CN217614351U - Oscillation device for laboratory water sample detection - Google Patents

Abstract

The utility model discloses a laboratory water sample detects uses oscillation device, including vibration case, case lid, case handle, hasp, connection bandage, control button, lift group price, vibration mounting bracket, accessory plate, auxiliary spring, vibration mechanism and test tube location auxiliary mechanism. The utility model belongs to the technical field of the experiment analysis, specifically a laboratory water sample detects uses oscillation device has increased the portability of device, has improved oscillation device's work efficiency through setting up oscillation mechanism and test tube location complementary unit to and set up the use that the lift group price has improved oscillation device and experience, adopt the box to place, prolonged the life of device, effectively solved the problem that oscillation device is inefficiency in the existing market.

Description

Oscillation device for laboratory water sample detection

Technical Field

The utility model belongs to the technical field of experimental analysis, specifically indicate a laboratory water sample detects uses oscillation device.

Background

The environmental monitoring is the otoscope of environmental protection management and is the basis of environmental protection law enforcement, and an environmental monitoring instrument is an important means and basis for acquiring monitoring data; the oscillator is a test device applied to extraction or leaching in a laboratory, and is widely applied to the industries related to toxicity identification, research, treatment and the like of solid wastes, such as environmental protection, solid waste treatment and the like. However, the existing oscillator is usually exposed in a laboratory and is easy to fall ash, so that vessels in the oscillator need to be cleaned before use, and the oscillator is inconvenient to carry or take, so that a novel oscillation device for laboratory water sample detection is provided.

SUMMERY OF THE UTILITY MODEL

To the above situation, for overcoming prior art's defect, the utility model provides a laboratory water sample detects uses oscillation device has increased the portability of device, has improved oscillation device's work efficiency through setting up oscillation mechanism and test tube location complementary unit to and set up elevating assembly and improve oscillation device's use and experience, adopt box to place, prolonged the life of device, effectively solved the problem of oscillation device inefficiency in the existing market.

The utility model adopts the following technical scheme: the utility model relates to a laboratory water sample detects uses oscillation device, including vibration case, case lid, case handle, hasp, connection bandage, control button, lifting unit, vibration mounting bracket, accessory plate, auxiliary spring, vibration mechanism and test tube location complementary unit, the case lid articulates to be located on the vibration case, the case handle is located on the case lid, the hasp is located between vibration case and the case lid, it locates on the lateral wall of vibration case to connect the bandage, control button locates on the antetheca of vibration case, lifting unit locates in the vibration case, the vibration mounting bracket is located on the lifting unit, the accessory plate is located on the vibration mounting bracket, auxiliary spring locates on the vibration mounting bracket, vibration mechanism locates on the vibration mounting bracket, test tube location complementary unit locates on the vibration mounting bracket and is connected with vibration mechanism.

To further illustrate the present solution, the control button is connected to the lifting assembly, the oscillation mechanism, the test tube positioning assistance mechanism, and the micro-oscillator.

Further, the oscillating mechanism comprises a driving worm, a driven worm wheel, a worm support plate, a worm wheel rotating shaft, an oscillating driving motor, an eccentric wheel, an auxiliary contact plate, a telescopic spring, a fixed guide plate and a reciprocating connecting rod, the worm wheel rotating shaft is rotatably arranged on the oscillating mounting frame, the driven worm wheel is arranged on the worm wheel rotating shaft, the worm support plate is fixedly connected onto the oscillating mounting frame, the driving worm is rotatably arranged on the worm support plate, the oscillating driving motor is arranged on the driving worm, the eccentric wheel is arranged on the worm wheel rotating shaft, the fixed guide plate is arranged on the auxiliary plate, the reciprocating connecting rod is arranged on the fixed guide plate in a penetrating and sliding mode, the auxiliary contact plate is arranged on the reciprocating connecting rod, the telescopic spring is arranged between the auxiliary contact plate and the fixed guide plate, the telescopic spring is arranged on the outer side of the reciprocating connecting rod, and the eccentric wheel is connected with the reciprocating connecting rod in a sliding contact mode.

Further, test tube location complementary unit includes slip direction shell, sliding stand, test tube body, standing groove, miniature electronic jar and guard plate, the slip direction shell is located on the vibration mounting bracket, the sliding stand slides and locates on the slip direction shell, the standing groove is located in the sliding stand, test tube body locates in the standing groove, miniature electronic jar is located in the sliding stand, the guard plate is located in the standing groove and is connected with miniature electronic jar.

Further, be equipped with the protection spring in the standing groove, be equipped with the protection base on the protection spring, the protection base links to each other with test tube body, miniature oscillator is located to the below of standing groove, miniature oscillator has the effect of supplementary oscillation.

Furthermore, the lifting assembly comprises a lifting mounting groove, a lifting threaded rod, a lifting threaded platform, a lifting motor, a connecting column and a supporting plate, the lifting mounting groove is formed in the oscillation box, the lifting threaded rod is rotatably arranged in the lifting mounting groove, the lifting threaded platform is arranged on the lifting threaded rod, the lifting motor is arranged on the oscillation box, the output end of the lifting motor is connected with the lifting threaded rod, the connecting column is arranged on the lifting threaded platform, and the supporting plate is arranged on the connecting column and connected with the oscillation mounting frame; and the driving worm is in meshed connection with the driven worm wheel.

Furthermore, a groove is formed in the box cover and is connected with the lifting motor in a clamping mode.

Adopt above-mentioned structure the utility model discloses the beneficial effect who gains as follows: the utility model provides a laboratory water sample detects uses oscillation device, has increased the portability of device, has improved oscillation device's work efficiency through setting up oscillation mechanism and test tube location complementary unit to and set up lifting unit and improve oscillation device's use and experience, adopt box placing, prolonged the life of device, effectively solved the problem that oscillation device inefficiency in the existing market.

Drawings

FIG. 1 is a front sectional view of an oscillation device for laboratory water sample detection according to the present embodiment;

FIG. 2 is an enlarged view of portion A of FIG. 1;

fig. 3 is a front view of an oscillation device for laboratory water sample detection according to the present embodiment.

The test tube test device comprises a vibration box 1, a vibration box 2, a box cover 3, a box handle 4, a buckle 5, a connecting binding band 6, a control button 7, a lifting component 8, a vibration mounting rack 9, an auxiliary board 10, an auxiliary spring 11, a vibration mechanism 12, a test tube positioning auxiliary mechanism 13, a driving worm 14, a driven worm wheel 15, a worm support board 16, a worm wheel rotating shaft 17, a vibration driving motor 18, an eccentric wheel 19, an auxiliary contact board 20, a telescopic spring 21, a fixed guide board 22, a reciprocating connecting rod 23, a sliding guide shell 24, a sliding table 25, a test tube body 26, a placing groove 27, a miniature electric cylinder 28, a protective board 29, a lifting mounting groove 30, a lifting threaded rod 31, a lifting threaded table 32, a lifting motor 33, a connecting column 34, a support board 35, a protective spring 36, a protective base 37, a miniature oscillator 38 and a groove.

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments; based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-3, the utility model relates to an oscillation device for laboratory water sample detection, including vibration box 1, case lid 2, case handle 3, hasp 4, connect bandage 5, control button 6, lifting unit 7, vibration mounting bracket 8, accessory plate 9, auxiliary spring 10, vibration mechanism 11 and test tube location auxiliary mechanism 12, case lid 2 articulates to be located on vibration box 1, case handle 3 locates on case lid 2, hasp 4 locates between vibration box 1 and case lid 2, connect bandage 5 and locate on the lateral wall of vibration box 1, control button 6 locates on the antetheca of vibration box 1, lifting unit 7 locates in vibration box 1, vibration mounting bracket 8 locates on lifting unit 7, accessory plate 9 locates on vibration mounting bracket 8, auxiliary spring 10 locates on vibration mounting bracket 8, vibration mechanism 11 locates on vibration mounting bracket 8, test tube location auxiliary mechanism 12 locates on vibration mounting bracket 8 and is connected with vibration mechanism 11.

To further illustrate the present solution, the control button 6 is connected to the lifting assembly 7, the oscillation mechanism 11, the test tube positioning assistance mechanism 12 and the micro-oscillator 37.

As shown in fig. 1, the oscillating mechanism 11 includes a driving worm 13, a driven worm wheel 14, a worm support plate 15, a worm wheel rotating shaft 16, an oscillating driving motor 17, an eccentric wheel 18, an auxiliary contact plate 19, a telescopic spring 20, a fixed guide plate 21 and a reciprocating link 22, the worm wheel rotating shaft 16 is rotatably disposed on the oscillating mounting frame 8, the driven worm wheel 14 is disposed on the worm wheel rotating shaft 16, the worm support plate 15 is fixedly connected to the oscillating mounting frame 8, the driving worm 13 is rotatably disposed on the worm support plate 15, the oscillating driving motor 17 is disposed on the driving worm 13, the eccentric wheel 18 is disposed on the worm wheel rotating shaft 16, the fixed guide plate 21 is disposed on the auxiliary plate 9, the reciprocating link 22 is slidably disposed on the fixed guide plate 21, the auxiliary contact plate 19 is disposed on the reciprocating link 22, the telescopic spring 20 is disposed between the auxiliary contact plate 19 and the fixed guide plate 21, the telescopic spring 20 is disposed outside the reciprocating link 22, and the eccentric wheel 18 and the reciprocating link 22 are connected in a sliding contact manner.

As shown in fig. 1, the test tube positioning assisting mechanism 12 includes a slide guide housing 23, a slide table 24, a test tube body 25, a placement groove 26, a micro electric cylinder 27, and a guard plate 28, the slide guide housing 23 is provided on the oscillation mounting frame 8, the slide table 24 is slidably provided on the slide guide housing 23, the placement groove 26 is provided in the slide table 24, the test tube body 25 is provided in the placement groove 26, the micro electric cylinder 27 is provided in the slide table 24, and the guard plate 28 is provided in the placement groove 26 and connected to the micro electric cylinder 27.

As shown in FIG. 1, a protection spring 35 is provided in the placement groove 26, a protection base 36 is provided on the protection spring 35, the protection base 36 is connected with the test tube body 25, a micro oscillator 37 is provided below the placement groove 26, and the micro oscillator 37 has an auxiliary oscillation function.

As shown in fig. 1, the lifting assembly 7 includes a lifting mounting groove 29, a lifting threaded rod 30, a lifting threaded table 31, a lifting motor 32, a connecting column 33 and a supporting plate 34, the lifting mounting groove 29 is disposed in the oscillation box 1, the lifting threaded rod 30 is rotatably disposed in the lifting mounting groove 29, the lifting threaded table 31 is disposed on the lifting threaded rod 30, the lifting motor 32 is disposed on the oscillation box 1, an output end of the lifting motor 32 is connected with the lifting threaded rod 30, the connecting column 33 is disposed on the lifting threaded table 31, and the supporting plate 34 is disposed on the connecting column 33 and connected with the oscillation mounting frame 8; the driving worm 13 is meshed with the driven worm wheel 14.

As shown in fig. 3, the cover 2 has a groove 38, and the groove 38 is engaged with the lift motor 32.

When the device is used, a user moves the device box to a proper position through the box handle 3, opens the box cover 2, starts the lifting motor 32 through the control button 6 to rotate so as to drive the lifting threaded rod 30 to rotate, then drives the lifting threaded platform 31 to move, then drives the support plate 34 on the connecting column 33 to move, then the support plate 34 moves to move the oscillation mounting frame 8 to the outside of the oscillation box 1, then the user loads a water sample in the test tube body 25 and then places the water sample in the placing groove 26, then starts the oscillation driving motor 17 through the control button 6 to rotate so as to drive the driving worm 13 to rotate, then drives the driven worm wheel 14 to rotate, then drives the worm wheel rotating shaft 16 to rotate, then drives the eccentric wheel 18 to rotate, the eccentric wheel 18 rotates to drive the reciprocating connecting rod 22 to push the auxiliary contact plate 19 to move, so as to drive the sliding platform 24 to reciprocate along the sliding guide shell 23, and in order to make the oscillation more effective, the user can also start the micro oscillator 37 to oscillate the placing groove 26. It is above that the utility model discloses holistic work flow, when using next time repeat this step can.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and the embodiments thereof have been described above, but the description is not limited thereto, and the embodiment shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. In summary, it should be understood that those skilled in the art should also understand the scope of the present invention without inventively designing the similar structure and embodiments of the present invention without departing from the spirit of the present invention.

Claims (8)

1. The utility model provides a laboratory water sample detects uses oscillation device which characterized in that: including vibration case, case lid, case handle, hasp, connection bandage, control button, lifting unit, vibration mounting bracket, accessory plate, auxiliary spring, vibration mechanism and test tube location complementary unit, the case lid is articulated to be located on the vibration case, the case handle is located on the case lid, the hasp is located between vibration case and the case lid, it locates on the lateral wall of vibration case to connect the bandage, control button locates on the antetheca of vibration case, lifting unit locates in the vibration case, the vibration mounting bracket is located on lifting unit, the accessory plate is located on the vibration mounting bracket, auxiliary spring locates on the vibration mounting bracket, vibration mechanism locates on the vibration mounting bracket, test tube location complementary unit locates on the vibration mounting bracket and is connected with vibration mechanism.

2. The oscillation device for laboratory water sample detection according to claim 1, wherein: the oscillating mechanism comprises a driving worm, a driven worm wheel, a worm supporting plate, a worm wheel rotating shaft, an oscillating driving motor, an eccentric wheel, an auxiliary contact plate, an expansion spring, a fixed guide plate and a reciprocating connecting rod, the worm wheel rotating shaft is rotatably arranged on an oscillating mounting frame, the driven worm wheel is arranged on the worm wheel rotating shaft, the worm supporting plate is fixedly connected onto the oscillating mounting frame, the driving worm is rotatably arranged on the worm supporting plate, the oscillating driving motor is arranged on the driving worm, the eccentric wheel is arranged on the worm wheel rotating shaft, the fixed guide plate is arranged on the auxiliary plate, the reciprocating connecting rod is arranged on the fixed guide plate in a penetrating and sliding mode, the auxiliary contact plate is arranged on the reciprocating connecting rod, the expansion spring is arranged between the auxiliary contact plate and the fixed guide plate, the expansion spring is arranged on the outer side of the reciprocating connecting rod, and the eccentric wheel is connected with the reciprocating connecting rod in a sliding contact mode.

3. The oscillation device for laboratory water sample detection according to claim 2, wherein: test tube location complementary unit includes slide steering shell, sliding stand, test tube body, standing groove, miniature electronic jar and guard plate, the slide steering shell is located on the vibration mounting bracket, the sliding stand slides and locates on the slide steering shell, the standing groove is located in the sliding stand, test tube body locates in the standing groove, miniature electronic jar is located in the sliding stand, the guard plate is located in the standing groove and is connected with miniature electronic jar.

4. The oscillation device for laboratory water sample detection according to claim 3, wherein: the lifting component comprises a lifting mounting groove, a lifting threaded rod, a lifting threaded platform, a lifting motor, a connecting column and a supporting plate, wherein the lifting mounting groove is formed in the oscillating box, the lifting threaded rod is rotatably arranged in the lifting mounting groove, the lifting threaded platform is arranged on the lifting threaded rod, the lifting motor is arranged on the oscillating box, the output end of the lifting motor is connected with the lifting threaded rod, the connecting column is arranged on the lifting threaded platform, and the supporting plate is arranged on the connecting column and is connected with the oscillating mounting frame.

5. The oscillation device for laboratory water sample detection according to claim 4, wherein: and the driving worm is in meshed connection with the driven worm wheel.

6. The oscillation device for laboratory water sample detection according to claim 5, wherein: the test tube comprises a placing groove and is characterized in that a protection spring is arranged in the placing groove, a protection base is arranged on the protection spring and is connected with a test tube body, and a micro oscillator is arranged below the placing groove.

7. The oscillation device for laboratory water sample detection according to claim 6, wherein: the box cover is provided with a groove, and the groove is connected with the lifting motor in a clamping manner.

8. The oscillation device for laboratory water sample detection according to claim 7, wherein: and the control button is connected with the lifting assembly, the oscillation mechanism, the test tube positioning auxiliary mechanism and the micro oscillator.

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