Patent Application
20160250884
The present invention relates to a pressure fluctuation buffering mechanism and an applicator.
Applicators (for example, fountain pens) each including an ink tank for accommodating ink have been known in the art. Various problems occur when pressure fluctuation is generated in the ink tank due to variations in the environmental conditions (such as pressure or ambient temperature) under which such an applicator is used. For example, if pressure in the ink tank is increased, the ink leaks from a nib. If pressure in the ink tank is decreased, on the other hand, the ink has difficulty in being discharged from the nib.
To solve such a problem, a writing instrument having a pressure fluctuation buffering mechanism including: a comb groove for retaining ink; an ink flow groove provided perpendicular to the comb groove; and an air flow groove provided perpendicular to the comb groove to solve the problem caused by pressure fluctuation in an ink tank has been known in the art (for example, Japanese Examined Utility Model Application Publication No. Sho. 62-028458).
However, the buffering ability of the pressure fluctuation buffering mechanism provided in the writing instrument described in the aforementioned literature has limitations.
Diligent studies made by the present inventor have led to the acquisition of knowledge that a shorter length of the pressure fluctuation buffering mechanism in an axial direction (direction moving from the ink tank toward the nib) is preferred, the largest possible thickness of the pressure fluctuation buffering mechanism is preferred, and the fulfillment of both is more preferred in order to enhance the buffering ability of the pressure fluctuation buffering mechanism as much as possible. To derive the highest possible buffering ability of the pressure fluctuation buffering mechanism, however, the shape of the whole writing instrument becomes short and thick. Such a short and thick writing instrument is hard to be gripped, and therefore impractical to use.
An ink guiding core for feeding ink from the ink tank to the nib is inserted into the pressure fluctuation buffering mechanism provided in the aforementioned writing instrument (for example, the aforementioned literature). However, the inserting structure of the ink guiding core disturbs the flow performance of the ink guiding core. Due to the disturbance of the flow performance of the ink guiding core, the pressure fluctuation buffering mechanism fails to exert the desired performance.
The diligent studies made by the present inventor have led to the acquisition of knowledge that at least one of (i) and (ii) described below is required to ensure the flow performance of the ink guiding core.
(i) To separate a guiding core holding structure that holds the ink guiding core for feeding ink from the ink tank to the nib from the pressure fluctuation buffering mechanism.
(ii) To facilitate the flow of ink and air between the ink tank and the ink guiding core.
In light of such circumstances, an object of the present invention is to provide a pressure fluctuation buffering mechanism having an extremely high ability to buffer pressure fluctuation and capable of maintaining its practicality even when applied to a writing instrument, for example.
Furthermore, an object of the present invention is to provide a pressure fluctuation buffering mechanism capable of ensuring the flow performance of an ink guiding core. Additionally, an object of the present invention is to provide an applicator including such a pressure fluctuation buffering mechanism.
Owing to the diligent researches made by the present inventor, the above-described objects can be achieved by the following means.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes: a first buffer space forming member for forming a first buffer space in the buffer space; and a second buffer space forming member for forming a second buffer space in the buffer space. The paint between the first buffer space and the paint flow space flows more easily than the paint between the second buffer space and the paint flow space.
Preferably, the second buffer space is directly connected to the application member.
Preferably, the first buffer space forming member includes a first paint flow channel forming member disposed in the first buffer space for forming a first paint flow channel, and a first air flow channel forming member disposed in the first buffer space for forming a first air flow channel; the second buffer space forming member includes a second paint flow channel forming member disposed in the second buffer space for forming a second paint flow channel, and a second air flow channel forming member disposed in the second buffer space for forming a second air flow channel; and the paint in the first paint flow channel flows more easily than the paint in the second paint flow channel. Moreover, the pressure fluctuation buffering mechanism preferably includes a plurality of first plates each provided with a first paint cutout and arranged at predetermined intervals, and a plurality of second plates each provided with a second paint cutout and arranged at predetermined intervals; the first paint flow channel is preferably formed by a portion between the first plates and the first paint cutout; the first air flow channel is preferably formed around the first plate; the second paint flow channel is preferably formed by a portion between the second plates and the second paint cutout; and the second air flow channel is preferably formed around the second plate. Furthermore, the plurality of first plates are preferably each provided with a first air cutout, and the first air cutout preferably forms the first air flow channel. Additionally, the second paint flow channel is preferably opened to the application member. Further, the second buffer space forming member preferably includes an external connection channel for connecting the second air flow channel to an external space, and a paint reserving portion provided in the external connection channel for reserving the paint.
Preferably, the paint flow space includes a paint accommodation space for accommodating the paint, and a paint feed space for feeding the paint from the paint accommodation space to the application member; the first buffer space forming member includes a first connection channel for connecting between the first buffer space and the paint feed space; and the second buffer space forming member includes a second connection channel for connecting between the second buffer space and the paint feed space. Moreover, the second connection channel is preferably positioned between the first connection channel and the application member. Furthermore, the paint feed space preferably accommodates a paint feed core for feeding the paint from the paint accommodation space to the application member. Additionally, at least one of the first buffer space and the second buffer space is preferably provided with an air reserving portion; and the air reserving portion is preferably opposed to the first connection channel via the first paint flow channel formed in the first buffer space or opposed to the second connection channel via the second paint flow channel formed in the second buffer space. Further, the first connection channel opposed to the air reserving portion or the second connection channel opposed to the air reserving portion preferably functions as a flow channel for the air as well as a flow channel for the paint.
Preferably, the paint flow space includes a paint accommodation space for accommodating the paint, and a paint feed space for feeding the paint from the paint accommodation space to the application member; and the first buffer space and the second buffer space are positioned in the paint feed space.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The buffer space is directly connected to the application member.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes a buffer space forming member for forming the buffer space. The buffer space forming member includes: an external connection channel for connecting an air flow channel formed in the buffer space to an external space; and a paint reserving portion provided in the external connection channel for reserving the paint.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes a buffer space forming member for forming the buffer space. The paint flow space includes: a paint accommodation space for accommodating the paint; and a paint feed space for feeding the paint from the paint accommodation space to the application member. The buffer space forming member includes a connection channel for connecting between the buffer space and the paint feed space. The buffer space is provided with an air reserving portion. The air reserving portion is opposed to the connection channel via a paint flow channel formed in the buffer space.
The connection channel opposed to the air reserving portion preferably functions as a flow channel for the air as well as a flow channel for the paint.
A pressure fluctuation buffering mechanism of the present invention includes: a feed core supporting structure for supporting a first core portion of a paint feed core for feeding paint from a paint accommodation space to an application member; a feed core locking structure for locking a second core portion of the paint feed core; and a pressure fluctuation buffering structure, including a buffer space connected to the paint accommodation space, for buffering pressure fluctuation in the paint accommodation space by flow of the paint and air between the paint accommodation space and the buffer space. The pressure fluctuation buffering structure is formed in the feed core supporting structure.
A communicating channel for connecting between a portion of the paint feed core closer to the application member than the second core portion and the paint accommodation space is preferably included.
A pressure fluctuation buffering mechanism of the present invention includes: a feed core supporting structure for supporting a first core portion of a paint feed core for feeding paint from a paint accommodation space to an application member; a feed core locking structure for locking a second core portion of the paint feed core; and a pressure fluctuation buffering structure, including a buffer space connected to the paint accommodation space, for buffering pressure fluctuation in the paint accommodation space by flow of the paint and air between the paint accommodation space and the buffer space. The pressure fluctuation buffering mechanism includes a communicating channel for connecting between a portion of the paint feed core closer to the application member than the second core portion and the paint accommodation space.
A connecting structure disposed between the feed core supporting structure and the feed core locking structure for connecting between the feed core supporting structure and the feed core locking structure is preferably included. Moreover, the feed core supporting structure is preferably a cylindrical body for accommodating the first core portion; the connecting structure preferably extends from an end face of the cylindrical body closer to the paint accommodation space toward the paint accommodation space; and the feed core locking structure is preferably provided on the paint accommodation space-side of the connecting structure.
The feed core locking structure is preferably positioned in the paint accommodation space. Moreover, the feed core supporting structure and the feed core locking structure are preferably formed integrally. Furthermore, the feed core locking structure preferably includes a fit portion to be fit to the second core portion. Additionally, the feed core locking structure preferably includes a press-fit portion into which the second core portion is press-fit. Furthermore, the feed core locking structure preferably includes a weld portion to be welded with the second core portion.
The second core portion is preferably positioned in the paint accommodation space. Moreover, a portion closer to the paint accommodation space than the second core portion is preferably positioned in the paint accommodation space.
Preferably, a paint flow channel and an air flow channel are formed in the buffer space; the pressure fluctuation buffering structure includes a plurality of plates each provided with a paint cutout and an air cutout and arranged in the buffer space at predetermined intervals; the paint flow channel is formed by the paint cutout; and the air flow channel is formed by the air cutout.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes a buffer space forming member for forming the buffer space. The paint flow space includes: a paint accommodation space for accommodating the paint; and a paint feed space for feeding the paint from the paint accommodation space to the application member. The buffer space forming member includes: an application member-side wall member for forming a wall of the buffer space closer to the application member; a paint accommodation space-side wall member for forming a wall of the buffer space closer to the paint accommodation space; a paint flow channel forming member disposed between the application member-side wall member and the paint accommodation space-side wall member for forming a paint flow channel in the buffer space; and an air flow channel forming member disposed between the application member-side wall member and the paint accommodation space-side wall member for forming an air flow channel in the buffer space. A buffering space communicated with the air flow channel is formed between the paint accommodation space-side wall member and the paint flow channel forming member.
The present invention provides a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes: a stopper mechanism for preventing, when the pressure fluctuation buffering mechanism is inserted into a cylinder, prevention of coming off from the cylinder due to its deformation; and an airtight mechanism for providing airtightness to the buffer space. A clearance space is formed between the stopper mechanism and the airtight mechanism, and the airtight mechanism and the stopper mechanism in a deformed state are apart from each other by the clearance space.
There is provided a pressure fluctuation buffering mechanism, including a buffer space connected to an application member via a paint flow space through which paint flows, for buffering pressure fluctuation in the paint flow space by flow of paint and air between the paint flow space and the buffer space. The pressure fluctuation buffering mechanism includes an air hole for opening the buffer space to an external space. The air hole directly faces a paint reserving space for reserving the paint.
An applicator of the present invention includes the above-described pressure fluctuation buffering mechanism.
The present invention can provide a pressure fluctuation buffering mechanism having an extremely high ability to buffer pressure fluctuation and capable of maintaining its practicality even when applied to a writing instrument, for example, as well as an applicator less likely to generate paint leakage due to pressure fluctuation. Moreover, the present invention can provide a pressure fluctuation buffering mechanism capable of ensuring the flow performance of an ink guiding core and an applicator including such a pressure fluctuation buffering mechanism.
An embodiment of the present invention will be described below with reference to the accompanying drawings.
As shown in
The cap 200 includes: an outer cap 210; an inner cap 220 disposed inside the outer cap 210; and an inner cap spring 230 disposed inside the outer cap 210 for biasing the inner cap 220. The outer cap 210 and the inner cap 220 are each made of a synthetic resin such as polypropylene (PP).
An engagement projection 211 is provided on the inner peripheral surface of the outer cap 210. The engagement projection 211 engages with a tip 221 of the inner cap 220. In the internal space of the outer cap 210, the inner cap 220 is movable between an engaged position at which the tip 211 engages with the engagement projection 211 and an unengaged position at which the tip 211 is separated from the engagement projection 211. In the internal space of the outer cap 210, the inner cap spring 230 is disposed between the inner peripheral surface of the outer cap 210 and the outer peripheral surface of the inner cap 220. The inner cap spring 230 biases the inner cap 220 toward the engaged position.
As shown in
The inner barrel 110 is formed in a cylindrical shape. An engagement projection 111 is formed on the outer peripheral surface of a midway portion 110C of the inner barrel 110 in an axial direction A. The engagement projection 111 engages with an open end of the cap 200 and an open end of the outer barrel 190. A front-side cylindrical portion 110F of the inner barrel 110 has a smaller outer diameter toward the front side thereof, thereby achieving a shape easier to grip with fingers. A rear-side cylindrical portion 110B of the inner barrel 110, on the other hand, has a substantially constant diameter from its front side to its rear side.
The paint tank 140 accommodates paint. Examples of the paint include ink used for writing instruments and liquid eye liners. Examples of the ink used for writing instruments include raw ink (the viscosity thereof is 10 poise or less, for example), gel ink (the viscosity thereof is in a range of 100 poise to 3,000 poise, for example), and high-viscosity ink (the viscosity thereof is in a range of 10,000 poise to 100,000 poise, for example). Examples of the liquid eye liner include oil-based type, water-based film type, and water-based non-film type liquid eye liners.
The paint tank 140 includes: an end cylinder 141 having openings at both sides; and an end cap 142 for closing the opening of the end cylinder 141 on the rear end side. The opening of the end cylinder 141 on the front end side is attached to the opening of the inner barrel 110 on the rear end side. The end cap 142 is detachably attached to the end cylinder 141, thus allowing for paint refill into the paint tank 140 by detachment and attachment operations of the end cap 142.
The agitating member 150 is accommodated in the paint tank 140 together with the paint. Thus, shaking the applicator 2 in the axial direction A can cause the agitation of the paint in the paint tank 140. Note that the agitating member 150 may have any shape such as a spherical body or a polyhedron (for example, a cube or a rectangular solid). The agitating member 150 may be omitted depending on a type of the paint used.
As shown in
The brush holding member 130 is formed in a cylindrical shape. The brush holding member 130 includes: a brush engagement portion 131 to engage with the base side of the brush 120 on the inner peripheral surface thereof; and an inner barrel engagement portion 132 to engage with the inner barrel 110 on the outer peripheral surface thereof. This allows the brush holding member 130 to hold the brush 120 on the front end side of the inner barrel 110.
The paint feeder 160 is formed in a rod shape and extends from the internal space of the paint tank 140 to the brush 120. The paint feeder 160 includes: a middle rod portion 160C; a front rod portion 160F extending from an end of the middle rod portion 160C closer to the brush 120; and a rear rod portion 160B extending from an end of the middle rod portion 160C closer to the paint tank 140. It is preferable that the front rod portion 160F and the rear rod portion 160B have pointed tips. The tip of the front rod portion 160F goes into the brush 120 and the tip of the rear rod portion 160B is exposed in the internal space of the paint tank 140. This allows the paint feeder 160 to feed the paint accommodated in the paint tank 140 to the brush 120. Any type of paint feeder, such as an ink absorber type in which ink is retained in a material such as a sponge, a porous material made of urethane, or a filling material made of a bundle of fibers, or a raw ink type in which ink is directly accommodated in an ink tank, may be used as the paint feeder 160.
As shown in
As described above, the main body cylindrical portion 170T functions as a supporting mechanism of the paint feeder 160 (feed core supporting structure) to accommodate the paint feeder 160. Moreover, the locking portion 170B functions as a locking mechanism of the paint feeder 160 (feed core locking structure) to lock a rear end portion of the paint feeder 160. The extended portion 170S functions as a connecting structure for connecting between the supporting mechanism of the paint feeder 160 and the locking mechanism of the paint feeder 160.
The inner barrel 110, the brush holding member 130, the paint tank 140, and the outer barrel 190 are each made of a synthetic resin such as polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), nylon, polyester, or acrylic, for example.
As shown in
The buffer space forming members 181 are arranged in the paint feeder holding cylinder 170 with a predetermined interval therebetween in the axial direction A. For example, one of the buffer space forming members 181 is provided in a front end portion 170F of the paint feeder holding cylinder 170 (a front end portion of the main body cylindrical portion 170T), whereas the other one of the buffer space forming members 181 is provided in a midway portion 170C of the paint feeder holding cylinder 170 (a rear end portion of the main body cylindrical portion 170T). Each buffer space forming member 181 erects from the outer peripheral surface of the paint feeder holding cylinder 170 and extends toward the inner peripheral surface of the inner barrel 110. In this manner, the buffer space K is formed over an area from the outer peripheral surface of the paint feeder holding cylinder 170 to the inner peripheral surface of the inner barrel 110 between at least the two buffer space forming members 181.
The separating member 182 is provided in the paint feeder holding cylinder 170 between the front-side buffer space forming member 181 and the rear-side buffer space forming member 181. The separating member 182 erects from the outer peripheral surface of the paint feeder holding cylinder 170 and extends toward the inner peripheral surface of the inner barrel 110. The separating member 182 separates the buffer space K into the first buffer space K1 and the second buffer space K2.
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
Incidentally, the intimate contact with the inner peripheral surface of the inner barrel 110 causes the stopper portion 170R to deform. Such deformation of the stopper portion 170R contributes to the prevention of the coming off of the stopper portion 170R from the inner barrel 110. When the stopper portion 170R and the airtight portion 170E are integrally formed, however, the deformation of the stopper portion 170R has an adverse effect on airtightness obtained by the airtight portion 170E. To solve such a problem, a clearance void ER may be provided between the stopper portion 170R and the airtight portion 170E (see
As shown in
Furthermore, paint cutouts 184TB are provided in the plurality of second protruded plates 184T (see
The second paint communicating groove 184B is apart from the first paint communicating groove 183B. The separating member 182 is positioned between the second paint communicating groove 184B and the first paint communicating groove 183B. In other words, the separating member 182 keeps the second paint communicating groove 184B and the first paint communicating groove 183B away from each other.
As shown in
Note that the plurality of second protruded plates 184T may be provided with air cutouts 184TA (see
As shown in
As shown in
Moreover, the width W183S of the first circumferential groove 183S is smaller than the width W184S of the second circumferential groove 184S. Thus, paint inflow due to the capillary force occurs more easily in the first circumferential groove 183S than in the second circumferential groove 184S.
The paint feeder holding cylinder 170 and the pressure fluctuation buffering mechanism 180 are each made of a synthetic resin. When water paint is used, examples of the synthetic resin preferably used include an ABS resin, an AS resin, a PET resin, a PBT resin, a styrene resin, a POM resin, polycarbonate, polyamide, and modified polyphenylene ether. Alternatively, when oil paint (in particular, paint using alcohol as a prime solvent) is used, examples of the synthetic resin preferably used include a PE resin, a PP resin, a POM resin, a PET resin, a PBT resin, and polyamide.
Functions of the present invention will be described next.
As described above, the width W183S of the first circumferential groove 183S is smaller than the width W184S of the second circumferential groove 184S. Thus, the inflow of the paint occurs easily in the first buffer space K1 prior to the second buffer space K2. The outflow of the paint occurs easily in the second buffer space K2 prior to the first buffer space K1. Thus, when pressure in the paint tank 140 (see
To make the inflow of the paint due to the capillary force more likely to occur in the first circumferential groove 183S prior to the second circumferential groove 184S, the width W183S of the first circumferential groove 183S is made smaller than the width W184S of the second circumferential groove 184S in the above-described embodiment. However, the present invention is not limited thereto. It is only required that the paint flows more easily in the first buffer space K1 than in the second buffer space K2. A specific example may employ the width W183TB of the paint cutout 183TB smaller than the width W184TB of the paint cutout 184TB, the first buffer space K1 having higher paint wettability than the second buffer space K2, or a combination of these.
As shown in
Although the separating member 182 separates the buffer space K, the first buffer space K1, and the second buffer space K2 in the above-described embodiment, the present invention is not limited thereto. Any separating structure capable of separating the buffer space K into the first buffer space K1 and the second buffer space K2 may be employed.
As shown in
One example of such a separating structure is a structure in which the front-end-side opening of the first paint communicating groove 183B in the first buffer space K1 is apart from the rear-end-side opening of the second paint communicating groove 184B in the second buffer space K2. An interval between these two openings may be just enough to prevent the generation of the capillary force between the two openings. Moreover, the positional relationship between these two openings may be either a positional relationship directly facing each other in the axial direction A or a positional relationship departed therefrom. Furthermore, when the interval between these two openings is just enough to prevent the generation of the capillary force between the two openings, the separating member 182 may be omitted.
Note that a gap (hereinafter referred to as a first gap) WX1 between the tip surface (outer peripheral surface) of the first protruded plate 183T and the inner peripheral surface of the inner barrel 110 is preferably larger than the width W183TB of the paint cutout 183TB as shown in
Note that the second gap WX2 is preferably larger than the first gap WX1. In such a case, paint flow is reduced in the second buffer space K2 as compared to the first buffer space K1.
Incidentally, when pressure is increased in the paint tank 140, the paint flows in to the first connection channel 185 and the first circumferential groove 183S. When such increase in pressure is rapid, however, the paint may be attached to an inner wall of the inner barrel 110 via the first connection channel 185 and the first circumferential groove 183S. The paint attached to the inner wall of the inner barrel 110 flows along the inner wall, thus leading to the paint leakage. To prevent such paint leakage, an air reservoir KA1 is preferably formed in the first buffer space K1 as shown in
As shown in
Here, the front end gap 192X preferably has a crank structure 192XC capable of reserving the paint. The paint having flowed to the connection hole 192A from the second buffer space K2 can be retained by the crank structure 192XC while air flow between the second buffer space K2 and the external space is maintained by the crank structure 192XC.
Although the crank structure 192XC is used as a paint reserving portion for reserving the paint, the present invention is not limited thereto. Any structure capable of reserving the paint may be used.
Incidentally, when the cap 200 is attached to the applicator body 100 as shown in
The cap 200 of the applicator 2 includes the inner cap 220 and the inner cap spring 230. Thus, when the cap 200 is attached to the applicator body 100, the inner cap 220 transitions from an unengaged state to an engaged state while resisting the biasing force of the inner cap spring 230. Thus, pressure increase in the paint tank 140 can be made gradual in an attachment operation of the cap 200. This can prevent paint leakage due to the attachment operation of the cap 200.
As shown in
The paint feeder holding cylinder 170 includes the paint tank communicating channel 170TX. The paint tank communicating channel 170TX allows for the flow of the paint and air between the paint feeder 160 and the paint tank 140. Therefore, part of the rear rod portion 160B held by the paint feeder holding cylinder 170 is preferably positioned in the paint tank 140. Furthermore, such part is preferably exposed in the paint tank 140. The flow of the paint and air occurs between the part exposed in the paint tank 140 and the paint tank 140 without the intervention of the pressure fluctuation buffering mechanism. In this manner, since the present invention can facilitate the flow of the paint and air between the paint tank 140 and the paint feeder 160, the desired pressure fluctuation buffering function can be exerted.
Although the locking portion 170B (see
Moreover, the width W183S of the first circumferential groove 183S is smaller than the width W184S of the second circumferential groove 184S. Thus, the inflow of the paint occurs easily in the first buffer space K1 prior to the second buffer space K2. The outflow of the paint occurs easily in the second buffer space K2 prior to the first buffer space K1. Thus, when pressure in the paint tank 140 (see
To make the inflow of the paint due to the capillary force more likely to occur in the first circumferential groove 183S prior to the second circumferential groove 184S, the width W183S of the first circumferential groove 183S is made smaller than the width W184S of the second circumferential groove 184S in the above-described embodiment. However, the present invention is not limited thereto. It is only required that the paint flows more easily in the first buffer space K1 than in the second buffer space K2. A specific example may employ the width W183TB of the paint cutout 183TB smaller than the width W184TB of the paint cutout 184TB, the first buffer space K1 having higher paint wettability than the second buffer space K2, or a combination of these.
As shown in
Although the separating member 182 separates the buffer space K, the first buffer space K1, and the second buffer space K2 in the above-described embodiment, the present invention is not limited thereto. Any separating structure capable of separating the buffer space K into the first buffer space K1 and the second buffer space K2 may be employed.
Although the separating member 182 is used in the above-described embodiment to separate the buffer space K, the first buffer space K1, and the second buffer space K2, the present invention is not limited thereto. The separating member 182 may be omitted to provide a paint flow channel and an air flow channel in one buffer space K.
As shown in
One example of such a separating structure is the structure in which the front-end-side opening of the first paint communicating groove 183B in the first buffer space K1 is apart from the rear-end-side opening of the second paint communicating groove 184B in the second buffer space K2. The interval between these two openings may be just enough to prevent the generation of the capillary force between the two openings. Moreover, the positional relationship between these two openings may be either a positional relationship directly facing each other in the axial direction A or a positional relationship departed therefrom. Furthermore, when the interval between these two openings is just enough to prevent the generation of the capillary force between the two openings, the separating member 182 may be omitted.
Note that the gap (hereinafter referred to as the first gap) WX1 between the tip surface (outer peripheral surface) of the first protruded plate 183T and the inner peripheral surface of the inner barrel 110 is preferably larger than the width W183TB of the paint cutout 183TB as shown in
Note that the second gap WX2 is preferably larger than the first gap WX1. In such a case, paint flow is reduced in the second buffer space K2 as compared to the first buffer space K1.
Incidentally, when pressure is increased in the paint tank 140, the paint flows in to the first connection channel 185 and the first circumferential groove 183S. When such increase in pressure is rapid, however, the paint may be attached to the inner wall of the inner barrel 110 via the first connection channel 185 and the first circumferential groove 183S. The paint attached to the inner wall of the inner barrel 110 flows along the inner wall, thus leading to the paint leakage. To prevent such paint leakage, the air reservoir KA1 is preferably formed in the first buffer space K1 as shown in
As shown in
Here, the front end gap 192X preferably has the crank structure 192XC capable of reserving the paint. The paint having flowed to the connection hole 192A from the second buffer space K2 can be retained by the crank structure 192XC while air flow between the second buffer space K2 and the external space is maintained by the crank structure 192XC.
Although the crank structure 192XC is used as the paint reserving portion for reserving the paint, the present invention is not limited thereto. Any structure capable of reserving the paint may be used.
Incidentally, when the cap 200 is attached to the applicator body 100 as shown in
The cap 200 of the applicator 2 includes the inner cap 220 and the inner cap spring 230. Thus, when the cap 200 is attached to the applicator body 100, the inner cap 220 transitions from the unengaged state to the engaged state while resisting the biasing force of the inner cap spring 230. Thus, pressure increase in the paint tank 140 can be made gradual in the attachment operation of the cap 200. This can prevent paint leakage due to the attachment operation of the cap 200.
Furthermore, a buffer groove 170M is formed between the rear-side buffer space forming member 181 and the first protruded plate 183T as shown in
The applicator of the present invention may be any of writing instruments (for example, ink pens, calligraphy pens, fountain pens, and the like) and makeup tools as long as it can apply paint to a predetermined object.
Incidentally, for fountain pens, there is no paint feeder 160 (see
As shown in
Note that the present invention is not limited to the above-described embodiments. It will be appreciated that various modifications are possible without departing from the scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2013-218159 | Oct 2013 | JP | national |
| 2013-242610 | Nov 2013 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2014/076111 | 9/30/2014 | WO | 00 |
