JP5443825B2 - Enamel wire printing equipment - Google Patents

Description

  The present invention relates to an enamel wire printing apparatus. Specifically, the present invention relates to a structure for preventing hot air from a baking furnace from entering a cooling tower in an enameled wire baking apparatus provided with a cooling tower on the upper side of the baking furnace.

  2. Description of the Related Art Conventionally, enamel wire printing apparatuses for producing enamel wires are known. This type of enameled wire baking apparatus includes a baking furnace for solvent drying and thermal crosslinking curing of the enamel coating applied to the wire, and a cooling tower for cooling the wire heated in the baking furnace. Is common. Examples of the baking furnace include those disclosed in Patent Document 1 and Patent Document 2.

JP-A-9-35556 JP 2003-187658 A

  By the way, when the baking furnace is of a vertical type (when the wire is inserted in the vertical direction), a rising air flow of high-temperature air is continuously generated in the baking chamber (baking chamber) by a so-called chimney effect. For this reason, in the enameled wire baking apparatus having a general configuration in which the cooling tower is disposed on the upper side of the baking furnace, there is a problem that hot air from the baking furnace is blown into the cooling tower. When the hot air in the baking furnace flows into the cooling tower, not only the cooling efficiency of the cooling tower decreases, but also the heat efficiency of the baking furnace decreases because the amount of heat in the baking furnace is lost.

  In order to solve the above problems, it is conceivable to provide a hot air rise prevention device that prevents the rise of hot air by blowing air between the baking furnace and the cooling tower and increasing the internal pressure. However, when the above hot air rise prevention device is used in an enameled wire baking device that arranges multiple enameled wires (wires coated with enamel paint) and performs the baking process at the same time, the direction and volume of air flow for each enameled wire There was a problem that it was difficult to blow air uniformly.

  Therefore, the present inventor has attempted to make a configuration in which a rotary damper (butterfly damper) 92 and a louver 93 are provided as shown in FIG. FIG. 5A is a plan sectional view of the hot air rise prevention device 9 provided with the rotary damper 92 and the louver 93, and FIG. 5B is a longitudinal sectional view.

  The hot air rise prevention device 9 includes a housing 90. Inside the housing 90, the rotary damper 92 and the louver 93 are attached. The housing 90 is formed with an electric wire passage 94 having a certain width in the apparatus width direction so that a plurality of enamel-coated electric wires 4 can be arranged in the apparatus width direction and allowed to pass in the vertical direction (device vertical direction). ing.

  On the inner wall of the housing 90, an air blowing port 95 for blowing an air flow into the housing 90 is formed. In addition, an air flow supply path 7 for supplying an air flow to the air blowing port 95 is connected to the housing 90.

  The rotary damper 92 is configured to be able to adjust the air volume by changing the opening area of the damper by rotating as shown in FIG.

  As shown in FIG. 6, the louver 93 has a structure in which an opening 931 is formed to be elongated and a blade plate 932 is attached so as to partially block the air blown from the opening 931. In the configuration of FIG. 5, by arranging the louver 93 in the wind blowing portion with respect to the electric wire passage 94, an appropriate resistance (pressure loss) is generated with respect to the passage of the air flow, and the air volume for each enamel coated electric wire 4 is made uniform. It is aimed to do.

  However, when the present inventor experimentally manufactured enameled wire with the enameled wire printing device provided with the hot air rise preventing device 9 configured as described above, a plurality of enameled coated wires 4 are subjected to wire blurring (vibration). ) Occurred, and the enamel coated electric wires 4 running in parallel adhered to each other, causing problems such as defects and process interruption.

  For this reason, in the enamel wire printing apparatus provided with the hot air rise prevention device 9 of FIG. 5, the production speed of the enamel wire could not be increased. That is, when trying to increase the production speed of the enameled wire, the wire speed of the enameled coated wire 4 is increased, or the number of enameled coated wires 4 passed through the enameled wire printing device is increased (the interval between the enameled coated wires 4 is narrowed). Is possible). However, if the linear velocity is increased, the velocity of the hot air in the baking furnace or the cold air in the cooling tower must be increased correspondingly, and the linear blur increases in the configuration of FIG. Moreover, if the space | interval of the enamel apply | coated electric wires 4 is narrowed, possibility that adjacent enamel apply | coated electric wires will contact by wire shake increases. Thus, in the configuration of FIG. 5, the manufacturing speed cannot be increased to improve the productivity, and further improvement has been demanded.

  The present invention has been made in view of the above circumstances, and its main purpose is to increase the wire speed of the enamel-coated electric wire in order to improve productivity, and in response to this, hot air and cooling tower in the baking furnace An object of the present invention is to provide an enameled wire printing apparatus that can suppress wire blurring that causes defective enameled wires and can improve thermal efficiency even if the wind speed of the inside cold air is increased.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

According to the viewpoint of this invention, while providing a cooling tower on the upper side of a baking furnace, the enamel wire printing apparatus comprised as follows is provided. That is, the enameled wire baking apparatus includes a hot air rise prevention device that prevents hot air from rising from the baking furnace to the cooling tower by blowing an air flow between the baking furnace and the cooling tower. The hot air rise prevention device includes a housing having a wire passage for allowing a plurality of enamel coated wires to pass side by side, and a blower opening formed on an inner wall of the housing for blowing an air flow into the housing. Moreover, the width | variety of the apparatus width direction is narrower than the width | variety of the apparatus width direction of the said electric wire channel | path for the ventilation opening. And the rectilinear advance prevention board which prevents the said air flow from advancing straight is provided in the said housing and the said ventilation port vicinity. The width of the rectilinear prevention plate in the apparatus width direction is smaller than the width of the housing in the apparatus width direction.

  Thereby, since the hot air from a baking furnace does not enter into a cooling tower, the thermal efficiency of a baking furnace and the cooling efficiency of a cooling tower can be improved. Further, by applying the air flow straightly introduced from the blower opening and introduced into the housing to the straight travel prevention plate, the straight flow of the air flow in the housing can be prevented at an early stage. Thereby, it is possible to disperse the air flow with a simple configuration, and to reduce the deviation of the wind speed and the wind direction of the air flow blown to the electric wire passage in the housing. Therefore, as a result of preventing the occurrence of wire blurring of the enameled coated wire, it is possible to increase the production speed of the enameled wire and improve the production efficiency.

  In the enameled wire printing apparatus, it is preferable that an air volume adjusting means for adjusting the air volume of the air flow is provided in the housing.

  Thereby, since the air volume adjustment of an air flow can be performed, an air flow can be sprayed with an appropriate air volume with respect to an enamel application | coating electric wire.

  The enameled wire printing apparatus is preferably configured as follows. That is, the space in the housing is divided into a plurality of areas in the direction in which the enameled coated wires are arranged. The air volume adjusting means is provided in each of the plurality of areas.

  Thereby, since the air volume can be individually adjusted by the air volume adjusting means for each zone, the deviation of the wind speed with respect to each enamel coated electric wire can be corrected, and the wire shake can be prevented.

  In the enameled wire printing apparatus, it is preferable that a wind pressure equalizing unit is provided at an air outlet for the air passage.

  As a result, it is possible to make the flow velocity of the air flow uniform by generating an appropriate pressure loss and to prevent the skew in the wind direction.

  In the enameled wire printing apparatus, it is preferable that the straight travel prevention plate is made of a punching metal.

  According to this, since the wind is not completely blocked, it is possible to disperse the air flow well and reduce the deviation of the wind speed.

  The enamel wire printing apparatus is preferably configured as follows. That is, the baking furnace includes a baking passage, a hot air passage, a fan, and a hot air flow rate adjusting means. The stoving passage is for allowing the plurality of enamel coated electric wires to pass side by side. The hot air flow path supplies hot air to the baking passage. The fan is provided in the hot air flow path for blowing hot air. The hot air flow rate adjusting means is arranged on the downstream side of the hot air flow path of the fan and adjusts the flow rate of hot air supplied to the baking passage.

  This makes it possible to adjust the amount of hot air blown to the enamel-coated wire in the baking furnace, making it possible to finely adjust the amount of heat applied to the wire and stabilizing the baking conditions, improving product quality. Can be made.

1 is a front sectional view of an enamel wire printing apparatus according to an embodiment of the present invention. (A) The plane sectional view of the hot air rise prevention device in this embodiment. (B) Similarly longitudinal section. (A) The simulation figure which shows the mode of the air flow in the hot-air rise prevention apparatus in this embodiment with a streamline. (B) The simulation figure which shows the mode of the airflow in the hot air rise prevention apparatus of a comparison object by a streamline. The graph which shows the standard deviation of the wind speed before and after improvement of a hot-air rise prevention apparatus. (A) Plan sectional drawing of the hot air rise prevention apparatus of a comparison object. (B) Similarly longitudinal section. The external perspective view of the louver with which the hot air rise prevention apparatus of a comparison object is provided. The plane sectional view of the hot air rise prevention device concerning a modification.

  Next, embodiments of the invention will be described with reference to the drawings. FIG. 1 is a front sectional view of an enameled wire printing apparatus according to an embodiment of the present invention. As shown in FIG. 1, the enamel wire baking apparatus 100 of the present embodiment mainly includes a baking furnace 1, a cooling tower 2, and a hot air rise prevention apparatus 3.

  As shown in FIG. 1, a passage through which an enamel coated electric wire 4 (a wire coated with an enamel paint) can pass is formed in the enamel wire printing apparatus 100 in the vertical direction. The enamel-coated electric wire 4 travels from the lower side to the upper side of the enamel wire baking apparatus 100 and passes through the baking furnace 1, the hot air rise prevention apparatus 3, and the cooling tower 2 in this order. In addition, the enameled wire printing apparatus 100 of the present embodiment is configured so that a plurality of enamel coated electric wires 4 can be arranged and a baking process can be performed. The passage has a width in a direction (device width direction) orthogonal to the paper surface of FIG. 1 so that a plurality of enameled electric wires 4 (for example, several tens to several hundreds at intervals of 10 mm to 20 mm) can be passed side by side. It is comprised.

  The baking furnace 1 is configured as a hot air circulation type baking furnace, and includes a baking chamber 11 and a circulation chamber 12.

  The baking chamber (baking passage) 11 constitutes a part of the passage of the enamel coated electric wire 4, and is formed in the vertical direction as shown in FIG. Hot air is supplied into the baking chamber 11 as shown by the arrows in FIG. 1, whereby the enamel coating applied to the enamel-coated electric wire 4 is subjected to solvent drying and thermal crosslinking curing.

  The circulation chamber (hot air flow path) 12 is formed in a curved shape so as to suck in hot air from the baking chamber 11 through the hot air inlet port 13 and blow out hot air from the hot air outlet 14 to the baking chamber 11. In the circulation chamber 12, a catalyst 15 for burning the evaporated solvent, a heater 16 for heating, and a fan 17 for circulating hot air are arranged.

  A damper (hot air flow rate adjusting means) 18 is disposed in front of the hot air outlet 14 and downstream of the circulation chamber 12 when viewed from the fan 17. The damper 18 is configured as a slide type damper, and is configured to be able to adjust the amount of hot air supplied into the baking chamber 11 by changing the flow passage area of the circulation chamber 12. Thereby, the temperature in the baking chamber 11 can be adjusted. Moreover, although illustration is abbreviate | omitted, the damper 18 is provided with two or more by the apparatus width direction (direction where the enamelled application | coating electric wire is located in a line), and it can adjust each separately. Thereby, since the air volume of the hot air blown from the hot air outlet 14 to the baking chamber 11 can be adjusted in the width direction, the air volume and temperature of the hot air in the baking chamber 11 can be adjusted to be uniform in the width direction.

  The hot air rise prevention device 3 is arranged between the baking furnace 1 and the cooling tower 2, and is configured to allow the enamel coated electric wire 4 to pass through the inside of the housing 30. An air flow supply path 7 is connected to the housing, and a blower fan (not shown) is connected to the air flow supply path 7. The hot air rise prevention device 3 blows air into the housing 30 from the air flow supply path 7 to increase the internal pressure, so that the hot air from the baking furnace 1 enters the cooling tower 2 by the chimney effect. It is for preventing. The configuration of the hot air rise prevention device 3 will be described later.

  The cooling tower 2 is provided with a cooling air blowing port 21 for blowing cold air therein, and a cooling air discharge port 22 for discharging the cooling air in the cooling tower 2, thereby enamel traveling in the cooling tower 2 It is comprised so that the application | coating electric wire 4 can be cooled.

  Next, a detailed configuration of the hot air rise prevention device 3 will be described with reference to FIG. FIG. 2A is a plan sectional view of the hot air rise preventing device 3 in the present embodiment, and FIG. 2B is a longitudinal sectional view.

As shown in FIG. 2, the hot air rise prevention device 3 includes a housing 30. Inside the housing 30, and the rectilinear prevention plate 31, the sliding damper (air flow rate adjusting means) 32, a punching metal (wind pressure equalizing means) 33, which is attached. The housing 30 is formed with a wire passage 34 having a predetermined width in the apparatus width direction so that a plurality of enamel coated wires 4 can be arranged in the apparatus width direction and passed in the vertical direction (vertical direction). Yes.

  On the inner wall of the housing 30, an air blowing port 35 for blowing an air flow into the housing 30 is formed. In addition, an air flow supply path 7 that supplies an air flow to the blower opening 35 is connected to the housing 30.

  The width of the blower opening 35 in the apparatus width direction is narrower than the width of the electric wire passage 34 in the apparatus width direction. Then, the air flow supplied from the air flow supply path 7 through the air blowing port 35 flows toward the electric wire passage 34 in the internal space of the housing 30 having a shape whose width is increased toward the downstream side. Therefore, the housing 30 serves as an air flow diffusion path for diffusing the air flow in the apparatus width direction.

  As described above, the hot air rise prevention device has a problem that the air flow is diffused so as to be uniform in the width direction. That is, since the air flow blown into the housing 30 from the air blowing port 35 goes straight in the housing 30 as it is, the wind speed at the center becomes high. If this air flow cannot be uniformly diffused in the width direction, the air velocity and the wind direction cannot be uniformly sprayed on the enamel coated electric wire. As described above, the inventors of the present application attempted the configuration shown in FIG. 5 in which the rotary damper 92 and the louver 93 were provided in order to make the air flow uniform in the width direction. I was doing it.

  As a result of studying the cause of the line blurring, the inventors of the present application have not been able to sufficiently diffuse the air flow in the width direction with the rotary damper 92 and the louver 93 alone, and this is the main cause of the line blurring. I found out.

  Therefore, the hot air rise prevention device 3 in the present embodiment is configured such that the straight advance prevention plate 31 faces the air blowing port 35 at a predetermined distance in the housing 30. As a result, the air flow straightly traveling from the blower opening 35 strikes the straight travel prevention plate 31 at an early stage and is diffused, so that the air volume in the hot air rise prevention device 3 can be made uniform in the width direction.

  In this embodiment, a punching metal is used as the rectilinear prevention plate 31. According to this, since the air flow that goes straight is not completely blocked, the air flow can be more suitably diffused. The optimum shape of the straight travel prevention plate 31 for the diffusion of the air flow varies depending on the size and shape of the hot air rise prevention device 3, but the width of the straight travel prevention plate 31 is about 1.2 times the width of the air blowing port 35 and It is particularly preferable that the opening ratio of the punching metal is not less than about 1.5 times and not less than 30% and not more than 40%. In the present embodiment, the rectilinear prevention plate 31 is made of a punching metal having a width of 380 mm and an aperture ratio of 35%, and the punching metal is installed at a position 200 mm from the air blowing port 35.

  Further, the hot air rise prevention device 3 in the present embodiment is different from the hot air rise prevention device 9 to be compared shown in FIG. 5 in that the sliding damper 32 is replaced with the rotary damper 92 and the punching metal is replaced with the louver 93. 33 is provided. This will be described below.

  As a result of further research on the cause of line blurring, the present inventors have found that the rotational damper 92 and the louver 93 cause a deviation in the wind direction. That is, in the rotary damper 92, the air volume is adjusted according to the amount of rotation of the damper, so that the direction of the straight air is changed downward, for example (see FIG. 5B). In addition, since the louver 93 is straight through the elongated opening 931, the louver 93 is likely to pass the wind whose direction of wind is skewed under the influence of the rotary damper 92.

  In this regard, the hot air rise prevention device 3 according to the present embodiment includes a sliding damper 32 as an air volume adjusting means for adjusting the air volume in the housing 30. The sliding damper 32 is configured to be slidable up and down as shown by the up and down arrows in FIG. 2B, and thereby the air volume can be adjusted by adjusting the opening area of the damper. . Unlike the rotary damper 92 shown in FIG. 5B, the slide damper 32 configured in this way does not change the direction of the wind, and is suitable for use in the hot air rise prevention device. is there.

  In the present embodiment, the space inside the housing 30 is divided into a plurality of zones (sections) in the width direction at the installation location of the sliding damper 32. A sliding damper 32 is arranged corresponding to each of the plurality of zones, and the opening area can be individually adjusted. Thereby, the wind speed can be adjusted for each zone. In this embodiment, as shown in FIG. 2A, the inside of the housing 30 is divided into four zones in the width direction, and four sliding dampers 32 are provided so as to correspond to the respective zones. Then, the wind speed at the outlet of each zone is measured, and each slide damper 32 is adjusted in advance so that the variation in wind speed in each zone is within an average value of about ± 10%.

  Further, in the hot air rise prevention device 3 according to the present embodiment, the punching metal 33 is arranged as a wind pressure uniformizing means for causing pressure loss to make the blowing speed uniform in the air blowing portion to the enamel coated electric wire 4. ing. Unlike the louver 93 in FIG. 6, the punching metal has a configuration that makes it difficult to pass the skewed wind as it is, and is therefore suitable for use in the hot air rise prevention device. In order to make the blown air speed uniform, it is necessary to generate a certain amount of pressure loss. However, if the pressure loss is too large, it is necessary to use a fan with high capacity to supply an air flow. This increases the equipment cost. Considering the above points, it is preferable that the punching metal 33 has an aperture ratio of 15% to 30%.

  The inventor of the present application performed a simulation by numerical analysis when the air flow was supplied under the same conditions for the hot air rise prevention device 3 and the comparison hot air rise prevention device 9 configured as described above. FIG. 3A shows the state of the air flow streamline inside the hot air rise prevention device 3 in this embodiment obtained by this simulation, and FIG. 3A shows the state of the air flow streamline inside the hot air rise prevention device 9 to be compared. Each is shown in 3 (b). Since the simulation results appear symmetrically, the streamlines are shown only in the lower half of the figure in FIGS. 3 (a) and 3 (b), and the corresponding hot air rise prevention device is shown in the upper half of the figure. The configuration is shown.

  As can be seen from FIG. 3B, in the hot air rise prevention device 9 to be compared, the wind supplied from the air flow supply path 7 flows downstream while spreading slightly in the width direction. The wind is blown directly (in a large amount) directly to the rotary damper 92 on the center side in the width direction where the opening area is relatively narrowed, and the direction is greatly changed immediately before the rotary damper 92. Due to this influence, an oblique air flow is generated in the downstream portion of the rotary damper 92, particularly in the vicinity of the center in the width direction of the housing 90. This oblique air flow passes through the louver 93 with almost no change in direction, and rotates so as to vortex in the vicinity of the enamel-coated electric wire 4 at the center in the width direction. As a result, not only the wind does not hit the enamel-coated electric wire 4 uniformly, but a turbulence of the wind occurs in the vicinity of the electric wire passage 94, which causes wire blurring.

  On the other hand, as shown in FIG. 3A, in the hot air rise prevention device 3 of the present embodiment, the air flow from the air blowing port is diffused at an early stage by the straight advance prevention plate 31, and the wind direction with respect to the sliding damper 32 is almost the same. You can see how it is uniform. It can also be seen that the wind direction is not changed by the sliding damper 32 or the punching metal 33, and as a result, the wind hits the enameled electric wire 4 straightly and uniformly, and there is little turbulence in the vicinity of the electric wire passage 34.

  In addition, the inventor of the present application calculated the standard deviation (size of variation) of the wind speed in the direction orthogonal to the traveling direction of the enamel coated electric wire 4 in the simulation. FIG. 4 shows a graph of this standard deviation. In FIG. 4, what is before improvement is the standard deviation of the comparative hot air rise prevention device 9 shown in FIG. 3 (b), and after improvement is the hot air rise prevention device of this embodiment shown in FIG. 3 (a). The standard deviation of 3. As can be seen from FIG. 4, compared with the hot air rise prevention device 9 before the improvement, the hot air rise prevention device 3 after the improvement has a standard deviation of the wind speed of about 84% in the width direction and the depth direction (of the enamel coated electric wire 4). In the direction perpendicular to the running direction and also perpendicular to the direction in which the enameled coated wires 4 are arranged), the number is reduced by about 76%.

  As described above, the straight travel prevention plate 31 is provided, and the rotary damper 92 is changed to the slide damper 32 and the louver 93 is changed to the punching metal 33, thereby suppressing variations in wind speed and direction. did it.

  Further, the inventor of the present application conducted an experiment for actually manufacturing an enameled wire with the enameled wire printing device 100 provided with the improved hot air rise preventing device 3. As a result, the line blur (vibration) when using the hot air rise prevention device 9 before the improvement is 10 mm or more, but the hot air rise prevention device 3 after the improvement can reduce the line blur to 3 to 6 mm or less. did it. As a result, even if the wire speed of the enameled coated wire 4 is increased in order to improve productivity and the wind speed is increased correspondingly, problems such as adhesion of the enameled wire that occurs due to wire blurring of the enameled coated wire will not occur. It was. And by providing the hot air rise prevention device 3 between the baking furnace 1 and the cooling tower 2, it is possible to prevent the hot air from rising due to the chimney effect, and to improve the thermal efficiency of the baking furnace and the cooling efficiency of the cooling tower. It was.

  As described above, the enamel wire baking apparatus 100 of the present embodiment includes the cooling tower 2 on the upper side of the baking furnace 1 and is configured as follows. That is, the enamel wire baking apparatus 100 includes a hot air rise prevention device 3 that prevents hot air from rising from the baking furnace 1 to the cooling tower 2 by blowing an air flow between the baking furnace 1 and the cooling tower 2. I have. The hot air rise prevention device 3 includes a housing 30 having a wire passage 34 for allowing a plurality of enamel coated wires 4 to pass side by side, a blower port 35 formed on the inner wall of the housing for blowing an air flow into the housing 30, Is provided. A straight travel prevention plate 31 is provided in the housing 30 in the vicinity of the air blowing port 35 to prevent the straight flow of the air flow.

  Thereby, since the hot air from the baking furnace 1 does not enter into the cooling tower 2, the thermal efficiency of the baking furnace 1 and the cooling efficiency of the cooling tower 2 can be improved. Further, the air flow introduced straight into the housing 30 through the blower opening 35 is applied to the straight travel prevention plate 31, thereby preventing the air flow from going straight. Thereby, the air flow can be dispersed with a simple configuration, and the deviation of the wind speed and the wind direction of the air flow blown to the electric wire passage 34 in the housing 30 can be reduced. Therefore, as a result of preventing the occurrence of line blurring of the enameled coated wire 4, it is possible to increase the production speed of the enameled wire and improve the production efficiency.

  Further, the enameled wire printing apparatus 100 of the present embodiment includes a sliding damper 32 in the housing 30 for adjusting the air volume of the air flow.

  Thereby, since the air volume adjustment of an air flow can be performed, an air flow can be sprayed with an appropriate air volume with respect to an enamel application | coating electric wire. In addition, since the sliding damper 32 does not change the wind direction when adjusting the air volume, it is possible to prevent line blurring of the plurality of enamel coated wires 4 due to the inclination of the wind direction.

  Moreover, the enameled wire printing apparatus 100 of the present embodiment is configured as follows. That is, the space in the housing 30 is divided into a plurality of zones in the direction in which the enameled coated wires 4 are arranged. A sliding damper 32 is provided in each of the plurality of zones.

  Thereby, since the air volume can be individually adjusted by the slide damper 32 for each zone, the deviation of the wind speed with respect to each enamel coated electric wire 4 can be corrected, and the line blur can be prevented.

  Further, the enameled wire printing apparatus 100 of the present embodiment includes a punching metal 33 at an air outlet for the electric wire passage 34.

  As a result, it is possible to make the flow velocity of the air flow uniform by generating an appropriate pressure loss and to prevent the skew in the wind direction.

  Moreover, in the enameled wire printing apparatus 100 of the present embodiment, the straight travel prevention plate 31 is made of a punching metal.

  According to this, since the wind is not completely blocked, it is possible to disperse the air flow well and reduce the deviation of the wind speed.

  Further, in the enamel wire baking apparatus 100 of the present embodiment, the baking furnace 1 includes a baking chamber 11, a circulation chamber 12, a fan 17, and a damper 18. The baking chamber 11 is for passing a plurality of enamel coated electric wires 4 side by side. The circulation chamber 12 supplies hot air to the baking chamber 11. A fan 17 is provided in the circulation chamber 12 for blowing hot air. The damper 18 is disposed on the downstream side of the circulation chamber 12 of the fan 17 and adjusts the amount of hot air supplied to the baking chamber 11.

  As a result, the amount of hot air blown onto the enamel-coated electric wire 4 can be adjusted in the baking furnace 1, so that the amount of heat applied to the wire can be finely adjusted and the baking conditions are stabilized, so that the product quality Can be improved.

  Although the preferred embodiment of the present invention has been described above, the above configuration can be changed as follows, for example.

  In the present embodiment, the baking furnace 1 is a hot air circulation type, but instead, for example, the configuration of the present invention can also be applied to an electrothermal baking furnace that performs solvent drying and thermal crosslinking curing of enamel paint by radiant heat. .

  In the present embodiment, the slide damper 32 is adjusted in advance. However, instead of this, for example, it may be configured such that it can be automatically adjusted during operation of the apparatus.

  The number of zones in which the wind speed can be individually adjusted by the sliding damper 32 is not limited to four zones, and may be two zones, three zones, or five zones or more, for example.

  Further, as the air volume adjusting means, for example, an iris type damper can be used instead of the slide type damper 32.

  The air volume adjusting means may be a rotary damper. In the present embodiment, since the straight travel prevention plate 31 is provided, even if a rotary damper is used as the air volume adjusting means, the change in the wind direction can be reduced. In this case, it is preferable to install a louver in front of the punching metal.

  As the wind pressure uniformizing means, a metal mesh, an expanded metal, a sintered porous metal, a glass cloth, or the like can be used instead of the punching metal 33.

  In the embodiment described above, the enamel-coated electric wire 4 is linearly arranged in the electric wire passage 34. However, as shown in FIG. 7, for example, the electric wire passage 34 is formed wider in the depth direction, and the enamel-coated electric wire 4 is formed. They can be arranged in a zigzag pattern. Thereby, since the space | interval between the enamel application electric wires 4 can be ensured, more enamel application electric wires 4 can be let through.

DESCRIPTION OF SYMBOLS 1 Baking furnace 2 Cooling tower 3 Hot-air rise prevention apparatus 11 Baking chamber (baking passage)
12 Circulation chamber (hot air flow path)
17 Fan 18 Damper (Hot air volume adjustment means)
30 Housing 31 Straight travel prevention plate 32 Sliding damper (air volume adjusting means)
33 Punching metal (means to equalize wind pressure)
34 Wire passage 35 Air outlet 4 Enamel coated wire 100 Enamel wire printing device

Claims (6)

In the enamel wire baking apparatus equipped with a cooling tower on the upper side of the baking furnace,
A hot air rise prevention device for preventing hot air from rising from the baking furnace to the cooling tower by blowing an air flow between the baking furnace and the cooling tower;
The hot air rise prevention device is
A housing having a wire passage for passing a plurality of enameled coated wires side by side;
And said inner housing are formed on the inner wall of the housing for blowing air flow Rutotomoni, the wire passage in the device width direction width blower opening width of the device width direction is formed narrower than the a,
With
A straight travel prevention plate for preventing the air flow from straight traveling is provided in the housing and in the vicinity of the air blowing port .
An enameled wire printing apparatus , wherein a width of the straight travel prevention plate in the apparatus width direction is smaller than a width of the housing in the apparatus width direction . The enameled wire printing apparatus according to claim 1,
An enameled wire printing apparatus comprising air volume adjusting means for adjusting the air volume of the air flow in the housing. The enameled wire printing apparatus according to claim 2,
The space in the housing is divided into a plurality of areas in the direction in which the enamel-coated electric wires are arranged,
The enamel wire printing apparatus, wherein the air volume adjusting means is provided in each of the plurality of areas. The enameled wire printing apparatus according to any one of claims 1 to 3,
An enameled wire printing apparatus comprising air pressure equalizing means at an air outlet of the air passage. The enameled wire printing apparatus according to any one of claims 1 to 4,
The enameled wire printing apparatus, wherein the straight travel prevention plate is made of a punching metal. The enameled wire printing apparatus according to any one of claims 1 to 5,
The baking furnace
A baking passage for passing the plurality of enamel-coated electric wires side by side;
A hot air passage for supplying hot air to the baking passage;
A fan provided in the hot air flow path for blowing hot air;
A hot air flow rate adjusting means arranged on the downstream side of the hot air flow path of the fan, for adjusting the flow rate of the hot air supplied to the baking passage;
An enameled wire printing apparatus comprising:

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