JP6230793B2 - Inkjet recording device - Google Patents

Description

  The present invention relates to an ink jet recording apparatus including a recording head that ejects ink that is cured when irradiated with light, and an irradiation device that emits light.

  2. Description of the Related Art Conventionally, ink jet recording apparatuses that use ink that is cured when irradiated with light such as ultraviolet rays (so-called photo-curable ink) are known. Such an ink jet recording apparatus includes a recording head that ejects ink toward a recording medium such as paper, and an irradiation device that irradiates light on the ink on the recording medium. Since the irradiation device generates heat, it needs to be cooled. Therefore, a cooling fan is often provided in an ink jet recording apparatus including an irradiation device.

  Patent Documents 1 and 2 describe an ink jet recording apparatus that includes a heat sink fixed to an irradiation device and a cooling fan attached on the heat sink. Patent Document 3 discloses an ink jet recording apparatus that includes a housing that covers the periphery of each irradiation device, and a cooling fan that is disposed on the housing, and a guide structure that guides air from the cooling fan is formed by the housing. Is described. According to the conventional ink jet recording apparatus, air is blown from one cooling fan to one irradiation apparatus.

JP 2008-143123 A JP 2011-84030 A JP 2010-735 A

  By the way, when the irradiation intensity of the irradiation device is increased, the amount of heat generated by the irradiation device increases. In order to cool the irradiation device more, it is necessary to increase the cooling capacity of the cooling fan. It is conceivable to increase the size of the cooling fan as means for increasing the cooling capacity of the cooling fan. However, the cooling fan is mounted on a carriage that reciprocates in the main scanning direction during printing together with the recording head and the irradiation device. Therefore, the cooling fan is desired to be small and light. However, the conventional idea of blowing air from one cooling fan to one irradiation device and individually cooling the irradiation device achieves both improvement of the cooling efficiency of the irradiation device and downsizing of the entire cooling fan. It was difficult to do.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an ink jet recording apparatus capable of achieving both improvement in the cooling efficiency of the irradiation apparatus and reduction in the overall size of the cooling fan. There is.

  An ink jet recording apparatus according to the present invention includes a recording head that discharges ink that is cured when irradiated with light onto a recording medium, a plurality of irradiation apparatuses that irradiate the ink on the recording medium with light, and at least the plurality A case that accommodates substantially the entire irradiation device, and one or more cooling fans disposed in the case, wherein the number of cooling fans in the case is greater than the number of irradiation devices. There are few air flow paths that guide the air blown by one cooling fan to two or more irradiation devices in the case.

  According to the ink jet recording apparatus of the present invention, it is possible to reduce the number of cooling fans while securing air blowing to each irradiation apparatus. Therefore, it is possible to achieve both the improvement of the cooling efficiency of the irradiation device and the miniaturization of the entire cooling fan.

It is a perspective view which cuts and shows a part of inkjet printer concerning a 1st embodiment. It is a perspective view showing typically the composition in the case of the head unit concerning a 1st embodiment. It is a plane sectional view showing typically composition in a case of a head unit concerning a 1st embodiment. It is a front sectional view showing typically the composition in the case of the head unit concerning a 1st embodiment, and is a figure showing the section which met the IV-IV line of Drawing 3. It is a perspective view which shows an example of the airflow in the case which concerns on 1st Embodiment. It is a plane sectional view showing typically composition in a case of a head unit concerning a modification of a 1st embodiment. It is a plane sectional view showing typically composition in a case of a head unit concerning a 2nd embodiment. It is a front sectional view showing typically composition in a case of a head unit concerning a 2nd embodiment, and is a figure showing a section which met a VIII-VIII line of Drawing 7. It is a vertical sectional view showing typically the composition in the right case of the head unit concerning a 2nd embodiment.

<First Embodiment>
As shown in FIG. 1, the ink jet recording apparatus according to the present embodiment is an ink jet printer (hereinafter simply referred to as a printer) 100 that performs printing on a recording paper 5. However, the present invention can be applied to any recording apparatus that performs ink jet recording, and its application target is not limited to an ink jet printer. The recording paper 5 is an example of the recording medium according to the present invention, but the recording medium according to the present invention is not limited to the recording paper 5. The recording medium may be another sheet-like recording medium, such as a resin sheet. Further, the flexibility and thickness of the recording medium are not limited. That is, the recording medium may be a hard material such as a glass substrate, or a thick material such as a corrugated cardboard.

  In FIG. 1 and the like, symbols F, Rr, L, and R represent front, rear, left, and right, respectively. A head unit 1 to be described later can move leftward and rightward, and the recording paper 5 can be conveyed forward and backward. If the moving direction of the head unit 1 and the conveying direction of the recording paper 5 are referred to as a main scanning direction and a sub scanning direction, respectively, the main scanning direction corresponds to the left and right direction, and the sub scanning direction corresponds to the front and rear direction. The main scanning direction and the sub scanning direction are orthogonal to each other. However, the main scanning direction and the sub-scanning direction are not particularly limited, and can be appropriately set according to the form of the printer 100 and the like. Further, as the transport device, a device for moving the table itself, on which the recording medium is placed, back and forth and right and left may be provided.

  The printer 100 includes a platen 2 that supports the recording paper 5. The platen 2 is provided with a cylindrical grid roller 3. The grid roller 3 is embedded in the platen 2 with its upper surface exposed. The grid roller 3 is driven by a feed motor (not shown). The grid roller 3 is an example of a feed mechanism that moves the recording paper 5.

  A guide rail 6 is disposed above the platen 2. The guide rail 6 is disposed in parallel with the platen 2 and extends to the left and right. Below the guide rail 6, a plurality of pinch rollers 7 are arranged at substantially equal intervals. The pinch roller 7 faces the grid roller 3. The pinch roller 7 is configured to be able to set the vertical position according to the thickness of the recording paper 5, and sandwiches the recording paper 5 between the grid rollers 3. The grid roller 3 and the pinch roller 7 are configured to be able to transport the recording paper 5 back and forth while pinching the recording paper 5.

  The guide rail 6 has an engaging portion 8 protruding forward. A carriage 21 is provided on the back surface of the case 20 of the head unit 1. A concave portion that is recessed forward is formed in the rear portion of the carriage 21. The engaging portion 8 of the guide rail 6 is engaged with the recess. The carriage 21 can slide along the guide rail 6 and can move left and right. The head unit 1 is guided left and right by the guide rail 6 via the carriage 21.

  A part of the drive belt 9 that extends to the left and right is fixed to the upper back of the case 20. The drive belt 9 is connected to a scan motor (not shown) and is driven by this scan motor. The head unit 1 is driven by a scan motor via a drive belt 9.

  FIG. 2 shows an arrangement of main components in the case 20. The printer 100 includes a recording head 15 that discharges ink that cures when irradiated with ultraviolet rays (that is, ultraviolet curable ink) to the recording paper 5, and a plurality of irradiation devices 31 to irradiate the ink on the recording paper 5 with ultraviolet rays. 36 and a plurality of cooling fans 41 to 44. The irradiation devices 31 to 36 are formed separately and can be separated from each other. In the present embodiment, almost all of the recording head 15, the irradiation devices 31 to 36, and the cooling fans 41 to 44 are accommodated in a single case 20. Here, “the recording head 15, the irradiation devices 31 to 36 and the cooling fans 41 to 44 are almost entirely accommodated in the case 20” includes the lower end of the recording head 15, the lower ends of the irradiation devices 31 to 36, When the lower ends of the cooling fans 41 to 44 are located above the lower end of the case 20 (in other words, the recording head 15, the irradiation devices 31 to 36, and the cooling fans 41 to 44 are completely accommodated in the case 20). Not only when the lower surface of the case 20 is opened or when an opening is formed on the lower surface of the case 20, the lower end of the recording head 15, the lower ends of the irradiation devices 31 to 36, Or the case where the lower end part of the cooling fans 41-44 protrudes below from the lower surface of case 20, or opening of a lower surface is also included. “The recording head 15, the irradiation devices 31 to 36, and the cooling fans 41 to 44 are almost entirely accommodated in the case 20” includes the recording head 15, the irradiation devices 31 to 36, and the cooling fans 41 to 44. The case where it is substantially accommodated in the case 20 is included, and the case where a part of the recording head 15, the irradiation devices 31 to 36, and the cooling fans 41 to 44 protrudes to the outside of the case 20 is included. In the case 20, the number of cooling fans 41 to 44 is smaller than the number of irradiation devices 31 to 36. Here, the number of cooling fans 41 to 44 is four and the number of irradiation devices 31 to 36 is six. It is. However, the number of cooling fans and irradiation devices can be changed as appropriate.

  As shown in FIG. 3, the recording head 15 includes a plurality of inkjet heads 16 each having a plurality of nozzles (not shown). Here, the recording head 15 includes six inkjet heads 16 that respectively eject yellow (Y), magenta (M), cyan (C), black (K), light magenta (LM), and light cyan (LC) ink. It has. The inkjet heads 16 are arranged side by side. However, the type of ink ejected by each inkjet head 16 is not particularly limited. Further, the number of inkjet heads 16 included in the recording head 15 is not limited at all. Furthermore, the arrangement of the inkjet head 16 may be a so-called staggered arrangement in which the inkjet head 16 is shifted in the front-rear direction.

  As shown in FIG. 2, the irradiation devices 31 to 36 include ultraviolet lamps 31 a to 36 a and heat radiators 31 b to 36 b as light sources, respectively. Although not shown, each of the ultraviolet lamps 31a to 36a includes a plurality of LEDs that emit ultraviolet rays. The ultraviolet lamps 31a to 36a are not necessarily provided with LEDs, and any type of light emitters such as a fluorescent lamp type can be used. The ultraviolet lamps 31a to 36a are configured to irradiate ultraviolet rays downward. In the present embodiment, the ultraviolet lamps 31a to 36a have the same structure and dimensions. However, the structures or dimensions of the ultraviolet lamps 31a to 36a may be different from each other.

  The radiators 31b to 36b are respectively attached to the upper portions of the ultraviolet lamps 31a to 36a. In the present embodiment, the radiators 31b to 36b are fixed so as to be in close contact with the upper surfaces of the ultraviolet lamps 31a to 36a. The heat radiators 31b to 36b are members that promote the heat radiation of the ultraviolet lamps 31a to 36a. Here, the heat radiators 31b to 36b are constituted by a heat sink in which a plurality of fins (not shown) are formed. However, the configuration of the radiators 31b to 36b is not particularly limited, and may be a member other than the heat sink. Further, the positions of the radiators 31b to 36b are not limited to above the ultraviolet lamps 31a to 36a, respectively. Furthermore, the heat radiators 31b to 36b are not necessarily required, and may be omitted. The irradiation devices 31 to 36 may be configured only by the ultraviolet lamps 31a to 36a, respectively.

  The cooling fans 41 to 44 have the same structure and dimensions. However, the structures or dimensions of the cooling fans 41 to 44 may be different from each other. In the present embodiment, the cooling fans 41 to 44 are configured to suck air from above and blow out downward.

  Next, the arrangement of the irradiation devices 31 to 36 and the cooling fans 41 to 44 will be described. As shown in FIGS. 2 and 3, the irradiation device 31 is disposed on the left side of the recording head 15, and the irradiation device 36 is disposed on the right side of the recording head 15. These irradiation devices 31 and 36 are examples of the “side irradiation device” according to the present invention, and are arranged on the side of the recording head 15. The irradiation devices 32 to 35 are an example of the “front irradiation device” according to the present invention, and are arranged in front of the recording head 15. In particular, in the present embodiment, the irradiation devices 32 to 35 are disposed in front of the recording head 15. The irradiation devices 32 to 35 are arranged side by side, and are arranged in order from left to right.

  As shown in FIGS. 2 and 4, the cooling fan 41 is disposed above the irradiation device 31, and the cooling fan 44 is disposed above the irradiation device 36. Specifically, the cooling fan 41 is disposed above the radiator 31b, and the cooling fan 44 is disposed above the radiator 36b. The cooling fan 41 and the radiator 31b are not in contact with each other, and a gap is provided between them. Similarly, the cooling fan 44 and the radiator 36b are not in contact with each other, and a gap is provided between them. As shown in FIG. 3, the cooling fan 41 is disposed on the left side of the recording head 15 and the cooling fan 44 is disposed on the right side of the recording head 15 in plan view. The cooling fans 41 and 44 are arranged beside the recording head 15 in plan view. In the state where the cooling fan 41 and the like are in contact with the irradiation devices 31 to 36, the air blown by the cooling fan 41 and the like is blown between the case of the cooling fan 41 and the irradiation devices 31 to 36. You may make it form the ventilation path led to.

  As shown in FIGS. 2 and 3, the cooling fan 42 is disposed above the two irradiation devices 32 and 33. Specifically, the cooling fan 42 is disposed above the radiators 32b and 33b. The cooling fan 42 is not in contact with the radiators 32b and 33b, and there are spaces between the cooling fan 42 and the radiator 32b and between the cooling fan 42 and the radiator 33b. As shown in FIG. 3, the cooling fan 42 is disposed at a position partially overlapping with the irradiation devices 32 and 33 in a plan view. The cooling fan 42 is disposed in front of the recording head 15 in plan view. The cooling fan 42 is not necessarily disposed above the irradiation device 32 or 33, and may be disposed on the side, front, rear, or lower side of the irradiation device 32 or 33.

  The cooling fan 43 is disposed above the two irradiation devices 34 and 35. Specifically, the cooling fan 43 is disposed above the radiators 34b and 35b. As shown in FIG. 2, the cooling fan 43 is not in contact with the radiators 34b and 35b, and there is a gap between the cooling fan 43 and the radiator 34b and between the cooling fan 43 and the radiator 35b. Is provided. As shown in FIG. 3, the cooling fan 43 is disposed at a position partially overlapping with the irradiation devices 34 and 35 in a plan view. The cooling fan 43 is disposed in front of the recording head 15 in plan view.

  Next, the case 20 will be described. The case 20 is formed in a substantially chevron shape in plan view, and the front side portion thereof is formed so that the lateral width decreases toward the front. Although illustration is omitted, openings are formed in a portion of the case 20 below the recording head 15 and a portion below the irradiation devices 31 to 36. In addition, the case 20 should just open the lower part of the recording head 15, and the lower part of the irradiation apparatuses 31-36. A part of the lower part of the case 20 may be open, or the whole may be open. The case 20 does not necessarily have a substantially mountain shape in a plan view, and may be a quadrangle in a plan view.

  As shown in FIG. 5, a left opening 51 is formed in the left wall 22 of the case 20, and a right opening 52 is formed in the right wall 23 of the case 20. The left opening 51 is located on the left side of the radiator 31b, and the right opening 52 is located on the right side of the radiator 36b. Although not shown, the radiators 31b and 36b are formed with a plurality of fins extending left and right. A front opening 53 is formed in the front wall 24 of the case 20. The front opening 53 is located in front of the radiators 32b, 33b, 34b, and 35b. Although illustration is omitted, the radiators 32b, 33b, 34b, and 35b are formed with a plurality of fins extending in the front-rear direction. Upper openings 54, 55, 56, and 57 are formed in the upper wall 25 of the case 20. The upper openings 54, 55, 56, and 57 are located above the cooling fans 41, 42, 43, and 44, respectively.

  The height positions of the lower edges of the left opening 51, the right opening 52, and the front opening 53 coincide with the height positions of the lower ends of the radiators 31b to 36b of the irradiation devices 31 to 36. However, the positions of the lower edges of the left opening 51, the right opening 52, and the front opening 53 may be lower than the positions of the lower ends of the radiators 31b to 36b. The upper edges of the upper openings 54 to 57 are higher than the upper ends of the radiators 31 b to 36 b of the irradiation devices 31 to 36. In the present embodiment, since the upper openings 54 to 57 are formed in the upper wall 25 of the case 20, the heights of the peripheral edges of the upper openings 54 to 57 are equal. Therefore, the entire periphery of the upper openings 54 to 57 corresponds to the upper edge. However, when the cooling fans 41 to 44 are arranged at positions shifted from the upper openings 54 to 57, the height positions of the upper edges of the upper openings 54 to 57 are equal to the height positions of the upper ends of the radiators 31b to 36b. You may do it.

  As described above, in the present embodiment, the cooling fans 41 to 44 suck in air from above and blow out downward, but the air blown out from at least one of the cooling fans 41 to 44 is from the irradiation devices 31 to 36. It is supplied to two or more of the radiators 31b to 36b. In the case 20, a blowing path 20 </ b> A that guides air blown from one of the cooling fans 41 to 44 to two or more of the irradiation devices 31 to 36 is formed.

  The arrow of FIG. 5 has shown an example of the flow (henceforth an airflow) of the air blown by the cooling fans 41-44. In this example, the air flowing into the case 20 from the upper opening 54 is blown downward by the cooling fan 41. A part of the air blown out from the cooling fan 41 passes through the periphery of the radiator 31 b to cool the irradiation device 31, and then flows out from the left opening 51. Another part of the air blown out from the cooling fan 41 passes through the periphery of the radiator 32 b to cool the irradiation device 32, and then flows out from the front opening 53.

  Air that flows into the case 20 from the upper opening 55 is blown downward by the cooling fan 42. A part of the air blown out from the cooling fan 42 passes through the periphery of the radiator 32 b to cool the irradiation device 32, and then flows out from the front opening 53. Another part of the air blown out from the cooling fan 42 passes through the periphery of the radiator 33 b to cool the irradiation device 33, and then flows out from the front opening 53.

  Air that flows into the case 20 from the upper opening 56 is blown downward by the cooling fan 43. A part of the air blown out from the cooling fan 43 passes through the periphery of the radiator 34 b to cool the irradiation device 34, and then flows out from the front opening 53. Another part of the air blown out from the cooling fan 43 passes through the periphery of the radiator 35 b to cool the irradiation device 35, and then flows out from the front opening 53.

  Air that has flowed into the case 20 from the upper opening 57 is blown downward by the cooling fan 44. A part of the air blown out from the cooling fan 44 passes through the periphery of the radiator 35 b to cool the irradiation device 35, and then flows out from the front opening 53. Another part of the air blown out from the cooling fan 44 passes around the heat radiating body 36 b to cool the irradiation device 36, and then flows out from the right opening 52.

  Note that the airflow is merely an example. For example, a part of the air blown out by the cooling fan 42 passes around the radiator 34b of the irradiation device 34 and / or the radiator 35b of the irradiation device 35. Of course, it is also good. A part of the air blown out by the cooling fan 43 may pass around the radiator 32 b of the irradiation device 32 and / or around the radiator 33 b of the irradiation device 33. The air passage 20A is merely an example, and the air passage in the case according to the present invention is not limited to the air passage 20A. At least one of the cooling fans 41 to 44 may guide air to only one of the irradiation devices 31 to 36. Further, at least one of the cooling fans 41 to 44 may guide air to three or more of the irradiation devices 31 to 36.

  During printing by the printer 100, the recording head 15 ejects ink while moving to the left and / or right, and the irradiation devices 31 to 36 irradiate ultraviolet rays while moving to the left and / or right. The ink ejected from the recording head 15 and landed on the recording paper 5 is cured by receiving the ultraviolet rays irradiated from the irradiation devices 31 to 36. Each time the recording head 15 and the irradiation devices 31 to 36 reciprocate once or a plurality of times, the recording paper 5 is sent forward. By repeating such an operation, an image is formed on the recording paper 5.

  As described above, the printer 100 according to this embodiment includes the recording head 15 that discharges ultraviolet curable ink onto the recording paper 5, the irradiation devices 31 to 36 that irradiate the ink on the recording paper 5 with ultraviolet rays, and at least the irradiation. The case 20 which accommodates the apparatuses 31-36 and the cooling fans 41-44 arrange | positioned in the case 20 are provided. Unlike the case of providing one cooling fan for one irradiation device, in the printer 100 according to the present embodiment, the number of cooling fans 41 to 44 in the case 20 is smaller than the number of irradiation devices 31 to 36, and the case 20 Inside, a blowing path 20A that guides air blown by one cooling fan to two or more irradiation devices is formed. Therefore, it is possible to reduce the number of cooling fans while securing air blowing to each of the irradiation devices 31 to 36. Therefore, it is possible to achieve both the improvement of the cooling efficiency of the irradiation devices 31 to 36 and the miniaturization of the cooling fans 41 to 44 as a whole.

  The printer 100 includes a cooling fan 42 disposed above the irradiation devices 32 and 33. Thus, by arranging one cooling fan 42 above the two irradiation devices 32 and 33, the air blown by one cooling fan 42 can be easily guided to the two irradiation devices 32 and 33. . Similarly, the printer 100 includes a cooling fan 43 disposed above the irradiation devices 34 and 35, and the air blown by the cooling fan 43 can be easily guided to the two irradiation devices 34 and 35.

  The printer 100 moves the recording head 15, the irradiation devices 31 to 36, the cooling fans 41 to 44, and the case 20 to the left and right, and the recording paper 5 relative to the recording head 15. The grid roller 3 is provided. The irradiation devices 31 to 36 include side irradiation devices 31 and 36 disposed on the left and right sides of the recording head 15 and front irradiation devices 32 to 35 disposed in front of the recording head 15. . The side irradiation devices 31 and 36 can immediately irradiate the ink ejected from the recording head 15 and landed on the recording paper 5 with ultraviolet rays. On the other hand, the front irradiation devices 32 to 35 can irradiate ultraviolet rays after the recording paper 5 is sent forward after the ink ejected from the recording head 15 has landed on the recording paper 5. That is, the front irradiation devices 32 to 35 can irradiate the ink landed on the recording paper 5 with ultraviolet rays after a certain amount of time has passed. Therefore, the printer 100 includes the side irradiation devices 31 and 36 and the front irradiation devices 32 to 35, so that the time from the ink landing on the recording paper 5 to the curing can be appropriately changed. By shortening the time until curing, it is possible to perform matte printing, and by increasing the time until curing, it is possible to perform glossy printing. Therefore, the printer 100 can selectively execute glossy printing and non-glossy printing.

  According to the printer 100, the cooling fan 42 is disposed above the two front irradiation devices 32 and 33, and the cooling fan 43 is disposed above the two front irradiation devices 34 and 35. According to the printer 100, the cooling fan 42 can blow air to the two front irradiation devices 32 and 33, and similarly, the cooling fan 43 can blow air to the two front irradiation devices 34 and 35. .

  The printer 100 includes a cooling fan 41 that blows air to the side irradiation device 31 and the front irradiation device 32. The printer 100 also includes a cooling fan 44 that blows air to the side irradiation device 36 and the front irradiation device 35. According to the printer 100, air can be blown to both the side irradiation device 31 and the front irradiation device 32 by the left cooling fan 41, and the side irradiation device 36 and the front irradiation device by the right cooling fan 44. Air can be blown to both 35.

  The case 20 has a left opening 51, a right opening 52, and a front opening 53 as examples of the first opening. The case 20 has upper openings 54 to 57 positioned above the left opening 51, the right opening 52, and the front opening 53 as examples of the second opening. The positions of the lower edges of the left opening 51, the right opening 52, and the front opening 53 are equal to or lower than the positions of the lower ends of the radiators 31b to 36b. The positions of the upper edges of the upper openings 54 to 57 are equal to or lower than the positions of the upper ends of the radiators 31b to 36b. By arranging the openings 51 to 57 in this way, the irradiation devices 31 to 36 can be effectively cooled by a small number of cooling fans 41 to 44.

  The printer 100 includes side irradiation devices 31 and 36 and front irradiation devices 32 to 35. Here, by appropriately setting the irradiation intensity of the side irradiation apparatuses 31 and 36 and the irradiation intensity of the front irradiation apparatuses 32 to 35, the surface property of the ink after printing can be set as appropriate. For example, a printed matter with less gloss can be obtained by making the irradiation intensity of the side irradiation apparatuses 31 and 36 higher than the irradiation intensity of the front irradiation apparatuses 32 to 35. On the contrary, by making the irradiation intensity of the front irradiation apparatuses 32 to 35 higher than the irradiation intensity of the side irradiation apparatuses 31 and 36, a printed matter with more gloss can be obtained.

  When the irradiation intensity of the side irradiation devices 31 and 36 is higher than the irradiation intensity of the front irradiation devices 32 to 35, the air blowing path 20 </ b> A has a blowing amount per unit time with respect to the side irradiation devices 31 and 36 of the front irradiation devices 32 to 35. It is preferable that the air flow rate is larger than the air flow rate per unit time for 35. Thereby, the side irradiation apparatuses 31 and 36 which generate heat more easily can be preferentially cooled, and the entire irradiation apparatuses 31 to 36 can be efficiently cooled. On the other hand, when the irradiation intensity of the front irradiation devices 32 to 35 is higher than the irradiation intensity of the side irradiation devices 31 and 36, the air blowing path 20 </ b> A has a blowing amount per unit time with respect to the front irradiation devices 32 to 35. It is preferable that the air flow rate per unit time for 31 and 36 is larger. Thereby, the front irradiation devices 32 to 35 that are more likely to generate heat can be preferentially cooled, and the entire irradiation devices 31 to 36 can be efficiently cooled.

  The printer 100 according to the present embodiment includes a guide rail 6 that extends to the left and right, a carriage 21 that moves to the left and right along the guide rail 6, and a left and right that moves integrally with the carriage 21. The recording head 15 that discharges to the right, the carriage 21 moves to the left and right integrally, irradiating devices 31 to 36 that irradiate the ink on the recording paper 5 with ultraviolet rays, and a cooling fan 41 that sends cooling air to the irradiating devices 31 to 36. ˜44, the recording head 15, the irradiation devices 31 to 36, and the case 20 that accommodates almost the entire cooling fans 41 to 44. According to the printer 100, not only the cooling fans 41 to 44 and the irradiation devices 31 to 36 but also the recording head 15 is accommodated in the case 20. As described above, since not only the cooling fans 41 to 44 and the irradiation devices 31 to 36 but also the recording head 15 is accommodated in the same case 20, a relatively large space is formed in the case 20, and the cooling fans 41 to 44 are formed. It is possible to secure a large blowing path 20A for guiding the air blown by the irradiation devices 31 to 36. Therefore, the whole irradiation apparatus 31-36 can be cooled effectively. Moreover, it becomes easy to guide the air blown by one cooling fan to two or more irradiation devices, and the entire irradiation devices 31 to 36 can be effectively cooled.

  By the way, in the ultraviolet curable resin ink, the viscosity tends to increase as the temperature decreases. In this embodiment, the temperature of the cooling air sent from the cooling fans 41 to 44 rises by cooling the irradiation devices 31 to 36. A part of the cooling air whose temperature is increased by cooling the irradiation devices 31 to 36 is sent toward the recording head 15. Therefore, the temperature of the ink in the recording head 15 is maintained by a part of the cooling air, and the viscosity of the ink can be kept relatively low and almost constant. For this reason, it is possible to discharge ink favorably from the recording head 15 and improve the image quality.

  In the present embodiment, the cooling fans 41 to 44 are configured to suck air from above and blow out downward. Therefore, it is possible to prevent the ink mist floating between the recording head 15 and the recording paper 5 from being sucked into the case 20. Therefore, it is possible to prevent ink from adhering to the inside of the case 20.

  In the present embodiment, the lower heights of the left opening 51, the right opening 52, and the front opening 53 are the same, and the heights of the upper ends thereof are also the same. However, the heights of their lower ends may be different, and the heights of their upper ends may be different.

  In the present embodiment, all the cooling fans 41 to 44 are configured to suck air from above and blow out downward. However, the cooling fans 41 to 44 may be configured to suck air from below and blow it upward. In that case, an airflow opposite to the direction of the airflow of this embodiment (see FIG. 5) is formed in the case 20.

  Further, a part of the cooling fans 41 to 44 may be configured to suck air from above and blow out downward, and the other part may be configured to suck air from below and blow out upward. The rotation direction of a part of the cooling fans 41 to 44 and the other part may be reversed. For example, the rotation direction of the cooling fans 41 and 42 located on the left side and the rotation direction of the cooling fans 43 and 44 located on the right side may be reversed. Further, even if the rotation direction of the cooling fans 41 and 44 positioned on the side of the recording head 15 in a plan view is opposite to the rotation direction of the cooling fans 42 and 43 positioned in front of the recording head 15 in a plan view. Good. A partition plate or a baffle plate may be provided in the case 20 so that airflows supplied by cooling fans whose rotation directions are opposite to each other do not collide with each other.

  In the embodiment, the cooling fan is not disposed above the recording head 15. However, a cooling fan may be disposed above the recording head 15. For example, as shown in FIG. 6, a cooling fan 45 is disposed above the recording head 15, an upper opening 58 is formed in an upper portion of the cooling fan 45 on the upper wall of the case 20, and an irradiation device on the lower wall of the case 20 Lower openings 59 and 60 may be formed on the left and right sides of 32-35. The cooling fan 45 may be configured to suck in air from above and blow out downward, or may be configured to suck in air from below and blow out upward. When the cooling fan 45 is configured to suck air from above and blow down downward, the air sucked into the case 20 from the upper opening 58 flows, for example, around the irradiation devices 32 to 35 and then the front opening. 53, the lower openings 59 and 60 are discharged. In this case, the air blown by the cooling fan 45 can be guided to the four irradiation devices 32 to 35, and the four irradiation devices 32 to 35 can be cooled by the air blown from the cooling fan 45. According to such an example, the space above the recording head 15 can be used as an installation space for the cooling fan 45.

Second Embodiment
The second embodiment is obtained by changing the configuration of the head unit 1 in the printer 100 of the first embodiment. As shown in FIGS. 7 and 8, in the second embodiment, the head unit 1 includes two cases 20, and the recording head 15 is disposed outside the case 20. In the following description, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  The head unit 1 of the present embodiment includes a left case 20 and a right case 20. The left case 20 is fixed to the left portion of the recording head 15, and the right case 20 is fixed to the right portion of the recording head 15. The left case 20 houses three irradiation devices 31, 32, and 33 and two cooling fans 41 and 42. The right case 20 houses three irradiation devices 34, 35, and 36 and two cooling fans 43 and 44.

  First, the internal configuration of the left case 20 will be described. The irradiation device 31 is an example of a side irradiation device, and is disposed on the left side of the recording head 15. The irradiation devices 32 and 33 are an example of a front irradiation device, and are disposed in front of the recording head 15. The irradiation devices 32 and 33 are arranged side by side. The irradiation device 33 is disposed in front of the irradiation device 31. The cooling fan 41 is disposed above the irradiation device 31 and is disposed to the left of the recording head 15 in plan view. The cooling fan 42 is disposed above the two irradiation devices 32 and 33 and is disposed in front of the recording head 15 in plan view. The cooling fan 42 is disposed in front of the cooling fan 41.

  The internal configuration of the left case 20 and the internal configuration of the right case 20 are symmetrical. Next, the internal configuration of the right case 20 will be described. The irradiation device 36 is an example of a side irradiation device, and is disposed on the right side of the recording head 15. The irradiation devices 34 and 35 are an example of a front irradiation device, and are disposed in front of the recording head 15. The irradiation devices 34 and 35 are arranged side by side. The irradiation device 34 is disposed in front of the irradiation device 36. The cooling fan 44 is disposed above the irradiation device 36 and is disposed to the right of the recording head 15 in plan view. The cooling fan 43 is disposed above the two irradiation devices 34 and 35 and is disposed in front of the recording head 15 in a plan view. The cooling fan 43 is disposed in front of the cooling fan 44.

  FIG. 9 is a vertical cross-sectional view showing the internal configuration of the right case 20, and is a cross-sectional view taken along line IX-IX in FIG. Upper openings 56 and 57 are formed in the upper wall 25 of the right case 20, a front opening 53 is formed in the front wall 24, and a right opening 52 is formed in the right wall. The upper opening 56 is located above the cooling fan 43, and the upper opening 57 is located above the cooling fan 44. The front opening 53 is located in front of the radiator 34b of the irradiation device 34 and the radiator 35b of the irradiation device 35. The right opening 52 is located on the right side of the radiator 36b of the irradiation device 36.

  Although illustration is omitted, the left case 20 has a symmetrical shape with the right case 20. An upper opening located above the cooling fan 41 and an upper opening located above the cooling fan 42 are formed in the upper wall of the left case 20. On the front wall of the left case 20, a front opening located in front of the heat radiating body 32 b of the irradiation device 32 and the heat radiating body 33 b of the irradiation device 33 is formed. In the left wall of the left case 20, a left opening is formed that is located to the left of the heat dissipating body 31 b of the irradiation device 31.

  Inside the left case 20 and the right case 20 are formed air passages 20A for guiding the air blown by one cooling fan to two or more irradiation devices, respectively. The arrows in FIG. 9 show an example of the airflow in the air blowing path 20A in the right case 20.

  In this example, the air flowing into the case 20 from the upper opening 56 is blown downward by the cooling fan 43. A part of the air blown out from the cooling fan 43 passes through the periphery of the radiator 34 b to cool the irradiation device 34, and then flows out from the front opening 53. Another part of the air blown out from the cooling fan 43 passes through the periphery of the radiator 35 b to cool the irradiation device 35, and then flows out from the front opening 53. Thus, the air blown by the cooling fan 43 is guided to the two irradiation devices 34 and 35.

  Air that has flowed into the case 20 from the upper opening 57 is blown downward by the cooling fan 44. A part of the air blown out from the cooling fan 44 passes through the periphery of the radiator 36 b to cool the irradiation device 36, and then flows out from the right opening 52. Other part of the air blown out by the cooling fan 44 passes around the radiator 36b to cool the irradiation device 36, and then passes around the radiators 34b and 35b to cool the irradiation devices 34 and 35. And flows out from the front opening 53. Thus, a part of the air blown by the cooling fan 44 is guided to the three irradiation devices 34 to 36. Although the description is omitted, a similar airflow is also formed inside the left case 20.

  Also in the present embodiment, the number of cooling fans 41 and 42 in the left case 20 is smaller than the number of the irradiation devices 31 to 33, and the air blown by one cooling fan is stored in the left case 20. The ventilation path 20A leading to two or more irradiation devices is formed. Also in the right case 20, the number of the cooling fans 43 and 44 is smaller than the number of the irradiation devices 34 to 36, and in the right case 20, two or more pieces of air blown by one cooling fan are irradiated. A ventilation path 20A leading to the apparatus is formed. Therefore, also in the present embodiment, it is possible to reduce the number of cooling fans while securing the air blowing to each of the irradiation devices 31 to 36. Therefore, the improvement of the cooling efficiency of the irradiation apparatuses 31-36 and the miniaturization of the whole cooling fans 41-44 can be made compatible. In the present embodiment, the right case 20 and the left case 20 have a bilaterally symmetric shape in plan view, but it is not necessary to have a bilaterally symmetric shape.

  According to this embodiment, since the recording head 15 is not disposed in the case 20, each case 20 can be reduced in size while obtaining the above-described effects. Therefore, as compared with the first embodiment, the entire head unit 1 can be reduced in size and weight.

  In the present embodiment, the above-described airflow is only an example, and the form of the airflow in the air blowing path 20A is not limited at all. In the present embodiment, all the cooling fans 41 to 44 are configured to suck air from above and blow downward, but some or all of the cooling fans 41 to 44 suck air from below and upward. You may be comprised so that it may blow out. The rotation direction of a part of the cooling fans 41 to 44 and the other part may be reversed.

  As shown in FIG. 7, in the present embodiment, in the left case 20, one side irradiation device 31 is disposed on the left side of the recording head 15, and two front irradiation devices 32 are provided in front of the recording head 15. 33 was arranged. In the right case 20, one side irradiation device 36 is disposed to the right of the recording head 15, and two front irradiation devices 34 and 35 are disposed in front of the recording head 15. However, in the left case 20, two side irradiation devices may be arranged on the left side of the recording head 15, and one front irradiation device may be arranged in front of the recording head 15. In the right case 20, two side irradiation devices may be arranged on the right side of the recording head 15, and one front irradiation device may be arranged in front of the recording head 15.

1 Head unit 3 Grid roller (feed mechanism)
15 Recording Head 20 Case 20A Blower Path 21 Carriage 31, 36 Irradiation Device (Side Irradiation Device)
32-35 Irradiation device (front irradiation device)
31a to 36a Light source 31b to 36b Radiator 41 to 44 Cooling fan 100 Inkjet printer (inkjet recording apparatus)

Claims (2)

A recording head that discharges ink that cures when irradiated with light onto a recording medium;
A plurality of irradiation devices for irradiating the ink on the recording medium with light;
A case for accommodating at least substantially the whole of the plurality of irradiation devices;
One or more cooling fans disposed in the case;
A carriage that moves the recording head, the irradiation device, the cooling fan, and the case to the left and right;
A feed mechanism for moving the recording medium forward relative to the recording head;
With
The number of cooling fans in the case is less than the number of irradiation devices,
In the case, a blowing path is formed for guiding the air blown by one cooling fan to two or more irradiation devices,
The irradiation device includes a side irradiation device arranged on the left or right side of the recording head, and a front irradiation device arranged in front of the recording head,
The irradiation intensity of the side irradiation device is higher than the irradiation intensity of the front irradiation device,
The ink jet recording apparatus, wherein the air supply path is configured such that an air supply amount per unit time for the side irradiation device is larger than an air supply amount per unit time for the front irradiation device. A recording head that discharges ink that cures when irradiated with light onto a recording medium;
A plurality of irradiation devices for irradiating the ink on the recording medium with light;
A case for accommodating at least substantially the whole of the plurality of irradiation devices;
One or more cooling fans disposed in the case;
A carriage that moves the recording head, the irradiation device, the cooling fan, and the case to the left and right;
A feed mechanism for moving the recording medium forward relative to the recording head;
With
The number of cooling fans in the case is less than the number of irradiation devices,
In the case, a blowing path is formed for guiding the air blown by one cooling fan to two or more irradiation devices,
The irradiation device includes a side irradiation device arranged on the left or right side of the recording head, and a front irradiation device arranged in front of the recording head,
The irradiation intensity of the front irradiation device is higher than the irradiation intensity of the side irradiation device,
The ink jet recording apparatus, wherein the air supply path is configured such that an air supply amount per unit time for the front irradiation device is larger than an air supply amount per unit time for the side irradiation device.

Images