CN216247889U - Measuring device for monitoring solid-liquid ratio of vacuum salt-making evaporation chamber in real time - Google Patents

Abstract

The utility model relates to a measuring device for monitoring the solid-liquid ratio of an evaporation chamber for vacuum salt production in real time, which comprises an evaporation tank, wherein a mixing mechanism is arranged at the bottom end of the evaporation tank, a fixed-point sampling mechanism is arranged at the top of the evaporation tank, one end of the fixed-point sampling mechanism is connected with a hose, one end of the hose is connected with a water pump, one side of the evaporation tank is provided with a measuring box, the water pump is arranged in the measuring box, one end of the water pump is connected with a communicating pipeline, one end of the communicating pipeline is connected with a sampling bottle, and one side of the measuring box is provided with a recording plate. The solid-liquid ratio of the raw materials is measured, and real-time detection can be performed.

Description

Measuring device for monitoring solid-liquid ratio of vacuum salt-making evaporation chamber in real time

Technical Field

The utility model relates to a measuring device for monitoring the solid-liquid ratio of a vacuum salt-making evaporation chamber in real time, belonging to the technical field of salt making.

Background

The salt and water are separated at high temperature in the production process of the salt making device, the liquid level of evaporation equipment and the solid-liquid ratio in the equipment are two very important control parameters in the salt making evaporation process, so that the online monitoring device for the solid-liquid ratio of the salt making evaporation chamber is particularly critical, the current solid-liquid ratio is mostly measured manually, the measurement is carried out once per hour, time and labor are wasted, and meanwhile, the measurement is inaccurate due to a plurality of factors, and the measurement of the solid-liquid ratio is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a measuring device for monitoring the solid-liquid ratio of a vacuum salt-making evaporation chamber in real time, which can carry out real-time detection by comparing the solid-liquid ratio of sampled liquid for multiple times through evaporation experiments after sampling raw materials at different depths through a fixed-point sampling mechanism so as to measure the solid-liquid ratio of the raw materials, thereby solving the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme:

the utility model provides a measuring device of real-time supervision vacuum salt manufacturing evaporation chamber solid-liquid ratio, includes the evaporating pot, mixing mechanism is installed to the bottom position of evaporating pot, fixed point sampling mechanism is installed at the top of evaporating pot, fixed point sampling mechanism's one end is connected with the hose, the one end of hose is connected with the water pump, one side of evaporating pot is provided with the measuring box, the water pump is installed in the measuring box, the one end of water pump is connected with the UNICOM's pipeline, the one end of UNICOM's pipeline is connected with the sample bottle, one side of measuring box is provided with the record board.

Further, the mixing mechanism includes servo motor, dwang and stirring fan blade, servo motor installs the outside at the evaporating pot, the dwang sets up in the evaporating pot, the one end and the servo motor of evaporating pot are connected.

Further, stirring fan blade is the echelonment and sets up on the dwang, evenly seted up the water conservancy diversion hole on the stirring fan blade.

Further, fixed point sampling mechanism includes the casing, rotates knob, gear, sampling pipe and pinion rack, the top at the evaporating pot is installed to the casing, it connects on the casing to rotate the knob, the one end and the gear connection that rotate the knob, the pinion rack sets up in the casing, pinion rack fixed connection is in one side of sampling pipe, just pinion rack and sampling pipe link up and pass the casing, gear engagement connects on the cardboard.

Furthermore, the measuring box is equidistantly provided with a placing groove, and the sampling bottle is arranged in the placing groove.

Further, the communication pipeline comprises a main pipeline and branch pipelines, the main pipeline is connected with the water pump, and the branch pipelines are evenly connected to the main pipeline.

The utility model has the beneficial effects that:

1. by arranging the fixed-point sampling mechanism, when the solid-liquid ratio of the raw materials in the evaporation tank is measured, the raw materials are uniformly mixed by the mixing mechanism, and after the raw materials at different depths are sampled by the fixed-point sampling mechanism, the solid-liquid ratio of the sampled liquid is compared for multiple times through evaporation experiments, the solid-liquid ratio of the raw materials is measured, and real-time detection can be carried out;

2. through being equipped with the measuring box, can deposit each sampling bottle respectively with the raw materials of sample in, be convenient for carry out follow-up detection experiment, can record the experiment result through the record board after the experiment is accomplished simultaneously to the solid-to-liquid ratio of raw materials evaporation in different time quantums is convenient for obtain.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model without limiting the utility model.

FIG. 1 is a schematic diagram of the overall structure of a measuring device for monitoring the solid-liquid ratio of a vacuum salt-making evaporation chamber in real time;

FIG. 2 is a schematic structural diagram of a mixing mechanism of a measuring device for monitoring the solid-liquid ratio of a vacuum salt-making evaporation chamber in real time according to the utility model;

FIG. 3 is a schematic structural diagram of a positioning sampling mechanism of a measuring device for monitoring the solid-to-liquid ratio of a vacuum salt-making evaporation chamber in real time according to the utility model;

FIG. 4 is a schematic diagram of the internal structure of a measuring box of the measuring device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time;

reference numbers in the figures: 1. an evaporator tank; 2. a mixing mechanism; 3. a fixed-point sampling mechanism; 4. a hose; 5. a water pump; 6. a measuring box; 7. communicating a pipeline; 8. sampling a bottle; 9. a recording plate; 10. a servo motor; 11. rotating the rod; 12. a stirring fan blade; 13. a housing; 14. rotating the knob; 15. a gear; 16. a sampling tube; 17. a toothed plate; 18. and (6) placing the groove.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred devices or elements must have specific orientations, be constructed in specific orientations, and be operated, and thus are not to be construed as limiting the present invention, and furthermore, the terms "first" and "second" are only used for descriptive purposes and are not to be construed as indicating or implying relative importance.

Referring to fig. 1-4, the present invention provides a technical solution:

the utility model provides a measuring device of real-time supervision vacuum salt manufacturing evaporation chamber solid-liquid ratio, includes evaporating pot 1, evaporating pot 1 is provided with the scale interval, can be convenient for carry out the sample record to the raw materials of the different degree of depth, mixing mechanism 2 is installed to the bottom position of evaporating pot 1, fixed point sampling mechanism 3 is installed at the top of evaporating pot 1, fixed point sampling mechanism 3's one end is connected with hose 4, the one end of hose 4 is connected with water pump 5, one side of evaporating pot 1 is provided with measuring box 6, water pump 5 is installed in measuring box 6, the one end of water pump 5 is connected with communicating pipe 7, the one end of communicating pipe 7 is connected with sampling bottle 8, one side of measuring box 6 is provided with record board 9.

Specifically, as shown in fig. 1, a placing groove 18 is equidistantly formed in the measuring box 6, and the sampling bottles 8 are arranged in the placing groove 18, so that the sampling bottles 8 can be placed and replaced conveniently.

Specifically, as shown in fig. 2, mixing mechanism 2 includes servo motor 10, dwang 11 and stirring fan blade 12, servo motor 10 installs in the outside of evaporating pot 1, dwang 11 sets up in evaporating pot 1, the one end and the servo motor 10 of evaporating pot 1 are connected, stirring fan blade 12 is the echelonment and sets up on dwang 11, the water conservancy diversion hole has evenly been seted up on stirring fan blade 12, when using this measuring device, starts mixing mechanism 2's servo motor 10 and drives dwang 11 and stirring fan blade 12 and rotate, stirs the raw materials for solid-to-liquid ratio in the raw materials keeps the equilibrium, is convenient for detect.

Specifically, as shown in fig. 3, fixed point sampling mechanism 3 includes casing 13, rotation knob 14, gear 15, sampling pipe 16 and pinion rack 17, casing 13 is installed at the top of evaporating pot 1, rotation knob 14 is connected on casing 13, the one end that rotates knob 14 is connected with gear 15, gear 15 sets up in casing 13, pinion rack 17 fixed connection is in one side of sampling pipe 16, just pinion rack 17 and sampling pipe 16 link up and pass casing 13, gear 15 meshing is connected on pinion rack 17, drives gear 15 through rotating knob 14 and rotates, makes pinion rack 17 drive sampling pipe 16 go up and down through the meshing of gear 15, adjusts the degree of depth of sampling pipe 16.

Specifically, as shown in fig. 4, the communication pipeline 7 comprises a main pipeline and branch pipelines, the main pipeline is connected with the water pump 5, the branch pipelines are uniformly connected to the main pipeline, and valves are arranged at the joints of the branch pipelines and the main pipeline.

The working principle of the utility model is as follows: when using this measuring device, the servo motor 10 that starts mixing mechanism 2 drives dwang 11 and stirring fan blade 12 and rotates, stir the raw materials, make the solid-to-liquid ratio in the raw materials keep the equilibrium, then take a sample to the raw materials of the different degree of depth through fixed point sampling mechanism 3, drive gear 15 through rotating knob 14 and rotate when using, meshing through gear 15 makes pinion rack 17 drive sampling pipe 16 go up and down, adjust the degree of depth of sampling pipe 16, the liquid of sampling passes through water pump 5 and communication pipeline 7 and deposits in getting into each sampling bottle 8, and detect the solid-to-liquid ratio of raw materials in the sampling bottle 8 through the evaporation experiment, through multiunit contrast experiment, obtain the solid-to-liquid ratio numerical value of raw materials under the current condition, and record on the record board 9 of measuring case 6 one side, can carry out the solid-to-liquid ratio of real-time detection raw materials, and be convenient for operation.

The above embodiments are preferred embodiments of the present invention, and those skilled in the art can make variations and modifications to the above embodiments, therefore, the present invention is not limited to the above embodiments, and any obvious improvements, substitutions or modifications made by those skilled in the art based on the present invention are within the protection scope of the present invention.

Claims (6)

1. The utility model provides a measuring device of real-time supervision vacuum salt manufacturing evaporation chamber solid-liquid ratio, includes evaporating pot (1), its characterized in that: mixing mechanism (2) are installed to the bottom position of evaporating pot (1), fixed point sampling mechanism (3) are installed at the top of evaporating pot (1), the one end of fixed point sampling mechanism (3) is connected with hose (4), the one end of hose (4) is connected with water pump (5), one side of evaporating pot (1) is provided with measuring box (6), install in measuring box (6) water pump (5), the one end of water pump (5) is connected with communicating pipe (7), the one end of communicating pipe (7) is connected with sampling bottle (8), one side of measuring box (6) is provided with record board (9).

2. The device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time according to claim 1, wherein: mixing mechanism (2) include servo motor (10), dwang (11) and stirring fan blade (12), the outside at evaporating pot (1) is installed in servo motor (10), dwang (11) set up in evaporating pot (1), the one end and the servo motor (10) of evaporating pot (1) are connected.

3. The device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time according to claim 2, wherein: stirring fan blade (12) are the echelonment and set up on dwang (11), the water conservancy diversion hole has evenly been seted up on stirring fan blade (12).

4. The device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time according to claim 3, wherein: fixed point sampling mechanism (3) include casing (13), rotate knob (14), gear (15), sampling pipe (16) and pinion rack (17), the top at evaporating pot (1) is installed in casing (13), it connects on casing (13) to rotate knob (14), the one end that rotates knob (14) is connected with gear (15), gear (15) set up in casing (13), pinion rack (17) fixed connection is in one side of sampling pipe (16), just pinion rack (17) and sampling pipe (16) link up and pass casing (13), gear (15) meshing connection is on pinion rack (17).

5. The device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time according to claim 4, wherein: the measuring box (6) is equidistantly provided with a placing groove (18), and the sampling bottle (8) is arranged in the placing groove (18).

6. The device for monitoring the solid-liquid ratio of the evaporation chamber for vacuum salt production in real time according to claim 5, wherein: the communicating pipeline (7) comprises a main pipeline and branch pipelines, the main pipeline is connected with the water pump (5), and the branch pipelines are uniformly connected to the main pipeline.

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