CN219326046U - Soil sample's save unit - Google Patents

Abstract

The utility model relates to the technical field of soil preservation, and provides a preservation unit for soil samples, wherein the whole preservation unit is obliquely arranged to accord with the habit of taking and placing by a human body, a soil sample bottle can be obliquely arranged in the preservation unit, and can automatically slide to the bottom of the preservation unit, so that the soil sample bottle cannot easily slide out of the preservation unit even if a preservation warehouse vibrates or inclines, and the safety of the preservation unit is improved; whether the soil sample bottle exists in the preservation unit or not is sensed by the sensor, and when the soil sample bottle is not sensed by the sensor, the indicator light is turned on, so that the state of the soil sample bottle can be monitored in real time; through binding the station identification code and the bar code on the soil sample bottle, the station which is placed correspondingly specifically can be found out according to the bar code corresponding to the soil sample.

Description

Soil sample's save unit

Technical Field

The utility model relates to the technical field of soil preservation, in particular to a preservation unit for a soil sample.

Background

Soil sample storage refers to the process of maintaining the availability of a soil sample at a specified time interval and under predetermined conditions from the time of soil sample collection until further processing. The existing soil sample preservation device has certain defects when in use, a general soil sample is placed in a soil sample bottle made of glass for preservation, the soil sample bottle is directly placed in a warehouse or vertically in a sample cabinet, and the soil sample bottle is directly placed in the warehouse in a placing mode, so that the storage mode is quite convenient, but the space utilization rate is quite low, and when the soil sample bottle is more, the soil sample bottle is inconvenient to manually take and place at a place far from a taking and placing point, and the information of a query soil sample is inconvenient to query; the sample cabinet vertically placed is internally provided with the partition plate, the soil sample bottles are placed in the partition plate, the sample cabinet comprises a sample cabinet with a cabinet door and a sample cabinet without a cabinet door, the problem of space utilization rate is solved, but certain problems still exist in the vertically placed sample cabinet, for example, when the sample cabinet without the cabinet door is inclined, the soil sample bottles are directly horizontally placed and easily slide out of the sample cabinet, and the safety coefficient is low; the sample cabinet with the cabinet door is inconvenient to inquire the information of the soil sample and take and put the soil sample bottle due to the existence of the cabinet door. There is therefore a need for a person skilled in the art to design a preservation unit to solve the existing problems of vertically placed sample cabinets.

Disclosure of Invention

In order to achieve the above object, the present utility model provides the following technical solutions:

the utility model provides a soil sample preservation unit, which is integrally and obliquely arranged, wherein the preservation unit is provided with an opening, and the opening enables a soil sample bottle to be obliquely placed into the preservation unit.

Further, the preservation units are arranged in a matrix in the sample preservation cabinet.

Further, the adjacent storage units share one side wall.

Further, the opening of the storage unit is rectangular or circular, the shape of the storage unit is not limited to rectangular or circular, and may be other shapes, and the specific shape may be determined according to the shape of the soil sample bottle placed therein. In addition, the depth of the preservation unit is smaller than the height of the soil sample bottle, and preferably, a part of the soil sample bottle is exposed outside after the soil sample bottle is placed in the preservation unit, so that the soil sample bottle is convenient to take.

Further, when the preservation unit is positioned on the top layer or the bottom layer of the sample preservation cabinet, one surface in the preservation unit is obliquely arranged.

Further, when the preservation unit is positioned between the top layer and the bottom layer of the sample preservation cabinet, two sides of the preservation unit are obliquely arranged.

Further, a control circuit board is arranged in the storage units, and the control circuit boards among the storage units are connected in parallel. The control circuit board is in modular design, can be installed and debugged on site, is simple, convenient and reliable, and does not influence other control circuit boards when one control circuit board is damaged. The control circuit board is connected with the power supply, and the control circuit board is arranged in the storage unit independently, so that the low-power supply can meet the power consumption requirement.

Further, a sensor is arranged on the preservation unit and used for sensing whether a soil sample bottle is placed in the preservation unit. The sensor has the function of transmitting and receiving data. The sensor transmits the sensed data to a server. The server has an information processing function and is a processor in the background. The sensor is also connected with the control circuit board to supply power to the sensor.

Further, the storage unit is provided with an indicator light, and the indicator light is connected with the control circuit board and used for indicating whether a soil sample bottle exists in the storage unit. The indicator lamp is also bound with the data receiving and sending module of the server and used for indicating whether a soil sample bottle exists in the storage unit or not, and the indicator lamp is controlled to be turned off and on by sensing data; when the sensor senses that the soil sample bottle exists in the storage unit, the indicator light is turned off; when the sensor does not sense that the soil sample bottles exist in the storage units, the indicator lights are turned on, an operator can directly judge which storage unit is idle according to the indication of the indicator lights, and the state of the soil sample bottles can be monitored in real time, including which storage units are provided with the soil sample bottles, which storage units are not provided with the soil sample bottles, how many spare storage units remain in the whole storage warehouse, how many soil sample bottles are stored and the like.

Further, one or more of the storage units are provided with a station identification code, and one station identification code can be correspondingly arranged on one storage unit or on four storage units, 8 storage units or more storage units, namely, a group of soil sample bottles are placed in the storage unit corresponding to one station identification code, so that the scanning process can be simplified. The station identification code contains specific position information of the storage unit. When the soil sample bottle is placed in the preservation unit, the bar code on the soil sample bottle is bound with the station identification code, and when a certain soil sample needs to be inquired, the corresponding station identification code can be found according to the bar code corresponding to the soil sample, so that a station which is specifically placed is known.

The utility model has the following beneficial effects:

(1) The integral inclined arrangement of the preservation unit accords with the taking and placing habit of a human body, the soil sample bottle can be obliquely placed in the preservation unit, and can automatically slide down to the bottom of the preservation unit, so that the soil sample bottle cannot easily slide out of the preservation unit even if the preservation warehouse vibrates or inclines, and the safety of the preservation unit is improved;

(2) The control circuit board with a module design is arranged in the storage unit, the control circuit boards are connected in parallel, and when one circuit board is damaged, the other control circuit boards are not affected;

(3) The sensor and the indicator light are arranged in the storage unit, whether the soil sample bottle exists in the storage unit or not is sensed by the sensor, and when the sensor does not sense the soil sample bottle, the indicator light is turned on, so that the number of idle storage units in the storage library can be intuitively known, and the state of the soil sample bottle can be monitored in real time;

(4) The station identification code is arranged on the storage unit, and the station which is placed in a specific mode can be quickly found according to the bar code corresponding to the soil sample through binding the station identification code with the bar code on the soil sample bottle.

Drawings

Fig. 1 is a schematic diagram of an arrangement of the present utility model.

Fig. 2 is a schematic view of the structure of the present utility model at the top of the sample holding cabinet.

FIG. 3 is a schematic view of the structure of the utility model in the bottom layer of the sample holding cabinet.

FIG. 4 is a schematic view of the structure of the present utility model between the top and bottom layers of the sample holding cabinet.

FIG. 5 is a schematic view of the various structures of the present utility model as they are between the top and bottom layers of the sample holding cabinet.

FIG. 6 is a schematic plan view of the present utility model when placed in a soil sample bottle.

Detailed Description

The following detailed description of the embodiments of the utility model, taken in conjunction with the accompanying drawings, should be taken as illustrative of the utility model only and not as limiting, the examples being intended to provide those skilled in the art with a better understanding and reproduction of the technical solutions of the utility model, the scope of the utility model still being defined by the claims.

The utility model provides a soil sample preservation unit 1, wherein the preservation unit 1 is integrally and obliquely arranged, the preservation unit 1 is provided with an opening 11, the opening 11 enables a soil sample bottle 2 to be obliquely placed into the preservation unit 1, and because the integral oblique arrangement of the preservation unit 1 accords with the taking and placing habit of a human body, the soil sample bottle 2 can be obliquely placed into the preservation unit 1, the soil sample bottle 2 can automatically slide to the bottom of the preservation unit 1, even if the soil sample bottle 2 shakes or inclines, the soil sample bottle 2 cannot easily slide out of the preservation unit 2, and the safety of the preservation unit is improved.

Preferably, the storage unit 1 may further be provided with a cover plate, and the cover plate is movably disposed at the opening and may cover the soil sample bottle 2.

As shown in fig. 1, the storage units 1 are arranged in a matrix in a sample storage cabinet 3.

In some preferred embodiments, the adjacently disposed holding units 1 share one side wall 12.

In some preferred embodiments, the opening 11 of the storage unit 1 is rectangular or circular, and the shape of the storage unit 1 is not limited to rectangular or circular, but may be other shapes, and the specific shape may be determined according to the shape of the soil sample bottle 2 placed therein. In addition, the depth of the storage unit 1 is smaller than the height of the soil sample bottle 2, and preferably, after the soil sample bottle 2 is put in, a part of the soil sample bottle 2 is exposed outside, so that the soil sample bottle is convenient to take.

As shown in fig. 2-3, when the storage unit 1 is positioned on the top layer or the bottom layer of the sample storage cabinet 3, one surface of the storage unit 1 is obliquely arranged, and when the storage unit 1 is positioned on the top layer of the sample storage cabinet 3, the bottom surface 14 of the storage unit 1 is obliquely arranged; when the holding unit 1 is positioned at the bottom of the sample holding cabinet 3, the top surface 13 of the holding unit 1 is obliquely arranged

As shown in fig. 4-5, when the storage unit 1 is located between the top layer and the bottom layer of the sample storage cabinet 3, two sides of the storage unit 1 are disposed obliquely, that is, the top surface 13 and the bottom surface 14 of the storage unit 1 are disposed obliquely.

As shown in fig. 6, the control circuit boards 4 are disposed in the storage units 1, and the control circuit boards 4 between the storage units 1 are connected in parallel. The control circuit board 4 is in modularized design, can be installed and debugged on site, is simple, convenient and reliable, and does not influence other control circuit boards 4 when one control circuit board 4 is damaged. The control circuit board 4 is connected with the power supply, and the low-power supply can meet the power consumption requirement because the control circuit board 4 is independently arranged in the storage unit 1.

In some preferred embodiments, a sensor (not shown) is provided on the storage unit 1, and the sensor (not shown) is used to sense whether the soil sample bottle 2 is placed in the storage unit 1. The sensor (occlusion not shown) has the function of transmitting and receiving data. The sensor (occlusion not shown) transmits the sensed data to the server. The server has an information processing function and is a processor in the background. The sensor (shade not shown) is also connected to the control circuit board 4 for powering the sensor (shade not shown).

In some preferred embodiments, the storage unit 1 is provided with an indicator light 5, and the indicator light 5 is connected with the control circuit board 4, and is used for indicating whether the soil sample bottle 2 exists in the storage unit 1. The indicator lamp 5 is also bound with the data receiving and sending module of the server and is used for indicating whether the soil sample bottle 2 exists in the storage unit 1 or not, and the turning-off and the turning-on of the indicator lamp are controlled through sensing data; when the sensor senses that the soil sample bottle 2 is arranged in the preservation unit 1, the indicator lamp 5 is turned off; when the sensor does not sense that the soil sample bottle 2 is arranged in the preservation unit 1, the indicator lamp 5 is turned on, an operator can directly judge which preservation unit 1 is idle according to the indication of the indicator lamp 5, and can monitor the state of the soil sample bottle 2 in real time, including which preservation units 1 are provided with the soil sample bottle 2, which preservation units 1 are not provided with the soil sample bottle 2, how many spare preservation units 1 remain in the whole sample preservation cabinet, how many soil sample bottles 2 are preserved, and the like.

In some preferred embodiments, one or more of the storage units 1 is provided with a station identification code 10, and one station identification code 10 may be correspondingly disposed on one storage unit 1 or may be correspondingly disposed on four storage units, 8 storage units, or more storage units, that is, a group of soil sample bottles are disposed in the storage unit corresponding to one station identification code, so that the scanning process may be simplified. The station identification code 10 contains specific position information of the storage unit 1. When the soil sample bottle 2 is placed in the preservation unit 1, the bar code on the soil sample bottle 2 is bound with the station identification code 10, and when a certain soil sample needs to be inquired, the corresponding station identification code 10 can be found according to the bar code corresponding to the soil sample, so that the station which is specifically placed is known.

While preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the application.

Claims (9)

1. The soil sample preservation unit is characterized in that the preservation unit is integrally and obliquely arranged, the preservation unit is provided with an opening, and the opening enables a soil sample bottle to be obliquely placed into the preservation unit; the adjacent storage units share one side wall.

2. The soil sample holding unit according to claim 1, wherein the holding units are arranged in a matrix in the sample holding cabinet.

3. A soil sample holding unit according to claim 1, wherein the opening of the holding unit is rectangular or circular.

4. A soil sample holding unit according to claim 2, wherein the top or bottom layer of the holding unit is inclined when the holding unit is positioned on the top or bottom layer of the sample holding cabinet.

5. A soil sample holding unit according to claim 2, wherein the upper and lower floors of said holding unit are disposed obliquely when said holding unit is located between the top and bottom floors of said sample holding cabinet.

6. The soil sample preservation unit according to claim 1, wherein control circuit boards are arranged in the preservation units, and the control circuit boards among the preservation units are connected in parallel.

7. The soil sample holding unit according to claim 1, wherein a sensor is provided on the holding unit, and the sensor is used for sensing whether a soil sample bottle is placed in the holding unit.

8. The soil sample preservation unit according to claim 6, wherein the preservation unit is provided with an indicator light, and the indicator light is connected with the control circuit board and used for indicating whether a soil sample bottle exists in the preservation unit.

9. A soil sample holding unit according to claim 1, wherein one or more of said holding units is provided with a station identification code.

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