CN111122451A - Volatile oil separation and determination device - Google Patents

Abstract

The invention discloses a volatile oil separation and determination device, and belongs to the field of instruments. The device includes: a support; the backflow monitoring device comprises an upper sliding disc, a lower sliding disc, a plurality of sliding blocks, stop blocks and first monitors, wherein the stop blocks correspond to the sliding blocks one by one; the upper sliding disc is circular, a first central hole is formed in the center of the upper sliding disc, first sliding grooves are uniformly formed in the upper sliding disc along the circumferential direction of the center, the track of each first sliding groove is arc-shaped, and the first sliding grooves are arranged in an inclined mode overall towards one side; the lower sliding disc is circular, a second central hole is formed in the center of the lower sliding disc, and second sliding grooves are uniformly formed in the upper edge of the lower sliding disc along the central circumferential direction; the sliding blocks are of an arc-shaped triangular structure on one side, and the sliding blocks are uniformly arranged along the central circumference of the lower sliding disc; the first monitor comprises a first processor, a buzzer and a first photoelectric sensing module. The invention can improve the monitoring precision, remind the staff to carry out the next operation in time, and greatly improve the experimental efficiency without manual monitoring in the process.

Description

Volatile oil separation and determination device

Technical Field

The invention relates to the field of instruments and meters, in particular to a volatile oil separation and determination device.

Background

A volatile oil is a mixture of several types of components, and a volatile oil often contains dozens to one or two hundred components, with one or more of the components accounting for the larger part.

The volatile oil tester is an instrument for testing the content of essential oil, and is suitable for testing the content of the essential oil containing volatile components in the tissues of medicines and plants in units such as pharmaceutical industry, medicine research, daily chemical industry, food industry and the like.

The Chinese pharmacopoeia records a method for measuring volatile oil. Weighing a proper amount of a sample, placing the sample in a flask, adding 300-500 ml of water and a plurality of glass beads, shaking and mixing, and connecting a volatile oil tester and a reflux condenser tube. Adding water from the upper end of the condensation tube to fill the graduated part of the volatile oil detector and overflow into the flask. Placing in an electric heating jacket or slowly heating to boil by other suitable methods, maintaining slightly boiling for about 5 hr until the oil content in the tester is not increased, stopping heating, placing for a moment, starting a piston at the lower end of the tester, slowly discharging water, lowering the upper end to be just level with the 0-line scale, reading the volatile oil content, and calculating the volatile oil content (%) in the sample.

At present, when the determination method is implemented, whether volatile oil still exists in a return pipe needs to be manually monitored, namely whether the volatile oil is completely extracted, and because the time of the volatile oil extraction process is long, the volatile oil extraction process needs to be monitored for a long time about 5 hours recorded in Chinese pharmacopoeia, the experiment efficiency is greatly reduced, measurement is inaccurate due to early ending, and the experiment period is too long due to too late ending. There is therefore a need for a device that can monitor whether there is still a flow of volatile oil in the return line.

Disclosure of Invention

The invention provides a volatile oil separation and determination device which can solve the problems that the volatile oil separation and determination device in the prior art needs long-time manual supervision and is low in efficiency during detection.

A volatile oil separation assay device comprising:

a support;

the backflow monitoring device comprises an upper sliding disc, a lower sliding disc, a plurality of sliding blocks, stop blocks and first monitors, wherein the stop blocks correspond to the sliding blocks one by one, and the number of the sliding blocks is even;

the upper sliding disc is circular, a first central hole is formed in the center of the upper sliding disc, first sliding grooves are uniformly formed in the upper sliding disc along the circumferential direction of the center, the track of each first sliding groove is arc-shaped and is arranged in an inclined mode overall towards one side, and a covered edge extends from the peripheral side of the upper sliding disc to one side;

the lower sliding disc is circular, a second central hole is formed in the center of the lower sliding disc, second sliding grooves are uniformly formed in the upper edge of the lower sliding disc along the circumferential direction of the center, the track of each second sliding groove is linear and is obliquely arranged on one side opposite to the first sliding groove, the surrounding side of the lower sliding disc is wrapped by the wrapping edge, and the lower sliding disc is fixedly connected to the support;

the sliding blocks are of an arc-shaped triangular structure at one side, the sliding blocks are uniformly arranged along the central circumference of the lower sliding disc, the sliding blocks are abutted in pairs to form an annular structure, the sliding blocks are positioned between the upper sliding disc and the lower sliding disc, connecting holes are formed in the sliding blocks, the first sliding grooves, the second sliding grooves, the sliding blocks and the stop blocks are in one-to-one correspondence, the stop blocks penetrate through the first sliding grooves and are rotatably connected to the connecting holes, the stop blocks are slidably arranged in the first sliding grooves, and limit sliding blocks are arranged on the side surfaces, facing the lower sliding disc, of the sliding blocks and are slidably arranged in the second sliding grooves;

when the upper sliding disc rotates, the sliding blocks are driven to move close to or away from each other;

first watch-dog includes first treater, bee calling organ and a photoelectric sensing module, the equal signal connection of a photoelectric sensing module is to first treater, a photoelectric sensing module sets up on the sliding block, a photoelectric sensing module is used for monitoring whether the medium changes in the return pipe.

Preferably, the first photoelectric sensing module is a first infrared transceiver module.

Preferably, the separation monitoring device comprises a base, a vertical rod, an adjusting seat, a supporting rod, an adjusting wheel, two mounting seats and two second monitors, wherein one end of the vertical rod is connected to the base, the other end of the vertical rod is connected to the adjusting seat, the adjusting wheel is rotatably arranged on the adjusting seat, lead screws are coaxially arranged on two sides of the adjusting wheel, threaded holes matched with the lead screws are formed in the supporting rod, the supporting rod is slidably arranged on the adjusting seat, and the lead screws are driven to move when rotating; the second watch-dog sets up on the mount pad, two the second watch-dog sets up relatively, the second watch-dog includes second treater, second photoelectric sensing module, solenoid valve and first wireless receiving module, first watch-dog still include with first wireless transmitting module of first wireless receiving module assorted, first wireless transmitting module signal connection to first treater, second photoelectric sensing module the solenoid valve with first wireless receiving module is all signal connection to the second treater, the liquid end at the volatile oil apparatus is installed to the solenoid valve, second photoelectric sensing module is used for monitoring whether the volatile oil apparatus inner medium changes, first watch-dog is located the second watch-dog top.

Preferably, the adjusting seat is provided with a containing cavity, one end of the supporting rod is located in the containing cavity, and the screw rod is located in the containing cavity.

Preferably, the second photoelectric sensing module is a second infrared transceiving module.

Preferably, the inner side of the edge cover is circumferentially and uniformly provided with first sliding teeth, the outer peripheral side of the lower sliding disc is circumferentially and uniformly provided with second sliding teeth, and the first sliding teeth are matched with the second sliding teeth.

The invention provides a volatile oil separation and determination device, which is characterized in that an upper sliding disc is rotated, a first sliding groove drives a stop block to move, the stop block drives a sliding block to move, the sliding block enables a plurality of sliding blocks to approach or separate from each other under the action of a second sliding groove, so that a gap is formed between the sliding blocks, one side surface of the sliding block can be attached to return pipes with different sizes, the device is suitable for instruments with different types and sizes, when the sliding block is attached to the return pipe, a first photoelectric module can be driven to approach the return pipe, the sliding blocks are even and correspond to each other, so that first photoelectric sensing modules are correspondingly wound around the periphery of the return pipe in pairs, the downward flow of volatile oil is monitored at multiple angles, the monitoring precision is improved, and by means of a buzzer is controlled by a first processor to alarm after the extraction of the volatile oil is finished, so, this process need not artifical control, very big improvement experiment efficiency.

Drawings

FIG. 1 is a schematic structural view of a reflux monitoring device of a volatile oil separation and determination device according to the present invention;

FIG. 2 is a schematic structural diagram of a reflux monitoring device of a volatile oil separation and determination device provided by the present invention;

FIG. 3 is an exploded view I of FIG. 2;

FIG. 4 is an exploded view II of FIG. 2;

FIG. 5 is a first schematic structural view of the upper sliding plate in FIG. 2;

FIG. 6 is a second schematic structural view of the upper sliding plate in FIG. 2;

FIG. 7 is a front view of FIG. 5;

FIG. 8 is a first schematic structural diagram of the slider shown in FIG. 2;

FIG. 9 is a second schematic structural diagram of the slider shown in FIG. 2;

FIG. 10 is a first schematic structural view of the lower sliding tray of FIG. 2;

FIG. 11 is a second schematic structural view of the lower sliding tray of FIG. 2;

FIG. 12 is a schematic structural diagram of a separation monitoring device of a volatile oil separation and determination device according to the present invention;

FIG. 13 is a schematic view of the partial cross-sectional structure of FIG. 12;

FIG. 14 is a schematic structural view of the working state of a separation monitoring device of the volatile oil separation and determination device provided by the present invention;

FIG. 15 is a first schematic diagram of a system for monitoring backflow in accordance with the present invention;

FIG. 16 is a second schematic diagram of a system for monitoring backflow in accordance with the present invention;

fig. 17 is a system schematic diagram of a separation monitoring device provided by the present invention.

Description of reference numerals:

10. backflow monitoring device, 11, upper sliding tray, 111, first center hole, 112, first chute, 113, bordure, 114, first sliding tooth, 12, sliding block, 121, connecting hole, 122, limiting sliding block, 13, stopper, 14, lower sliding tray, 141, second center hole, 142, second chute, 143, second sliding tooth, 20, base, 21, pole setting, 22, adjusting seat, 23, bracing piece, 24, mount pad, 25, adjusting wheel, 251, lead screw, 30, first photoelectric sensing module, 40, second photoelectric sensing module.

Detailed Description

An embodiment of the present invention will be described in detail below with reference to the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the embodiment.

The first embodiment is as follows:

as shown in fig. 1 to 4, an apparatus for separating and measuring volatile oil according to an embodiment of the present invention includes a support and a backflow monitoring device 10; the bracket is used for supporting the backflow monitoring device 10; the backflow monitoring device 10 comprises an upper sliding disc 11, a lower sliding disc 14, a plurality of sliding blocks 12, stop blocks 13 corresponding to the sliding blocks 12 one by one and a first monitor, wherein the number of the sliding blocks 12 is even, and the sliding blocks 12 are arranged oppositely in pairs;

as shown in fig. 5 and 6, the upper sliding tray 11 is circular, a first central hole 111 is formed in the center of the upper sliding tray 11 to form an annular structure, first sliding grooves 112 are uniformly formed in the upper sliding tray 11 along the central circumferential direction, the track of the first sliding grooves 112 is arc-shaped and is generally arranged in an inclined manner towards one side, and a covered edge 113 is extended from one side of the outer circumference of the upper sliding tray 11;

as shown in fig. 7, the lower sliding plate 14 is circular, a second central hole 141 is formed in the center of the lower sliding plate 14 to form an annular structure, the second central hole 141 corresponds to the first central hole 111, the diameter of the second central hole is also equal to the diameter of the first central hole, second sliding grooves 142 are uniformly formed in the lower sliding plate 14 along the central circumferential direction, the second sliding grooves 142 correspond to the first sliding grooves 112 one by one, the track of each second sliding groove 142 is linear, one side of each second sliding groove is obliquely arranged opposite to the corresponding first sliding groove 112, the outer diameter of the lower sliding plate 14 is equal to the outer diameter of the upper sliding plate 11, the wrapping edges 113 wrap the circumferential side of the lower sliding plate 14, so that the upper sliding plate 11 and the lower sliding plate 14 cannot be separated from each other, and the lower sliding plate;

as shown in fig. 8 and 9, sliding block 12 is in a triangular structure with one side being arc-shaped, sliding blocks 12 are uniformly arranged along the central circumference of lower sliding plate 14, sliding blocks 12 are abutted in pairs to form an annular structure, and it is needless to say that the shape shown in fig. 8 and 9 can be designed according to actual design requirements, such as consideration of weight reduction, etc., at this time, the shape formed by abutting sliding blocks 12 in pairs is shown in fig. 3, sliding block 12 is located between upper sliding plate 11 and lower sliding plate 14, sliding block 12 is provided with connecting hole 121, first sliding slot 112, second sliding slot 142, sliding block 12 and stopper 13 are in one-to-one correspondence, stopper 13 passes through first sliding slot 112 and is connected to sliding block 121, stopper 13 is rotatably connected to sliding block 12, stopper 13 is slidably arranged in first sliding slot 112, and the side of sliding block 12 facing lower sliding plate 14 is provided with limit slider 122, the limit slider 122 is slidably disposed in the second chute 142; the inclination directions of first sliding chute 112 and second sliding chute 142 are opposite, when upper sliding tray 11 rotates, since stopper 13 is connected to sliding block 12, stopper 13 moves along the track of first sliding chute 112 under the action of first sliding chute 112 at this time, and simultaneously drives sliding block 12 to move, but since stopper 122 moves along the track of second sliding chute 142 at this time, sliding block 12 is driven to rotate, and finally, a plurality of sliding blocks 12 move close to and away from each other; the stopper 13 is cylindrical, an upper end cap is disposed at the upper end of the stopper 13, a groove (not shown) may be formed at the lower end of the sliding block 12, and a lower end cap (not shown) is disposed at the lower end of the stopper 13 to prevent the stopper 13 from being separated. Also can adopt the upper end cap to set to magnetism and inhale the formula, adopt magnetism to inhale the material with upper sliding plate 11 and make to it is fixed through magnetism mode to rely on upper end cap and upper sliding plate 11, thereby prevents that dog 13 and upper sliding plate 11 from breaking away from.

First watch-dog includes first treater, bee calling organ and first photoelectric sensing module 30, first photoelectric sensing module 30 and sliding block 12 one-to-one, and first photoelectric sensing module 30 is installed on sliding block 12, and first photoelectric sensing module 30 is equal signal connection to first treater, and first photoelectric sensing module 30 is used for monitoring whether the medium changes in the return duct. The first photoelectric sensing module 30 may be a first infrared transceiver module. The first infrared transceiver module and the first processor may be in wireless communication or in wired communication, the first processor and the buzzer may be mounted on the lower sliding plate 14, or may be mounted on the bracket, or the first photoelectric sensing module 30 and the first processor may be in wireless communication, and the first processor and the buzzer are integrated into a movable integrated module. The specific installation form and position can be adjusted according to the actual design requirement.

When the device is used, the backflow pipe penetrates through a space surrounded by the sliding block 12, the space corresponds to the first center hole 111 and the second center hole 141, as shown in fig. 1, the upper sliding disc 11 is rotated, the upper sliding disc 11 drives the stop block 13, the stop block 13 drives the sliding block 12, one side surface of the sliding block 12 is tightly attached to the backflow pipe, as the sliding block 12 is uniformly arranged along the circumferential direction of the backflow pipe at the moment, the sliding block 12 is provided with the first infrared receiving and transmitting modules and corresponds to each other two by two, therefore, the device can monitor from multiple angles, the backflow position of the volatile oil is not fixed, the extraction condition of the volatile oil can be better monitored by the multiple-angle monitoring, false detection alarm is avoided, as different medium light guide rates are different, when the volatile oil is continuously extracted and flows downwards along the backflow pipe, the volatile oil flows along the inner wall of the backflow pipe, the data monitored by the first infrared transceiver module are uniformly sent to the first processor, the first processor judges and compares the data, when the volatile oil flows, only part of the pipe wall flows, the data monitored by the first infrared transceiver module changes when the volatile oil flows, the volatile oil flows and the volatile oil does not flow, and the data monitored by the first infrared transceiver module is also different, so that whether the volatile oil is extracted or not can be monitored through the characteristics, and if any first infrared transceiver module monitors that the volatile oil flows, the volatile oil is considered to be extracted. And when the data monitored by the first infrared transceiver module are inconsistent, the volatile oil is still extracted. When the volatile oil is extracted and no volatile oil flows, the values monitored by all the first infrared transceiver modules do not change any more, and the monitored values are different from the values when the volatile oil flows, so that the relevant data can be consulted in advance or the relevant values can be monitored in an experimental mode and written into the first processor for summarizing in a budget, when the values are fixed and unchanged, when the volatile oil extraction is considered to be finished, a fixed time can be set, and if the values monitored by the first infrared transceiver modules within three minutes do not change, the volatile oil extraction is considered to be finished. As shown in fig. 15, when the first processor determines that the volatile oil extraction is completed, the first processor sends a signal to control the buzzer to alarm, and the worker is reminded to perform the next action.

Example two:

on the basis of the first embodiment, as shown in fig. 12, the present embodiment further includes a separation monitoring device, which includes a base 20, an upright rod 21, an adjusting seat 22, a supporting rod 23, an adjusting wheel 25, two mounting seats 24, and two second monitors, wherein one end of the upright rod 21 is connected to the base 20, the other end of the upright rod is connected to the adjusting seat 22, the adjusting wheel 25 is rotatably disposed on the adjusting seat 22, lead screws 251 are coaxially disposed on two sides of the adjusting wheel 25, threaded holes matched with the lead screws 251 are disposed on the supporting rod 23, the supporting rod 23 is slidably disposed on the adjusting seat 22, and the lead screws 251 drive the supporting rod 23 to move when rotating; the second watch-dog sets up on mount pad 24, two second watch-dogs set up relatively, the second watch-dog includes the second treater, second photoelectric sensing module 40, solenoid valve and first wireless receiving module, first watch-dog still includes with first wireless receiving module assorted first wireless transmitting module, first wireless transmitting module signal connection is to first treater, second photoelectric sensing module 40, solenoid valve and first wireless receiving module are all signal connection to the second treater, the liquid end at the volatile oil apparatus is installed to the solenoid valve, second photoelectric sensing module 40 is used for monitoring whether the medium changes in the return pipe, first watch-dog is located the second watch-dog top. Specifically, the accommodating cavity is formed in the adjusting seat 22, one end of the supporting rod 23 is located in the accommodating cavity, and the screw 251 is located in the accommodating cavity. The second photoelectric sensing module 40 is a second infrared transceiver module. According to the method recorded in Chinese pharmacopoeia, after the volatile oil is extracted, a piston needs to be opened to discharge water. Therefore, when the backflow monitoring device 10 detects that the volatile oil extraction is completed, as shown in fig. 16 and 17, the first processor sends a signal to the second processor through the first wireless transmitting module, the first wireless receiving module receives the signal from the first wireless transmitting module and transmits the signal to the second processor, the second processor controls the electromagnetic valve to be opened and the water is discharged, the second photoelectric sensing module 40 is located at the liquid outlet of the volatile oil extraction device at the moment, because the light guiding rate of the water is different from the light guiding rate of the oil, when the electromagnetic valve opens and the water is discharged, the light guiding rate of the water is monitored by the second photoelectric sensing module 40, when the water is discharged to the oil, the second photoelectric sensing module 40 monitors the signal change and transmits the signal to the second processor, the second processor judges that the water is discharged, and at the moment, the second processor controls the electromagnetic valve to be closed. At this time, the experimenter is reminded to read the data through an alarm or reminding device (not shown in the figure).

Example three:

on the basis of the first or second embodiment, the inner side of the wrapping edge 113 is uniformly provided with the first sliding teeth 114 in the circumferential direction, the outer peripheral side of the lower sliding disk 14 is uniformly provided with the second sliding teeth 143 in the circumferential direction, and the first sliding teeth 114 are matched with the second sliding teeth 143. In order to prevent slide block 12 from moving during operation, first slide tooth 114 and second slide tooth 143 are provided, and first slide tooth 114 and second slide tooth 143 are engaged to realize positioning, and when a change is required, upper slide plate is rotated, first slide tooth 114 and second slide tooth 143 are pressed and deformed to generate dislocation, so that the positioning is engaged again.

The above disclosure is only for a few specific embodiments of the present invention, however, the present invention is not limited to the above embodiments, and any variations that can be made by those skilled in the art are intended to fall within the scope of the present invention.

Claims (6)

1. A volatile oil separation and measurement device, comprising:

a support;

the backflow monitoring device comprises an upper sliding disc, a lower sliding disc, a plurality of sliding blocks, stop blocks and first monitors, wherein the stop blocks correspond to the sliding blocks one by one, and the number of the sliding blocks is even;

the upper sliding disc is circular, a first central hole is formed in the center of the upper sliding disc, first sliding grooves are uniformly formed in the upper sliding disc along the circumferential direction of the center, the track of each first sliding groove is arc-shaped and is arranged in an inclined mode overall towards one side, and a covered edge extends from the peripheral side of the upper sliding disc to one side;

the lower sliding disc is circular, a second central hole is formed in the center of the lower sliding disc, second sliding grooves are uniformly formed in the upper edge of the lower sliding disc along the circumferential direction of the center, the track of each second sliding groove is linear and is obliquely arranged on one side opposite to the first sliding groove, the surrounding side of the lower sliding disc is wrapped by the wrapping edge, and the lower sliding disc is fixedly connected to the support;

the sliding blocks are of an arc-shaped triangular structure at one side, the sliding blocks are uniformly arranged along the central circumference of the lower sliding disc, the sliding blocks are abutted in pairs to form an annular structure, the sliding blocks are positioned between the upper sliding disc and the lower sliding disc, connecting holes are formed in the sliding blocks, the first sliding grooves, the second sliding grooves, the sliding blocks and the stop blocks are in one-to-one correspondence, the stop blocks penetrate through the first sliding grooves and are rotatably connected to the connecting holes, the stop blocks are slidably arranged in the first sliding grooves, and limit sliding blocks are arranged on the side surfaces, facing the lower sliding disc, of the sliding blocks and are slidably arranged in the second sliding grooves;

when the upper sliding disc rotates, the sliding blocks are driven to move close to or away from each other;

first watch-dog includes first treater, bee calling organ and a photoelectric sensing module, the equal signal connection of a photoelectric sensing module is to first treater, a photoelectric sensing module sets up on the sliding block, a photoelectric sensing module is used for monitoring whether the medium changes in the return pipe.

2. The apparatus according to claim 1, wherein the first photoelectric sensing module is a first infrared transceiver module.

3. The volatile oil separation and determination device according to claim 1, further comprising a separation monitoring device, which comprises a base, a vertical rod, an adjusting seat, a support rod, an adjusting wheel, two mounting seats and two second monitors, wherein one end of the vertical rod is connected to the base, the other end of the vertical rod is connected to the adjusting seat, the adjusting wheel is rotatably disposed on the adjusting seat, a lead screw is coaxially disposed on two sides of the adjusting wheel, a threaded hole matched with the lead screw is disposed on the support rod, the support rod is slidably disposed on the adjusting seat, and the lead screw drives the support rod to move when rotating; the second watch-dog sets up on the mount pad, two the second watch-dog sets up relatively, the second watch-dog includes second treater, second photoelectric sensing module, solenoid valve and first wireless receiving module, first watch-dog still include with first wireless transmitting module of first wireless receiving module assorted, first wireless transmitting module signal connection to first treater, second photoelectric sensing module the solenoid valve with first wireless receiving module is all signal connection to the second treater, the liquid outlet end at volatile oil apparatus is installed to the solenoid valve, second photoelectric sensing module is used for monitoring whether the medium of volatile oil apparatus liquid outlet changes, first watch-dog is located the second watch-dog top.

4. The device for separating and measuring volatile oil according to claim 3, wherein the adjusting seat is provided with a receiving cavity, one end of the supporting rod is positioned in the receiving cavity, and the lead screw is positioned in the receiving cavity.

5. The apparatus according to claim 3, wherein the second photoelectric sensing module is a second infrared transceiver module.

6. The volatile oil separation and determination device according to any one of claims 1 to 5, wherein first sliding teeth are uniformly circumferentially arranged on the inner side of the edge cover, second sliding teeth are uniformly circumferentially arranged on the outer peripheral side of the lower sliding disk, and the first sliding teeth are matched with the second sliding teeth.

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