CN221107973U - Test tube oscillating device for sample processing - Google Patents

Abstract

The utility model discloses a test tube vibration device for sample processing, which comprises a base, wherein the top of the base is provided with a notch, and the device also comprises a test tube clamping assembly and a vibration power assembly, wherein the test tube clamping assembly is provided with a test tube seat and an upper pressing plate.

Description

Test tube oscillating device for sample processing

Technical Field

The utility model relates to the technical field of test tube vibration devices, in particular to a test tube vibration device for sample processing.

Background

At present, little scientific technology has been developed to understand various things and their changing conditions. The mutual fusion of different matters can be used for understanding the matters and finding out novel matters produced after the fusion. In the experimental process, an experimenter needs to put a certain amount of reactant in a test tube for full oscillation, and the manual oscillation is low in efficiency and cannot enable the reaction to be complete, so that the experiment personnel needs to have a test tube oscillator to assist in working.

And current test tube oscillating device has certain drawback, at first, current oscillating device is inconvenient to fix a position the centre gripping to the test tube of not co-altitude, and secondly, current oscillating device can't drive the test tube and carry out multi-direction oscillation to influence the effect of oscillation.

Disclosure of utility model

In order to solve the problems, the utility model provides a test tube oscillating device for sample processing, which is realized by the following technical scheme.

The utility model provides a sample processing is with test tube concussion device, includes the base, the notch has been seted up at the top of base, still including test tube clamping assembly and concussion power module, test tube clamping assembly is equipped with test tube seat, top board, the central position fixedly connected with sleeve pipe in test tube seat top, and the central position rotation in test tube seat top is connected with the threaded rod, the bottom fixedly connected with spliced pole of test tube seat, the bottom fixedly connected with intubate of top board, threaded hole has been seted up jointly between top board and the intubate, concussion power module is equipped with servo motor, servo motor's output shaft fixedly connected with centrifugal pull rod.

Further, the upper pressing plate is located right above the test tube seat, test tube grooves are formed in the top of the test tube seat, and eight test tube grooves are distributed annularly.

Further, one end of the threaded rod is located inside the sleeve, and the threaded rod is in threaded fit with the cannula through the threaded hole.

Further, one end of the cannula is movably embedded into the sleeve, two limiting grooves are formed in the inner wall of the sleeve, and a limiting block which is in sliding fit with the limiting grooves is fixedly connected to one end of the cannula embedded into the sleeve.

Further, the servo motor is arranged in the notch, and the other end of the centrifugal pull rod is rotatably sleeved on one end of the connecting column.

Further, an inner gear ring is fixedly connected to the inner wall of the notch, and an outer gear ring meshed with the inner gear ring is fixedly sleeved on the outer surface of the test tube seat.

Further, four spherical protruding blocks distributed in an annular mode are fixedly connected to the bottom of the test tube seat, a plurality of sliding grooves distributed in an annular mode are formed in the inner wall of the notch, and the sliding grooves are in sliding fit with the spherical protruding blocks.

The device has the beneficial effects that in the working process, the test tube is firstly placed on the test tube groove formed in the top of the test tube seat, the test tube is clamped and limited by adjusting the lifting of the upper pressing plate, then the servo motor is opened to drive the centrifugal pull rod to rotate, the centrifugal pull rod can drive the connected connecting column to do circular motion, and the connecting column can drive the connected test tube seat to do circular motion.

Drawings

In order to more clearly illustrate the technical solutions of the present utility model, the drawings that are needed in the description of the specific embodiments will be briefly described below, it being obvious that the drawings in the following description are only some examples of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1: the utility model discloses a structure schematic diagram of a test tube oscillating device for sample treatment;

Fig. 2: the utility model relates to a connection schematic diagram of a base and a test tube seat;

Fig. 3: an enlarged view of a portion of the portion a shown in fig. 2;

fig. 4: the cross-section of the test tube seat and the sleeve of the utility model;

fig. 5: the upper pressing plate and the cannula are structurally schematic.

The reference numerals are as follows:

1. a base; 101. a notch; 102. an inner gear ring; 103. a chute;

2. A test tube holder; 201. an outer toothed ring; 202. spherical protruding blocks; 203. a connecting column; 204. a test tube groove; 205. a sleeve; 206. a limit groove; 207. a threaded rod;

3. An upper press plate; 301. a cannula; 302. a limiting block; 303. a threaded hole;

4. a servo motor; 401. and (5) centrifuging the pull rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-5, the present utility model has the following specific examples.

Examples:

A test tube vibration device for sample processing, which comprises a base 1, a notch 101 is arranged at the top of the base 1, and also comprises,

The test tube clamping assembly is provided with a test tube seat 2 and an upper pressing plate 3, a sleeve 205 is fixedly connected to the center of the top of the test tube seat 2, a threaded rod 207 is rotatably connected to the center of the top of the test tube seat 2, a connecting column 203 is fixedly connected to the bottom of the test tube seat 2, an insertion tube 301 is fixedly connected to the bottom of the upper pressing plate 3, and a threaded hole 303 is formed between the upper pressing plate 3 and the insertion tube 301;

The vibration power assembly is provided with a servo motor 4, and an output shaft of the servo motor 4 is fixedly connected with a centrifugal pull rod 401.

Through adopting above-mentioned technical scheme, when using the device, firstly place the test tube on the test tube groove 204 that test tube seat 2 top was offered, go up and down through adjusting top board 3 and carry out the centre gripping spacing to the test tube, then drive centrifugal pull rod 401 rotatory through opening servo motor 4, centrifugal pull rod 401 can drive the spliced pole 203 of connection and do circular motion, spliced pole 203 can drive the test tube seat 2 of connection and do circular motion, simultaneously, test tube seat 2 is connected through outer ring gear 201 and ring gear 102 meshing, thereby make test tube seat 2 rotate, can drive the test tube and carry out many reverse centrifugal concussions, moreover, the steam generator is rational in infrastructure, the effect of test tube concussion is convenient for improve.

Specifically, the upper pressing plate 3 is located right above the test tube seat 2, the top of the test tube seat 2 is provided with test tube grooves 204, and the number of the test tube grooves 204 is eight in annular distribution.

Through adopting above-mentioned technical scheme, test tube groove 204 that test tube seat 2 top was seted up can be placed the test tube quick positioning, makes test tube seat 2 and upper plate 3 that mutually support carry out spacing centre gripping to the test tube simultaneously, and wherein, test tube seat 2 and upper plate 3 all adopt rubber material to make, can protect the spacing test tube of centre gripping.

Specifically, one end of the threaded rod 207 is located inside the sleeve 205, and the threaded rod 207 is threadedly engaged with the cannula 301 through the threaded hole 303;

One end of the insertion tube 301 is movably embedded into the sleeve 205, two limiting grooves 206 are formed in the inner wall of the sleeve 205, and one end of the insertion tube 301 embedded into the sleeve 205 is fixedly connected with a limiting block 302 in sliding fit with the limiting grooves 206.

Through adopting above-mentioned technical scheme, can fix a position the centre gripping to the test tube, the top board 3 that sets up promptly imbeds sleeve 205 inside mutual sliding fit through intubate 301, wherein, slide each other between stopper 302 and the spacing groove 206, the threaded rod 207 that sets up rotates inside sleeve 205, simultaneously, threaded rod 207 passes through screw thread fit between stopper 302 and the intubate 301, thereby can rotate threaded rod 207 and drive intubate 301 and go up and down, intubate 301 drives top board 3 and goes up and down, then can carry out spacingly to the test tube of placing between top board 3 and test tube seat 2, wherein, test tube groove 204 that test tube seat 2 top was seted up can fix a position the test tube.

Specifically, the servo motor 4 is installed inside the notch 101, and the other end of the centrifugal pull rod 401 is rotatably sleeved on one end of the connecting column 203.

Through adopting above-mentioned technical scheme, the servo motor 4 that sets up can drive centrifugal pull rod 401 and rotate, and centrifugal pull rod 401 can drive the spliced pole 203 rotation of connection to make spliced pole 203 can drive test tube seat 2 and carry out annular motion.

Specifically, the inner wall of the notch 101 is fixedly connected with an inner gear ring 102, and the outer surface of the test tube seat 2 is fixedly sleeved with an outer gear ring 201 engaged with the inner gear ring 102.

Through adopting above-mentioned technical scheme, the external tooth ring 201 that test tube seat 2 cup jointed can be connected with the meshing between the ring gear 102 to the rotation can be carried out when test tube seat 2 carries out annular motion, thereby can improve centrifugal effect.

Specifically, four spherical protruding blocks 202 distributed in an annular mode are fixedly connected to the bottom of the test tube seat 2, a plurality of sliding grooves 103 distributed in an annular mode are formed in the inner wall of the notch 101, and the sliding grooves 103 are in sliding fit with the spherical protruding blocks 202.

Through adopting above-mentioned technical scheme, the spherical lug 202 that test tube seat 2 bottom set up can slide the collision in the inside a plurality of spout 103 that notch 101 inner wall was seted up to make test tube seat 2 have the effect of vibration at rotatory in-process.

The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not intended to be exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.

Claims (7)

1. The utility model provides a test tube concussion device for sample processing, includes base (1), notch (101) are seted up at the top of base (1), its characterized in that: also comprises a medicine liquid, and the medicine liquid also comprises,

The test tube clamping assembly is provided with a test tube seat (2) and an upper pressing plate (3), a sleeve (205) is fixedly connected to the position of the top center of the test tube seat (2), a threaded rod (207) is rotationally connected to the position of the top center of the test tube seat (2), a connecting column (203) is fixedly connected to the bottom of the test tube seat (2), a cannula (301) is fixedly connected to the bottom of the upper pressing plate (3), and threaded holes (303) are formed between the upper pressing plate (3) and the cannula (301);

The vibration power assembly is provided with a servo motor (4), and an output shaft of the servo motor (4) is fixedly connected with a centrifugal pull rod (401).

2. The cuvette oscillator for sample processing according to claim 1, wherein: the upper pressing plate (3) is located right above the test tube seat (2), test tube grooves (204) are formed in the top of the test tube seat (2), and the number of the test tube grooves (204) is eight in annular distribution.

3. The cuvette oscillator for sample processing according to claim 1, wherein: one end of the threaded rod (207) is positioned inside the sleeve (205), and the threaded rod (207) is in threaded fit with the cannula (301) through the threaded hole (303).

4. A cuvette oscillator for sample processing according to claim 2, wherein: one end of the insertion tube (301) is movably embedded into the sleeve (205), two limiting grooves (206) are formed in the inner wall of the sleeve (205), and a limiting block (302) in sliding fit with the limiting grooves (206) is fixedly connected to one end of the insertion tube (301) embedded into the sleeve (205).

5. The cuvette oscillator for sample processing according to claim 1, wherein: the servo motor (4) is arranged in the notch (101), and the other end of the centrifugal pull rod (401) is rotatably sleeved on one end of the connecting column (203).

6. The cuvette oscillator for sample processing according to claim 1, wherein: the inner wall of the notch (101) is fixedly connected with an inner gear ring (102), and the outer surface of the test tube seat (2) is fixedly sleeved with an outer gear ring (201) which is meshed with the inner gear ring (102).

7. The cuvette oscillator for sample processing according to claim 1, wherein: four spherical protruding blocks (202) which are distributed in an annular mode are fixedly connected to the bottom of the test tube seat (2), a plurality of sliding grooves (103) which are distributed in an annular mode are formed in the inner wall of the notch (101), and the sliding grooves (103) are in sliding fit with the spherical protruding blocks (202).