RU2300364C2 - Test-tube - Google Patents

Abstract

FIELD: medicine; manufacture of medical ware.

SUBSTANCE: test-tube has case. Cross-lateral section of test-tube has one line of external boundary of section and one line of internal boundary of section. Line of section external boundary of all the possible pairs of points has two pints being mostly distant one from other. Line of internal boundary of section of all possible pairs of points has two points being most distant one from other. Straight line drawn onto plane of section through points being most distant one from other and which are disposed onto line of external boundary of section, is disposed at angle of 0,017 radian to 3,123 radian to straight line drawn onto plane of section. Thickness of test-tube along external border of section varies. Moreover one part of line of external section in rectangular coordinate system has onto plane is descried by equation of (X/A)²-(Y/B)² -1=0, where X and Y are coordinate axes, A and B are rational numbers different from zero. One part of line of internal boundary of cross-section in rectangular coordinate system is described by equation of (X/C)²-(Y/D)²-1=0, where X and Y are coordinates, C and D are rational numbers different from zero.

EFFECT: improved efficiency of heat transfer.

10 cl, 14 dwg

Description

The technical field to which the invention relates. Fields of application of the invention are medicine, the chemical industry, in particular manufacturing for the manufacture of medical glassware, namely test tubes of various shapes made of glass, plastics and other materials.

The level of technology. The applicant knows the analogue of the invention - the test tube described in the patent of the Russian Federation for invention No. 2037456 "Locking device for the end side of a cylindrical container", published 1995.06.19. The test tube contains a housing made in the form of a cylindrical container containing an open end side and a closed blind end. The inner cavity of the tube is cylindrical. The longitudinal axis of the tube is a straight line. In cross section, the tube body has an external and internal section boundary made in the form of circles. The wall thickness is unchanged along the entire length of the tube body and along the outer border of the cross section.

With the essential features of the claimed invention, the following features of the analogue coincide: the tube contains a housing, and in one of the cross sections the tube contains an external section boundary and an internal section boundary.

The reasons that impede the receipt of technical results that are provided by the invention are as follows.

The form of the test tube-analogue does not provide resistance to destruction with increasing internal pressure in a closed tube, for example, with an increase in the volume of a freezing (transforming into a crystalline state) liquid substance. The analog tube is round in cross section, that is, the tube in cross section contains one line of the external boundary of the section and one line of the internal boundary of the section, and these lines are made in the form of circles centered at one point. An increase in the internal volume of such a tube is possible only due to thinning (thinning) of the walls of the tube body, which can lead to destruction of the body.

An analog test tube over the entire surface of its body provides the same process of heat transfer in all directions in magnitude from the radiant energy source located on the outside of the test tube to the substance in the test tube through the test tube wall.

The test tube-analogue has a low reliability of holding mechanical devices or fingers during operation due to the small contact surface (contact) of the tube and devices, as well as the fingers.

The closest analogue to the invention is the test tube described in the patent of the Russian Federation for invention No. 2068253 "Container for egg fertilization", published 1996.10.27. The test tube contains a housing, and the housing is made in the form of a cylindrical container for placement of the cultural medium. The tube is provided with a membrane mounted above the inlet of the tube. The air volume of the tube is 2 cm ³ . The tube has a length of 4 cm, an outer diameter of 1.5 cm. In at least one cross-section, the tube contains one line of the external boundary of the section and one line of the internal boundary of the section. The boundaries of the section are in the form of circles. The inner and outer walls of the tube are smooth and free from injury. The blind end of the tube is rounded. The wall thickness is constant over the entire length of the tube body.

With the essential features of the claimed invention, the following features of the prototype coincide: a test tube containing a housing, and, ... in at least one of the cross-sections, the test tube contains one line of the external boundary of the section and one line of the internal boundary of the section.

The reasons that impede the receipt of technical results that are provided by the invention are as follows.

The form of the test tube-analog does not provide resistance to fracture with increasing internal pressure in a closed tube, for example, with an increase in the volume of a freezing (transforming into a crystalline state) liquid substance. With an increase in internal pressure, stresses arise in the tube body, and stresses (circumferential stresses), which increase the inner diameter of the tube, are twice as large as stresses (axial stresses), which increase the length of the tube body. The internal volume of the tube will increase until the circumferential stresses exceed the tensile strength of the tube material, after which the tube will fail.

This analogue over the entire surface of its housing provides the same process of heat transfer in all directions from the source of radiant energy located on the outside of the tube to the substance in the tube through the wall of the tube.

The rotation of the tube around the longitudinal axis will not lead to a change in the process of heat transfer, and therefore, such a tube does not have the direction of heat transfer properties. This analogue has a low reliability of holding the tube with mechanical devices or fingers during operation.

Disclosure of the invention. The test tube claimed in the invention is a type of glassware and is intended for laboratory research, transportation and storage of various substances, in particular liquid and solid tissues (or tissue cells) of a person, animal or plant.

The claimed invention is aimed at solving the following problem:

improving the reliability of the test tube.

The invention provides one main technical result and several additional technical results.

The main technical result is:

heat transfer process, different on the surface of the tube, from the source of radiant energy located on the outside of the tube to the substance in the tube through the wall of the tube.

Additional technical results are:

a significant increase in fracture resistance with an increase in internal pressure in a closed tube, for example, with an increase in the volume of a freezing (crystallizing) liquid substance for tubes elliptical in cross section, in which the ratio of the major axis to the smaller axis is 1.15 or more (experimentally confirmed, that when water freezes in such a test tube, the latter does not collapse);

a significant increase in the reliability of holding the tube with mechanical devices or fingers during operation for tubes elliptical in cross section, in which the ratio of the major semi-axis to the smaller semi-axis is 2 or more (the adhesion force of the hand with the tube is more than doubled).

The indicated technical results are achieved in that the tube contains a housing, and in at least one of the cross sections the tube contains one line of the external boundary of the section and one line of the internal boundary of the section, and the line of the external boundary of the section of all possible pairs of points contains two points, the most distant from each other, and the line of the inner boundary of the section from various pairs of points contains two points that are farthest from each other; and a straight line drawn on the section plane through the points farthest from each other and located on the line of the outer boundary of the section is located at an angle from 0.017 rad to 3.123 rad to a straight line drawn on the section plane through the points farthest from each other and located on the line of the inner boundary of the section and the thickness of the tube along the outer boundary of the section is variable.

The invention differs from the closest analogue in the following set of features: the line of the outer boundary of the cross section of all possible pairs of points contains two points farthest from each other, and the line of the internal border of the cross section of various pairs of points contains two points farthest from each other and the thickness of the tube along the outer boundary of the section is variable.

Heat transfer is an irreversible process of heat transfer in space due to an inhomogeneous temperature field. There are three types of heat transfer: thermal conductivity, convection, and radiant heat transfer. The source of radiant energy can be sunlight, a burner flame, a ray of light focused at a specific point or a specific area on the surface of the tube.

The heat transfer value is characterized by the values of the heat transfer coefficient, the heat transfer surface area (irradiation area) and the temperature gradient. In this case, the heat transfer surface area is the surface area of the tube exposed to irradiation.

Rotation of the claimed test tube around the longitudinal axis with a stationary source of radiant energy will lead to a change in the process of heat transfer (due to a change in the irradiation area), and therefore, such a test tube has the direction of heat transfer properties.

If in the cross section the thickness of the tube along the outer boundary of the cross section is unchanged, then the heat transfer in the longitudinal plane normal to the longitudinal plane of the tube passing through the two points of the outer border of the cross section farthest from each other will be greater than the heat transfer in the longitudinal plane of the tube passing through two points of the outer border of the cross section, the most distant from each other (due to the smaller irradiation area).

In the general case, in the cross section, the thickness of the tube along the outer boundary of the section is variable. Then, the process of heat transfer, different on the surface of the tube, from the source of radiant energy located on the outside of the tube to the substance in the tube through the tube wall will be determined not only by the irradiation surface, but also by the thickness of the tube varying along the perimeter of the cross section.

The heat exchange between the substance in the test tube and the space surrounding the test tube through the tube body separating them is called heat transfer.

Increased resistance to destruction with increasing internal pressure in a closed tube is due to the fact that with increasing internal pressure the tube changes its cross-sectional shape, for example, from an oblong (oblate oval) shape it tends to a round shape. This increases the internal volume required to fill with an expanding substance during freezing, and destructive stresses do not occur in the tube body.

The increased reliability of holding the tube with mechanical devices or fingers during operation is also due to the flattened shape of the tube body.

Holding the tube in a plane normal to the longitudinal plane of the tube passing through two points of the outer border of the cross section that are farthest from each other will be more reliable than in the longitudinal plane of the tube passing through two points of the outer border of the cross section that are farthest from each other .

The following are signs characterizing the invention only in particular cases of its execution. These features, together with the essential features of the invention, will provide all the technical results of the invention, as well as particular technical results.

The test tube can be made in such a way that at least part of the tube body is made in the form of a tube.

The test tube can be made in such a way that the housing contains a neck, and on the external or internal surface of the housing, in particular at the neck, a thread is made for screwing (screwing) the plug.

The test tube can be made in such a way that the thread is made on a surface area with a length of 0.1: 0.5 of the length of the tube (the length of the tube body). In addition to the body, the tube may contain a cork, various labels glued to the body or cork. For a tube without a tube, the lengths of the tube and the tube body are the same. The length of the tube with the tube may be greater than the length of the tube body.

The tube can be made in such a way that at least part of the tube body, in particular 0.5: 0.9 of the length of the tube body, is made with a variable outer diameter along the length of the case, and the ratio of the maximum diameter to the minimum diameter takes a value from 1.1 to 10 Outer diameter refers to the upper bound of the distances between all kinds of pairs of points on the outer border of the cross section.

The tube can be made in such a way that at least part of the tube body, in particular 0.5: 0.9 of the length of the tube body, is made with a variable inner diameter along the length of the case, and the ratio of the maximum diameter to the minimum diameter ranges from 1.1 to 10 Under the inner diameter is understood the upper bound of the distances between all kinds of pairs of points on the inner boundary of the cross section.

The test tube can be made in such a way that at least one of the sections of the line of the outer boundary of the section in a rectangular coordinate system on the plane is described by the equation

(X / A) ² - (Y / B) ² -1 = 0,

where X and Y are the coordinate;

A and B are rational numbers other than zero.

Moreover, A ≠ B.

The test tube can be made in such a way that at least one of the sections of the line of the internal boundary of the section in a rectangular coordinate system on the plane is described by the equation

(X / C) ² - (Y / D) ² -1 = 0,

where X and Y are the coordinate;

C and D are non-zero rational numbers.

Moreover, C ≠ D. And, in addition, A ≠ C, as well as B ≠ D.

A test tube, in the general case, in cross section may have more than two lines of section boundaries. So, if the test tube has an additional external casing, then there will be four lines of section boundaries.

The test tube can be made with a density (at 20 ° C) from a range of values from 0.92 g / cm ³ to 2.00 g / cm ³ . Currently, the most developed technologies for injection molding of plastic masses (plastic) with densities from the specified range.

The test tube can be made of plastic (plastic) with a breaking stress during transverse compression of the test tube from a range of values from 0.015 Mn / m ² to 1400 Mn / m ² . These strength characteristics ensure the reliability of the tubes at both positive and negative (cryogenic) temperatures.

The tube can be made in such a way that at least a part of the tube body is multilayer, for example, of two layers. So, an additional layer of material with a high ability to reflect radiant energy, will significantly influence (reduce) the transfer of heat from the source of radiant energy to the tube body.

The test tube can be made in such a way that a straight line drawn on the section plane through the points farthest from each other and located on the line of the external border of the section is located at an angle from 0.017 rad to 3.123 rad to a straight line drawn on the section plane through points farthest from each other and located on the line of the internal boundary of the section.

The test tube can be made in such a way that at least part of the test tube or the entire test tube is made of plastic (plastic).

The test tube can be made in such a way that a thermoplastic polymer is used as the plastic.

The test tube can be made in such a way that polystyrene or polypropylene is used as the thermoplastic polymer.

The tube body in at least one of the cross sections is made in such a way that the thickness along the outer boundary of the cross section is variable, and the ratio of the maximum thickness to the minimum thickness takes a value from the range from 1.1 to 10.

Thus, the objective of the invention is solved.

A brief description of the drawings. The invention is illustrated graphic materials.

Figure 1 shows a tube in which on the outer side of the neck there is a thread for twisting the tube. Figure 2 shows a cross-section aa tubes (shown in figure 1). Figure 3 shows a cross section bB test tubes (shown in figure 1). Figure 4 shows a scan of part of the cross-section BB (see figure 3) tubes. 5 shows a coated tube. Figure 6 shows a test tube with variables along the length of the body of the outer and inner diameters. In Fig.7 shows a section aa and bb test tubes (depicted in Fig.6). On Fig shows a test tube made of two parts connected (glued) to each other. Figure 9 shows the injection mold for the manufacture of one of the parts of the tube (for the manufacture of half the body of the tube). Figure 10-13 explains the sequence of manufacture of the tubes according to PET technology. On Fig shows a cross section of a tube made by PET technology.

The implementation of the invention. The tube contains a casing 1 (see FIG. 1), and in cross section the tube contains one line of the outer border 2 of the cross section (see FIG. 2) and one line of the inner border 3 of the cross section (see FIG. 2).

Figure 3 presents a section BB tubes, in which the line of the outer border 4 of the section, from all kinds of pairs of points, contains two points 5 and 6, the most distant from each other, and the line of the inner border 7 of the section, from all kinds of pairs of points, contains two points 8 and 9, the most distant from each other.

A straight line 13 (see Fig. 4), drawn on the section plane through points 5 and 6, the most distant from each other and located on the line, the outer borders of section 4, is located at an angle of 25 ° (in the general case, not equal to 0 degrees or 180 °, i.e., pi-radian) to a straight line 14 drawn on the section plane through points 8 and 9, the most distant from each other and located on the line of the inner boundary of section 7.

Tube 1 (see Fig. 1) contains a neck 10 and a blind end (bottom) 11. A part of the tube body is made in the form of a tube. Inside the tube body is located the inner cavity of the tube 12.

On the body of the tube 1 is a thread 15 (see figure 1). The thread 15 is located on the outer surface of the tube. The tube shown in Fig. 8 contains a thread 16 located on the inner surface of the neck. These threads are made on surface sections with a length of approximately 0.2 of the length of the tube. If necessary, threads can be performed on surface sections with a length of 0.1 to 0.5 of the length of the tube.

Figure 6 shows a tube in which part of the tube body is made with variable external and internal diameters. So, the test tube between cross sections 17 and 18 is made with an outer diameter variable along the length of the casing, and the ratio of the maximum diameter to the minimum diameter in this section takes the value 1.8 (from the range of values from 1.1 to 10). In addition, this test tube between the cross sections 19 and 20 is made with a variable inner diameter along the length of the casing, and the ratio of the maximum diameter to the minimum diameter assumes a value of 1.8 (from a range of values from 1.1 to 10).

Test tube 21 (see Fig. 5) in cross section is made in such a way that in the section between points 22 and 23, the line of the external boundary of the section in a rectangular coordinate system on the plane is described by the equation

(X) ^2- Y / 1.2) ² = 0.

Test tube 21 (see Fig. 5) in cross section is made in such a way that in the region between points 24 and 25, the line of the internal boundary of the section in a rectangular coordinate system on the plane is also described by the equation

(X / 1.5) ² - (Y) ² -1 = 0.

The test tube is made of polystyrene with a density (at 20 ° C) of 1.047 g / cm ³ , breaking stress 80 Mn / m ² . Such a test tube is robust in operation, relatively easy to dispose of under a press, and its fragments are slowly deposited in water, which allows you to first separate heavy (first precipitated) non-plastic elements, and then, after the plastic elements are deposited, light floating debris is removed from the water surface .

In the general case, tubes can be made of plastics (for example, polypropylene, polyethylene, polyethylene terephthalate, etc.) with a density (at 20 ° С) from a range of values from 0.92 g / cm ³ to 2.00 g / cm ³ and breaking stress during transverse compression from a range of values from 0.015 Mn / m ² to 1400 Mn / m ² . These ranges provide the use of tubes for cryogenic freezing of liquid and solid tissues of humans and animals.

To change the heat-conducting properties, the test tube can be multilayer, for example, part of the plastic casing of the test tube 21 (see Fig. 5) is made with an additional plastic surface layer 26. As a coating, a paintwork or metallized reflective coating can also be used.

Figure 5 presents a test tube made in such a way that a straight line 28 drawn on the section plane through the points farthest from each other and located on the line of the external border of the section is located at an angle of 1 -57 rad to a straight line 29 drawn on section planes through points farthest from each other and located on the line of the internal boundary of the section.

In Fig.7 presents sections aa and bb test tubes on the thread. The thread is made intermittent due to thickening of the body.

The manufacture of the test tubes described above is carried out by injection molding, in particular injection molding of the half-shells of the tubes with their subsequent joining, for example, gluing or thermal joining. The manufacturing process for half-shell castings is to fill the mold with molten plastic. Injection molds are made of metal on a milling machine. As a rule, the form is made collapsible of two or more parts. Details of the means for the manufacture of injection tubes and manufacturing methods are described in the source / 1 /.

Figure 9 shows a collapsible injection mold 30, consisting of the upper (conditionally) 31 and lower 32 parts. In the upper part, a filler channel 33 is made, to which, when casting, a worm injection machine is attached to feed the molten plastic into the mold. The form is intended to produce a half-shell test tube depicted in Fig.8. One half-shell of test tube 34 is obtained by filling with plastic the inner cavity of the injection mold 35 (see FIG. 9). And then the test tube is obtained by connecting two half-shells to each other along the connection plane 36. In Fig. 8, in section BB shows the right (conditionally) half-shell of the test tube.

The test tube can also be obtained using PET technology, which is currently being intensively developed. The test tube is prepared as follows: a plastic (polyethylene terephthalate) preform is inserted into the mold, the mold and the preform are heated, and the tube is blown out of the preform through the neck of the mold in the form specified by the mold / 2 /. In this way, tubes with a constant cross section along the outer boundary of the section thickness are obtained.

A method for producing tubes with variable thickness in cross section is illustrated in FIGS. 10-14. Figure 10 shows the mold with a section aa. The mold consists of two elements 37 and 38. First, the elements 37 and 38 are placed at an angle of 39 to the horizontal plane (see Fig. 11). Plastic 40 and 41 are poured into them. After cooling the plastic, it is not separated from the mold elements (they are left in the molds). The mold elements are interconnected (see Fig. 12), the preform 42 is inserted, the preform and the mold are heated until the preform softens. They apply pressure to the inner cavity of the preform. The material of the preform 43 (see Fig. 13) encircles the elements of the mold 37 and 38 from the inside and at the same time connects to the plastic elements 41 and 42. After cooling the material (plastic), the mold is opened and a tube 44 is obtained (see Fig. 14 ), in which in the cross section 45 the thickness of the tube along the outer boundary of the section is variable. Maximum thickness 46 is 1.8 times the minimum thickness 47.

The tube shown in figures 1-3 is made in section BB with variable thickness along the boundary of the section (for example, along the outer boundary of the section). In section BB (see FIG. 3), the thickness 48 is 3 times less than the thickness 50 (maximum thickness of the section). Figure 4 shows a scan of half the section BB, the abscissa "X" shows the outer boundary of the section (the length of the outer border of the section), the ordinate "b" shows the thickness of the tube body (tube thickness). In the graph of FIG. 4 and in the section of FIG. 3, thicknesses 48, 49, 50 and 51 are indicated.

Heat transfer (heat transfer) depends on the value of the heat transfer coefficient, which, in turn, depends on the thickness of the housing directed towards the source of radiant energy. The greater the thickness, the lower the heat transfer coefficient. Heat transfer is maximum if the energy source with respect to the test tube (locally in the form of a beam) acts in direction 52 (for the cross section shown in FIG. 3), or acts in direction 54 (for FIG. 5), or acts in direction 55 ( for Fig. 8), or acts in the direction 56 (for Fig. 14). Conversely, heat transfer is minimal if the energy source with respect to the tube acts in directions 57 and 58 (for FIG. 3), or acts in direction 59 (for FIG. 5), or acts in direction 60 (for FIG. 8), or acts in direction 61 (for FIG. 14).

For the cross section (see figure 3), the heat transfer when the source is in the direction 53 is 2 times less than the heat transfer when the source is in the direction 52.

If the energy source is not local, but acts as a front (irradiates the entire tube surface turned to the radiation source), then in this case the heat transfer surface will be affected by the heat transfer surface area (irradiation area). In this case, the heat transfer surface area is the surface area of the tube exposed to irradiation.

The claimed test tube has a unique property that distinguishes it from analogues, it is the ability to control the heating rate of the substance in the test tube by rotating the test tube around its longitudinal axis. Currently, heating is controlled by changing the radiation intensity and removing (approximating) the radiation source from (k) the tube, which is not always feasible, especially with overall limitations.

Increased resistance to fracture with increasing internal pressure in a closed tube (for example, see Fig. 8) is due to the fact that with increasing internal pressure the tube changes its cross-sectional shape, for example, from an oblong oval shape it will tend to a round shape, which increases the internal volume in the test tube 62, and in the tube body no destructive stresses occur.

The test tube can be made of: polyethylene VD with a density of 0.92 g / cm ³ , a composite material based on boron fiber and a polyamide matrix with a density of 2 g / cm ³ and with a breaking stress under compression of 1250 Mn / m ² , organic glass with a density of 1.2 g / cm ³ , CBAM fiberglass with a density of 1.9 g / cm ³ , a composite material based on boron fiber with a breaking stress of 1350-1450 Mn / m ² , a composite material based on Ti-Al-V with a breaking stress of 1400 Mn / m ^2, the composite material based on foam PS-1 p zrushayuschim compressive stress 1 MN / m ^2, propylene bursting compressive stress of 100 MN / m ^2.

In the case of a test tube made of foam, its strength will depend on the value of the apparent density of the foam. Polyfoam PHV-1 with a density of 0.2 g / cm ³ has a breaking stress of compression equal to 2.6 Mn / m ² , respectively, at a density of 0.001 g / cm ³ breaking stress of compression will be 0.015 Mn / m ² .

The increased reliability of holding the tube with mechanical devices or fingers during operation is shown in Fig. 8. It is most convenient to hold the tube, pressing it in the direction of 63 and 64. In this case, the contact area of the tube and the holding means is maximum.

Thus, the invention provides for obtaining the technical results declared in the “disclosure of the invention” section, namely:

the process of heat transfer, different on the surface of the tube, is provided from the source of radiant energy located on the outside of the tube to the substance in the tube through the tube wall;

provides increased resistance to destruction with increasing internal pressure in a closed tube;

provides increased reliability of holding the tube with mechanical devices or fingers during operation.

Literature

1. Zavgorodniy V.K. and others. Equipment for plastic processing enterprises. - L., 1972

2. Package, No. 1, 2000, Kursiv Publishing House, Moscow.

Claims (10)

1. The test tube containing the housing, and in cross section, the test tube contains one line of the external boundary of the section and one line of the internal boundary of the section, characterized in that the line of the external border of the section from all possible pairs of points contains two points that are farthest from each other, and the line of the internal the boundary of the section of various pairs of points contains two points that are farthest from each other; and a straight line drawn on the section plane through the points farthest from each other and located on the line of the outer boundary of the section is located at an angle from 0.017 to 3.123 rad to a straight line drawn on the section plane through the points farthest from each other and located on the line of the inner boundary of the section, and the thickness of the tube along the outer boundary of the section is variable; and, in addition, one of the sections of the line of the outer boundary of the section in a rectangular coordinate system on the plane is described by the equation (X / A) ² - (Y / B) ² -1 = 0, where X and Y are the coordinates; A and B are rational numbers other than zero, and also one of the sections of the line of the internal boundary of the section in a rectangular coordinate system on the plane is described by the equation (X / C) ² - (Y / D) ² -1 = 0, where X and Y are the coordinates; C and D are non-zero rational numbers. 2. The tube according to claim 1, characterized in that the part of the tube body is made in the form of a tube. 3. The tube according to claim 1, characterized in that a part of the tube body, in particular 0.5: 0.9, of the length of the tube body, is made with a variable outer diameter along the length of the case, and the ratio of the maximum diameter to the minimum diameter is from 1.1 to 10. 4. The tube according to claim 1, characterized in that a part of the tube body, in particular 0.5: 0.9, of the length of the tube body, is made with a variable inner diameter along the length of the case, and the ratio of the maximum diameter to the minimum diameter ranges from 1.1 to 10. 5. The test tube according to claim 1, characterized in that it is made with a density (at 20 ° C) from 0.92 to 2.00 g / cm ³ . 6. The tube according to claim 1, characterized in that it is made with a breaking stress during transverse compression of the tube from 0.015 to 1400 Mn / m ² . 7. The tube according to claim 1, characterized in that the part of the tube body is multilayer, for example of two layers. 8. The tube according to claim 1, characterized in that part of the tube or the entire tube is made of plastic. 9. The test tube of claim 8, characterized in that a thermoplastic polymer is used as the plastic. 10. The test tube according to claim 9, characterized in that polystyrene or polypropylene is used as the thermoplastic polymer.

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