DE3900266A1 - Toxin remover, particularly for smokers - Google Patents

Abstract

A toxin remover appliance, particularly for cigarette smokers, is proposed in which the fact that the smoke is subject to Newton's second law or to the laws of centrifugal force is exploited in order to separate toxins, in particular tar, from the smoke and to keep these inside the appliance so that the smoker inhales only cleaned smoke when smoking. Design forms are in this case developed which are particularly effective in separating out the toxins or which have a shape such that the appliance can be cleaned easily and quickly under warm water. Design forms which are particularly simple and inexpensive to produce are also developed.

Description

Poison removers for cigarettes are known, for example filters, that are in the cigarette and poison collector hoods that you put on put the cigarette holder on by placing the cigarette holder in the holder inserts. While some of the known arrangements are not that good there are also those that, when you put them on as hoods throughout the day used, work so well that in the evening thick collections of tar in the container. The latter versions of the But cigarette holders are expensive and dirty due to the accumulation of tar. They have to be cleaned almost every day and cleaning takes a lot Time, so that cleaning is mostly avoided due to lack of time. Then but accumulates so much tar in the channels that the cleaners to the No more polluters.

The previous cigarette holder therefore have, besides advantages, also shortcomings, so that their improvement An urgent requirement is when we humans as far as we are smokers are not supposed to die of premature death.

The invention is therefore based on the object of a poison remover or pollutant remover especially for removing tar from the To create cigarette smoke that is cheap, effective and simple and which may be intended for single use only, so that the limits described disadvantages of the known cigarette hoods.

This task is performed in aggregates of the generic term for cigarette smoke cleaners solved according to the characterizing part of claim 1. Further advantageous refinements emerge from the patent claims 2 to 18.

Fig. 1 and 2 show cigarettes seen from the side with in Fig. 2 shown the cigarette in an aggregate of the invention.

Figure 7 also shows a cigarette in an assembly of the invention.

Fig. 13 shows a section through a filter cigarette of the known art.

Fig. 3, 8, 16, 27 and 34 show aggregates of the present invention in sections.

Fig. 5, 6, 9, 10, 11, 12, 15, 17 to 22, 26, 28 to 33 and 35 show parts of the invention in a separated representation.

Fig. 14 shows a cigarette in a "pipe" and Figs. 23 to 25 show a "pipe" of the known technique in sections.

Description of the prior art

Fig. 13 is a longitudinal section through the filter cigarette on the market. The actual cigarette part 51 with the tobacco 53 embedded in the paper tube 54 can be seen . To the right of this is the filter part 52 , which contains the paper layers of the filtering paper or other agent in the sleeve 55 . This filter essentially consists of rolled filter layers 56 , which lie close together, but nevertheless form spaces 57 of very narrow cross-section. The smoke passes through these gaps when inhaled, and by sweeping along the paper filter layers 56 , the poison should partially stick or attach to the walls thereof and thus excrete from the smoke. This is partly true, but not perfect, as will become clear from the further explanation of the invention.

Fig. 14 shows this filter cigarette inserted in a "pipe". A "pipe" is a cigarette hood, which is called "pipe" in English. It is intended to purify the smoke from poisons by inserting the cigarette into the opening in the pipe while smoking. This "pipe" is available in multiple versions. Some of them are also highly effective in releasing toxins or tar. But these effective "pipes" cost up to 8.00 DM per piece and require daily cleaning, for example in warm water with thin brushes and wires. In addition, these "pipes", as the 1: 1 figure shows, are very long and this length, as well as the risk of the cigarette falling out, bothers many smokers. But the need for daily cleaning is particularly disruptive, which leads to the fact that cleaning is forgotten, and the "pipes" then become dirt and poison collection containers that the smoker wears in their mouths and inhales his smoke continuously through the poison collection points. As a result of these disadvantages of the known protective articles of the known prior art, there is a need to provide a better protective means for the smoker against inhalation of poison, which is therefore the object of the present invention.

Description of the preferred embodiments

Fig. 1 shows the now common filter cigarette in view from the side at a scale of 1: 1. The filter member 5 is vorgebaut the actual cigarette part 4.

Fig. 2 shows the same cigarette as Fig. 1, but shown in dashed lines, the outer shape 1 with insert 2 of an aggregate (article) of the invention. This device of the invention is relatively thin and long. It is inserted into the filter part 5 from the front. As a result, the filter layers within their cylindrical outer skin are pressed closer together and flow of smoke through the filter layers is thereby deliberately restricted.

FIG. 3 shows the longitudinal section through the unit of the invention as inserted into the cigarette in FIG. 2, but on an approximately 8: 1 enlarged scale. You can see the sleeve 1 with the insert 2 inserted into it and held by the flange 17 .

Fig. 4 shows the jacket 1 in a separate representation and Fig. 5 shows an insert 2 in a separate representation, while Fig. 6 shows an insert 2 with a slightly different design, which can also be inserted into the sleeve, the jacket 1 .

The jacket 1 has a cylindrical front part 22 and a rear conical part 21 . The cylindrical part also contains the part 23 for the later flanging and holding of the insert 2 in the jacket 1 . In the conical part 21 there are the inlet openings for the smoke, namely the openings 6, 7 or 76 . The insert 2 has such an outer diameter that it fits tightly into the jacket, but it is somewhat shorter so that the jacket part of length 23 can be flanged radially inward around the front tip of the insert for the purpose of holding it, if the insert is from the right in the jacket of Fig. 4 deep and sealing on the jacket, pushed in. Corresponding to the inner surface of the jacket 1 , into which the insert 2 is to fit sealingly, the insert 2 also has a conical part 2 and a cylindrical front part without reference numerals. A groove 8 is worked into the conical part 2 in a serpentine shape, which later forms the smoke duct after the article has been assembled. From the position 9 of this spiral groove, an obliquely directed bore 10 is arranged, which goes into the insert and opens into a chamber 11 in the insert. The chamber 11 has a very large cross section compared to the spiral groove 8 . From the chamber 11 , the intermediate channel 12, 13 leads to the first post-chamber 14 , which is connected with a narrow channel 114 to the second post-chamber 15 . The outlet 16 leads from the second post-chamber 15 to the front end face of the insert and through it to the outside. When the insert is crimped into the jacket, the sleeve 1 , part 23 of the jacket partially encompasses the end face of the insert, see FIG. 3, as a result of which the insert is held firmly in the jacket.

After this assembly and ignition of the cigarette as well as the retraction of smoke when smoking, the following process occurs:

The narrowed filters 24, 25 ( FIG. 2) block or reduce the flow of smoke. As a result, the smoke is forced through the bores 6, 7 , 76 of the casing 1 to enter the spiral spiral channel 8 of the insert and continue to flow therein. From there, the smoke flows through channel 10 into chamber 11 , then through channel 12, 13 into first post-chamber 14 , from there through channel 114 into second post-chamber 15 , from where the smoke passes through outlet 16 into the mouth of the smoker continues to flow. This creates the following cleaning effect, which at least partially cleans the smoke of poison, especially tar:

In channel 8 with channel 10 , the smoke reaches high speed due to the narrow cross sections of these channels. When suddenly entering the chamber 11 with a large cross-section compared to the channel 8 , the speed of the smoke suddenly decreases. The heavier parts in the smoke with the higher specific weight cannot be delayed as quickly as the air portion of the smoke with the lower specific weight, because according to Newton's law of force: the heavier components have a greater force than "force equals mass times acceleration" the negative acceleration, because their mass per unit of space is greater than that of the air portion of the smoke. As a result, the heavier, poisonous parts, especially tar parts, which are not visible to the eye in the smoke, smack (fly) against the beyond wall of chamber 14 and collect at place 24 . They condense into poison and tar liquid or sticky form and put in the chamber 14 in place 24 determined to stay there, so do not continue to flow into the smoker's mouth. Since the channels 12, 13 again have a narrow cross-section in the further course of the flow, the intermediate channel 114 also has, but the post-chambers 14 and 15 again have very large cross-sections in comparison, the same effect occurs in the post-chambers 14 and 15 as in the chamber 11 . One finds again accumulations of toxins 25 in the chamber 14 (and / or 15 ) which remain there and do not flow further into the smoker's mouth.

Through the outlet channel 16 , the cleaned smoke flows out of the post-chamber 15 into the mouth of the smoker.

Fig. 5 shows the use of 2 left in the figure in a view from the side, yielding the spiral and at the same tapered profile of the groove 8, so the flue channel 8 recognizes. The longitudinal section through this part of the insert 2 can be seen from the cutting line to the right in the figure.

Fig. 6 shows another embodiment of the insert 2 , which is why the insert here in Fig. 6 is denoted by 2 ' . In contrast to FIG. 5, the chamber 11 in FIG. 6 is set at right angles to the channel 10 in order to achieve an increased venom separation by means of a sharper angle of the change in flow direction. The channel 13 is also set at a steeper angle relative to the channel 12 , which likewise results in a stronger poison separation by a sharper change in direction of the flow. Finally, in FIG. 6, the second post-chamber is rotated ninety degrees relative to the first post-chamber 14 . Therefore, the second post-chamber in FIG. 6 has the reference number 26 and the channel between the two post-chambers has the reference number 214 . The rotation of the axis of the second post-chamber relative to the axis of the first post-chamber in turn serves to aid in changing the direction of the smoke flow.

Fig. 15 shows in the same way a further embodiment of the insert 2. Therefore, the use in Fig. 15 is denoted by 2 '' . In Figs. 6 and 15, the chamber 11 is denoted by 111, because it has a steeper angle to the channel 10 in comparison with Fig. 5. In FIG. 15, the channel part 12 is longer and the channel section 213 runs at an even sharper angle than the channel sections 13 and 113 of FIGS. 5 and 6. As a result, a greater change in the direction of the smoke is in turn enforced and thus an increased poisoning is achieved. What is new in FIG. 15 compared to FIGS. 5 and 6 is that the channel part 314 is formed at a sharp angle to and between the secondary chambers 14 and 26 . In this way, in the case of FIG. 15, a particularly strong re-secretion of poisons is sought, particularly in the second post-chamber.

Fig. 7 shows a cigarette with another embodiment of the poison separator of the invention seen from the side, again approximately on a scale of 1: 1. The cigarette 30 has the filter head 31 , which is partially encompassed by the cylinder 33 of the poison remover 32 . The filter can be shortened to reinforce the cleaning head of the poison remover with surface 34 .

Fig. 8 shows a longitudinal section through this Giftentferner in strong, about 8: 1, on an enlarged scale.

This poison remover of the invention has the jacket 35 with the two inserts 36 and 37 . These parts can also be seen separately in FIGS. 9 to 12. Figs. 8 to 12 are therefore here now described together. The jacket has the cylindrical part 35 which fits tightly around the filter head 31 of the cigarette 30 . At the front, the jacket has the cover 45 with the smoke outlet 44 . The lid and cylindrical part are usually made in one piece. The inserts 36 and 37 have cylindrical outer diameters which closely fit the cylindrical inner diameter of the cylindrical part 35 . Otherwise, the two inserts are flat circular plates with flat and parallel axial end faces. The insert 37 is pressed deep into the jacket until it lies tight against the end face of the cover 45 . The insert 36 is then pressed into the jacket 35 until its front end face lies tightly against the flat rear surface of the insert 37 . The front insert 37 has the smoke inlet duct 41 , the poison collector chamber 42 with a large cross-section in comparison to the duct 41 and also the front insert has the outlet duct 43 , which leads from the poison remover chamber 42 to the smoke outlet 44 of the cover part 45 . Starting from the rear surface, the rear insert 36 has the smoke inlet duct 38 which projects axially through the insert and opens into the snake duct 39 which is worked into the insert 36 from the front end surface. Since Fig. 12 is the section through the part of Fig. 11, which contains the snake passage 39, one can see the shape of this channel 39 clear in FIG. 12. FIG. 9 thus is the longitudinal section through the shell, Fig. 10 through the first insert and FIG. 11 through the second, the rear insert of FIG. 8. The end of the serpentine channel 39 is the mouth 40 which, after installation in the jacket, is flush with the inlet 41 of the first insert, ie it opens into it. In this embodiment of the poison remover of the invention, the poison collects primarily on the radially outward walls of the snake channel 39 and in the poison collection chamber 42 .

Fig. 13 shows a filter cigarette in a "pipe" of the known technique. In the paper wrapper you have the tobacco with the spaces 51 for air and smoke. The filter is surrounded by the jacket 55 and usually consists of cylindrical paper layers 56 with narrow spaces 57 . It has been believed in the art that the narrowness of the spaces 57 would deposit poison on the walls of the paper layers 56 . That is partly true. Because sticky tar that runs along the paper walls actually settles on the walls of the filter paper. However, the present invention recognizes that the poisonous components, in particular the tar, are not forced in this known filter technique to flow towards the paper walls. Therefore, a large part of the poison can flow through the filter without sticking to the walls of the filter. Because of the essentially parallel paper layers of the filter, the smoke flows in a straight direction in parallel flow threads through the channels 57 between the paper walls 56 . The toxic components of the smoke, especially the tar components of the smoke, have a higher specific weight than the pure air warmed by the fire of the cigarette. As soon as the poison components have the same speed as the heated air, the invention recognizes that they flow with a stronger force (again according to Newton's law of force) in a straight direction through the channels 57 between the filter layers 56 and refuse due to their larger dimensions to change the current seal perpendicular to the walls of the papers 56 . Resistance to acceleration to change direction according to Newton's law thus prevents the poison from flowing onto the filters 56 , as the present invention believes to recognize. Therefore, these known filters of Fig. 13 cannot be fully effective.

FIG. 14 shows the cigarette of FIG. 7 not in the poison remover of the invention but in the conventional "pipe" 60 .

FIG. 23 shows this "pipe" 60 in cross section and FIGS. 24 and 25 are cross sections through FIG. 23 along the arrowed lines of FIG. 23. One can see the cylindrical part 60 , which is followed by a taper 61 . In the front you have the mouthpiece 64 with the intermediate part 63 . The intermediate part 63 and the mouthpiece 64 are flattened in the mouth for the purpose of more convenient retention, that is, they are not cylindrical. This shape of the known "pipe" of technology creates dead corner spaces 62 between the flattened and the cylindrical parts. In these corner rooms 62 , tar and poison accumulate, which sticks there so firmly that it cannot be removed during washing and cleaning. This type of pipe therefore proves in the long run to be a dirt and poison collector that is not cleanable, so that the smoke that comes into the smoker's mouth, once the pipe has been used a few times, on these poison collectors Corner rooms 62 flows along. The smoke fills up with a portion of the poison that the pipe had previously removed from the smoke. This "pipe" of the prior art therefore also has considerable disadvantages, which the present invention also has to overcome.

The further FIGS. 16 to 22 therefore show in particular those exemplary embodiments of poison removers of the invention which are particularly easy to clean, so that the poison collection points 62 of the conventional "pipe" are avoided because these poison removers of the invention can be cleaned well of toxins. In addition, they are structurally simpler and therefore cheaper.

FIG. 16 therefore shows a further exemplary embodiment of the invention in longitudinal section, while FIGS. 17 and 18 show their parts separately in longitudinal sections and FIG. 19 is the cross section through FIG. 18 along the arrowed line through FIG. 18.

You have again the jacket, which is now designated 35 ' and the cover part 45' with the smoke outlet 44 ' . But this embodiment of the invention has only a single insert 36 ' . This is, as shown in Fig. 16, again deeply pressed into the cylindrical part 35 'of the jacket until it touches the cover part with its front end face closely and sealingly. On the smoke outlet 44 ' opens the channel 43' . It is important here for practice to design the channel 43 ' with a smaller cross section than the outlet 44' , so that one pushes against the surface difference with a plunger and thus removes the insert from the jacket for cleaning (washing in warm water, e.g. under the warm shower head of the bathroom). The smoke flows through the inlet 38 'of the insert in the channel 65 and from it into the first venom collection chamber 66 with a larger cross-section in comparison to the channel 65 for the speed change of the flow of the smoke. Channel 67 leads from chamber 66 to post-chamber 68, which in turn has a larger cross section than channel 67 . The channel 69 leads from chamber 68 to the second post-chamber 70 , which in turn has a larger cross section than the channel 69 . From chamber 70 , the channel 71 leads to the outlet channel 43 ' , which opens onto the outlet 44' of the jacket. It can be seen in the sectional figure 19 that the channels open into the chambers at acute angles and one also sees that the channels are arranged at different angles to the chambers and not opposite the input channels.

This embodiment of the invention thus offers a multitude of changes in direction and velocity changes in the flow of smoke. More specifically, this example of the invention forces smoke several times to change roughly the directions and roughly the speeds. In the Speed change creates an acceleration or deceleration, where the deceleration is a negative acceleration according to Newton's Force law is. Every change of direction is according to Newton's law of force also an acceleration. Any acceleration of the smoke according to the invention causes secretion of toxins, in particular of tar. After smoking 20 cigarettes, thick layers of tar collect in the chambers and opposite of speed changes after 20 cigarettes fill almost all chambers and channels.

Therefore, the parts should be cleaned after about 5 cigarettes Example by showering under the hot water of the bathtub shower.  

While FIGS. 18 and 19 show an effective use, 20 to 22, a simpler application of the invention is shown in FIGS. Illustrated, which is easier to manufacture by means of mechanical processing. This use has been used in most of the trials underlying the invention. One sees again an inlet 38 '' and the outlet duct 43 '' . The insert is labeled 36 '' . From the inlet 38 '' extend from the two channels 72 and 73 to the first venom collection chambers 74 and 75 with larger cross-sections compared to the channels 72 and 73 mentioned for speed deceleration. From the chambers 74 and 75 , the channels 76 and 77 lead to the post-chamber 78 and from the post-chamber 78 , the channel 79 leads to the outlet channel 43 '' . These channels and chambers are molded from the front end into the insert 36 '' , but do not go axially through it. From the rear end surface, the channels 80 and 81 are shaped into the insert in a cross shape, but not so deep that they would hit the aforementioned chambers and channels 72 to 79 . A wall thus remains between the channels (and chambers) 72 and 79 and the channels 80 to 81 . The cross channel 80 - 81 is used to collect the smoke before the filter or before the tobacco and to guide in the inlet channel 38 '' .

The ring channel 72 to 79 is not quite as effective as the arrangement according to FIGS. 16 to 19. Nevertheless, it has a relatively good effect compared to the simplicity of the design.

The invention has the following rough considerations, among others underlying that are not definitive and have corrected over time or may be subject to improvements. In particular, the following are Numbers are only very, very rough and they only serve the purpose To make the system more understandable.

Air has a specific weight of approximately 1.293 kg per cubic meter. Tar weighs about 0.8 kilograms per cubic decimeter. Tar is one of those Major poisons in the smoke of the cigarette. If you reshape these values, you get one weighs about 0.0008 grams of tar per cubic millimeter and about 0.00000129 grams of air per cubic millimeter. If you divide this tar value that of air, you get the result 620. The same room weighs tar about 620 times as much as the same room air. Because the crowd after Newton's force law divides the weight by the acceleration due to gravity the tar has a mass that is about 620 times greater than that of the air. The tar is in tiny tiny fractions of a cubic millimeter in that Smoke contained in the cigarette.

Assuming that the smoker with about a hundredth of an atmosphere,  So with 0.01 bar negative pressure sucks in the smoke with your mouth, then you get according to the outflow formula

and with "rho" for air = 0.125 for V = velocity of the aspirated smoke,

In FIG. 21, the cross section of the channels 72, 73, 76, 77 is assumed to be 1 square millimeter each and the average radius of these channels is 2.5 mm. Then the smoke flows through these channels at around 40 m / sec. The circular shape of the channels arises due to a centrifugal force in the smoke, because the smoke is accelerated continuously radially inwards along the circular path. This centrifugal force is Z = mV / r with V speed, m = mass and r = radius. If you use the above values, you get:

Z = mV² / r (2)

where the mass of the smoke is only that mass which is currently in the channels 72, 73, 76, 77 . It is 2 r pi by 1 square millimeter, i.e. about 15 cubic millimeters. So the mass of the smoke is 15 × 0.00000129 grams or 0.00000000129 kg. Then the centrifugal force of the smoke in the channels mentioned:

This is the force that the smoke exerts radially outward from the mass of the air radially outward from the ring part channels of FIG. 21 onto the walls of the channels. However, as stated in the previous section, the mass of tar is about 620 times greater than that of air. The force exerted radially outwards against the walls of the ring sub-channels 72, 73, 76, 77 of FIG. 21 by the tar parts of the smoke is therefore approximately 620 times greater, namely 0.0000679 kg times 620 = 0.0421 kg or around 42 grams.

In practice, contraction coefficients arise with all changes of direction, which delay the speeds by up to half or roughly double the suction power required. These are coefficients the steeper the angles, the stronger the effect Expressed numbers that may be taken into account in the further improvement will. The above calculations are only intended to show that actually so great forces occur that the small invisible tar particles of smoke due to the forces acting on them on the walls and settle in the poison collection chambers.  

The following basic formulas are summarized:

Newton's law of power:

K = m · b (4)

Dimensions:

kg / 9.81 m / s² (5)

Density:

Outflow rate:

Centrifugal force:

With:
K = force in kg,
m = mass = kgs² / m = weight in kg / 9.81 m / s²,
b = acceleration,
Rho = density,
Gamma = specific weight,
g = gravitational acceleration = 9.81,
V = speed = m / s,
Z = centrifugal force = kg and:
r = radius in meters.

When flowing out of one of the channels into a poison collection chamber the speed is decelerated to "zero" and continues to flow from the chamber into a canal, the smoke is "zero" again accelerated to full channel speed. In practice, this likes Current flow in the arch and dead spaces in the chambers and corners form in which the smoke rests or flows through vortexes due to friction. For the basic calculation, however, it is assumed that the smoke at Arriving from the channel in the poison collection chamber is delayed to "zero". This deceleration from the above 40.8 m / s to "zero" is an acceleration (negative) in the sense of Newton's law of force according to equation (4).  

Per quarter annular channel of FIG. 21 has about 3 cubic millimeters. The flow is 40.8 m / s; thus 40800 mm / sec. The emptying of an annular channel quarter of FIG. 21 in one of the chambers 74, 75 or 75 is thus in 3/40 800 seconds time short in 0.00007 seconds. To calculate the force with which the smoke is decelerated, you probably get according to Newton's law of force:

K = (0.00000000129 / 9.81) 40.8 / 0.0000735 = 0.0000566 kg.

For the tar portion the 620 times greater force, so: dto × 620 = 0.035 kg, or 35 grams.

Analogous forces occur in the chambers of FIGS. 3, 5, 6, 15, 19. Comparing the forces in the chambers, which according to the above calculation were 35 grams with the 42 grams in the ring channels of FIG. 21, and considering that in practice the deceleration does not always go completely to "zero", rounded flow with eddies in dead space corners, then one gets the impression that the ring channel of FIG. 21 with the centrifugal force acting on it in the smoke, i.e. on air and tar, is one of the most effective solutions for cleaning the smoke and removing it of tar and toxins out of it. Then you can arrange a simple ring channel in Fig. 21, namely the ring channel 82 shown in Fig. 26 from the inlet 38 '' to the channel 79 ' , which then leads to the outlet channel 43'' . Fig. 26 is therefore an alternative figure to FIG. 21 with the ring channel 82 according to the invention and its connections within the insert 36 '' .

Fig. 27 shows a result of this consideration, namely that several ring channels can be arranged one after the other in order to achieve a high cleaning effect. In FIG. 27, therefore, a plurality of inserts 236, 336, 436 are arranged axially one behind the other, which correspondingly correspond to insert 136 of FIG. 2b. Figs. 28 to 30 show the longitudinal sectional views of the inserts of Fig. 27 and Figs. 31 to 32 show the cross sections of Figs. 28 to 30 along which arrowed lines.

It is still to be reported that the physical-mathematical considerations have not yet been examined by experts. In the context of the invention, the effect of the constructions of the invention was tested and the deposition of toxins, in particular tar, was determined. The calculations are the first rough attempts to gradually build up an exact calculation method for the effect of the invention. The ring channel 82 of FIG. 26 is wider than that of FIG. 21, so that space for the deposits 83 of the poison, tar, is created in the ring channel of FIG. 26.

For rough support, it follows from the above that one cubic millimeter of air weighs about 0.00000129 grams and one cubic millimeter of tar weighs about 0.0008 grams. The masses of air and tar are the same (grams above divided by g = 9.81):

Mass of 1 mm³ air = 1.31 · 10 ^-7 mass gram = 1.31 · 10 ^-10 mass kilogram.

Mass of 1 mm tar = 8.15 x 10 ^-5 mass grams = 8.15 x 10 ^-8 mass kilograms.

At the previous 40.8 m / s smoke speed by suction, it must be taken into account that at 0.01 bar suction Negative pressure is only reached if there is a free, unimpeded flow, which is not the case in the cigarette. With many redirections in the Cleaning channels and the contraction coefficients that occur, the smoker may have to suck in 5 to 20 times more, to achieve such a high flow rate. Therefore, in the following again with a lower smoke speed of 10 meters per second recalculated:

The only interesting thing is the question with what force the tar (poison) is delayed by the invention (accelerated negatively or accelerated radially outwards).

For the smoke in the circular channel, the radius " r " = 2.5 mm is:

For the delay when suddenly leaving a straight channel and hitting the opposite surface considering that the Speed of 10 m / s in a time of 1/10 000 seconds. The then negative acceleration is:

b = 10 m / s / 0.0001 = 100 000 m / s²

and the force " K " is:

In the context of the invention it is assumed that these relate to the toxins, especially tar, acting forces are the cause that they separate from the air and settle in the device of the invention.

Different forces can be seen here as a result, depending on whether you choose an embodiment of the invention that works according to equation (4) or whether you choose one that works according to equation (8). In those according to equation (4), the flow velocity plays the essential role, while in those according to equation (8) the radius of the circular channel is added. Equation (8) shows directly that the smaller the radius " r " of the toroidal channel, the greater the force " F ", with otherwise the same flow velocity. Since with the cigarette and the poison remover according to the invention, this radius " r " is always a very small one, there is a possibility here to make the poisoning force as large as possible.

Therefore, the other figures are particularly promising Embodiments of the invention, which are also special Offer simplicity and cheapness in production:

In Fig. 27, therefore, are arranged in the casing 235, the three (or more or alternatively less) inserts 236, 336 and 436. The rear insert 236 again has the radial slots 80, 81 for collecting the smoke. From there, the smoke flows through entrance 85 into and through the annular duct 86 , then via outlet 87 to the inlet 88 of the middle insert 336 , from there into and through the annular duct 89 into the outlet 90 , from there into the inlet 91 of the front insert 436 , from there into and through the ring channel 92 to the outlet 216 , from which the smoke flows through the outlet 218 of the jacket into the mouth of the smoker.

In Fig. 34 in the shell 335 only a single insert 95 is disposed. While it is drawn in longitudinal section in FIG. 34, FIG. 35 shows it, the insert, seen from the side. The jacket corresponds in principle to that of FIG. 27, but can be shorter. The insert 95 again has the radial channels 80, 81 or one of the same at the rear end for collecting the smoke. All around the circumference, the spiral groove 96 is worked into the insert as a smoke line in order to open into the outlet 315 , which leads to the outlet 318 of the jacket. The insert 95 is closely fitted into the cylindrical inner diameter 98 of the jacket. As a result, the webs 97 sit tightly in the casing 335 between the spiral groove 96 , so that the smoke is forced to flow around the insert in accordance with the number of turns. The inner diameter 98 can also be kept smaller than the inner diameter that holds the cigarette. This is because a small radius " r " is reached, which increases the force with which the toxin is forced onto the wall 98 of the jacket.

In Fig. 27 the smoke is forced to flow through several smoke channels of different uses. In Fig. 34, the smoke is forced to flow around the insert several times with a narrow radius. In the circular arc channels of Fig. 27 and 34 with their section and separation figures of the smoke of the centrifugal force "F" according to equation (8) is subjected. As a result, the centrifugal force 620 times less acts on the air, but the centrifugal force 620 times greater on the tar. On the long way through the long smoke channels of these figures, the centrifugal force " F " causes the toxin components, in particular tar, to gradually condense to liquid or solid and settle on the wall parts 98 of the jacket, or on the radial outer walls of the channels 86, 89 , 92 discontinues.

As a result of the high influence of smoke speed on secretion of toxins according to the formulas above, it is appropriate in order Achieving high flow rates of smoke with small channels Cross sections, e.g. B. to use well below a square millimeter.

To Figs. 2 to 6 is also to be noted that the casing 1 mounts or barbs may have 19 (Fig. 3) in order to have a better hold in the cigarette or filter. In addition, the jacket 1 or the insert 2 may have a holder 102 for fastening a pane 100 or hood 100-101 . The jacket or insert can also be in one piece with the disk or hood. The disc or cap 100 or 100 to 101 may then forward the filter close to the through-flow of smoke hindering further and to force smoke stream through the jacket 1 and the use of the second You can also serve in front of the plate 100 or 100 of the hood - quench 101 poisons that have passed through the filter. 5 The hood part 101 may roughly encompass the front part of the cigarette or the filter, while the disc or the hood part 100 to 102 is shown in FIGS . 2 and 3, which is to mean that it also applies to the other figures with jackets 1 and inserts 2 can be.

Since the invention is described in more detail in the claims , the claims are intended to be part of the description of the exemplary embodiments be valid.

For the invention it is not claimed that it would remove all toxins from the smoke of the cigarette and that Smoking cigarettes completely harmless to health by the invention had become. Although the device of the invention most used when smoking cigarettes because there is more There are cigarette smokers as pipe smokers, but the device is the one Invention also for removing toxins from the smoke of cigars or the pipes can be used by looking at the dimensions of the fixings or coats to match the cigars or pipes.

Claims (18)

1. Poison removal device, in particular for smokers of cigarettes, which can be connected to the front part of the cigarette, for example encompasses the front part of the cigarette or can be inserted into the front part of the cigarette and in which channels and body parts are arranged, characterized in that the smoke through channels is guided with a shape that forces the release of toxins, especially tar, from the smoke and the deposition of these substances within the device. 2. Device according to claim 1, characterized in that the device 1 can be inserted into the cigarette holder. 3. Device according to claim 1, characterized in that the device contains only agents that are under a hot water shower can be cleaned. 4. Apparatus according to claim 1, characterized in that the device for single use with a single cigarette is firmly connected. 5. Apparatus according to claim 1, characterized in that the device consists of a jacket 1 and an insert 2 . 6. Apparatus according to claim 5, characterized in that the insert is provided with a spiral channel 8, which employed in a toxic collection chamber 11, 111 in comparison with the channel 8 larger cross-section and at an angle to the duct 8, flows. 7. Apparatus according to claim 6, characterized in that the poison collection chamber 11 , etc., a post-chamber 14, 15 is connected via a further channel 12, 13 . 8. Apparatus according to claim 6, characterized in that the channel 8 is formed spirally and conically around a conical insert 2 . 9. Apparatus according to claim 1, characterized in that the device consists of a jacket with end cover 45 on a cylindrical jacket part 35 with a closely fitting in the inside diameter of the cylindrical part 35 and the end cover 45 is provided with a smoke outlet 44 . 10. Apparatus according to claim 9, characterized in that the device contains two inserts 36 and 37 , the insert 36 containing a smoke channel and the insert 37 containing a poison collection chamber 42 with a larger cross section than the smoke channel 39 . 11. Apparatus according to claim 9, characterized in that the smoke channel 39 has 36 "S-shaped" cross section in use. 12. Apparatus according to claim 9, characterized in that the insert 36, 36 ', 36'' is arranged alone in the jacket 35' . 13. Apparatus according to claim 9, characterized in that the insert 36 'contains a plurality of channels 65, 67, 69, 71 directed at different angles to one another, each of which opens into poison collection chambers 66, 68, 70 one after the other, or emanate from them. 14. Apparatus according to claim 9, characterized in that the insert 36 '' is provided with an annular channel 72, 73, 76, 77 which opens into at least one poison collection chamber 74, 75, 78 . 15. Apparatus according to claim 9, characterized in that in the insert 136 there is only an annular duct provided with inlet and outlet, in which the smoke is subjected to centrifugal force as it passes and is forced to separate poison in the annular duct 89 . 16. Apparatus according to claims 9, characterized in that a plurality of inserts 236, 336, 436 with annular channels 89, 86, 92 , and inlet and outlet are arranged in a jacket 235 . 17. Apparatus according to claim 1, characterized in that an insert 95 is closely fitted in a jacket 335 , which forms on its periphery an outwardly enclosed by the jacket spiral groove 96 and said insert with a smoke collection inlet 80, 81 and with an outlet 316 is connected, while the smoke is subjected to the centrifugal force when flowing through the spiral channel and is forced to separate toxins radially outside the spiral groove on the inner wall of the jacket 335 . 18. Apparatus according to claim 1, characterized in that in an aggregate at least one spiral, flowed through passage of smoke narrow cross-section with high smoke speed, in which the poison of the smoke is subjected to centrifugal force and settles on the radially outer wall of the passage is and also a passage, which may be the former, is arranged in a chamber with a larger cross-section than the said passage with a wall opposite the mouth, whereby the smoke and the poison in the smoke once the centrifugal force in the spiral passage and others are additionally subjected to the sudden deceleration (negative acceleration) and thus a repeated and different removal of the poison (tar) from the smoke is forced by the arrangement of the passage and the chamber ( FIGS. 3, 4, 5, 6, 15, etc. ).