KR100323209B1 - A hot wind supply system of a machine for tentering - Google Patents

Abstract

PURPOSE: A system for the supply of hot air of a tenter machine capable of shutting off the entrance of an air spray duct in the event of a sudden stoppage of fiber fabric transfer for passing through an air spray duct is provided which permits uniform distribution of hot air to fiber and prevents the deterioration of quality thereof. CONSTITUTION: A hot air supply system of a tenter machine comprises: a support frame(20) comprising a plurality of vertical and horizontal supporters(21,22); a closing member(30) containing a fiber fabric inlet(31) and outlet(31a') and constructed on the side of the support frame; a drive motor(40) constructed on the edge part of an upper plate(32) of the closing member; a plurality of air injection ducts(50) containing an air injection hole constructed at the lower part of the support frame; an air transfer duct(60) constructed at the air injection duct; a burner(70) constructed at the air transfer duct; and a pair of doors movably constructed at a discharge hole.

Description

Hot air supply system of tenter machine {A HOT WIND SUPPLY SYSTEM OF A MACHINE FOR TENTERING}

The present invention relates to a hot air supply system of a tenter, and more particularly, it is configured to distribute the hot air evenly to the fiber fabric to improve the reliability of the product to effectively rearrange the installation position of the internal components and at the same time air The present invention relates to a hot air supply system of a tenter, in which the inlet of the air injection duct is blocked when the transfer of the fiber fabric passing between the injection ducts is stopped to prevent the quality of the fiber fabric from being degraded.

Glossiness--Proceeds through a sequence of inspections, in which spreading is particularly important as a process to prevent shrinkage of the product by adjusting the shrinked fabric to a constant width.

As a device for performing the above-described deburring, a tenter is used, which is composed of a system in which hot air is supplied to the fiber fabric to be conveyed, and the related art is described with reference to FIG. 1. do.

1 is a configuration diagram showing a hot air supply system of a tenter according to the prior art.

As shown, a lower side of the rectangular chamber 1 having a substantially rectangular parallelepiped shape is provided with a drive motor M, and a circulation fan 3 is fixed to the motor shaft 2 of the drive motor M. have.

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.

A burner B is provided at one lower side of the rectangular chamber 1 corresponding to the opposite side on which the driving motor M is installed.

Between the burner (B) and the circulation fan (3) of the drive motor (M), a duct member (4) through which air flows is fixed, but one end thereof is installed to surround the entire circulation fan (3). When the circulation fan 3 is rotated by the driving motor M, the heat generated from the burner B is guided to flow toward the circulation fan 3 in the direction of the arrow.

The air guide duct 5 which is connected 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 enters the air guide duct 5.

Specifically, the air guide duct 5 consists of a pair of upper and lower branch ducts 5a and 5b which are spaced up and down by a predetermined gap, and a predetermined interval is vertically disposed on the outlet side of the upper and lower branch ducts 5a and 5b. The upper and lower air ducts 6 and 7 which are spaced apart so as to hold | maintain are fixed.

The upper and lower air ducts 6 and 7 have a structure in which the inside is sealed to the outside, and minute holes (not shown) are formed on side surfaces facing each other.

Hot air transferred through the air guide duct 5 is injected into the minute hole to reach the fiber fabric T passing between the upper and lower air ducts 6 and 7.

Therefore, the fiber fabric (T) is adjusted to a constant width of the fabric shrinked by hot air to prevent deformation of the product.

However, according to the prior art, the heat of the burner (2) is forcibly sucked along the duct member (4) by the circulation fan (3) which is rotated in accordance with the drive of the drive motor (M), so that it is approximately near the circulation fan (3). The flow path is changed upwards to 90 ° and then blown to the air guide duct 5, since the heat of the burner B is not properly mixed due to the narrow space in the vicinity of the circulation fan 3. As a result, a difference in temperature distribution occurs at the leading end point P ₁ , the center point P ₂ , and the rear end point P ₃ of the air injection duct 6, 7. There was a problem that adversely affects.

In addition, since the air injection ducts 6 and 7 are located above the rectangular chamber 1, the fiber fabric passing between the air injection ducts 6 and 7 sags downward due to its own weight. There was a problem.

In addition, in the hot air supply system according to the prior art, when the fiber fabric passing through the air injection ducts is suddenly stopped due to external conditions, a driving motor is used to prevent the hot air from being excessively supplied to the fiber fabric. The current supplied is cut off, and even when the current supplied to the driving motor is cut off, the driving motor rotates the motor shaft for a predetermined time due to the residual current.

As the motor shaft rotates for such a short time, hot air is forcedly supplied to the fiber fabric through the air blowing duct by the blowing fan, which causes the quality of the fiber fabric to deteriorate.

An object of the present invention is to solve the above problems, and is configured to distribute the hot air evenly to the fiber fabric to effectively rearrange the installation position of the internal configuration device to improve the reliability of the product at the same time It is to provide a hot air supply system of a tenter which can block the inlet of the air injection duct when the transfer of the fiber fabric passing between the air injection ducts is stopped to prevent the quality of the fiber fabric from deteriorating. .

1 is a block diagram showing a hot air supply system of a tenter according to the prior art.

Figure 2 is an exploded perspective view showing a hot air supply system of the tenter according to the present invention.

3 is a cross-sectional view showing a hot air supply system of a tenter according to the present invention.

4 and 5 are views showing the flow of hot air according to the present invention.

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

20: support frame 21: vertical support

22: horizontal support 30: sealing member

31: one side wall plate 31 ': fiber fabric inlet

31a ': fiber fabric outlet 32: top plate

33: lower plate 40: drive motor

41: motor shaft 42: axial fan

50: air injection duct 51: air injection hole

60: air transfer duct 62a, 62b, 62c: upper, middle and lower outlet

70: burner 80,80a: door

100: filter

The hot air supply system of the tenter according to the present invention for achieving the above object is a rectangular parallelepiped support frame made by connecting several vertical and horizontal supports; A fiber member inlet and a fiber fabric outlet are respectively formed at a lower side of a pair of one side wall plates facing each other in a left and right direction, the sealing members being fixedly installed on each side of the support frame; A drive motor fixedly installed at an edge of the upper plate of the sealing member such that a motor shaft is positioned below the upper plate of the sealing member; An axial fan fixed to the motor shaft of the drive motor; Spaced up and down spaced apart by a predetermined interval so that the fiber fabric inserted into the fiber fabric inlet opening, air injection holes are formed on the surface facing each other so that air is injected to the upper and lower surfaces of the fiber fabric, respectively, the upper and lower sides of the support frame A pair of air injection ducts fixedly installed with; One side is installed adjacent to the axial fan to form an inlet for air intake, the other side is formed with the upper, middle and lower outlets for the air is diverted into three paths, the upper, middle outlets are connected to the air injection duct, respectively It is installed, and the air transfer duct fixedly installed on the inner upper side of the support frame; A burner fixed to the air transfer duct through the upper plate of the sealing member; A pair of doors installed in the upper and middle outlets so as to be rotatable, and installed to alternately open and close the lower outlets at the middle outlets; And driving means for driving the door.

Hereinafter, a preferred embodiment of a hot air supply system of a tenter according to the present invention will be described in detail with reference to the accompanying drawings.

2 is an exploded perspective view showing a hot air supply system of a tenter according to the present invention, Figure 3 is a cross-sectional view showing a hot air supply system of a tenter according to the present invention.

As shown, the support frame 20 is formed in a substantially rectangular parallelepiped shape, and the vertical and horizontal supports 21 and 22 are connected to each other.

The six sides of the support frame 20 are opened to communicate with the inside.

On the six sides of the support frame 20, sealing members 30 made of upper and lower plates 32 and 33 and front, rear, left and right wall plates 31, 31a, 31b and 31c are fixedly installed to support the frame. 20) to block the inside of the outside.

That is, the support frame 20 is to act as a chamber by the sealing member (30).

Here, the fiber fabric inlet 31 'and the fiber fabric outlet 31a' are formed in the lower side of the front and rear side wall plate 31 in the structure of the sealing member 30, respectively.

Among the edges of the upper plate 32 of the sealing member 30, the drive motor 40 is fixedly installed at the edge adjacent to the right wall plate 31c in the drawing, and the driving motor 40 has the motor shaft 41 of the sealing member. It is fixedly installed to be located below the upper plate 32 of the (30).

That is, the drive motor 40 is fixedly installed on the bracket member 43 connected between the upper plate 32 of the sealing member 30 and the air transfer duct to be described later.

An axial fan 42 is fixed to the motor shaft 41 of the drive motor 40.

A pair of air injection ducts 50 fixed up and down are fixedly installed in the lower side of the support frame 20. The air injection ducts 50 are formed of fiber fabric inlets formed on the front and rear wall plates 31 and 31a. 31 'and the outlet 31a' are horizontally spaced apart from each other by a predetermined interval so that the end is fixedly installed through the support bracket 52.

By installing as described above, the fiber fabric (T) is discharged through the fiber fabric outlet (31a ') after being fed through the fiber fabric inlet (31') and then transferred between the air injection duct 50, the air injection duct (50) ) Is located in the lower side of the support frame 20, the phenomenon that the fiber fabric passing between the air injection duct 50 is not sag downward due to its own weight.

Here, the fabric is passed through the air injection duct 50 in a predetermined width by a predetermined exposing or exposing device (not shown), the exposing device is a support frame which is located below the fiber fabric 20 is installed.

Therefore, the fiber fabric is not dirty or damaged by oil leaking from the ejection apparatus.

In the air injection duct 50, air injection holes 51 are formed on the surfaces facing each other such that air is injected to the upper and lower surfaces of the fiber fabric T, respectively.

An air transfer duct 60 is fixedly installed on the inner upper side of the support frame 20.

One side of the air transfer duct 60 is installed adjacent to the axial fan 42, the inlet portion 61 is formed so that the air is sucked, the other side is the upper, middle, lower side so that the air is branched and discharged in three paths Outlets 62a, 62b and 62c are formed.

Here, among the upper, middle and lower outlets 62a, 62b and 62c, the upper and middle outlets 62a and 62b are connected to communicate with the air injection duct 50, and the remaining lower outlet 62c is the middle outlet ( Adjacent to 62b).

Here, reference numeral 63 is a hot air branch member.

The burner 70 is fixedly installed in the middle of the air transfer duct 60 through the upper plate 32 constituting the sealing member 30.

Here, the flame (f) direction of the burner 70 preferably corresponds to the blowing direction of the axial fan 42.

The reason is that the flame f of the burner 70 is evenly mixed with the air by the axial fan 42 inside the air transfer duct 60, and at the same time, the mixing time is shortened, and hot air is blown out in a short time. To flow into the duct 50.

Here, in place of the burner 70 described above, a conventional one capable of raising the air temperature inside the air transfer duct 60 may be used. For example, a radiator may be installed outside the air transfer duct 60. By installing a circulation tube inside the air transfer duct 60, the hot water or oil of the radiator is circulated through the circulation tube to increase the internal temperature of the air transfer duct 60.

Doors 80 and 80a rotatably installed around the hinges 81 and 81a are respectively installed in the upper and middle outlets 62a and 62b, and the doors 80a installed in the middle outlet 62b are provided. In some cases, the lower outlet 62c is also opened and closed.

The doors 80 and 80a are driven by separate driving means, and a motor or an air cylinder may be used as the driving means.

In the above-described embodiment, the air injection duct 50 and the air conveying duct 60 are the upper and lower plates 32 and 33 and the front, rear, left and right wall plates 31, 31a, constituting the sealing member 30. It is preferable to be installed inside the support frame 20 so as to be spaced apart from the predetermined distance (L) 31b, 31c, because the heat is removed from the hot air passing through the air injection duct 50 and the air transfer duct 60 This is to reduce the amount to a minimum.

In addition, in the above-described embodiment, the lower portion of the axial fan 42 is a filter as a filtration means for removing foreign matters or debris generated from the fiber fabric discharged from the air discharged through the lower outlet 62c or the air injection duct 50. 100 is fixedly installed via the bracket 101.

By fixing the filter 100 as described above, foreign matters are not introduced into the axial flow fan 42, so that it is possible to continuously generate clean hot air at all times.

Referring to the accompanying drawings the operation of the hot air supply system of the present invention configured as described above are as follows.

4 and 5 are views showing the flow of hot air according to the present invention.

First, as shown in FIG. 4, the fiber fabric T injected through the fiber fabric inlet 31 ′ of the front wall plate 31 constituting the sealing member 30 is moved between the air injection ducts 50. At this time, when the burner 70 is operated to generate a flame f, the driving motor 40 is sequentially driven by applying current.

As the drive motor 40 is driven, the motor shaft 41 rotates the axial fan 42.

Subsequently, as the axial fan 42 is rotated, the heat generated inside the air transfer duct 60 by the burner 70 is converted into hot air, and the air transfer duct 60 is blown along the inside. Will be reached.

Here, when the above-described driving motor 40 is driven, the doors 80 and 80a installed at the upper and middle outlet openings 62a and 62b of the air transfer duct 60 are half on the drawings by separate driving means. It rotates clockwise to open the upper and middle outlet ports 62a and 62b of the air transfer duct 60.

In this case, the doors 80 and 80a installed in the middle outlet port 62b open the middle outlet port 62b and close the lower outlet port 62c so that all the hot air flows into the air injection duct 50.

As described above, since the flame of the burner 70 is pushed to the axial fan 42 of the drive motor 40 from the rear of the air transfer duct 60, the flame of the burner 70 is mixed well as hot air. The converted hot air does not have a temperature difference at each point in the air injection duct 50, so that the phenomenon of streaked marks on the fiber fabric is not generated.

On the other hand, when the transfer of the fiber fabric which is transported between the air injection duct 50 by the external conditions during the hot air supply to the fiber fabric (T) is stopped, the hot air is blocked to prevent the degradation of the fiber fabric, Firstly, the driving of the driving motor 40 is determined. Then, when a separate driving means is operated, the doors 80 and 80a installed at the upper and middle discharge ports 62a and 62b are rotated, and then the doors 80, The upper and middle discharge ports 62a and 62b are closed by 80a).

In this case, the doors 80 and 80a installed in the middle outlet 62b open the lower outlet 62c as shown in FIG. 4.

Accordingly, the hot air flowing into the air transfer duct 60 does not flow into the air injection duct 50 and constitutes the air injection duct 50 and the sealing member 30 through the lower outlet 62c. It is bypassed through the space between the lower plates 33.

After the bypassed hot air is raised to the position where the filter 100 is installed due to its own property, foreign matters are filtered out of the filter 100 and flow to the axial fan 42.

As described above, according to the present invention, the hot air is evenly distributed to the fiber fabric to effectively rearrange the installation positions of the internal components so as to improve the reliability of the product and at the same time pass between the air ducts When the transfer of the fiber fabric is stopped, the inlet of the air injection duct can be blocked to prevent the quality of the fiber fabric from being degraded.

Claims (4)

A rectangular parallelepiped support frame 20 formed by interconnecting a plurality of vertical and horizontal supports 21 and 22; A fiber fabric inlet 31 'and a fiber fabric outlet 31a' are respectively formed at a lower side of a pair of one side wall plate 31 facing in the left and right directions, and are hermetically fixed to each side of the support frame 20. Member 30; A drive motor 40 fixedly installed at an edge of the upper plate 32 of the sealing member 30 such that the motor shaft 41 is positioned below the upper plate 32 of the sealing member 30; An axial flow fan 42 fixed to the motor shaft 41 of the drive motor 40; Spaced apart from the sealing member 30 at a predetermined interval and face each other so that air is sprayed on the upper and lower surfaces of the fiber fabric while being spaced up and down a predetermined distance so that the fiber fabric introduced into the fiber fabric inlet 31 ′ can pass therethrough. A pair of air spraying ducts 50 formed on the surface of each of the air spraying ducts 50 and fixed to the inner lower portion of the support frame 20; The sealing member 30 is spaced apart from the predetermined interval, one side is installed adjacent to the axial flow fan 42, the inlet portion 61 is formed, the other side is formed so that the air is branched and discharged in three paths, Middle and lower outlets 62a, 62b, and 62c are formed, and the upper and middle outlets 62a and 62b are connected to the air injection ducts 50, respectively, and are fixedly installed on the upper side of the support frame 20. The air transfer duct 60; The burner 70 is fixedly installed in the air transfer duct 60 through the upper plate 32 of the sealing member 30, and is installed such that the flame f direction corresponds to the blowing direction of the axial fan 42. Wow; A pair of doors 80 and 80a which are rotatably installed in the upper and middle outlets 62a and 62b, respectively, so as to alternately open and close the lower outlet 62c at the middle outlet 62b; Hot air supply system of the tenter machine comprising a; drive means for driving the door (80, 80a). delete delete delete