105: upper hot air spray duct

106: lower hot air spray duct 109: temperature sensor

110: air duct duct 111: upper branch duct

112: lower branch duct 113: intermediate partition wall

120: control panel 130: central partition membrane

131,132: Blocking plate

The present invention relates to a tenter, and more particularly, to a hot air supply distribution structure for allowing the hot air supplied for the deburring operation of the fabric fabric to be made uniformly up, down, left and right.

Generally, a tenter is used as a device for performing a heat setting step performed as a pre-dyeing step, a drying step performed as a post-dyeing step, and a shrinkage step by heat treatment.

Such a tenter constitutes a system for supplying hot air to the fiber fabric to be transported, which will be described with reference to FIG. 1.

As shown in FIG. 1, a lower side of the rectangular chamber 1 having a substantially rectangular parallelepiped shape is provided with a driving motor M, and a circulation fan 3 is provided on the motor shaft 2 of the driving motor M. As shown in FIG. It is fixedly installed.

Here, the circulation fan 3 is an axial flow fan is formed so as to blow at a right angle to the suction direction of the air.

Then, a burner (B) is provided at a lower side of the square chamber (1) corresponding to the opposite side where the drive motor (M) is installed, and air is provided between the burner (B) and the circulation fan (3) of the drive motor (M). Flowing duct member 4 is fixed, but one end is installed to surround the entire circulation fan (3), the burner (B) when the circulation fan (3) is rotated by the drive of the drive motor (M) The heat generated from) serves to guide the flow toward the circulation fan (3) in the direction of the arrow.

The air guide duct 5 communicated to the upper side is branched and installed in the duct member 4 in which the circulation fan 3 is installed, and the heat generated from the burner B by the circulation fan 3 is converted into hot air. It is introduced into the air guide duct (5), the air guide duct (5) is composed of the upper and lower branch ducts (5a, 5b), the upper and lower branches which are installed spaced apart to maintain a predetermined interval on the outlet side of the upper and lower branch ducts (5a, 5b) The injection ducts 6 and 7 are fixed.

The upper and lower injection ducts 6 and 7 have a structure in which the inside is sealed to the outside, and minute holes (not shown) serving as nozzles are formed on opposite surfaces facing each other, so that hot air is injected.

However, in the case of such a prior art tenter, the distribution of the amount of hot air in the process of forcing hot air forced up by the circulation fan 3 into the air guide duct 5 and then branching to the upper and lower branch ducts 5a and 5b. There was no uniformity, and thus there was a problem in that the hot air quantity and temperature distribution non-uniformity sprayed from the upper and lower spray ducts (6, 7) occurred to reduce the quality of the fiber fabric.

The present invention has been proposed to improve the above problems in the prior art, the hot air forced into the air guide duct during the operation of the tenter to be uniformly distributed in the up and down and left and right directions of the injection duct to the fiber fabric The aim is to achieve a uniform temperature distribution that acts.

The object is an upper and lower hot air spray duct for simultaneously injecting hot air from the upper and lower portions of the fiber fabric to be transported, and an air guide duct installed in communication with one side to guide the hot air to the hot air spray duct side, and the air guide duct. The tenter is provided with a circulation fan for forcibly circulating hot air to the side, 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. The air guide duct is provided with an upper branch duct and a lower branch duct for branching the hot air forced by the circulation fan to guide the upper and lower hot air spray ducts, respectively. Through the hot air supply distribution structure of the tenter, characterized in that to form a guide flow path of the same shape and length by It can be so.

Hereinafter, a specific embodiment of the present invention will be described in detail with reference to FIGS. 2 to 5.

Figure 2 is a cross-sectional view showing the internal structure of the tenter according to the first embodiment of the present invention, Figure 3 is a detailed view showing an enlarged one side duct chamber of the tenter, Figure 4 is an application example, Figure 5 to 7 is a view showing the structure and the main cross section of the tenter according to the second embodiment of the present invention.

First, referring to Figure 2 of the overall configuration of the tenter according to the present embodiment, the burner 101 is installed on one side as a heating member for hot air heating in the lower chamber 100, the burner 101 On the other side opposite to the circulating fan 103 for forcibly raising and circulating the hot air has a common structure in communication with each other by the duct member 102 in the state installed with the drive motor 104.

And, the upper portion of the circulation fan 103 is equipped with an air guide duct 110 for guiding the hot air, the air guide duct 110 is the upper branch duct 111 and the lower branch to branch the hot air. It is provided with a duct 112, and each branch duct (111, 112) is installed in communication with the upper, lower hot air spray ducts 105, 106 located in the upper and lower centers around the path of the fiber fabric (P).

Particularly, the upper and lower branch ducts 111 and 112 are formed to guide passages A and B of the same shape and length by the intermediate partition wall 113, as shown in FIG. The lower branch duct 112 is formed in the same shape as the wall 111a, and the lower branch duct 112 forms a guide flow path by the intermediate partition wall 113 and the lower wall 112a.

On the other hand, Figure 4 is an application of the present invention control plate 120 for adjusting the distribution amount of the hot air supply amount to the starting point of the middle partition wall 113, which is the branching point of the upper branch duct 111 and the lower branch duct 112 Is a state diagram further provided to be rotatable within a predetermined angle range.

In the figure, reference numeral 108 denotes an air filter, and 109 denotes a temperature sensor for measuring the temperature of the supply hot air.

The effect of the operation of the tenter of the present invention constituting such a configuration will be described.

The burner 101 mounted inside the tenter is operated when passing between the upper and lower branch ducts 111 and 112 in a constant speed feed of the fiber fabric P in a predetermined width by a predetermined exposing or exposing device. The flame is generated and at the same time the power is applied to the drive motor 104 is driven to rotate the circulation fan 103.

As the driving is performed, the heat generated inside the duct member 102 is converted into hot air by the circulation force of the circulation fan 103 and forced to the air guide duct 110 side. The upper branch duct 111 and the lower branch duct 112 divided by the wall 113 are supplied to each of the distribution.

The hot air supplied to the branch ducts 111 and 112 is continuously supplied to the upper hot air spraying duct 105 and the lower hot air spraying duct 106 and then hot air is blown toward the upper and lower surfaces of the fiber fabric P. By spraying evenly, the fiber fabric (P) supplied with hot air is adjusted to a constant width of the fabric in the contracted state to prevent the deviation of the product.

In particular, in the tenter of the present invention, since the guide passages A and B of the upper branch duct 111 and the lower branch duct 112 form the same path in the hot wind supply process, the supply amount balance of the hot air distributed is It can be made uniform, accordingly to maintain the amount of hot air injected through the upper, lower hot air spraying ducts 105 and 106 evenly.

In addition, the hot wind flow path in the duct can be increased through the intermediate partition wall 113, so that the overall wind volume distribution of the hot air spray ducts 105 and 106 together with the wind rectifying effect can be achieved.

On the other hand, while the hot air distribution between the upper and lower parts is maintained evenly, depending on the environmental factors such as the weight of the fiber fabric (P), if necessary, the upper hot air spraying duct 105 or the lower hot air spraying duct 106 side. It may be necessary to adjust the amount of hot air finely.

Therefore, in this case, the hot air supplied to the upper and lower hot air spraying ducts 105 and 106 can be adjusted to a desired distribution amount by variably adjusting the angle of the control plate 120 installed at the branched position of the hot air as shown in FIG. 4. It can be seen that the optimum hot air distribution and supply to both sides of the fiber fabric (P) can be made.

5 to 7 illustrate a duct structure according to another embodiment of the present invention, and as shown in FIG. 5, a central partition membrane for horizontally partitioning left and right sides of the air guide duct 110 in the center of the chamber 100. 130 and separate circulation fans 103a and 103b and driving motors 104a and 104b are installed on both sides of the central partition membrane 130, respectively. As described above, one side of the air guide ducts 110 on both the left and right sides allows the air to be introduced only to the upper branch duct 111 and the other side to prevent selective air inflow so that only the lower branch duct 112 enters the air. (131, 132) were installed at the inlet side of each branch duct (111, 112).

In this state, since the air duct 110 is divided into left and right sides by the central partition membrane 130, the hot air raised by the circulation fan 103a on the left side is not shown in FIG. As described above, the inflow is made only to the upper hot air spraying duct 105 through the upper branch duct 11, and the hot air raised by the circulation fan 103b on the right side passes through the lower branch duct 112 as shown in FIG. 7. Inflow is made only to the lower hot air spray duct 106 side.

Therefore, in the left and right duct flow paths, hot air supply may be increased by the separate circulation fans 103a and 103b, and the upper and lower hot air spray ducts 105 and 106 may be controlled by a separate control unit (inverter). Since the hot air distribution amount and the air volume control is made, the control of the distribution amount can be made more precisely by adjusting the individual rotational force of each of the circulation fans 103a and 103b.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the hot air supply structure of the tenter of the present invention may be variously modified and implemented by those skilled in the art.

For example, in the above embodiment, a burner is installed at one side of the lower part as a heating member for heating the internal air in the tenter chamber, but such a heating member may be provided with a fin tube-type heat exchanger on the inlet duct flow path. do.

Therefore, such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments shall fall within the appended claims of the present invention.

The present invention as described above, by spraying hot air to both sides of the fiber fabric to be transported by forming the shape of the supply passage branched to the upper and lower hot air injection duct side in the same way up and down, the injection of hot air And the feed amount can be uniformly distributed, thereby improving the production quality of the fiber fabric.

In particular, the length of the flow path for guiding the hot air in the duct structure can be increased to induce a more even air volume distribution through the air rectification effect.

Claims (3)

Upper and lower hot air spray ducts 105 and 106 for simultaneously injecting hot air from the upper and lower portions of the fiber fabric P to be transported, and an air guide duct installed in communication with one side to guide the hot air to the hot air spray ducts 105 and 106. 110, a circulation fan 103 for forcibly circulating hot air to the air guide duct 110, a duct member 102 for guiding the air recovered in the chamber 100 to the circulation fan 104. In the tenter equipped with a heating member for reheating the air guided through the duct member 102, The air guide duct 110 is branched to the upper branch duct 111 and the lower branch duct 112 for guiding the hot air forced by the circulation fan 103 to the upper and lower hot air spraying ducts 105 and 106, respectively. Wherein, each branch duct (111, 112) is a hot air supply distribution structure of the tenter, characterized in that the guide flow path of the same shape and length by mutually formed by the intermediate partition wall 113 is formed in a curved shape upward. The method according to claim 1, Hot air supply distribution structure of the tenter, characterized in that the control plate 120 for adjusting the distribution of the hot air supply amount is branched at the branching point of the upper branch duct 111 and the lower branch duct (112). The method according to claim 1, The center of the chamber 100 is provided with a central partition membrane 130 for partitioning the left and right of the air guide duct 110 in the transverse direction; The circulation fan 103 is separately installed on both sides with respect to the central partition membrane 130; Air guide ducts 110 on both the left and right sides of the tenter, hot air supply, characterized in that the blocking plate (131, 132) for preventing the inflow of air into any one of the upper branch duct 111 and the lower branch duct 112 is installed. Distribution structure.

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