CN211436007U - Shake flask device for conveying belt - Google Patents

Abstract

The utility model provides a bottle shaking device for a conveyer belt, which comprises a shaking tube seat and a shaking tube device; the tube shaking seat is arranged on the conveying belt, is provided with a through hole into which the test tube can be inserted, and can shake the test tube within a certain angle range; still be equipped with and shake a tub device, shake a tub device and be located the below of shaking the tube socket for the drive test tube shakes. Through setting up the rocker seat at the conveyer belt, with shake a tub device cooperation, can realize the shake bottle operation along with the production line, be convenient for realize the operation of biological field based on the production line.

Description

Shake flask device for conveying belt

Technical Field

The utility model relates to a detection area, especially a shake bottle device for conveyer belt.

Background

Shake flasks are common practice for mixing the various media evenly during the experiment, but shake flask practice in the prior art is usually carried out individually or in batches and is difficult to apply to a production line, which makes it difficult to achieve large-scale production in production or inspection operations involving the biological field. For example CN110052203A biological assay of facilitating use and collection is with even shake bottle device that rocks, including shaking bottle body, backup pad, rotor plate, motor and lower extreme casing, the fixed cover of upper end outer lane department of shaking bottle body is equipped with the iron ring, is equipped with the handle on the right flank of iron ring, the handle is half circle ring structure, the utility model discloses a motor drives the rotor plate and rotates for the dwang of rotor plate one side is circumferential rotation in rotating the annular, can utilize the magnetic suction head of upper end to adsorb the tip downward sloping of iron seat when the dwang rotates, and this has just formed the phenomenon that the body of shaking bottle naturally rocked on the standing groove, and has rocked evenly, and the mode that rocks replaces the pivoted mode, makes liquid degree of mixing higher in shaking bottle body, does benefit to the experiment liquid mixing, and actual experiment effect is better. CN110129194A compound enzyme triangular flask of constant temperature water bath formula device of shaking a bottle, including fixing device, vortex generating device, vertical support device, wave device, spray set, heating device, the inside warm water that is provided with of fixing device, the inside vortex generating device that still is provided with of fixing device, the triangular flask receives warm water buoyancy and vortex generating device to produce the effort of vortex simultaneously, make the inside triangular flask of fixing device swing about, vibrate from top to bottom, and then make the triangular flask shake a bottle abundant, make the material in the triangular flask loose ventilative with the bacterial, prevent the bacterial caking. Meanwhile, the power of the vortex generating device can be adjusted, so that the optimal working power can be optimized according to the expansion process, and the flask shaking effect of the triangular flask can be optimal; a spraying device is also arranged to reduce the temperature of the fermentation of the strains in the triangular flask; the heating device is also arranged, so that the triangular flask in the box body is always in a constant-temperature water bath environment at the temperature of 25-35 ℃, and hypha in the triangular flask can grow favorably. The above-mentioned schemes are single or batch embodiments, and the schemes hinder the efficiency improvement of large-scale production in the biological field.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a shake bottle device for conveyer belt is provided can realize continuous shake bottle operation with the mode of assembly line to realize biological field's large-scale production.

In order to solve the technical problem, the utility model discloses the technical scheme who adopts is: a shake flask device for a conveying belt comprises a shake flask seat and a shake flask device;

the tube shaking seat is arranged on the conveying belt, is provided with a through hole into which the test tube can be inserted, and can shake the test tube within a certain angle range;

still be equipped with and shake a tub device, shake a tub device and be located the below of shaking the tube socket for the drive test tube shakes.

In the preferred scheme, in the tube shaking seat, the swinging ring is movably connected with the conveying belt, and the outer wall of the swinging ring is provided with an arc-shaped section, so that the inserted test tube can be shaken within a certain angle range.

In the preferred scheme, a fixed sleeve is further arranged and fixedly connected with the conveying belt, the swinging ring is movably arranged in the fixed sleeve, and the inner wall of the fixed sleeve is provided with an arc section corresponding to the arc section of the swinging ring.

In a preferred scheme, the structure of the pipe shaking device is as follows: a piston rod of the tube shaking cylinder is fixedly connected with a tube shaking motor, an output shaft of the tube shaking motor is connected with a rotating disc, and when the tube shaking cylinder rises, the rotating disc is contacted with the bottom of the test tube;

the tube shaking device is fixedly arranged on the frame of the tube shaking seat; or the pipe shaking device is arranged on another conveying belt which runs synchronously below the pipe shaking seat;

the outer wall of the swinging ring is also provided with a straight line section or a flange to limit the swinging angle range of the swinging ring.

In the preferred scheme, still be equipped with the solid fixed ring of test tube in the swing ring, the solid fixed ring of test tube and swing ring joint or threaded connection, the solid fixed ring centre of test tube is equipped with the through-hole of different diameters to the test tube of the solid fixed ring adaptation different diameters of test tube through changing.

In the preferred scheme, the rotating disc is provided with a raised edge for limiting the shaking range of the test tube, and the inner diameter of the edge is larger than the diameter of the bottom of the test tube;

the stroke of the pipe shaking cylinder is larger than the height of the raised edge of the rotating disc.

In the preferred scheme, the position that the rolling disc contacts with the test tube bottom is equipped with the rubber or the silica gel material that increases frictional force.

In a preferable scheme, one end of the tube shaking cylinder, which is close to the piston rod, is also provided with a limiting end cover for limiting the rotation of the piston rod, the limiting end cover is provided with a hole for the piston rod to pass through, and the hole and the piston rod form a slidable and non-rotatable structure;

a spring for resetting is arranged in a rod cavity of the tube shaking cylinder.

In a preferred scheme, the cross section of the piston rod is in a non-circular shape, and a hole in the limiting end cover is in a corresponding shape.

In the preferred scheme, the piston rod is welded with parallel limiting rods, and the holes in the limiting end covers are in shapes corresponding to the cross sections of the piston rod and the limiting rods.

The utility model provides a shake bottle device for conveyer belt through setting up the tube seat of shaking at the conveyer belt, with shake the cooperation of tub device, can realize along with the shake bottle operation of production line, is convenient for realize that biological field is based on the operation of production line.

Drawings

The invention will be further explained with reference to the following figures and examples:

fig. 1 is a schematic top view of the overall structure of the present invention.

Fig. 2 is a schematic view of the conveyer belt according to the present invention.

Fig. 3 is a schematic sectional view a-a of fig. 2.

Fig. 4 is a schematic structural view of the pipe shaking device of the present invention.

Fig. 5 is a top view of the pipe shaking device of the present invention.

In the figure: conveyer belt 1 shakes pipe seat 2, swing ring 21, segmental arc 22, straightway 23, fixed cover 24, the solid fixed ring 25 of test tube, test tube feeding device 3, sample liquid supply device 4 shakes pipe device 5, rolling disc 51, shake a tub motor 52, shake a tub cylinder 53, gag lever post 54, spacing end cover 55, spring 56, liquid feeding device 6, test tube jacking device 7, baffle 8, retrieve test tube conveyer belt 9, retrieve test tube conveyer belt 10, test tube 11, first accurate liquid device 12 of joining in marriage, the liquid device 13 is joined in marriage to the second accuracy, test tube recovery conveyer belt 14, baffle 15.

Detailed Description

As shown in FIG. 1, a shaking flask device for a conveyor belt comprises a shaking flask seat 2 and a shaking flask device 5;

the rocker base 2 is mounted on a conveyor belt 1, in which case the conveyor belt 1 is preferably an endless track conveyor belt, for example for a rotating sushi. It is also possible to use ordinary flat rubber strips. Further preferably, the rocking tube base 2 may be provided in plural along the width direction of the conveying belt 1. To improve the efficiency of the production line. The conveyor belt 1 preferably adopts an intermittent stepwise motion.

The tube shaking seat 2 is provided with a through hole into which the test tube 11 can be inserted, and the test tube 11 can be shaken within a certain angle range; with this structure, the test tube 11 can be shaken on the conveyor belt, thereby facilitating the uniform mixing of the medium on the production line.

As shown in FIG. 3, the tube shaking device 5 is located below the tube shaking base 2, and usually the tube shaking device 5 is fixedly installed on the frame of the tube shaking base 2. Further preferably, as shown in fig. 4, the pipe shaking device 5 is mounted on another synchronously running conveyor belt below the pipe shaking seat 2, so that a section of the range in which the pipe shaking device 5 runs constitutes a shaking station. By the structure, the design of the production line is facilitated, namely the production line does not need to pause for too long time at the station due to the requirement of shaking up the station, so that the design of the production line is more flexible. The conveying stroke of the conveying belt on which the pipe shaking device 5 is positioned is smaller than that of the conveying belt 1.

As shown in fig. 3 and 4, the structure of the pipe shaking device 5 is: the piston rod of the tube shaking cylinder 53 is fixedly connected with the tube shaking motor 52, the output shaft of the tube shaking motor 52 is connected with the rotating disc 51, and when the tube shaking cylinder 53 is lifted, the rotating disc 51 is contacted with the bottom of the test tube 11. With this structure, when the rotary disc 51 contacts the bottom of the test tube 11, the test tube 11 rotates with the rotary disc 51 and swings simultaneously with the rotation of the tube-swinging motor 52, thereby constituting a swinging motion.

In the preferred embodiment shown in fig. 3 and 4, the swing ring 21 is movably connected to the conveyor belt 1 in the swing pipe seat 2, and an arc-shaped segment 22 is provided on the outer wall of the swing ring 21 to enable the inserted test pipe 11 to swing within a certain angle range.

In a preferred scheme, as shown in fig. 3 and 4, a fixing sleeve 24 is further provided, the fixing sleeve 24 is fixedly connected with the conveyor belt 1, the swinging ring 21 is movably arranged in the fixing sleeve 24, and an arc-shaped section corresponding to the arc-shaped section of the swinging ring 21 is arranged on the inner wall of the fixing sleeve 24.

Preferably, as shown in fig. 3 and 4, a straight line segment 23 or a flange is further provided on the outer wall of the swing ring 21 to limit the swing angle range of the swing ring 21. By the above solution, the swinging ring 21 is installed reliably and will not be pulled out from the fixing sleeve 24. Preferably, the wobble ring 21 is made of teflon to reduce friction.

The preferred scheme is as in fig. 3, 4, still be equipped with test tube fixed ring 25 in swing ring 21, test tube fixed ring 25 with swing ring 21 joint or threaded connection, be equipped with the through-hole of different diameters in the middle of the test tube fixed ring 25 to the test tube 11 of different diameters is adapted to through changing different test tube fixed ring 25. The clamping is preferably adopted, the outer wall of the test tube fixing ring 25 is provided with a protrusion, the inner wall of the swinging ring 21 is provided with a clamping groove, the protrusion is clamped into the clamping groove, the installation is completed, and the test tube fixing device is very convenient.

In a preferred embodiment, as shown in fig. 3 and 4, the rotating disc 51 is provided with a raised edge for limiting the swing range of the test tube 11, and the inner diameter of the edge is larger than the diameter of the bottom of the test tube 11;

the stroke of the pipe shaking cylinder 53 is greater than the height of the raised edge of the rotating disc 51. Preferably, when the piston rod of the tube rocking cylinder 53 is fully extended, the top end of the test tube 11 will be spaced from the top of the test tube fixing ring 25, thereby leaving room for rocking.

In a preferred scheme, the position where the rotating disc 51 contacts with the bottom of the test tube 11 is provided with rubber or silica gel material for increasing friction force. It is further preferable that the center of the top of the rotating disk 51 is provided with a sharp protrusion to make the bottom of the test tube 11 move more easily toward the edge of the rotating disk 51.

In a preferable scheme, as shown in fig. 4 and 5, a limit end cover 55 for limiting the rotation of the piston rod is further arranged at one end of the tube shaking cylinder 53 close to the piston rod, a hole for the piston rod to pass through is formed in the limit end cover 55, and a slidable and non-rotatable structure is formed between the hole and the piston rod;

preferably, a spring 56 for return is provided in the rod chamber of the rocker cylinder 53. According to the scheme, the structure and control can be simplified, the air source is connected to the rodless cavity of the rocker tube air cylinder 53, and when the rodless cavity needs to be reset, the rodless cavity is connected with the atmosphere through the electromagnetic valve directly.

In a preferred embodiment, the cross section of the piston rod is non-circular, and the hole in the limit end cap 55 is correspondingly shaped. Such as rectangular, oval, etc., whereby the piston rod can be restricted from rotating with the tube motor 52.

In a preferred scheme, as shown in fig. 5, the piston rod is welded with a parallel limit rod 54, and a hole on a limit end cover 55 is in a shape corresponding to the cross-sectional shapes of the piston rod and the limit rod 54. With this structure, the processing is easier.

When in use, as shown in figure 1, a test tube 11 falls into a shaking tube seat 2 of a conveyer belt 1 through a turntable type test tube supply device 3, a medium needing to be uniformly mixed is input through a sample liquid supply device 4 and a recovered test tube conveyer belt 10, the conveyer belt 1 advances to the next station step by step, a piston rod of a shaking tube cylinder 53 of the shaking tube device 5 extends out, a rotating disc 51 jacks up the test tube 11 for a distance, a shaking tube motor 52 is started, the rotating disc 51 drives the bottom of the test tube 11 to shake, the piston rod of the shaking tube cylinder 53 retracts after a preset time is reached, the conveyer belt 1 advances to the next station step, a liquid adding device 6 adds the medium again, the subsequent station, the synchronous shaking tube device 5 performs shaking tube operation at each station to further uniformly mix the medium until the medium moves to the upper side of a test tube jacking device 7, the medium in the test tube at the position of the test tube jacking device 7 or the previous station is pumped away through a lifting suction device, the suction device is not completely shown in the figure, the test tube jacking device 7 jacks up the test tube 11, and the test tube 11 slides into the recovery test tube conveying belt 9 along the baffle plate, so that an automatic continuous shake flask process is completed.

The above embodiments are merely preferred technical solutions of the present invention, and should not be considered as limitations of the present invention, and the features in the embodiments and the examples in the present application may be arbitrarily combined with each other without conflict. The protection scope of the present invention shall be defined by the claims and the technical solutions described in the claims, including the technical features of the equivalent alternatives as the protection scope. Namely, equivalent alterations and modifications within the scope of the invention are also within the scope of the invention.

Claims (10)

1. A shake flask device for conveyer belt, characterized by: it comprises a shaking tube seat (2) and a shaking tube device (5);

the shaking tube seat (2) is arranged on the conveying belt (1), a through hole into which the test tube (11) can be inserted is formed in the shaking tube seat (2), and the test tube (11) can be shaken within a certain angle range;

the tube shaking device (5) is further arranged and located below the tube shaking seat (2) and used for driving the test tube (11) to shake.

2. A roller bottle apparatus for a conveyor belt according to claim 1, wherein: in the shaking tube seat (2), a swinging ring (21) is movably connected with the conveying belt (1), and an arc-shaped section (22) is arranged on the outer wall of the swinging ring (21) so that the inserted test tube (11) can shake within a certain angle range.

3. A roller bottle apparatus for conveyor belts according to claim 2, wherein: the conveying belt conveyor is also provided with a fixed sleeve (24), the fixed sleeve (24) is fixedly connected with the conveying belt (1), the swinging ring (21) is movably arranged in the fixed sleeve (24), and the inner wall of the fixed sleeve (24) is provided with an arc section corresponding to the arc section of the swinging ring (21).

4. A roller bottle apparatus according to claim 2 or 3, wherein: the structure of the pipe shaking device (5) is as follows: a piston rod of the tube shaking cylinder (53) is fixedly connected with the tube shaking motor (52), an output shaft of the tube shaking motor (52) is connected with the rotating disc (51), and when the tube shaking cylinder (53) rises, the rotating disc (51) is contacted with the bottom of the test tube (11);

the tube shaking device (5) is fixedly arranged on the frame of the tube shaking seat (2); or the tube shaking device (5) is arranged on another synchronously running conveying belt below the tube shaking seat (2);

a straight line section (23) or a flange is further provided on the outer wall of the swing ring (21) to limit the swing angle range of the swing ring (21).

5. A roller bottle apparatus according to claim 2 or 3, wherein: still be equipped with the solid fixed ring of test tube (25) in swing ring (21), the solid fixed ring of test tube (25) and swing ring (21) joint or threaded connection, the solid fixed ring of test tube (25) centre is equipped with the through-hole of different diameters to through changing the solid fixed ring of test tube (25) of different diameters's test tube (11).

6. A roller bottle apparatus for conveyor belts according to claim 4 wherein: the rotating disc (51) is provided with a raised edge for limiting the shaking range of the test tube (11), and the inner diameter of the edge is larger than the diameter of the bottom of the test tube (11);

the stroke of the pipe shaking cylinder (53) is larger than the height of the raised edge of the rotating disc (51).

7. A roller bottle apparatus for conveyor belts as in claim 6 wherein: rubber or silica gel materials for increasing friction force are arranged at the contact position of the rotating disc (51) and the bottom of the test tube (11).

8. A roller bottle apparatus for conveyor belts according to claim 4 wherein: one end of the tube shaking cylinder (53) close to the piston rod is also provided with a limiting end cover (55) for limiting the rotation of the piston rod, the limiting end cover (55) is provided with a hole for the piston rod to pass through, and the hole and the piston rod form a slidable and non-rotatable structure in front;

a spring (56) for return is arranged in a rod cavity of the pipe shaking cylinder (53).

9. A roller bottle apparatus for a conveyor belt according to claim 8, wherein: the cross section of the piston rod is in a non-circular shape, and a hole in the limiting end cover (55) is in a corresponding shape.

10. A roller bottle apparatus for a conveyor belt according to claim 8, wherein: the piston rod is welded with a parallel limiting rod (54), and a hole in the limiting end cover (55) is in a shape corresponding to the cross-sectional shapes of the piston rod and the limiting rod (54).

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