The present invention relates to a filter for cigarette product and a cigarette product.
In a filtered cigarette product, which is one of cigarette products such as a cigarette, an electronic cigarette, and a snuff, methods of changing the fragrance inhaling taste have been known, such as a method of placing an aroma capsule filled with aroma inside the filter (see Patent Document 1, for example), and a method of controlling the amount of air that dilutes mainstream smoke.
[Patent document 1] National Publication of International Patent Application No. 2007-520204
However, when placing the aroma capsule inside the filter, the fragrance inhaling taste is changed by crushing the aroma capsule. This is based on the premise that the aroma delivery amount is changed. Also, after crushing the aroma capsule, it is difficult to bring back the original fragrance inhaling taste. Additionally, while the fragrance inhaling taste changes by controlling the rate (ventilation rate) of air introduced into mainstream smoke through ventilation holes in a tipping paper, this is based on the premise that the amounts of tar and nicotine are changed. Also, this method is not effective in changing the fragrance inhaling taste while smoking according to the smoker's preference. The present invention has been made in view of the above problems, and aims to provide a filter for cigarette product and a technique related to a cigarette product that can reversibly change the fragrance inhaling taste at an arbitrary timing.
To solve the above problems, in a mouthpiece end side-filter material of the present invention arranged on the mouthpiece end side of a filter, a low air flow-resistance (pressure drop) unit is arranged in a part of the cross section, and a high air flow-resistance unit is arranged in the remainder of the cross section. At least in a rear end surface of the mouthpiece end side-filter material, the low air flow-resistance unit is arranged only in one semicircular area, of two parts into which the cross section of the mouthpiece end side-filter material is divided.
More specifically, as a first aspect of the present invention, provided is a filter for cigarette product including: a mouthpiece end side-filter material that is arranged on the mouthpiece end side; and a front stage-filter material that is arranged at the front stage of the mouthpiece end side-filter material and filters mainstream smoke, in which: the mouthpiece end side-filter material has a low air flow-resistance unit that is arranged in a part of a cross section from a front end surface to a rear end surface and having a relatively low air flow-resistance, and a high air flow-resistance unit that is arranged in the remainder of the cross section from the front end surface to the rear end surface and having a higher air flow-resistance than the low air flow-resistance unit; and at least on the rear end surface of the mouthpiece end side-filter material, the low air flow-resistance unit is arranged only in one semicircular area, of two parts into which the cross section of the mouthpiece end side-filter material is divided. The present invention can provide a filter for cigarette product that can change the part where the mainstream smoke sucked into the mouth cavity hits, by rotating the filter around the longitudinal axis of the filter by the smoker.
Here, a hollow cavity unit may be provided between the front stage-filter material and the mouthpiece end side-filter material. Thus, it is possible to avoid partial obstruction of the flow of the mainstream smoke in the cross section of the front stage-filter material, when the mainstream smoke passes through the front stage-filter material. Accordingly, it is possible to effectively use the entire section (entire cross section) of the front stage-filter material as a filtering medium of smoke constituents (components).
Also, the high air flow-resistance unit may be formed of a single material. This can reduce the number of steps in the manufacturing process of the filter as compared to forming the high air flow-resistance unit with multiple materials, whereby manufacturing cost can be reduced.
Also, in the mouthpiece end side-filter material, an upstream unit and a downstream unit respectively positioned on the front end side and the rear end side of an intermediate unit, which is positioned between the front end surface and the rear end surface, may be freely rotatable relative to each other. In this case, a slit that is formed in the intermediate unit of the mouthpiece end side-filter material and cut in while leaving a center part of the cross section of the mouthpiece end side-filter material may allow the upstream unit and the downstream unit to freely rotate relative to each other. Accordingly, by rotating the upstream unit and the downstream unit of the mouthpiece end side-filter material relative to each other, the linear velocity of the mainstream smoke flowing into the mouth cavity of the smoker from the mouthpiece end of the filter can be changed. Hence, the intensity of stimulation sensed when smoking can be changed.
Also, the low air flow-resistance unit may be a hollow unit formed from the front end surface to the rear end surface of the mouthpiece end side-filter material. When the low air flow-resistance unit is formed of a hollow unit, the filtering of smoke in the hollow unit is eliminated, whereby the flow of smoke is more easily decentered in a more distinctive manner. Additionally, since the filtering of smoke in the hollow unit is eliminated, it is easier to control the delivery amount of smoke constituents. As a result, this facilitates assurance of values on product labels, for example. Also, identification unit that allows a smoker to identify a position of the low air flow-resistance unit, which is arranged in a decentered manner in the cross section of the mouthpiece end side-filter material, may be provided on an outer peripheral surface of the filter. Hence, the smoker can easily identify the position of the low air flow-resistance unit arranged in a decentered manner in the mouthpiece end side-filter material based on the identification unit. This makes it easier to change the fragrance inhaling taste of the cigarette product when smoking. Also, the mouthpiece end side-filter may be a polygon. The present invention may also be specified as a cigarette product including any of the aforementioned filters for cigarette product.
Note that means for solving the problem of the invention may be adopted in any possible combination.
The present invention can provide a filter for cigarette product and a cigarette product that can reversibly change the fragrance inhaling taste at an arbitrary timing.
Hereinafter, embodiments of a filter for cigarette product of the present invention will be described in detail with reference to the drawings. Dimensions, materials, shapes, relative arrangements and the like of components described in the embodiments do not limit the technical scope of the invention, if not particularly stated otherwise.
The cigarette rod 2 is formed into a columnar shape (bar shape) by wrapping tobacco shreds 21 in a cigarette paper 22, and is also referred to as “single roll.” The filter 4 is a member for filtering out smoke constituents contained in mainstream smoke, when allowing passage of the mainstream smoke generated at the time of smoking of the cigarette 1. The filter is formed into a columnar shape having substantially the same diameter as the cigarette rod 2.
The filter 4 is a fragrance inhaling taste-variable filter that can reversibly change the fragrance inhaling taste of the cigarette 1 at any timing while smoking. The filter 4 is wrapped in the tipping paper 3, and is connected to the rear end side of the cigarette rod 2 through the tipping paper 3. The tipping paper 3 wraps together the end part of the cigarette rod 2 and the filter 4, to thereby connect (join) the parts. Hereinafter, in the longitudinal direction (axial direction) of the filter 4, an end part connected to the cigarette rod 2 is referred to as a “front end,” and an end part opposite to the front end is referred to as a “mouthpiece end (rear end).” A section of the filter 4 cut along the longitudinal direction (axial direction) is defined as a “longitudinal section,” and a section cut along a direction orthogonal thereto is defined as a “cross section.” Reference sign CL in
In the filter 4, a front stage-filter material 41, a cavity unit 42, and a mouthpiece end side-filter material 43 are arranged in this order from the front end side. The cavity unit 42 is a hollow space, and is arranged between the front stage-filter material 41 and the mouthpiece end side-filter material 43.
The front stage-filter material 41 is a filter material in which a cellulose acetate fiber bundle formed into a columnar shape is wrapped with wrapping paper. Note, however, that the front stage-filter material 41 of the embodiment is not limited to the cellulose acetate fiber bundle, and various materials may be used. For example, the front stage-filter material 41 may include an adsorbent (e.g., activated carbon) that adsorbs smoke constituents of mainstream smoke, or other additives. Additionally, other than the filtering of the mainstream smoke, the front stage-filter material 41 may be configured to serve as a mesh that prevents tobacco shreds 21 and other fine powders from entering the mouth part. The front stage-filter material 41 may also include an aromatic material or a plant leaf (e.g., aroma extract, mint leaf).
The mouthpiece end side-filter material 43 is arranged on the mouthpiece end side of the filter 4, and is a filter material in which a cellulose acetate fiber bundle formed into a columnar shape and having a hollow passage 431 formed in the axial direction is wrapped with wrapping paper. The mouthpiece end side-filter material 43 has the hollow passage 431 extending from a front end surface 43a to a rear end surface 43b.
As illustrated in
Note that in the embodiment, the high air flow-resistance unit 432 in the mouthpiece end side-filter material 43 is formed of a single material, whereby the air flow-resistance of the high air flow-resistance unit 432 is uniform in the cross section direction. In other words, this means that the air flow-resistance does not change in the cross section direction of the high air flow-resistance unit 432.
Here, as illustrated in
Also, as illustrated in
When smoking, the cigarette 1 configured in the above manner is smoked by the smoker, after mainstream smoke generated in a fire source unit of the cigarette rod 2 passes through the filter 4. The mainstream smoke flowed into the filter 4 from the cigarette rod 2 sequentially passes through the front stage-filter material 41, cavity unit 42, and mouthpiece end side-filter material 43, and is sucked into the mouth cavity of the smoker from the mouthpiece end. At this time, when the mainstream smoke having flowed into the filter 4 passes through the front stage-filter material 41, smoke constituents such as tar and nicotine are filtered out. Also, the outside air introduced into the filter 4 through the air holes 31 pierced in the tipping paper 3 is mixed with the mainstream smoke passing through the front stage-filter material 41, whereby tar, nicotine, CO and other components contained in the mainstream smoke are diluted.
Then, the mainstream smoke having passed the front stage-filter material 41 and the cavity unit 42 flows through the hollow passage 431 in the mouthpiece end side-filter material 43, and is sucked into the mouth cavity of the smoker. Since the hollow passage 431 of the mouthpiece end side-filter material 43 of the embodiment is arranged in a decentered manner in the cross section direction, the mainstream smoke can be guided into the mouth cavity of the smoker with a degree of directionality. Accordingly, when smoking the cigarette 1, the smoker can arbitrarily change the part where the mainstream smoke guided into the mouth cavity hits, by changing the posture (direction, position) of holding the filter 4 in his/her mouth. Specifically, the smoker can change the part where the mainstream smoke sucked into the mouth cavity hits, by rotating the filter 4 around its longitudinal axis (central axis CL) (i.e., rotate filter 4 in its circumferential direction). Particularly, since the hollow passage 431 in the embodiment is arranged only in the one first semicircular area A1, of two parts into which the cross section of the mouthpiece end side-filter material 43 is divided, and is not arranged in the other second semicircular area A2, the smoker can more distinctively change the part where the mainstream smoke sucked into the mouth cavity hits, when rotating the filter 4 around the longitudinal axis (central axis CL).
For example, as illustrated in
A human upper jaw has many olfactory receptors that sense aroma (smell). Meanwhile, a human tongue has many taste receptors that sense taste. According to the cigarette 1 of the embodiment, the smoker can freely change the part where the mainstream smoke introduced into the mouth cavity hits, by rotating the filter 4 around the longitudinal axis (central axis CL) according to his/her preference or feeling. In other words, in the above example, the smoker can sense a strong aroma and stimulation (somatic sensation) to the upper jaw and throat, by smoking with the filter 4 held in the mouth in the smoke upward-flowing posture illustrated in
Additionally, according to the cigarette 1 of the embodiment, since the rate (ventilation rate) of air introduced into the mainstream smoke through the air holes 31 in the tipping paper 3 do not change with a change in the posture of holding the filter 4 in the mouth when smoking, changes in the amounts of tar and nicotine (TN amount) can be suppressed. Also, there is no aroma capsule arranged in the filter 4 illustrated in
Moreover, according to the cigarette 1 of the embodiment, the smoker can change the position of holding the filter 4 in his/her mouth at an arbitrary timing while smoking, by rotating the filter 4 around the longitudinal axis (central axis CL) thereof. This changes the part where the mainstream smoke hits in the mouth cavity when the mainstream smoke is sucked into the mouth cavity, so that the smoker can enjoy a change in the fragrance inhaling taste when smoking. For example, various ways of smoking can be achieved, such as switching the posture of the filter 4 from the smoke upward-flowing posture to the smoke downward-flowing posture to shift to a state (this state is hereinafter referred to as “taste rich state”) where the stimulation of taste is made larger than the stimulation of aroma, and then bringing the posture of the filter 4 back to the smoke upward-flowing posture to shift to a state (this state is hereinafter referred to as “aroma rich state”) where the stimulation of aroma is made larger than the stimulation of taste. Since the taste rich state and the aroma rich state can be switched easily by switching the posture of holding the filter 4 in the mouth between the smoke upward-flowing posture and the smoke downward-flowing posture while smoking, the filter 4 of the embodiment is capable of reversibly changing the fragrance inhaling taste. Note that capable of reversibly changing the fragrance inhaling taste means to be capable of freely switching the fragrance inhaling taste of the cigarette 1 between the taste rich state and the aroma rich state, when smoking.
As has been described, according to the filter 4 of the embodiment, the fragrance inhaling taste can be reversibly changed at an arbitrary timing, without changing the aroma delivery amount or amounts of tar and nicotine while smoking. Note that in the embodiment, the identification mark 32 is printed on the outer surface of the tipping paper 3, and the smoker can easily identify the position of the hollow passage 431 arranged in a decentered manner in the cross section of the mouthpiece end side-filter material 43 based on the identification mark 32. This makes it easier to change the fragrance inhaling taste of the cigarette 1 when smoking.
Moreover, according to the filter 4 of the embodiment, the high air flow-resistance unit 432 of the mouthpiece end side-filter material 43 is formed of a single material, and has a uniform air flow-resistance in the cross section direction. Hence, the number of steps in the manufacturing process of the filter 4 can be reduced as compared to forming the high air flow-resistance unit 432 with multiple materials, whereby manufacturing cost can be reduced.
Furthermore, in the filter 4 of the embodiment, the hollow cavity unit 42 is arranged between the front stage-filter material 41 and the mouthpiece end side-filter material 43. This allows the mainstream smoke having flowed through the entire cross section (entire area) of the front stage-filter material 41 to flow out as it is into the cavity unit 42, without narrowing the flow path. Then, the cavity unit 42 can be used to function as a buffer of the mainstream smoke, to allow the mainstream smoke to flow into the hollow passage 431 of the mouthpiece end side-filter material 43 from the cavity unit 42. Thus, it is possible to avoid partial obstruction of the flow of the mainstream smoke in the cross section of the front stage-filter material 41, when the mainstream smoke passes through the front stage-filter material 41. In other words, it is possible to effectively use the entire section (entire cross section) of the front stage-filter material 41 as a filtering medium of smoke constituents. Note, however, that the front end of the mouthpiece end side-filter material 43 may be connected to the rear end of the front stage-filter material 41, without providing the cavity unit 42 between the front stage-filter material 41 and the mouthpiece end side-filter material 43 as in a modification illustrated in
Various variations may be adopted as the configuration of the mouthpiece end side-filter material 43. Hereinafter, variations of the mouthpiece end side-filter material 43 of the embodiment will be described.
A mouthpiece end side-filter material 43 illustrated in
In mouthpiece end side-filter materials 43 illustrated in
In the mouthpiece end side-filter material 43 illustrated in
Note that the hollow passage 431 (low air flow-resistance unit) of the mouthpiece end side-filter material 43 of the embodiment may at least be arranged only in one first semicircular area A1, of two parts into which its cross section is divided, in a position on the rear end surface 43b (mouthpiece end). Since the hollow passage 431 (low air flow-resistance unit) is arranged at least in a decentered manner in the first semicircular area A1 in a position on the rear end surface 43b (mouthpiece end) of the mouthpiece end side-filter material 43, the smoker can change the fragrance inhaling taste of the cigarette 1, by appropriately rotating the filter 4 around the longitudinal axis (central axis CL), and changing the part where the mainstream smoke hits in the mouth cavity.
Additionally, although the hollow passage 431 (low air flow-resistance unit) of the mouthpiece end side-filter material 43 is arranged parallel to the longitudinal axis (central axis) of the filter 4 from the front end surface 43a to the rear end surface 43b of the mouthpiece end side-filter material 43 in the example illustrated in
Although the present invention will next be described more specifically by use of examples, the invention is not limited to descriptions of the following examples, as long as it is within the gist of the invention.
<<Measurement of Amounts of Tar and Nicotine and Air Flow-Resistance>>
Samples of a cigarette of an example were created, and the tar amount, nicotine amount, and the air flow-resistance were measured.
The cavity unit included-type was formed by attaching, subsequent to the AF filter, a 5 mm-long mouthpiece end side-filter material 43 adhered to an inner surface of a 7 mm-long paper tube 5 with CMC paste. In the cavity unit included-type, a 2 mm-long cavity unit 42 is formed between a rear end surface of the AF filter and a front end surface of the mouthpiece end side-filter material 43. The cavity unit not included-type was formed by attaching, subsequent to the AF filter, a 7 mm-long mouthpiece end side-filter material 43 adhered to an inner surface of a 7 mm-long paper tube 5 with CMC paste. In the cavity unit not included-type, a rear end surface of the AF filter and a front end surface of the mouthpiece end side-filter material 43 are brought together and connected with no space in between. Note that the paper tube 5 was connected to the AF filter with tape. Of the mouthpiece end side-filter material 43, a high air flow-resistance unit 432 is formed of a 2.2Y/44000 cellulose acetate fiber, a low air flow-resistance unit 433 is formed of an 8.6Y/21000 cellulose acetate fiber, and the material was prepared by setting the triacetin content on the high air flow-resistance unit side to 23%.
A mouthpiece end side-filter material 43 of Example 2 corresponds to the mouthpiece end side-filter material 43 illustrated in
A mouthpiece end side-filter material 43 of Example 3 corresponds to the mouthpiece end side-filter material 43 illustrated in
A mouthpiece end side-filter material 43 of Example 4 corresponds to the mouthpiece end side-filter material 43 illustrated in
A mouthpiece end side-filter material 43 of Example 5 corresponds to the mouthpiece end side-filter material 43 illustrated in
Next, a mouthpiece end side-filter material 43 of Example 6 corresponds to the mouthpiece end side-filter material 43 illustrated in
Three samples were created for cigarettes of each of the above examples and the comparative example, and the amounts of tar and nicotine and the air flow-resistance were measured under the following conditions and environment. Specifically, the samples were set to an automatic smoking machine (SM 410, manufactured by SERULEAN) under the environment of 22 degrees C. room temperature, 60% relative humidity, and 0.2 m/second wind speed, and were smoked according to the ISO standard smoking conditions (repeat action of smoking 35 ml for 2 seconds in a single empty puff at 58 second intervals per burn-type smoking article). Of the mainstream smoke, particulate phase constituents were collected by use of a Cambridge filter (borgwaldt, 400 Filter 44 mm), and gas phase constituents were collected by use of a gas bag (SUPELCO, Tedlar Bag). As for the particulate phase constituents, after calculating the TPM (Total Particular Matter) from a change in weight of the Cambridge filter, shake extraction was performed for 20 minutes by use of 10 ml of Isopropanol, and the amounts of water and nicotine were measured by use of GC-FID/TCD (6890N, Agilent) to calculate the amount of tar. The air flow-resistance was measured in the usual way by use of the air flow-resistance measurement device PV21 (created by JT Toshi, Inc.).
As indicated in
<<Sensory Evaluation Test>>
Next, effects related to the change in the fragrance inhaling taste when smoking the cigarette of the example were evaluated, based on the following sensory evaluation test. The sensory evaluation test was performed for the aforementioned Examples 1 to 5 and the reference cigarette. The reference cigarette was formed by adding, to the AF filter of the control cigarette described in
The sensory evaluation was made by making five evaluators (A to E) smoke each of the cigarettes of s 1 to 5 and the reference cigarette, and evaluating the difference in the fragrance inhaling taste, which was obtained when the way of holding the filter in the mouth was vertically inverted. Note that when smoking the cigarettes of Examples 1 to 5, the smoke upward-flowing posture illustrated in
As indicated in
In other words, the obtained result indicates that when smoking the cigarette of the example with the filter held in the mouth in the smoke upward-flowing posture, in terms of somatic sensation, the intensity of stimulation to the upper jaw, throat, and airway can be made relatively strong, and the intensity of stimulation to the tongue can be made relatively weak. The obtained result also indicates that in the smoke upward-flowing posture, the intensity of aroma can be made relatively stronger than taste.
Meanwhile, the obtained result indicates that when smoking the cigarette of the example with the filter held in the mouth in the smoke downward-flowing posture, in terms of somatic sensation, the intensity of stimulation to the upper jaw, throat, and airway can be made relatively weak, and the intensity of stimulation to the tongue can be made relatively strong. The obtained result also indicates that in the smoke downward-flowing posture, the intensity of taste can be made relatively stronger than aroma. These tendencies have been observed in both cases of crushing the aroma capsule while smoking to increase the aroma delivery amount, and not crushing the aroma capsule while smoking.
As has been described, according to the filter of the embodiment and the cigarette including the filter, the fragrance inhaling taste can be reversibly changed at an arbitrary timing, without changing the aroma delivery amount or amounts of tar and nicotine while smoking.
As illustrated in
Next, the borderline maximum distance Dmax refers to the distance, from the borderline BL between the first semicircular area A1 and the second semicircular area A2, of a part of the low air flow-resistance unit farthest away from the borderline BL. Meanwhile, the borderline minimum distance Dmin refers to the distance, from the borderline BL between the first semicircular area A1 and the second semicircular area A2, of a part of the low air flow-resistance unit closest to the borderline BL.
In Example 7, the low air flow-resistance unit (hollow passage 431B) has a circular section with a 2 mm diameter, a width dimension W of 2.0 mm, a borderline maximum distance Dmax of 2.8 mm, and a borderline minimum distance Dmin of 0.8 mm. Comparative Example 1 indicated in
Next, low air flow-resistance units (hollow passages 431C) of Examples 8 to 10 will be described. The low air flow-resistance units (hollow passages 431C) of Examples 8 and 9 are both formed into a small moon shape having a sectional area S of 5.2 mm2 and a width dimension W of 4.0 mm, but have different borderline minimum distances Dmin and different borderline maximum distances Dmax. While Example 8 has a borderline maximum distance Dmax of 2.1 mm and a borderline minimum distance Dmin of 0.1 mm, Example 9 has a borderline maximum distance Dmax of 2.9 mm and a borderline minimum distance Dmin of 0.7 mm. Next, a low air flow-resistance unit (hollow passage 431C) of Example 10 is formed into a large moon shape having a sectional area S of 7.8 mm2 and a width dimension W of 5.3 mm, and has a borderline maximum distance Dmax of 2.8 mm and a borderline minimum distance Dmin of 0.1 mm. Comparative Example 2 indicated in
A sensory evaluation test was performed for Examples 7 to 10 and Comparative Examples 1 and 2. The sensory evaluation was made by making five evaluators (A to E) smoke each sample, and evaluating the difference in the fragrance inhaling taste, which was obtained when the way of holding the filter 4 in the mouth was vertically inverted. Then, each sample was evaluated in terms of the intensity of change in the fragrance inhaling taste, when smoking by switching to the smoke upward-flowing posture and to the smoke downward-flowing posture, by using four levels of evaluation including “very strong,” “strong,” “weak,” and “very weak.”
As indicated in the evaluation result of
For example, by setting the borderline maximum distance Dmax and the borderline minimum distance Dmin of the low air flow-resistance unit of Example 7 larger than those of Comparative Example 1, the change in the fragrance inhaling taste when switching between the smoke upward-flowing posture and the smoke downward-flowing posture was intensified.
According to a comparison between Example 8 and Comparative Example 2, by setting the borderline minimum distance Dmin of the low air flow-resistance unit of Example 8 larger than that of Comparative Example 2, the change in the fragrance inhaling taste when switching between the smoke upward-flowing posture and the smoke downward-flowing posture was intensified. Also, according to a comparison between Example 8 and Example 10, by setting the borderline maximum distance Dmax of the low air flow-resistance unit of Example 10 larger than that of Example 8, the change in the fragrance inhaling taste when switching between the smoke upward-flowing posture and the smoke downward-flowing posture was intensified. Also, according to a comparison between Example 9 and Example 10, by setting the borderline minimum distance Dmin of the low air flow-resistance unit of Example 9 larger than that of Example 10, the change in the fragrance inhaling taste when switching between the smoke upward-flowing posture and the smoke downward-flowing posture was intensified.
Here, a larger borderline minimum distance Dmin, and also a larger borderline maximum distance Dmax are likely to increase the amount of change in the part where the mainstream smoke collides inside the mouth cavity, when the posture while smoking is switched between the smoke upward-flowing posture and the smoke downward-flowing posture. As a result, it appears that the degree of change in the fragrance inhaling taste before and after switching between the smoke upward-flowing posture and the smoke downward-flowing posture has intensified. According to the evaluation results indicated in
Similarly, from the viewpoint of intensifying the change in the fragrance inhaling taste before and after switching between the smoke upward-flowing posture and the smoke downward-flowing posture, the borderline maximum distance Dmax of the low air flow-resistance unit is preferably set equal to or larger than 2.1 mm, and more preferably set equal to or larger than 2.8 mm. When the borderline maximum distance Dmax is normalized by use of a value divided by the diameter of the filter 4, the ratio of the borderline maximum distance Dmax to the filter diameter is preferably equal to or higher than 29.2%, and more preferably equal to or higher than 38.9%. Hence, the ratio of the borderline maximum distance Dmax to the filter diameter is preferably equal to or higher than 29% and lower than 100%, and more preferably equal to or higher than 38% and lower than 100%.
In a filter 4A of the cigarette 1A of the embodiment, a mouthpiece end side-filter material 43 is configured such that an upstream unit 430b and a downstream unit 430c respectively positioned on the front end side and the rear end side of an intermediate unit 430a, which is positioned between a front end surface and a rear end surface, are freely rotatable relative to each other. Specifically, the intermediate unit 430a of the filter 4A has a slit 434, which is cut in while leaving a center part of the cross section of the mouthpiece end side-filter material 43, and the upstream unit 430b and downstream unit 430c are allowed to rotate relative to each other by being twisted relative to each other on both sides of the slit 434.
The same hollow passages 431 are formed in the upstream unit 430b and the downstream unit 430c of the mouthpiece end side-filter material 43. Specifically, in the upstream unit 430b and the downstream unit 430c of the mouthpiece end side-filter material 43, a hollow passage 431 having a relatively lower air flow-resistance than a high air flow-resistance unit 432 is placed only in a first semicircular area A1, of the one first semicircular area A1 and the other second semicircular area A2 that divide the cross section of the upstream unit 430b and the downstream unit 430c into two parts, while a high air flow-resistance unit 432 is placed in other areas in the cross section. Hereinafter, in the mouthpiece end side-filter material 43, the hollow passage provided in the upstream unit 430b is referred to as “upstream hollow passage 431b,” and the hollow passage provided in the downstream unit 430c is referred to as “downstream side hollow passage 431c.” Also, a paper tube 5 is adhered to the outer periphery of the downstream unit 430c of the mouthpiece end side-filter material 43. The front end side of the paper tube 5 overlaps the outside of a tipping paper 3 that wraps the upstream unit 430b of the mouthpiece end side-filter material 43, but the paper tube 5 and the tipping paper 3 are not glued together. Since the upstream unit 430b and the downstream unit 430c of the mouthpiece end side-filter material 43 of the embodiment are rotatable relative to each other, an identification mark 32 is provided on outer peripheral surfaces of both of the upstream unit 430b and the downstream unit 430c.
According to the cigarette 1A of the embodiment, it is possible to vary an area (hereinafter referred to as hollow passage facing area S) in which the upstream side hollow passage 431b of the upstream unit 430b and the downstream side hollow passage 431c of the downstream unit 430c overlap each other at the intermediate unit 430a, by rotating the downstream unit 430c of the mouthpiece end side-filter material 43 relative to the upstream unit 430b thereof by twisting, for example. Then the rate of linear velocity of mainstream smoke flowing through the downstream side hollow passage 431c of the mouthpiece end side-filter material 43 is controlled by the hollow passage facing area S. Hence, when smoking the cigarette 1A, the linear velocity of mainstream smoke flowing into the mouth cavity of the smoker from the mouthpiece end of the filter 4A can be varied by rotating the upstream unit 430b and downstream unit 430c of the mouthpiece end side-filter material 43 relative to each other. That is, the velocity of mainstream smoke flowing into the mouth cavity when smoking can be increased by reducing the hollow passage facing area S, and conversely, the velocity of mainstream smoke flowing into the mouth cavity when smoking can be reduced by increasing the hollow passage facing area S.
According to the filter 4A and the cigarette 1A of the embodiment, the fragrance inhaling taste can be changed by changing the posture of the filter 4a held in the mouth when smoking, to thereby change the part where the mainstream smoke hits in the mouth cavity, as in Embodiment 1. Moreover, by changing the relative angle between the upstream unit 430b and downstream unit 430c of the mouthpiece end side-filter material 43 as mentioned above, the linear velocity of the mainstream smoke flowing into the mouth cavity of the smoker can be changed, so that the intensity of stimulation sensed when smoking can be changed arbitrarily.
Although preferable embodiments of the present invention have been described, various changes, improvements, combinations and the like can be made for the filter for cigarette product of the embodiment. Additionally, although the above embodiments have been described by using a case of applying the filter for cigarette product of the invention to a cigarette as an example, the filter for cigarette product of the invention is also applicable to cigarette products other than a cigarette, such as a cigar, a cigarillo, a SNUS, a snuff, a chewing tobacco, and an electronic cigarette.
A non-heating suction tool illustrated in
A non-heating suction tool 1B illustrated in
According to the mouthpiece 4B of the non-heating suction tool 1B configured in this manner, the flavor of the snuff material can be changed by changing the posture of the mouthpiece 4B when sucking in, and thereby changing the part where the sucked in air containing the flavor of the snuff material hits in the mouth cavity.
A heating suction tool 1C illustrated in
Since this heating suction tool 1C, too, includes the same mouthpiece 4C as the mouthpiece 4B illustrated in
This application is a continuation application of International Application PCT/JP2015/057432 filed on Mar. 13, 2015 and designated the U.S., the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/JP2015/057432 | Mar 2015 | US |
Child | 15702410 | US |