KR101586042B1 - Manufacturing device for cooling duct - Google Patents

Abstract

The purpose of the present invention is to provide a manufacturing apparatus of a cooling duct having excellent workability and a relatively simple structure by attaching a plurality of ducts at the same time. To this end, the apparatus for manufacturing a cooling duct having a duct in an upper end of an insulating sheet comprises: a base which supports a structure of an entire apparatus; a supply reel portion which is attached on a side of the base, supplies the insulating sheet, and includes a brake which is operated in accordance with tension of the insulating sheet; a coating portion which forms two adhesion portions in the upper end of the insulating sheet supplied through the supply reel portion; a duct transfer portion which locates the ducts in each adhesion portion, and is operated by a plurality of cams which are operated by the rotation of a single duct motor; a duct supply portion which continuously supplies the ducts transferred by the duct transfer portion; a compression portion which compresses the ducts located in the upper end of the insulating sheet through the duct transfer portion, and composes the duct in a cooling duct shape; a feeding portion which transfers the cooling duct in a longitudinal direction; a heating portion which heats the cooling duct, which passes through the feeding portion, for a certain period; a buffer unit which adjusts the tension of the cooling duct which passes through the heating portion; and a winding portion which winds the cooling duct which passes through the buffer unit.

Description

{Manufacturing device for cooling duct}

The present invention relates to a cooling duct manufacturing apparatus, and more particularly, to a cooling duct manufacturing apparatus for manufacturing a cooling duct used for cooling a transformer.

The cooling duct is a relatively simple type in which ducts (protrusions) are attached at regular intervals on a long insulating paper to increase the cooling effect of the insulating oil to cool the heat generated by the windings during the production of the transformer.

The cooling duct is manufactured in such a manner that a separate insulating paper and a previously manufactured duct are prepared, and the duct is attached to the upper end of the insulating paper by an adhesive while moving the insulating paper.

The above-mentioned manufacturing method can be confirmed through the registered patent No. 346139. The present invention is characterized in that the automatic paper feeding device automatically feeds the insulating paper by a predetermined pitch intermittently by the automatic paper feeding device, And the duct is automatically supplied and attached to the duct with the duct holder unit and the upper picker or the like on the insulating paper on which the bond is discharged. In comparison with the conventional method for manufacturing the cooling duct, Reduction of material loss, and minimization of human labor, thereby improving the productivity and reducing the defect rate.

Particularly, in the above invention, the apparatus is constituted in such a manner that the insulating paper is continuously fed, the adhesive is applied to the upper end of the insulating paper, and the duct is pressed, and a tension holding device for maintaining the tension of the insulating paper is provided. And the user can adjust the pitch at which the duct is attached, thereby being able to cope with various pitches.

However, there is a limitation in raising the overall working speed because the entire configuration is implemented by attaching only one duct. In addition, there are four buffer clamps and two buffer buffers interlocked with the clamp to maintain the tension of the insulating paper And the overall construction of the equipment is complicated. Accordingly, the construction of the pneumatic piping for operating the above-described configurations is also complicated due to the complicated construction, which makes it difficult to manufacture and maintain the equipment.

Therefore, there is a need for a new manufacturing apparatus which is relatively simple in structure, easy to manufacture and maintain, and capable of increasing the workability by simultaneously joining a plurality of ducts.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cooling duct manufacturing apparatus having a plurality of ducts at the same time, which is excellent in workability and is relatively simple in structure, in order to overcome the disadvantages of the related art as described above.

To achieve the above object, the present invention provides a cooling duct manufacturing apparatus for manufacturing a cooling duct in which a duct is attached to an upper end of an insulating sheet, comprising: a base supporting the structure of the entire apparatus; A supply reel attached to the side of the base to supply the insulating paper, the brake including a brake that operates according to the tension of the insulating paper; An application unit configured to form two adhesive portions on top of an insulating paper supplied through the supply reel unit; A duct transferring unit operable by a plurality of cams, each of which is operated by rotation of a single duct motor, with a duct positioned at each adhered portion; A duct supply unit for continuously supplying a duct to which the duct transfer unit is transferred; A compression unit configured to pressurize a duct located at an upper end of the insulating paper through the duct transmission unit to form a cooling duct; A feeding unit for feeding the cooling duct in the longitudinal direction; A heating unit for heating a cooling duct passing through the feeding unit for a predetermined time; A buffer unit for adjusting the tension of the cooling duct passing through the heating unit; And a winding unit for winding the cooling duct passing through the buffer unit.

Preferably, the duct transmission unit comprises: a conveyance base slidably fixed to a side surface of the base; A horizontal transfer actuator for transferring the transfer base; A grip portion for gripping the duct; And a vertical transfer actuator fixed to the transfer base and vertically transferring the grip portion.

More preferably, the duct supply part includes two rotating parts to which a duct is supplied, a guide connected to each of the rotating parts to guide the duct, and an exposed part formed at the end of the guide.

Preferably, the pressing unit includes a pressing base contacting the upper end of the cooling duct, and a pressing actuator having one end coupled to the base and vertically feeding the pressing base.

Preferably, the feeding portion includes: a feeding base slidingly coupled to the base in the longitudinal direction; A horizontal feeding actuator for reciprocating the feeding base longitudinally; A vertical feeding actuator fixed to the feeding base and operating up and down; And a contact portion attached to an end of the vertical feeding actuator to press the upper end of the cooling duct.

Preferably, the heating unit includes a heating plate for pressing the cooling duct, a heating actuator for vertically feeding the heating plate, and a heating unit formed on the base corresponding to the heating plate.

More preferably, the temperature of the heat generating portion is 130 ° C to 150 ° C.

More preferably, the temperature of the heating plate is 130 ° C to 150 ° C.

More preferably, the heating unit is two.

Preferably, the buffer unit includes: a buffer base vertically installed on the base side; A moving body that slides the buffer base up and down; A buffer wheel rotatably fixed to the moving body; An upper limit sensor recognizing an upper limit of the height of the buffer wheel; And a lower limit sensor for recognizing a height limit point of the buffer wheel.

More preferably, the winding unit includes a support frame attached to the base side, a winding motor fixed to the support frame, a winding roll fixed to the winding motor rotation shaft, and a control unit for recognizing information of the upper limit sensor and the lower limit sensor Wherein the control device rotates the winding motor until the upper limit sensor recognizes the buffer wheel when the lower limit sensor recognizes the buffer wheel.

Preferably, the duct conveying portion includes: a fixing portion extending from the base; a rotating shaft rotatably coupled to the fixing portion and rotated by the duct motor; A vertical cam and a horizontal cam fixed to the rotary shaft and rotating; A vertically moving part sliding vertically to the fixing part; A horizontal conveying unit that horizontally slides on the vertical conveying unit; A vertical follower rotatably coupled to the fixed portion and having one end coupled to the guide groove formed in the vertical cam and the other end coupled to a vertical guide formed at the vertical transfer end; A vertical follower rotatably coupled to the fixed portion and having one end coupled to a guide groove formed in the horizontal cam and the other end coupled to a horizontal guide formed at the end of the feed; And a grip part formed at the horizontal end of the feeding part.

The distribution cam includes a distribution guide for guiding the cooling duct to the left and right and a distribution cam for reciprocating right and left of the distribution guide, and the distribution cam rotates in the same manner as the take-up roll, do.

The cooling duct manufacturing apparatus according to the present invention is configured in such a manner that a plurality of ducts are attached to insulating paper at the same time so as to have a high production speed. Further, the rotation of the winding roll for winding the cooled duct, It is possible to adjust the tension of insulating paper with a relatively simple structure because it is controlled by interlocking, and it is possible to increase production speed by integrating two actuators by applying cam device, and it is easy to produce and maintain by simple structure of whole device In particular, since the winding rolls are wound in a plurality of cooling ducts arranged in the width direction as well, a large number of cooling ducts can be wound by replacement of one cooling roll, so that the winding roll replacement cycle is maintained for a long period of time.

1 is a front view of a cooling duct manufacturing apparatus according to the present invention,
Fig. 2 is a configuration diagram of the supply reel unit shown in Fig. 1,
Fig. 3 is an operational state diagram of Fig. 2,
Fig. 4 is a configuration diagram of the duct transmission unit shown in Fig. 1,
Fig. 5 is a configuration diagram of grooves formed in the vertical cam and the horizontal cam shown in Fig. 2,
Fig. 6 is an operational state diagram of Fig. 4,
FIG. 7 is a plan view of a duct supply unit for supplying a duct to the duct transmission unit of FIG. 4,
8 is a side view of the pressing portion shown in Fig. 1,
Fig. 9 is a configuration diagram of the feeding unit shown in Fig. 1,
Fig. 10 is an operational view of Fig. 9,
11 is a side view of the heating unit shown in Fig. 1,
Fig. 12 is a configuration diagram of the buffer unit and the winding unit shown in Fig. 1,
13 is a plan view of Fig. 12,
Fig. 14 is a configuration diagram of the distribution cam shown in Fig. 12; Fig.

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

1, a cooling duct manufacturing apparatus 100 according to the present invention includes a base 10, a supply reel 20 located on the left side of the base to supply the insulating paper 1, A duct feeding part 140 for placing the duct 2 at the upper end of the insulating paper 1 to which the adhesive is applied, a duct feeding part 140 for continuously supplying the duct 2 to the duct feeding part 140, A pressing portion 60 for pressing the attached duct 2, a feeding portion 70 for feeding the entire insulating paper 1, a first heating portion 80 for applying heat to the attached duct 2, A buffer unit 110 for controlling the tension of the cooling duct 3 to which the duct 2 is attached and a second heating unit 90 for further heating the cooling duct 3, And a winding unit 120 for winding up the winding unit 3.

First, the base 10 is configured to have appropriate stiffness, to support other components and to act as a structure of the overall device, to be of relatively long length, have.

The supply reel 20 is located on the left side of the base 10 and the supply reel 20 includes an extension 21 attached to the base 10 and an extension And a supply reel 22 which is rotatably fixed to the main body 21.

A band-type brake 23 is installed on the rotating part of the supply reel 22, and the brake 23 is connected to the connecting rod 24.

A plurality of fixed rolls 25 are arranged vertically in the extended portion 21 and a moving body 26 moving horizontally in the extended portion 21 is located on the right side of the fixed roll 25, The moving body 26 is disposed so as to be pressed to the right by the spring 27 so that the brake 23 is operated.

A plurality of moving rolls 28 are vertically arranged in the moving body 26. The insulating paper 1 supplied from the supply reel 22 is wound in the form of a zigzag as shown in FIG. When the tension of the insulating paper 1 is strong, the moving body 26 moves to the left to release the brake 23 to rotate the supply reel 22. When the tension of the insulating paper 1 is weak, The brake 23 operates so as to suppress the rotation of the supply reel 22 by the action of the clutches 27 and 27.

Therefore, the tension of the insulating paper 1 is kept to be maintained at a certain level.

The insulating paper (1) unwound from the supply reel (22) first passes through the application part (30). The application unit 30 includes a tank 31 for containing an adhesive and two outflow ports 32 connected to the tank 31 for spraying an adhesive and a valve 33 for opening and closing the outflow port 32 When the valve 33 is activated, the adhesive is sprayed through the outlet 32.

At this time, when the two outflow ports 32 are kept equal to the arrangement interval of the ducts 2, an adhesive is applied to the portions where the two ducts 2 are disposed at the same time.

When an appropriate pressure is applied to the inside of the tank 31 containing the adhesive, the adhesive is applied only by the operation of the valve 33.

 A duct transfer part 140 is positioned on the side of the adhesive part 30 and the duct 2 is positioned on the upper end of the front spread paper 1 to which the adhesive is applied.

4, the duct transfer part 140 includes a fixing part 141 extending from the base 10 and a rotating shaft (not shown) rotated by a duct motor 142 fixed to the fixing part 141 A vertical cam 144 coupled to the rotation shaft 143 and having a guide groove formed therein and a vertical cam 144 disposed on a side surface of the vertical cam 144 and coupled to the rotation shaft 143, A horizontal cam 145 having a guide groove formed therein, a vertical conveying part 146 sliding up and down to the fixing part 141, and a horizontal conveying part 147 sliding horizontally to the vertical conveying part 146 .

A vertical guide 151 formed at the end of the vertical transfer unit 146 and a horizontal guide 152 formed at the end of the horizontal transfer unit 147 are formed.

One end of the vertical guide 144 is inserted into a guide groove formed in the vertical cam 144 and the other end is connected to a vertical guide 151 formed at an end of the vertical transfer unit 146 The vertical follower 161 is rotated at the same point as the rotation point of the vertical follower 161 and one end of the vertical follower 161 is inserted into a guide groove formed in the horizontal cam 145, And a horizontal guide 162 which is coupled to the horizontal guide 152 formed at the end of the horizontal guide 152.

At this time, a separate roller is attached to the end of the vertical follower 161 and the horizontal follower 162 for the purpose of contact and operation accuracy.

Further, it is preferable that guide grooves formed in the vertical cam 144 and the horizontal cam 145 are formed as shown in FIG.

A grip portion 40 is formed at the other end of the horizontal transfer portion 147. The grip portion 40 grips or ungrips the duct 2 by a separate air pressure.

As shown in FIG. 6, the duct transfer unit 140 repeats movement of the duct unit 40 in the vertical direction and horizontally by the rotation of the duct motor 142, The grips and the ungrips of the ducts 2 are controlled so that the feeding of the ducts 20 is completed.

The above configuration is advantageous in that it can be operated by a single motor and can be operated at a high speed.

7, the duct supplying part 50 includes two cylindrical rotating parts 51. When a plurality of ducts 2 are inserted into the rotating body 51, The ducts 2 are linearly fed through the guide 52 formed at one side of each of the rotary parts 51 and thus have the same structure as that of the conventional parts feeder.

The ducts 2 finally guided are passed through the guides 52 and then are waiting at the exposed portion 53 and the ducts are fed one by one through the sending portion 40.

The pressing portion 60 is located on the right side of the duct transfer portion 40 and the pressing portion 60 is provided on the right side of the duct transfer portion 40. The pressing portion 60 rotates the pressing base 61 and the pressing base 61 upward and downward, Wherein one side of the squeezing actuator 62 is fixed to the base 10 and the other end is attached to the squeezing base 61 so that the squeezing action of the squeezing actuator 62 The pressing base 61 reciprocates vertically. At this time, when the pressing base 61 moves to the lower end, it presses the two ducts 2 located at the upper end of the insulating paper 1 to increase the adhesive force.

A feeding part 70 is located on the right side of the pressing part 60. The feeding part 70 serves to feed the insulating paper 1 with the duct 2, that is, the cooling duct 3 in the longitudinal direction. As shown in FIG. 9, A horizontal feeding actuator 72 for feeding the feeding base 71 and a contact portion 73 for being vertically transportably coupled to the feeding base 71. [ And a vertical feeding actuator 74 connected to the feeding base 71 and the contact unit 73 to feed the contact unit 73 up and down. At this time, as shown in FIG. 10, the feeding unit 70 lowers the vertical feeding actuator 74 so that the contact portion 73 presses the cooling duct 3. Then, the horizontal feeding actuator 72 is operated to the right to move the feeding base 71 to the right side. At this time, the cooling duct 3 is transferred. After completion of the feeding, the vertical feeding actuator 74 is raised to release the contact between the contact portion 73 and the cooling duct 3, To move the feeding base 71 to the left side. At this time, the stroke of the horizontal feeding actuator 72 is configured to be synchronized with the duct connecting portion 40 and the bonding portion 30 that simultaneously operates the two ducts 2.

The first heating unit 80 and the second heating unit 90 are sequentially positioned on the right side of the feeding unit 70 and are also configured in the same structure.

11, the first heating unit 80 and the second heating unit 90 include a first heating plate 81 and a second heating plate 91 that are vertically coupled to the base 10, And a first heating actuator 82 and a second heating actuator 92 for vertically feeding the base 10 and the first heating plate 81 and the second heating plate 91, The heating plates 81 and 91 are vertically fed according to the operation of the actuators 82 and 92.

The operation of the heating plates 81 and 91 operates in conjunction with the operation of the duct transfer unit 40 and functions to press the cooling duct 3. A separate heating unit is formed on the base 10 positioned below the heating plates 81 and 91 to heat the lower surface of the cooling duct 3 to be transported. Here, the temperature of the heat generating part is preferably set to 130 to 150 ° C.

If the temperature is less than 130 ° C, the effect of improving the adhesion of the cooling duct 3 by heating is insignificant. If the temperature exceeds 150 ° C, the duct 3 may be damaged.

All the actuators are driven by pneumatic pressure, and the pneumatic pressure used is preferably about 30 to 40 kgf / cm 2.

On the other hand, the cooling duct 3 passing through the second heating portion 90 is partially wound around the buffer unit 110 shown in FIG. The buffer unit includes a moving body 112 attached to a side surface of the base 10 and moving up and down along the buffer base 111 and a buffer wheel 113 fixed to the moving body 112 And the cooling duct 3 is wound around the buffer wheel 113. When the tension of the cooling duct 3 is large, the buffer wheel 113 moves upward, In the weakest case, it moves downward by gravity.

The buffer base 111 is provided with an upper limit sensor 114 and a lower limit sensor 115 for recognizing the upper and lower positions of the buffer wheel 113, respectively.

A winding unit 120 fixed to a support frame 121 extending from the base 10 is disposed on the right side of the buffer unit 110.

The winding unit 120 includes a winding motor 122 fixed to the support frame 121 and a winding roll 125 connected to the rotation shaft of the winding motor 122. The buffer wheel 113 is provided with a part And the wound cooling duct 3 is finally wound on the winding roll 125.

At this time, when the buffer wheel 113 is at the position of the lower limit sensor 115, the winding motor 122 operates to increase the tension by winding the cooling duct 3, And is controlled by a separate control device 130 in the form of stopping the operation when it is located at the sensor 114.

Therefore, the tension of the cooling duct 3 is maintained at a constant level by the interaction between the raising unit 120 and the buffer unit 110.

As shown in FIG. 13, the winding roll 125 is configured to have a width at which a plurality of cooling ducts 3 can be disposed. At this time, the cooling ducts 3, And the distribution guide 123 swings and guides the cooling duct 3 in the width direction of the winding roll 125 when the winding roll 125 rotates.

The distribution guide 123 is guided by the distribution cam 124 shown in Fig. 14, and the distribution cam 124 is made up of two spirals in a cylindrical shape. At this time, when one end of the distribution guide 123 is inserted into the spiral, the length of the distribution cam 124 reciprocates when one end of the spiral is connected to each other and the distribution cam 124 rotates in one direction.

At this time, the distribution guide 123 is slidably engaged with the support frame 121, and the distribution cam 124 rotates in the same manner as the take-up roll 125.

On the other hand, the control device 130 may control all the actuators, if necessary. At this time, the actuator control is performed by driving a pneumatic valve that regulates a pneumatic pressure supplied to the actuator. Further, the valve 33 of the application unit 30 and the grip unit 40 of the duct transfer unit 140 are interlocked with the operation of the actuator .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, And all of the various forms of embodiments that can be practiced without departing from the technical spirit.

1: Insulating paper 2: Duct
3: Cooling duct 10: Base
20: supply reel unit 21: extension unit
22: supply reel 23: brake
24: connecting rod 25: stationary roll
26: moving body 27: spring
28: moving roll 30:
31: tank 32: outlet
33: valve 40: grip part
50: duct supply part 51:
52: guide 53: exposed portion
60: a pressing part 61: a pressing base
62: Compression actuator 70: Feeding part
71: Feeding base 72: Horizontal feeding actuator
73: contact portion 74: vertical feeding actuator
80: first heating part 81: first heating plate
82: first heating actuator 90: second heating part
91: second heating plate 92: second heating actuator
100: Cooling duct manufacturing apparatus 110: Buffer unit
111: buffer base 112: mobile body
113: Buffer wheel 114: Upper limit sensor
115: lower limit sensor 120:
121: support frame 122: winding motor
123: distribution guide 124: distribution cam
125: take-up roll 130: control device
140: duct transmission 141:
142: duct motor 143: rotary shaft
144: vertical cam 145: horizontal cam
146 vertical conveyance 147 horizontal conveyance
151: vertical guide 152: horizontal guide
161: Vertical follower 162: Horizontal follower

Claims (12)

A cooling duct manufacturing apparatus for manufacturing a cooling duct in which a duct is attached to an upper end of an insulating sheet,
A base for supporting the structure of the entire apparatus;
A supply reel attached to the side of the base to supply the insulating paper, the brake including a brake that operates according to the tension of the insulating paper;
An application unit configured to form two adhesive portions on top of an insulating paper supplied through the supply reel unit;
A duct transferring unit operable by a plurality of cams, each of which is operated by rotation of a single duct motor, with a duct positioned at each adhered portion;
A duct supply unit for continuously supplying a duct to which the duct transfer unit is transferred;
A compression unit configured to pressurize a duct located at an upper end of the insulating paper through the duct transmission unit to form a cooling duct;
A feeding unit for feeding the cooling duct in the longitudinal direction;
A heating unit for heating a cooling duct passing through the feeding unit for a predetermined time;
A buffer unit for adjusting the tension of the cooling duct passing through the heating unit; And
And a winding unit for winding up the cooling duct passing through the buffer unit.
The duct according to claim 1, wherein:
A transfer base slidably fixed to a side surface of the base;
A horizontal transfer actuator for transferring the transfer base;
A grip portion for gripping the duct; And
And a vertical transfer actuator fixed to the transfer base for vertically transferring the grip portion.
The apparatus for manufacturing a cooling duct according to claim 2, wherein the duct supply part includes two rotating parts to which a duct is supplied, a guide connected to each of the rotating parts, a guide for guiding the duct, and an exposed part formed at the guide end.
The apparatus for manufacturing a cooling duct according to claim 1, wherein the pressing portion includes a pressing base contacting the upper end of the cooling duct, and a pressing actuator having one end coupled to the base and vertically feeding the pressing base.
The feeding unit according to claim 1,
A feeding base slidingly coupled to the base in the longitudinal direction;
A horizontal feeding actuator for reciprocating the feeding base longitudinally;
A vertical feeding actuator fixed to the feeding base and operating up and down; And
And a contact portion attached to an end of the vertical feeding actuator to press the upper end of the cooling duct.
The apparatus for manufacturing a cooling duct according to claim 1, wherein the heating unit includes a heating plate for pressing the cooling duct, a heating actuator for vertically feeding the heating plate, and a heating unit formed on the base corresponding to the heating plate.
7. The cooling duct manufacturing apparatus according to claim 6, wherein the temperature of the heat generating unit is 130 to 150 deg.
The cooling duct manufacturing apparatus according to claim 7, wherein the heating unit is two.
The apparatus of claim 1, wherein the buffer unit comprises:
A buffer base vertically installed on the base side;
A moving body that slides the buffer base up and down;
A buffer wheel rotatably fixed to the moving body;
An upper limit sensor recognizing an upper limit of the height of the buffer wheel; And
And a lower limit sensor for recognizing a height limit point of the buffer wheel.
[Claim 9] The apparatus of claim 9, wherein the winding unit comprises: a support frame attached to the base side; a winding motor fixed to the support frame; a winding roll fixed to the winding motor rotation shaft; and a control for recognizing information of the upper limit sensor and the lower limit sensor Wherein the control device rotates the winding motor until the upper limit sensor recognizes the buffer wheel when the lower limit sensor recognizes the buffer wheel.
[2] The duct according to claim 1,
A fixing unit extended from the base;
A rotating shaft rotatably coupled to the fixed portion and rotated by the duct motor;
A vertical cam and a horizontal cam fixed to the rotary shaft and rotating;
A vertically moving part sliding vertically to the fixing part;
A horizontal conveying unit that horizontally slides on the vertical conveying unit;
A vertical follower rotatably coupled to the fixed portion and having one end coupled to the guide groove formed in the vertical cam and the other end coupled to a vertical guide formed at the vertical transfer end;
A vertical follower rotatably coupled to the fixed portion and having one end coupled to a guide groove formed in the horizontal cam and the other end coupled to a horizontal guide formed at the end of the feed; And
And a grip portion formed at the horizontal end of the feeding duct.
[Claim 11] The apparatus according to claim 10, wherein a distribution guide for guiding the cooling duct to the left and right and a distribution cam for reciprocating the distribution guide in the left and right directions are provided in front of the winding roll, and the distribution cam rotates in the same manner as the winding roll Cooling duct manufacturing apparatus.

Images