KR101612316B1 - Multi-test tube supporter - Google Patents

Abstract

The present invention relates to a multipurpose test tube rack which can mount test tubes and mass cylinders together. The multipurpose test tube rack comprises: a base plate arranged to level with the ground; a plurality of vertical bars arranged perpendicular to both sides of the base plate; a test tube insert which is arranged to be separated from the bottom of the base plate by a certain height, and to which the bottom of a test tube is inserted; a mass cylinder insert arranged to be separated from the bottom of the base plate by the width of a support plate of the mass cylinder and forms a cylinder insertion space to which the support plate is inserted; a test tube upper support bar which is inserted between a pair of neighboring vertical bars and supports the upper flank of a test tube inserted through the test tube insert; and a mass cylinder upper support bar which is detachably inserted to the vertical bars and supports the upper flank of a mass cylinder inserted through the mass cylinder insert.

Description

Multi-test tube holder {MULTI-TEST TUBE SUPPORTER}

The present invention relates to a multi-test stand, and more particularly, to a multi-test stand capable of securely mounting a test tube and a mass cylinder together.

The test tube is used to mix the reagent and the test solution and to see the reaction. The test tube is usually made of a transparent glass material so that the reaction of the internal reagents can be visually confirmed from the outside. Therefore, the test tube is damaged by the impact during the test or the washing process. Therefore, a test tube is used for safe storage of test tubes. An example of a test tube is disclosed in Published Utility Model No. 1982-0001071, " Prefabricated Test Generator. "

Mass cylinders, on the other hand, are widely used in experiments with test tubes as experimental instruments for measuring the volume of liquids. The mass cylinder has a body in which a solution to be measured is placed, and a pedestal for holding the body horizontally on the ground. Mass cylinders are generally made of glass with a low coefficient of thermal expansion in order to prevent errors in volume measurement due to the volume change depending on the temperature change. Therefore, due to the physical characteristics of the mass cylinder which is weak to impact, a large number of mass cylinders are damaged during the experiment or storage. That is, even if the diameter of the receiving portion is made so large that the mass cylinder is not easily tilted, the mass cylinder may fall over due to inadvertent physical contact during the experiment or during storage.

Test tubes and mass cylinders are often used together for the experiment, but there are no cradles that can be stored together. Particularly, since there is no separate means for storing the mass cylinder, there is a risk of damage during storage.

An object of the present invention is to provide a multi-tube holder that can safely store both a test tube and a mass cylinder together.

Another object of the present invention is to provide a multi-tube holder which can improve the stability of storage by contacting and supporting the lower portion and the upper portion of the test tube and the mass cylinder.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by a multi-tube holder which is capable of mounting a test tube and a mass cylinder together. The multi-test tube holder of the present invention comprises: a base plate horizontally disposed on the ground; A plurality of vertical bars vertically disposed on opposite sides of the base plate; A test tube insertion portion which is disposed at a predetermined height from the bottom of the base plate and into which a lower portion of the test tube is inserted; A mass cylinder inserting unit arranged at a distance from the bottom of the base plate by a thickness of the pedestal of the mass cylinder to form a cylinder inserting space into which the pedestal is inserted; A test tube upper support bar inserted between a pair of adjacent vertical bars and supporting an upper side surface of the test tube inserted into the test tube insertion portion; And a mass cylinder upper support bar detachably inserted into the plurality of vertical bars and supporting an upper side surface of the mass cylinder inserted into the mass cylinder insertion portion.

According to an embodiment of the present invention, the test tube insertion portion includes a rectangular frame which is coupled to the bottom surface of the base plate at a predetermined height, A plurality of connecting bars coupled at regular intervals along a longitudinal direction of the rectangular frame; And a compartment bar which is coupled across the plurality of connection bars to form a plurality of test tube insertion holes corresponding to the diameter of the test tube between the plurality of connection bars and the square frame.

According to one embodiment, the mass cylinder inserting portion includes a pair of guides (not shown) coupled to the bottom surface of the base plate at a distance corresponding to the diameter of the mass cylinder, Bar; And a movement restricting bar disposed at an inner end of the guide bar at a distance from the bottom surface of the base plate in the longitudinal direction of the base plate by the thickness of the pedestal to form the cylinder insertion space.

According to an embodiment of the present invention, the upper connecting bar may be coupled to the connecting bar so as to guide the test tube to the test tube insertion hole.

According to an embodiment of the present invention, there is further provided a cylinder supporting bar rest which is laterally coupled to an upper portion of the plurality of vertical bars, wherein both ends of the upper bar are bent in a downward direction, As shown in Fig.

The multi-tube holder according to the present invention can mount the test tube and the mass cylinder together. In the multi-test tube holder according to the present invention, the round bottom portion of the test tube is inserted into the test tube insertion hole to fix the position, and the upper portion is secured between the upper support bars of the test tube to fix the position securely.

Further, the pedestal of the mass cylinder is inserted into the cylinder insertion space while being guided between the pair of guide bars, and the upper part of the mass cylinder is supported by the detachable mass cylinder upper support bar.

Therefore, even if an external force is applied, the lower part and the upper part of the test tube and the mass cylinder can be fixed in a double position, and can be safely stored without falling down.

1 is an exemplary view showing a state in which a test tube and a mass cylinder are mounted together on a multi-test tube holder according to the present invention,
FIG. 2 is a perspective view showing a state where a test tube is inserted into a multi-test tube holder according to the present invention,
3 and 4 are perspective views illustrating a process of inserting a mass cylinder into a multi-test tube holder according to the present invention,
5 is a cross-sectional view showing a cross-sectional structure taken along the line AA in Fig.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is an exemplary view showing a state in which a test tube 10 and a mass cylinder 20 are mounted together on a multi-test tube holder 100 according to the present invention.

As shown in the figure, the test tube 10 and the mass cylinder 20 may be mounted together in the multi-test tube holder 100 according to the present invention. In addition, the test tube 10 and the mass cylinder 20 can independently and independently support the lower part and the upper part, respectively, so that the test tube 10 and the mass cylinder 20 can be stably maintained in an independent state.

2 is a perspective view showing a state where the test tube 10 is inserted into the multi-test tube holder 100 according to the present invention. As shown in the figure, the multi-test tube holder 100 according to the present invention includes a base plate 110 horizontally disposed on the ground, a plurality of vertical bars 120 and 120a vertically coupled to both sides of the base plate 110, A test tube insertion portion 130 disposed at a predetermined height from the bottom surface of the base plate 110 to support the lower portion of the test tube 10 and a lower portion of the mass cylinder 20 provided at one side of the test tube insertion portion 130. [ A test tube upper support bar 150 for supporting the upper portion of the test tube 10 and a mass cylinder upper support bar 160 for supporting the upper portion of the mass cylinder 20 do.

Here, the test tube 10 is formed in the form of a glass tube having a small diameter and a long length. The lower portion 13 of the test tube 10 is rounded in a semicircular shape, and the upper portion of the test tube 10 is closed or opened by the cap 11.

The mass cylinder 20 is formed larger in diameter than the test tube 10. A pedestal 21 is provided at the bottom of the mass cylinder 20.

The base plate 110 is formed of a plate-like material having a predetermined area. The base plate 110 is horizontally disposed on the ground and is coupled to the vertical bars 120 and 120a. The area of the base plate 110 may be determined according to the number and specifications of the test tube 10 and the mass cylinder 20 to be mounted.

The vertical bars 120 and 120a are vertically coupled to both sides of the base plate 110. The plurality of vertical bars 120 and 120a are coupled along the side surface of the base plate 110 at regular intervals. At this time, a plurality of vertical test bars 120 supporting the test tube 10 are disposed on one side of the base plate 110, and a mass cylinder side vertical bar 120a supporting the mass cylinder 20 beside the test bars Respectively.

In the multi-test tube holder 100 according to the preferred embodiment of the present invention, three test bars 120 are provided facing each other on both sides and three mass cylinder-side vertical bars 120a facing each other on both sides.

The vertical bar 120 and the vertical bar 120a are coupled to each other by a rectangular frame rest 121. The test bar supporting bar 123 is coupled to the upper portion of the test vertical bar 120, The cylinder supporting bar rest 125 is engaged.

The rectangular frame holder 121 is coupled to both ends of the base plate 110 to support the vertical bars 120 and 120a and the rectangular frame 131 of the test tube insertion portion 130. The rectangular frame rest 121 is formed in a bar shape, and the vertical bars 120 and 120a are coupled to the outer side and the rectangular frame rest 121 is coupled to the upper side.

The test tube support bar rest 123 is coupled to the upper inside of the test observing vertical bar 120 as shown in FIG. 2 to allow the test tube support bar 150 to engage. The test tube supporting bar 123 is bent in the shape of "a" so that its side is fixed to the test vertical bar 120 and the test tube supporting bar 150 is fixed to the upper surface of the bent portion.

The cylinder supporting bar rest 125 is laterally coupled to the upper outer side of the mass cylinder side vertical bar 120a. As shown in FIG. 3, the upper support bar 160 of the mass cylinder is detachably mounted on the upper portion of the cylinder support bar rest 125. Here, the thickness of the cylinder supporting bar rest 125 is formed to be capable of engaging with the engaging projection 161 formed at the end of the mass cylinder upper supporting bar 160.

Here, the base plate 110, the vertical bars 120 and 120a, the rectangular frame rests 121, the test tube supporting bar rests 123, and the cylinder supporting bar rests 125 may be made of wood, synthetic resin, or metal. The vertical bar 120 and 120a, the rectangular frame holder 121, the test tube support bar holder 123 and the cylinder support bar holder 125 may be adhesives or bolts, depending on the material of the multiple test tube holder 100, , Welding, or the like.

The test tube insertion portion 130 supports the lower portion of the test tube 10. 2, the test tube inserting unit 130 includes a rectangular frame 131 mounted on the rectangular frame rest 121 and a plurality of connecting bars (not shown) coupled at regular intervals in the longitudinal direction of the rectangular frame 131 133 and a dividing bar 137 which is coupled to the connecting bar 133 and divides a plurality of test tube insertion holes 135.

The rectangular frame 131 and the plurality of connection bars 133 are integrally formed. The rectangular frame 131 is mounted on a pair of rectangular frame rests 121 disposed on both sides of the base plate 110. Thereby, a difference in height is produced between the rectangular frame 131 and the base plate 110 as much as the rectangular frame rest 121.

The plurality of connection bars 133 are spaced apart from each other by a predetermined distance. And the partitioning bar 137 is coupled across the plurality of connecting bars 133. The test tube insertion hole 135 is formed in the spacing space between the plurality of connection bars 133 by the partitioning bar 137. [ In the multi-test tube holder 100 of the present invention, one compartment bar 137 is coupled to form a test tube insertion hole 135 on both sides of the compartment bar 137. However, this is merely an example, and in some cases, the two compartment bars 137 may be combined to form three test tube insertion holes 135 between the compartment bars 137.

The number of the connection bars 137 may be determined in consideration of the dimensions of the test tube 10 to be inserted and the size of the rectangular frame 131 and the connection bar 133.

In some cases, the partitioning bars 137 may be eccentrically joined to one side so that test tube insertion holes 135 of different sizes may be formed on both sides of the partitioning bar 137. In this case, test tubes 10 of different specifications can be inserted together.

The mass cylinder inserting portion 140 is coupled to the base plate 110 between the mass cylinder side vertical bars 120a. The mass cylinder inserting section 140 guides the mass cylinder 20, which is relatively large in size and heavy compared to the test tube 10, to be safely moved to the multi-test tube holder 100, and fixes the position of the tray 21 .

The mass cylinder inserting portion 140 includes a guide bar 141 coupled to the plate surface of the base plate 110 from outside to inside to guide the movement of the mass cylinder 20, And a movement restricting bar 143 coupled to the mass cylinder 20 to restrict movement of the mass cylinder 20.

The guide bars 141 are provided on the upper surface of the base plate 110, as shown in FIG. The distance W between the pair of guide bars 141 is provided corresponding to the diameter R of the pedestal 21 of the mass cylinder 20. The user moves the mass cylinder 20 inwardly from the side surface of the base plate 110 and inserts it between the pair of guide bars 141. When the pedestal 21 is inserted between the guide bars 141, the mass cylinder 20 is pressed so that the pedestal 21 is inserted into the cylinder insertion space 145 between the movement restricting bar 143 and the base plate 110 .

The movement restricting bar 143 is laterally coupled to the ends of the plurality of guide bars 141. The movement restricting bar 143 forms a cylinder inserting space 145 as much as the height of the guide bar 141 with respect to the base plate 110. Whereby the pedestal 21 is inserted into the cylinder insertion space 145 and the mass cylinder 20 extending to the upper portion of the pedestal 21 is held in contact with and supported by the movement restricting bar 143.

The test tube upper support bar 150 is mounted on the test tube support bar rest 123 to support the upper portion of the test tube 10 inserted into the test tube insertion portion 130. The test tube upper support bar 150 is inserted and fixed between neighboring test test vertical bars 120. At this time, both ends of the test tube supporting bar 150 are fixed to the test tube supporting bar rest 123 provided inside the test observing vertical bar 120, and are fixed by an adhesive means such as an adhesive.

On the other hand, the plurality of test tube supporting bars 150 are fixed by the upper connecting bar 151 along the longitudinal direction. The upper connection bar 151 is coupled to the upper test support bar 150 at a position corresponding to the connection bar 133. As a result, the upper connection bar 151 and the upper test support bar 150 form a lattice shape, and a test tube insertion hole 135 is formed in the lattice.

The user can insert the test tube 10 into the test tube insertion hole 135 to fix the position of the test tube 10.

The mass cylinder upper support bar 160 is detachably coupled to the cylinder side vertical bar 120a to support the upper side so that the mass cylinder 20 inserted into the mass cylinder insertion portion 140 is not released to the outside.

The mass cylinder upper support bar 160 is formed to have a length corresponding to the length of the base plate 110. The mass cylinder upper support bar 160 is inserted between the adjacent cylinder side vertical bars 120a.

Both ends of the mass cylinder upper support bar 160 are provided with a locking protrusion 161 bent downward. 3 and 4, the mass cylinder upper support bar 160 is seated on the cylinder support bar rest 125 when inserted between the cylinder side vertical bars 120a and the rest projection 161 is engaged with the cylinder support bar rest 120 (Not shown).

The upper support bar 160 of the mass cylinder supports the upper side of the mass cylinder 20 and blocks the mass cylinder 20 from being released to the outside. The pedestal 21 of the mass cylinder 20 is held in contact with the movement limiting bar 143 in a state of being inserted in the cylinder insertion space 145 and the upper portion of the mass cylinder 20 is supported by the upper portion of the mass cylinder upper support bar 160 So that the position is fixed. Also, since the pedestal 21 is supported inside the pair of guide bars 141, the flow on the upper surface of the base plate 110 is also limited.

A manufacturing process and a use process of the multi-test tube holder 100 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 5. FIG.

In order to manufacture the multi-test tube holder 100, the rectangular frame holder 121 is coupled to both sides of the upper surface of the base plate 110. A plurality of vertical bars 120 and 120a are arranged outside the rectangular frame holder 121. The test bar 120 and the cylinder bar 120a are arranged at regular intervals and the test bar supporting bar 123 is coupled to the inside of the upper part of the test bar vertical bar 120. Then, the cylinder supporting bar rest 125 is coupled to the upper outside of the cylinder-side vertical bar 120a.

The test tube insertion portion 130 and the mass cylinder insertion portion 140 are coupled to the bottom surface of the base plate 110, respectively. The rectangular frame 131 and the connecting bar 133 are coupled to each other on the rectangular frame rest 121 and the partitioning bar 137 is coupled to cross the center area of the connecting bar 133, ).

A plurality of guide bars (141) are coupled from the outside of the base plate (110) to the inside. The guide bars 141 are arranged so that two of them are paired. And the movement restricting bar 143 is engaged with the upper portion of the inner end of the guide bar 141.

The test tube supporting bar 150 is coupled to the test tube supporting bar rest 123 and the mass cylinder upper supporting bar 160 is coupled to the cylinder supporting bar rest 125 to complete the assembly of the multiple test tube rest 100. The mass cylinder upper support bar 160 is detachably provided.

When the user intends to mount the test tube 10 on the multi-test tube holder 100 while the reagent sample is being tested using the mass cylinder 20 and the test tube 10, as shown in FIG. 3, 150 and the upper connection bar 151. The test tube 10 is inserted into the space between the upper connection bar 151 and the upper connection bar 151,

5, the round bottom 13 of the test tube 10 is inserted into the rectangular frame 131, the connecting bar 133, and the separating bar 137. The test tube 10 is inserted into the test tube insertion portion 130, Inserted into the test tube insertion hole 135 surrounded by the test tube insertion hole 135. The upper portion of the test tube 10 is supported between neighboring test tube support bars 150. As a result, the lower part of the test tube 10 is surrounded by the connecting bar 133, the square frame 131 and the dividing bar 137, and the upper part is supported by the upper test bar supporting bar 150, do. Therefore, even if an impact is applied from the outside, the standing position of the test tube 10 can be stably maintained.

3, when the user wishes to mount the mass cylinder 20 on the multi-test tube holder 100, the pedestal 21 under the mass cylinder 20 is moved between the pair of guide bars 141 . The pedestal 21 is pushed inward along the guide bar 141 to insert the pedestal 21 into the cylinder inserting space 145 between the movement restricting bar 143 and the base plate 110.

At this time, the remaining area of the pedestal 21 remains in contact with the pair of guide bars 141.

The user inserts the upper portion of the mass cylinder upper support bar 160 into the space between the cylinder side vertical bars 120a so that the engagement protrusion 161 is engaged with the cylinder support bar rest 125 as shown in FIG. 5, the position of the mass cylinder upper support bar 160 is fixed, and the upper portion of the mass cylinder 20 is positioned between the test tube upper support bar 150 and the mass cylinder upper support bar 160 . Therefore, even if an external force is applied to the mass cylinder 20, the mass cylinder 20 can be kept in a self-standing state and can be safely stored without falling.

As described above, the multi-tube holder according to the present invention can mount the test tube and the mass cylinder together. In the multi-test tube holder according to the present invention, the round bottom portion of the test tube is inserted into the test tube insertion hole to fix the position, and the upper portion is secured between the upper support bars of the test tube to fix the position securely.

Further, the pedestal of the mass cylinder is inserted into the cylinder insertion space while being guided between the pair of guide bars, and the upper part of the mass cylinder is supported by the detachable mass cylinder upper support bar.

Therefore, even if an external force is applied, the lower part and the upper part of the test tube and the mass cylinder can be fixed in a double position, and can be safely stored without falling down.

The embodiments of the multi-tube holder of the present invention described above are merely illustrative and those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. It will be possible. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: Multi-test tube holder 110: Base plate
120,120a: vertical bar 121: square frame cradle
123: Test tube support bar stand 125: Cylinder support bar stand
130: Test tube insertion part 131: Square frame
133: Connection bar 135: Test tube insertion hole
137: compartment bar 140: mass cylinder insert part
141: guide bar 143: movement limit bar
145: sealer insertion space 150: test tube upper support bar
151: Upper connection bar 160: Mass cylinder upper support bar
161:

Claims (5)

In a multi-tube holder that can hold a test tube and a mass cylinder together,
A base plate horizontally disposed on the ground;
A plurality of vertical bars vertically disposed on opposite sides of the base plate;
A test tube insertion portion which is disposed at a predetermined height from the bottom of the base plate and into which a lower portion of the test tube is inserted;
A mass cylinder inserting unit arranged at a distance from the bottom of the base plate by a thickness of the pedestal of the mass cylinder to form a cylinder inserting space into which the pedestal is inserted;
A test tube upper support bar inserted between a pair of adjacent vertical bars and supporting an upper side surface of the test tube inserted into the test tube insertion portion;
And a mass cylinder upper support bar detachably inserted into the plurality of vertical bars to support an upper side surface of the mass cylinder inserted into the mass cylinder insertion portion.
The method according to claim 1,
The test tube insertion part
A square frame coupled to the bottom surface of the base plate at a predetermined height;
A plurality of connecting bars coupled at regular intervals along a longitudinal direction of the rectangular frame;
And a compartment bar coupled to the plurality of connecting bars to form a plurality of test tube insertion holes corresponding to the diameter of the test tube between the plurality of connection bars and the square frame.
3. The method of claim 2,
Wherein the mass cylinder inserting portion includes:
A pair of guide bars coupled to the bottom surface of the base plate at a distance corresponding to the diameter of the mass cylinder from outside to inside in a predetermined length to guide the movement of the mass cylinder;
And a movement restricting bar disposed at an inner end of the guide bar at a distance from the bottom surface of the base plate in the longitudinal direction of the base plate by the thickness of the pedestal to form the cylinder insertion space.
The method of claim 3,
Further comprising an upper connecting bar coupled to the connecting bar so as to guide the test tube to the test tube insertion hole on the upper support bar of the test tube.
5. The method of claim 4,
Further comprising a cylinder support bar rest coupled transversely to the top of the plurality of vertical bars,
Wherein the mass cylinder upper support bar is bent at both ends in a downward direction and engaged with the cylinder supporting bar rest.

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