CN113075392B

CN113075392B - Organism structure of ultrasonic biological treatment device in laboratory

Info

Publication number: CN113075392B
Application number: CN201911306591.4A
Authority: CN
Inventors: 屈百达; 程宪宝; 姜愉; 梁家海; 胡俐蕊; 农国才
Original assignee: Beibu Gulf University
Current assignee: Beibu Gulf University
Priority date: 2019-12-18
Filing date: 2019-12-18
Publication date: 2021-11-26
Anticipated expiration: 2039-12-18
Also published as: CN113075392A

Abstract

A machine body structure of a laboratory ultrasonic biological treatment device comprises an operation surface, a treatment tank, a material returning pipe, an energy converter, a circulating pump, a material returning pipe, a machine body, a mechanism beam, a touch screen, a power switch key, a temperature controller, a refrigerator, a signal wire pipe, a monitoring terminal, a liquid outlet valve, an anti-drip cover, a circuit box, an assembly beam and the like. The operation surface is attached to the back side of the top of the machine body and faces forwards. The processing tank is assembled at the upper end part of the machine body. The return pipe is assembled in a cavity between the left wall of the shell on the left side of the machine body and the left wall of the processing tank. The transducer is embedded at the bottom of the outer wall of the treatment tank. The circulating pump is assembled on the inner wall of the shell at the left side of the machine body and at the left lower side of the treatment tank. The feed back pipe is assembled below the processing tank. The touch screen is assembled in the center of the operation surface. The temperature controller is embedded in the rear part of the operation surface and above the treatment tank. The heat absorption and conduction linings of the refrigerator are embedded and attached to the outer sides of the front wall and the rear wall of the treatment tank in pairs. The monitoring terminal is assembled in the middle position at the lower right of the processing tank and is connected with the rear guide pipe in a downward connection mode.

Description

Organism structure of ultrasonic biological treatment device in laboratory

Technical Field

The invention relates to a device structure, a process and a method for ultrasonic biological treatment in a laboratory.

Background

The laboratory device, the process and the method of ultrasonic biological treatment still belong to the modes of single-frequency treatment, group comparison and induction effect at present. The current laboratory method of ultrasonic biological treatment is as follows: by setting or selecting a certain operating frequency of the ultrasonic wave generating apparatus in advance, the ultrasonic wave of the frequency is applied to the treatment object. However, the processing rate of the ultrasonic waves to the object is highly related to the ultrasonic frequency, and the ultrasonic frequency is different, so that the processing efficiency is greatly different; furthermore, the type of biological cells to be treated is highly correlated with the frequency of ultrasonic waves, and different biological cells have greatly different sensitivities to ultrasonic waves of different frequencies. This makes the determination of the primary ultrasonic frequency of the conventional ultrasonic biological treatment method blind, and further makes the additional ultrasonic frequency analysis and determination dependent. The actual working process is as follows: processing conditions of certain biological cells under different frequencies are utilized to carry out sub-band comparison and analysis determination to obtain related data; in later work, the appropriate ultrasound frequency was determined empirically, using the data for that particular object. This has been a common practice. Essentially, such a method cannot guarantee that the working ultrasonic frequency is the efficient optimal frequency for the object, and cannot perform precise fine frequency adjustment on different objects, and the accumulated experience is not the optimal process; moreover, the method not only consumes a lot of manpower, financial resources and material resources in the initial stage, but also frequently requires observation, adjustment and maintenance in the lifetime. In view of the above, there is a need to develop a new and efficient strategy for ultrasound bioprocessing that does not follow the inefficient procedure of first cross-band comparison, analysis to determine the ultrasound frequency, and then empirically determining the desired frequency, but rather makes the process of determining the desired frequency maximally efficient and automated. The scheme for solving the problems can be divided into a multi-body integrated networking visual structure experimental device, a process and a method, or a multi-frequency integrated visual structure experimental device, a process and a method.

Disclosure of Invention

The invention provides a machine body structure of a laboratory ultrasonic biological treatment device, which aims to realize measurable and controllable ultrasonic biological treatment process and realize broadband search and control in a biological-mechanical-electric integrated visual treatment system. The operation surface is attached to the back side of the top of the machine body and faces forwards. The processing tank is assembled at the upper end part of the machine body. The return pipe is assembled in a cavity between the left wall of the shell on the left side of the machine body and the left wall of the processing tank. The transducer is embedded at the bottom of the outer wall of the treatment tank. The circulating pump is assembled on the inner wall of the shell at the left side of the machine body and at the left lower side of the treatment tank. The feed back pipe is assembled below the processing tank. The machine body is formed by wrapping a wall shell outside a four-corner column, and the bottom of the four-corner column is connected with an adjustable column base. Two ends of each mechanism beam are horizontally arranged at the middle lower parts of the left and right corner posts. The touch screen is assembled in the center of the operation surface. The power switch key is assembled in the right middle of the operation surface. The temperature controller is embedded in the rear part of the operation surface and above the treatment tank. The heat absorption and conduction linings of the refrigerator are embedded and attached to the outer sides of the front wall and the rear wall of the treatment tank in pairs. The vertical section of the signal line pipe is coated on the inner side of the rear right corner post, and the lower port of the horizontal section of the signal line pipe is connected with and communicated with the monitoring terminal outlet; the upper port of the operation panel is matched and connected with the top surface of the machine body and the right rear corner position of the rear lower surface of the operation panel. The monitoring terminal is assembled in the middle position at the lower right of the processing tank and is connected with the rear guide pipe in a downward connection mode. The liquid outlet valve is assembled on the right wall of the shell of the machine body, and the middle position of the right lower part of the processing groove. The tray bottom of the drip-proof cover is applied and assembled below the two mechanism beams. The circuit box is assembled on the two assembling beams and below the anti-dripping cover.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the organism structure of the ultrasonic biological treatment device in the laboratory comprises an operation surface, a treatment tank, a material returning pipe, an energy converter, a circulating pump, a material returning pipe, an organism, a mechanism beam, a touch screen, a power switch key, a temperature controller, a refrigerator, a signal wire pipe, a monitoring terminal, a liquid outlet valve, a drip-proof cover, a circuit box, an assembly beam and the like.

The operation surface is used as a mechanism part for man-machine interaction support and operation, is in a rectangular structure made of stainless steel sheet materials, is attached to the back side of the top of the machine body, and faces forwards. The processing tank is used as a machine body component for containing the processing liquid of the object, is in a rectangular parallelepiped groove-shaped structure made of 304 stainless steel materials, and is assembled at the upper end part of the machine body. The material returning pipe is used as a machine body running component for circulating and homogenizing the treatment liquid, is in a 304 type stainless steel circular pipe structure, and is assembled in a cavity channel between the left wall of the machine shell on the left side of the machine body and the left wall of the treatment tank. The transducer is used as an element for converting ultrasonic frequency electric energy into mechanical energy with the same frequency and is embedded and matched at the bottom of the outer wall of the treatment tank. The circulating pump is used as a device for driving and guiding the circulation and homogenization of the treatment liquid and is assembled on the inner wall of the shell on the left side of the machine body, the liquid outlet of the left lower part of the treatment tank is communicated with the return pipe, and the liquid suction port is communicated with the return pipe. The material return pipe is used as a machine body running component for circulating and homogenizing the treatment fluid, is of a 304 type stainless steel circular pipe structure, is assembled below the treatment tank, and is communicated with a fluid suction port of the circulating pump at the left end and is communicated with a front guide pipe of the liquid outlet valve at the right end. The machine body is used as a device framework of the whole system, is of a stainless steel rectangular section cylinder structure and is formed by wrapping a wall shell outside a four-corner column, and the bottom of the four-corner column is connected with an adjustable column base. The mechanism beam is used as a component for reinforcing the machine body and assembling and connecting the drip-proof cover and is of a structure of two stainless steel angle steel rods, and the two ends of each stainless steel angle steel rod are horizontally arranged at the middle lower parts of the left and right angle columns. The touch screen is used as a medium for man-machine interaction, is a rectangular electronic device and is assembled in the center of the operation surface. The power switch key is used as a power-on and power-off operating mechanism of a main power supply of the system, is a key type electrical appliance device with an indicator light and is assembled in the right middle position of the operating surface. The temperature controller is used as a matching device for controlling the temperature of the treatment liquid in the treatment tank through the refrigerator, and is embedded at the rear part of the operation surface, above the treatment tank, and the inner side of the machine shell at the right side of the machine body is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller faces outwards and leaks out from the opening of the operation surface of the temperature controller of the machine shell. The refrigerator is used as a cooling device for system operation, is a semiconductor refrigeration device with a rectangular disc structure, and is embedded and stuck with the outer sides of the front wall and the rear wall of the treatment tank pairwise by heat absorption and heat conduction linings thereof. The signal line pipe is used as a component for bearing and passing through the monitoring signal transmission line, is of a stainless steel long pipe-shaped structure, is coated on the inner side of the rear right corner post by the vertical section of the signal line pipe, and is connected with and communicated with the monitoring terminal wire outlet by the lower port of the horizontal section of the signal line pipe; the upper port of the operation panel is matched and connected with the top surface of the machine body and the right rear corner position of the rear lower surface of the operation panel. The monitoring terminal is used as a device for accommodating a monitoring object and a sensing device and is of a structure that an elliptical cross-section cylinder shell accommodates an inner pulp, a front guide pipe of the monitoring terminal is matched with a liquid outlet pipe of the processing tank, and the monitoring terminal is assembled in a middle position at the lower right of the processing tank and is connected with a rear guide pipe. The liquid outlet valve is used as an accessory for discharging treatment liquid, is a 304 type stainless steel standard component, is matched with the monitoring terminal, the material return pipe and the right wall of the shell of the machine body, and is assembled on the right wall of the shell of the machine body and the middle position at the lower right side of the treatment tank. The drip-proof cover is used as a component for preventing liquid from dripping and protecting a circuit from drying, and is of a rectangular dish structure which is made of stainless steel thin plates, and the bottom of the dish is applied and assembled below two mechanism beams. The circuit box is used as a device for assembling and supporting the circuit structure of the system and is assembled on the two assembling beams and below the anti-dripping cover.

The invention has the beneficial effects that: the integration greatly simplifies the system structure and the operation, is convenient for adjusting the control scheme and realizing various novel control strategies through the change of program software, can realize the automatic storage of operation data, can make the ultrasonic biological treatment process measurable and controllable, realizes the biological-mechanical-electrical integration, and is beneficial to realizing the intellectualization of the ultrasonic biological treatment; the frequency of the transducer can be continuously monitored and adjusted to provide the best ultrasonic output; the process monitoring and parameter graphic display function of the touch screen display is utilized to specially program all processing operation parameters and graphically express the change of ultrasonic frequency, power, processing speed and processing process physicochemical parameters; the processing program can be adjusted through a man-machine conversation mode of the control terminal, and an operator can input related data according to prompts, so that the operation is intuitive and clear; the long time consumption of sub-band comparison and analysis for determining the optimal frequency is avoided, the proper frequency for processing various biological cells is easy to find, and the optimal process conditions are quickly established. The mode that the resonant inductor is additionally provided with the secondary winding current detection coil is adopted, the utility/volume ratio of the inductance coil is improved, the problem that the inductance coil is subjected to point and current detection is solved, the occupation of the machine body space is reduced, and the utilization rate of detection points is greatly improved. The circuit is an ultrasonic driving power supply circuit with high cost performance, can powerfully drive the processing tank energy converter, and enables the laboratory ultrasonic biological processing device to become an ultrasonic experiment and test device which is portable, easy to operate, and suitable for wide application type biological processing in various occasions. The device is convenient to realize and adjust, simple in structure and easy for batch production; the software and hardware of the system are formed, so that the maintenance and the repair are simple and easy.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a front view of the device structure of the present invention.

Fig. 2 is a left side view of the device structure of the present invention.

Fig. 3 is a front view of the operation surface of the device structure.

Fig. 4 is a top view of the device structure.

FIG. 5 is a front view of a processing bath arrangement of the apparatus.

FIG. 6 is a plan view of a processing bath arrangement of the apparatus.

FIG. 7 is a bottom view of the configuration of the treatment tank arrangement part of the apparatus.

FIG. 8 is a bottom view of a treating tank arrangement of the apparatus.

FIG. 9 is a sectional view showing the configuration of the acousto-optic detection arrangement of the processing bath.

FIG. 10 is a right side view of the acousto-optic detection structure of the processing tank.

FIG. 11 is a sectional view taken along line A-A of the acousto-optic detection structure of the processing bath.

FIG. 12 is a sectional view taken along line B-B of the acousto-optic detection structure of the processing bath.

In FIGS. 1 to 8: 1. the device comprises an operation surface, 2 parts of a processing tank, 3 parts of a material returning pipe, 4 parts of an energy converter, 5 parts of a circulating pump, 6 parts of a material returning pipe, 7 parts of a machine body, 8 parts of a mechanism beam, 9 parts of a touch screen, 10 parts of a power switch key, 11 parts of a temperature controller, 12 parts of a refrigerator, 13 parts of a signal wire pipe, 14 parts of a monitoring terminal, 15 parts of a liquid outlet valve, 16 parts of an anti-drip cover, 17 parts of a circuit box and 18 parts of an assembly beam.

In FIGS. 2 to 8: 19. the machine body framework.

In FIGS. 3 to 8: 1.1. and touch screen mounting holes.

In FIGS. 4 to 8: 20. the bottom opening of the groove.

In FIGS. 5 to 8: 15.1. and (5) bending the pipe.

In FIGS. 9 to 12: 14.1. the temperature measuring device comprises a shielding shell, 14.2, a temperature measuring part, 14.3, a sound transmission pipe, 14.4, a connecting hoop, 14.5, a light transmission pipe, 14.6, a light projecting part, 14.7, a light measuring part, 14.8, a sound measuring part, 15.2, a lower matching hoop, 15.3, an upper matching hoop and 15.4, a short joint.

Detailed Description

In the front view of the device structure of the invention shown in fig. 1: the operation surface 1 is used as a mechanism part for man-machine interaction support and operation, is in a rectangular structure made of stainless steel sheet materials, is attached to the back side of the top of the machine body 7, and faces forwards. The treatment tank 2 is a rectangular parallelepiped tank-shaped structure of 304 type stainless steel material as a body member for containing a treatment liquid as an object, and is attached to an upper end portion of the body 7. The return pipe 3 is used as a machine body running component for circulating and homogenizing the treatment liquid, is in a 304 type stainless steel circular pipe structure, and is assembled in a cavity channel between the left wall of the machine shell on the left side of the machine body 7 and the left wall of the treatment tank 2. The transducer 4 is used as an element for converting ultrasonic frequency electric energy into mechanical energy with the same frequency, and is embedded and matched at the bottom of the outer wall of the processing tank 2. The circulating pump 5 is used as a device for driving and guiding the circulation and homogenization of the treatment liquid and is assembled on the inner wall of the shell on the left side of the machine body 7, the liquid outlet of the left lower part of the treatment tank 2 is communicated with the return pipe 3, and the liquid suction port is communicated with the return pipe 6. The material return pipe 6 is used as a machine body running component for circulating and homogenizing the treatment fluid, is of a 304 type stainless steel circular pipe structure, is assembled below the treatment tank 2, and is communicated with a fluid suction port of the circulating pump 5 at the left end and is communicated with a front guide pipe of the liquid outlet valve 15 at the right end. The machine body 7 is used as a device framework of the whole system, is of a stainless steel rectangular section cylinder structure, and is formed by wrapping a wall shell outside a four-corner column, and the bottom of the four columns is connected with adjustable column feet. The mechanism beam 8 is used as a component for reinforcing the machine body and assembling the anti-drip cover 16 and is of a structure of two stainless steel angle steel rods, and the two ends of each stainless steel angle steel rod are horizontally arranged at the middle lower parts of the left and right angle posts. The touch screen 9 is a rectangular electronic device as a medium for man-machine interaction, and is assembled at the center of the operation surface 1. The power switch key 10 is used as a power-on/power-off operation mechanism of a main power supply of the system, is a key-type electrical device with an indicator light, and is assembled in the right middle of the operation surface 1. The temperature controller 11 is used as a matching device for controlling the temperature of the treatment liquid in the treatment tank through the refrigerator 12, and is embedded at the rear part of the operation surface 1, on the upper surface of the treatment tank 2, and the inner side of the machine shell at the right side of the machine body 7 is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller 11 faces outwards and leaks out from the opening of the operation surface of the machine shell. The refrigerator 12 is a cooling device for system operation, and is a semiconductor refrigeration device with a rectangular disc structure, and the heat absorption and conduction linings of the refrigerator are embedded and attached to the outer sides of the front wall and the rear wall of the treatment tank 2 in pairs. The signal line pipe 13 is used as a component for bearing and passing through the monitoring signal transmission line, is of a stainless steel long pipe-shaped structure, is coated on the inner side of the rear right corner post by the vertical section, and is connected and matched with the outlet of the monitoring terminal 14 by the lower port of the horizontal section and is communicated with the outlet; the upper port is matched and connected with the top surface of the machine body 7 and the right rear corner position of the rear lower surface of the operation surface 1. The monitoring terminal 14 is used as a device for accommodating a monitoring object and a sensing device, is of a structure that an elliptical cross-section cylinder shell accommodates an inner pulp, and is provided with a front conduit which is matched with a liquid outlet pipe of the processing tank 2, is assembled in the middle position at the lower right of the processing tank 2 and is connected with a rear conduit. The liquid outlet valve 15 is a 304 type stainless steel standard component as a fitting for discharging the treatment liquid, is matched with the monitoring terminal 14, the material return pipe 6 and the right wall of the shell of the machine body 7, and is assembled on the right wall of the shell of the machine body 7 and at the middle position at the lower right of the treatment tank 2. The drip-proof cover 16 is a rectangular dish structure made of a thin stainless steel plate and attached to the bottom of the two mechanism beams 8 to prevent liquid from dripping and protect the circuit from drying. The circuit box 17 is used as a device for assembling and supporting the circuit structure of the system and is assembled on two assembling beams 18 and below the anti-drip cover 16.

In the front view of the device structure of the invention shown in fig. 1 and the left view of the device structure of the invention shown in fig. 2: the operation surface 1 is attached to the back side of the top of the machine body 7, faces forwards and upwards, and is inclined at an angle of 60 degrees with the plane of the top. The processing groove 2 is assembled at the upper end of the machine body 7 and at the front part of the operation surface 1, and the upper outer edge of the processing groove is jointed with the upper inner edge of the top frame of the machine body framework 19 through silica gel. The transducers 4 are mounted in three rows on the bottom of the outer wall of the treatment tank 2. The circulating pump 5 is assembled on the inner wall of the shell on the left side of the machine body 7, the middle position on the lower left side of the processing tank 2 is provided with a liquid outlet communicated with the return pipe 3, and a liquid suction port communicated with the return pipe 6. The temperature controller 11 is embedded in the back of the operation surface 1, on the processing tank 2, and is closely attached to the right wall of the machine shell at the inner side of the machine shell at the right side of the machine body 7, and the operation surface of the temperature controller 11 faces outwards and leaks out from the opening of the operation surface of the temperature controller 11 of the machine shell. The heat absorbing surfaces of the refrigerators 12 are embedded in pairs and are deviated from the outer sides of the front and rear walls of the treatment tank 2. The lower end of the horizontal section of the signal conduit 13 is connected with and communicated with the outlet of the monitoring terminal 14. The liquid outlet valve 15 is assembled on the right wall of the shell of the machine body 7, and the middle position of the right lower part of the processing groove 2.

In the left side view of the device structure of the invention shown in fig. 2: the machine body framework 19 is used as a framework structure for supporting the whole machine body 7, is made of stainless steel material angle steel profiles, forms a whole machine framework in a four-corner column-upper beam and lower beam mode, the rear part of the upper beam frame is upward, extends to form an operating circuit chamber for accommodating a human-computer interaction operating circuit, and the middle part and the front part are pasted with the processing tank 2; the bottom of the four columns is connected with an adjustable column base.

In a front view of the device structure of the invention shown in fig. 1, a left side view of the device structure of the invention shown in fig. 2 and a front view of the operating face of the device structure shown in fig. 3: the operation surface 1 is a rectangular structure made of stainless steel sheet material, and the center of the operation surface is provided with an opening for assembling the touch screen 9. The touch screen 9 is mounted behind an opening in the center of the operating panel 1, the panel facing forward and fitting into the opening. The power switch key 10 is mounted in the right middle of the operation panel 1.

In the front view of the operating face of the device structure shown in fig. 3: the touch screen mounting hole 1.1 is used as a screw through hole for assembling the touch screen 9, is coordinated with the screw through holes at four corners of the touch screen 9, and is drilled at the four corners of the central position of the operating surface 1.

In the device structure view of the invention shown in fig. 1 to 3 and the device structure top view shown in fig. 4: the operation surface 1 is attached to the back side of the top of the machine body 7, the operation surface faces forwards and upwards, the operation surface and the plane of the top are inclined at an angle of 60 degrees, and the upper top edge of the inclined plane is welded with the front edge of the top beam of the back frame of the machine body 7. The processing groove 2 is assembled on the upper end surface of the machine body 7, the front platform of the operation surface 1, and the upper outer edge of the front platform is jointed with the upper inner edge of the top frame of the machine body framework 19 through silica gel. The return pipe 3 is arranged in a cavity between the left wall of the shell on the left side of the machine body 7 and the left wall of the processing tank 2. The circulating pump 5 is assembled on the inner wall of the shell on the left side of the machine body 7, the liquid outlet of the left lower part of the processing tank 2 is communicated with the return pipe 3, and the liquid suction port is communicated with the return pipe 6. The feed back pipe 6 is assembled below the processing tank 2, the left end of the feed back pipe is connected and communicated with a liquid suction port of the circulating pump 5, and the right end of the feed back pipe is connected and communicated with a rear guide pipe of the monitoring terminal 14. The touch panel 9 is mounted at the center of the operation panel 1. The power switch key 10 is disposed in the right middle of the operation panel 1. The temperature controller 11 is arranged at the back part of the operation surface 1 and above the processing tank 2, the inner side of the machine shell at the right side of the machine body 7 is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller 11 faces outwards and leaks out from the opening of the operation surface of the temperature controller 11 of the machine shell. The refrigerator 12 is embedded and adhered with the heat absorption and conduction lining surfaces of the refrigerator two by two on the outer sides of the front wall and the rear wall of the processing tank 2. The lower port of the horizontal section of the signal conduit 13 is connected with and matched with the outlet of the monitoring terminal 14 and is communicated with the outlet; the rear section of which is guided into the right rear corner of the rear lower face of the worktop 1. The monitoring terminal 14 is matched with a liquid outlet pipe at the bottom opening 20 of the processing tank 2 through a front guide pipe thereof and is assembled at the lower right middle position of the processing tank 2; the lower end of the monitoring terminal 14 is connected with a rear duct in a penetrating way. The liquid outlet valve 15 is matched with a rear guide pipe of the monitoring terminal 14, the right end of the material return pipe 6 and the right wall of the shell of the machine body 7, and is assembled on the right wall of the shell of the machine body 7 and the middle position of the right lower part of the processing groove 2.

In the top view of the device structure shown in fig. 4: the tank bottom port 20 is a standard component made of 304 type stainless steel materials and is tightly assembled at the liquid outlet of the processing tank 2 as a structure for discharging the processing liquid and adapting to the front conduit of the monitoring terminal 14, and the lower port is sleeved and communicated with the front conduit of the monitoring terminal 14.

In the structural views of the apparatus of the present invention shown in FIGS. 1 to 4 and the front view of the arrangement structure of the processing bath of the apparatus shown in FIG. 5: the opening of the processing groove 2 is an upward round-angle rectangular groove, and the notch is of an outer flashing edge structure. The material returning pipe 3 is assembled outside the left wall of the processing tank 2, and the right corner at the upper end is connected and communicated with the upper part of the left wall of the processing tank 2. The transducers 4 are staggered in three rows and three columns, so that the energy transmission surface is adhered and fitted at the bottom of the outer wall of the treatment tank 2 by using a strong AB adhesive. The circulating pump 5 is assembled at the lower left of the processing tank 2, the liquid outlet of the circulating pump is communicated with the return pipe 3, and the liquid suction port is communicated with the return pipe 6. The feed back pipe 6 is assembled below the processing tank 2, the left end of the feed back pipe is connected and communicated with a liquid suction port of the circulating pump 5, and the right end of the feed back pipe is connected and communicated with a rear guide pipe of the monitoring terminal 14. The refrigerator 12 is adhered and embedded with two strong AB glue on the heat absorption and conduction lining surface of the refrigerator and the outer sides of the front wall and the rear wall of the processing tank 2.

In the front view of the processing tank arrangement of the apparatus shown in FIG. 5: the bent pipe 15.1 is a pipe fitting for connecting and communicating the liquid outlet valve 15 with the inner conduit of the monitoring terminal 14, is a rear conduit of the monitoring terminal 14 and extends in a 90-degree arc bending manner, the upper end is the rear conduit of the monitoring terminal 14, and the lower end is connected and communicated with the liquid inlet of the liquid outlet valve 15.

In the structural view of the apparatus of the present invention shown in FIGS. 1 to 5 and the structural plan view of the arrangement of the treatment tank of the apparatus shown in FIG. 6: 2 ascending fillet rectangular channels of opening of treatment trough, the notch is outer sudden strain of a muscle border structure, and the tank bottom is the thickening enhancement plane of 1.2 mm. The refrigerator 12 is adhered and embedded with two strong AB glue on the heat absorption and conduction lining surface of the refrigerator and the outer sides of the front wall and the rear wall of the processing tank 2. The liquid outlet valve 15 is communicated with an inner conduit of the monitoring terminal 14 through an elbow 15.1, is communicated with a tank bottom port 20 and is assembled in the middle position at the lower right of the processing tank 2. The tank bottom port 20 is tightly fitted to a liquid outlet at the right middle portion of the treatment tank 2.

In the structural view of the apparatus of the present invention shown in FIGS. 1 to 6 and the structural bottom view of the treatment tank disposition part of the apparatus shown in FIG. 7: 2 ascending fillet rectangular channels of opening of treatment trough, the notch is outer sudden strain of a muscle border structure, and the tank bottom is the thickening enhancement plane of 1.2 mm. The transducers 4 are staggered in three rows and are grouped at A, B, C triple-frequency intervals, so that the energy transmission surfaces are attached to the outer wall of the bottom of the processing tank 2 by strong AB glue. The refrigerator 12 is adhered and embedded with two strong AB glue on the heat absorption and conduction lining surface of the refrigerator and the outer sides of the front wall and the rear wall of the processing tank 2. The tank bottom port 20 is tightly fitted to a liquid outlet at the right middle portion of the treatment tank 2.

In the structural view of the apparatus of the present invention shown in FIGS. 1 to 7 and the bottom view of the arrangement structure of the treatment tank of the apparatus shown in FIG. 8: 2 ascending fillet rectangular channels of opening of treatment trough, the notch is outer sudden strain of a muscle border structure, and the tank bottom is the thickening enhancement plane of 1.2 mm. The transducers 4 are staggered in three rows and are grouped at A, B, C triple-frequency intervals, so that the energy transmission surfaces are attached to the outer wall of the bottom of the processing tank 2 by strong AB glue. The circulating pump 5 is assembled on the inner wall of the shell on the left side of the machine body 7, the liquid outlet of the left lower part of the processing tank 2 is communicated with the return pipe 3, and the liquid suction port is communicated with the return pipe 6. The feed back pipe 6 is assembled below the middle column of the transducer 4 under the processing tank 2, the left end of the feed back pipe is connected and communicated with the liquid suction port of the circulating pump 5, and the right end of the feed back pipe is connected and communicated with the rear guide pipe of the monitoring terminal 14. The refrigerator 12 is adhered and embedded with two strong AB glue on the heat absorption and conduction lining surface of the refrigerator and the outer sides of the front wall and the rear wall of the processing tank 2. The lower end of the horizontal section of the signal conduit 13 is connected with and communicated with the outlet of the monitoring terminal 14. The monitoring terminal 14 is matched with a liquid outlet pipe at the bottom opening 20 of the processing tank 2 through a front guide pipe thereof and is assembled at the lower right middle position of the processing tank 2; the lower end of the monitoring terminal 14 is connected with a rear duct in a penetrating way. The liquid outlet valve 15 is communicated with an inner conduit of the monitoring terminal 14 through an elbow 15.1, is communicated with a tank bottom port 20 and is assembled in the middle position at the lower right of the processing tank 2.

In the bottom view of the processing tank arrangement structure of the apparatus shown in FIG. 8 and the cross-sectional view of the processing tank acousto-optic detection arrangement structure shown in FIG. 9: the elbow 15.1 is the back pipe extension of the inner pipe of the monitor terminal 14, the upper end is connected with the inner pipe of the monitor terminal 14 and is communicated with the liquid inlet of the liquid outlet valve 15, and the lower end is connected with the liquid inlet of the liquid outlet valve. The short section 15.4 is used as a front conduit of the monitoring terminal 14, and the lower port forms watertight compression fit with an inner buckling edge of a buckling ring on the upper adapter coupling 15.3 through an outer umbrella edge of the short section.

In the cross-sectional view of the processing tank acoustooptic detection configuration shown in FIG. 9: the shielding shell 14.1 is used as a containing and protecting shell of the monitoring terminal 14 and is of an elliptical-section cylindrical cavity thin shell structure, the upper opening of the shielding shell is in watertight fastening fit with a front guide pipe, the lower opening of the shielding shell is in fastening fit with a rear guide pipe, the middle part of the shielding shell is offset from the upper right side opening of the shielding shell and is used as a wire outlet of the monitoring terminal 14, the shielding shell is in embedded fit with the outer side of the lower opening of the flat transverse section of the signal wire pipe 13 through a sealant ring, and the cavity of the shielding shell is communicated with the inner cavity of the lower opening of the flat transverse section of the signal wire pipe 13. The temperature measuring part 14.2 is used as a sensing device for detecting the temperature of the processing liquid in the processing tank, the temperature sensing surface is attached to the left surface of the sound transmission pipe 14.3, the signal wire descends at the upper part of the inner cavity of the shielding shell 14.1, bypasses the right part after reaching the lower part, and then ascends to the port of the signal wire pipe 13 to penetrate into the signal wire pipe 13. The sound transmission tube 14.3 is used as a rectangular tube structure with a round corner in cross section and communicated with a front guide tube and a light transmission tube 14.5 of the monitoring terminal 14, the tube wall is a 304 type stainless steel sound guide material thin plate, an upper port is made to be communicated with the front guide tube of the monitoring terminal 14 through an upper matching hoop 15.3, and a lower port is communicated with the light transmission tube 14.5 through a connecting hoop 14.4. The coupling band 14.4 is made of 304 type stainless steel material as a pipe member for connecting and penetrating the sound transmission tube 14.3 and the light transmission tube 14.5, and has an upper inner wall closely adhered to the sound transmission tube 14.3 and a lower inner wall closely adhered to the light transmission tube 14.5. The light transmission tube 14.5 is a rectangular tube structure with a round corner in cross section and is connected and communicated with the sound transmission tube 14.3 and the rear guide tube of the monitoring terminal 14, the tube wall is made of high-temperature glass full-transparent material, the upper port is connected and communicated with the sound transmission tube 14.3 through a connecting hoop 14.4, and the lower port is connected and communicated with the rear guide tube of the monitoring terminal 14 through a lower matching hoop 15.2. The light projecting part 14.6 is used as a light source device of a target concentration or density monitoring sensing device in the processing liquid, is a group of 200-400nM ultraviolet LED device circuit components, and is pasted on the left surface of the light transmitting tube 14.5 by the LED light projecting end surface, and the driving electric wire of the light projecting part is converged and paralleled with the signal wire at the lower part of the inner cavity of the shielding shell 14.1, and simultaneously bypasses to the right part, and then goes up to the port of the signal wire tube 13 to penetrate into the signal wire tube 13. The photometry part 14.7 is used as a light receiving device of a target concentration or density monitoring sensing device in the processing liquid, is a group of 200-400nM ultraviolet sensitive device circuit components, is pasted on the right side of the light transmitting tube 14.5 by the light receiving end surface, and the signal wire of the photometry part runs to the port of the signal wire tube 13 at the lower part of the inner cavity of the shielding shell 14.1 and penetrates into the signal wire tube 13. The sound-detecting part 14.8 is used as a sensing device for ultrasonic sound intensity sensing, and is attached to the right side of the sound-transmitting tube 14.3 by the sound-receiving surface, and the signal wire of the sound-detecting part descends to the port of the signal wire tube 13 at the upper part of the inner cavity of the shielding shell 14.1 and penetrates into the signal wire tube 13. The lower adapter collar 15.2 is used as a connecting transition standard pipe fitting which is connected, buckled and penetrates through the lower port of the light transmitting tube 14.5 and a rear guide tube of the monitoring terminal 14, is of a structure with reverse internal threads at the upper half section and reverse internal threads at the lower half section and is screwed rightwards, the upper snap ring is of a transition structure from the cross section of a round-angle rectangular ring to the cross section of a circular ring, and the lower part of the upper snap ring is milled with a rightwards screwed external thread; the lower retaining ring is of a circular cross section structure, and the upper part of the lower retaining ring is milled with a left screwing external thread. The upper matching collar 15.3 is used as a connecting transition standard pipe fitting which is connected, buckled and runs through the upper port of the sound transmission pipe 14.3 and the front guide pipe of the monitoring terminal 14, is of a structure with reverse internal threads at the upper half part and reverse internal threads at the lower half part and is of a right screwed tight structure, the upper snap ring is of a circular cross section structure, and right screwed tight external threads are milled at the lower part; the lower retaining ring is a transition structure from the cross section of a round-corner rectangular ring to the cross section of a circular ring, and the upper part of the lower retaining ring is milled with a left-hand tightening external thread. The lower port of the short section 15.4 forms watertight and compact fit with the inner edge of the upper retaining ring of the upper matching hoop 15.3 through the outer umbrella edge.

In the cross-sectional view of the acousto-optic detection arrangement of the processing tank shown in FIG. 9 and the right side view of the acousto-optic detection arrangement of the processing tank shown in FIG. 10: the upper port of the sound transmission tube 14.3 is connected and communicated with the front guide tube of the monitoring terminal 14 through an upper matching hoop 15.3, and the lower port is connected and communicated with the light transmission tube 14.5 through a connecting hoop 14.4. The inner wall of the upper part of the connecting hoop 14.4 is tightly sealed with the sound transmission tube 14.3 silica gel, and the lower part is tightly sealed with the light transmission tube 14.5 silica gel. The upper port of the light transmission tube 14.5 is connected and communicated with the sound transmission tube 14.3 through a connecting hoop 14.4, and the lower port is connected and communicated with the rear guide tube of the monitoring terminal 14 through a lower matching hoop 15.2. The photometry part 14.7 is attached to the right side of the light transmitting tube 14.5 by the light receiving end face thereof, and the signal line thereof goes up to the port of the signal line tube 13 at the lower part of the inner cavity of the shielding case 14.1 to penetrate into the signal line tube 13. The sound-receiving surface of the sound-detecting part 14.8 is attached to the right side of the sound-transmitting tube 14.3, and the signal line passes through the signal line tube 13 at a port that descends to the signal line tube 13 in the upper part of the inner cavity of the shield case 14.1. The elbow 15.1 is the back pipe extension of the inner pipe of the monitor terminal 14, the upper end is connected with the inner pipe of the monitor terminal 14 and is communicated with the liquid inlet of the liquid outlet valve 15, and the lower end is connected with the liquid inlet of the liquid outlet valve. The lower adapting hoop 15.2 is a structure with reverse internal threads and right screwing on the upper half section and the lower half section, the upper snap ring is a transition structure from the cross section of a round-corner rectangular ring to the cross section of a circular ring, and right screwing external threads are milled on the lower part of the upper adapting hoop; the lower retaining ring is of a circular cross section structure, and the upper part of the lower retaining ring is milled with a left screwing external thread; a silica gel gasket is lined between the inner buckle edge of the upper buckle ring and the outer umbrella edge of the lower port of the light transmission tube 14.5, so that the inner buckle edge of the upper buckle ring and the outer umbrella edge of the lower port of the light transmission tube 14.5 form watertight and compact fit; a silica gel gasket is lined between the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the elbow 15.1, so that the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the elbow 15.1 form watertight and compact fit. The upper adapting hoop 15.3 is a structure with reverse internal threads and right screwing on the upper half section and the lower half section, the upper snap ring is a circular cross section structure, and right screwing external threads are milled on the lower part; the lower retaining ring is a transition structure from the cross section of a round-corner rectangular ring to the cross section of a circular ring, and the upper part of the lower retaining ring is milled with a left-hand tightening external thread; a silica gel gasket is lined between the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the sound transmission pipe 14.3, so that the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the sound transmission pipe 14.3 form watertight and compact fit. A silica gel gasket is lined between the outer umbrella edge of the lower port of the short section 15.4 and the inner buckling edge of the upper buckling ring of the upper matching hoop 15.3, so that the outer umbrella edge of the lower port of the short section 15.4 and the inner buckling edge of the upper buckling ring of the upper matching hoop 15.3 form watertight and compact fit.

In the sectional view of the processing bath acousto-optic detection arrangement structure shown in FIG. 9, the right side view of the processing bath acousto-optic detection structure shown in FIG. 10, and the A-A direction sectional view of the processing bath acousto-optic detection structure shown in FIG. 11: the temperature measuring part 14.2 is attached to the left side of the sound tube 14.3 with its temperature sensing surface. The upper port of the sound transmission tube 14.3 is connected and communicated with the front guide tube of the monitoring terminal 14 through an upper matching hoop 15.3, and the lower port is connected and communicated with the light transmission tube 14.5 through a connecting hoop 14.4. The inner wall of the upper part of the connecting hoop 14.4 is tightly sealed with the sound transmission tube 14.3 silica gel, and the lower part is tightly sealed with the light transmission tube 14.5 silica gel. The sound receiving surface of the sound measuring unit 14.8 is attached to the right surface of the sound transmitting tube 14.3, and the signal line passes through the signal line tube 13 at a port extending downward to the signal line tube 13 in the upper part of the inner cavity of the shield case 14.1. The elbow 15.1 is an extension of the conduit behind the monitoring terminal 14. The lower adapting hoop 15.2 is a structure with reverse internal threads and right screwing on the upper half section and the lower half section, the upper snap ring is a transition structure from the cross section of a round-corner rectangular ring to the cross section of a circular ring, and right screwing external threads are milled on the lower part of the upper adapting hoop; the lower retaining ring is of a circular cross section structure, and the upper part of the lower retaining ring is milled with a left screwing external thread.

In the views of the acousto-optic detection structure of the processing tank shown in FIGS. 9 to 11 and the B-B cross-sectional view of the acousto-optic detection structure of the processing tank shown in FIG. 12: the upper port of the sound transmission tube 14.3 is connected and communicated with the front guide tube of the monitoring terminal 14 through an upper matching hoop 15.3, and the lower port is connected and communicated with the light transmission tube 14.5 through a connecting hoop 14.4. The upper port of the light transmission tube 14.5 is connected and communicated with the sound transmission tube 14.3 through a connecting hoop 14.4, and the lower port is connected and communicated with the rear guide tube of the monitoring terminal 14 through a lower matching hoop 15.2. The light projecting part 14.6 is pasted on the left side of the light transmitting tube 14.5 by the LED light projecting end face, and the driving wire of the light projecting part is wound to the right part at the lower part of the inner cavity of the shielding shell 14.1 and then goes up to the port of the signal conduit 13 to penetrate into the signal conduit 13. The photometry part 14.7 is attached to the right side of the light transmitting tube 14.5 by the light receiving end face thereof, and the signal line thereof goes up to the port of the signal line tube 13 at the lower part of the inner cavity of the shielding case 14.1 to penetrate into the signal line tube 13. The elbow 15.1 is an extension of the conduit behind the monitoring terminal 14. The lower adapting hoop 15.2 is a structure with reverse internal threads and right screwing on the upper half section and the lower half section, the upper snap ring is a transition structure from the cross section of a round-corner rectangular ring to the cross section of a circular ring, and right screwing external threads are milled on the lower part of the upper adapting hoop; the lower retaining ring is of a circular cross section structure, and the upper part of the lower retaining ring is milled with a left screwing external thread; a silica gel gasket is lined between the inner buckle edge of the upper buckle ring and the outer umbrella edge of the lower port of the light transmission tube 14.5, so that the inner buckle edge of the upper buckle ring and the outer umbrella edge of the lower port of the light transmission tube 14.5 form watertight and compact fit; a silica gel gasket is lined between the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the elbow 15.1, so that the inner buckle edge of the lower buckle ring and the outer umbrella edge of the upper port of the elbow 15.1 form watertight and compact fit.

Claims

1. A machine body structure of a laboratory ultrasonic biological treatment device comprises an operation surface, a treatment tank, a material returning pipe, an energy converter, a circulating pump, a material returning pipe, a machine body, a mechanism beam, a touch screen, a power switch key, a temperature controller, a refrigerator, a signal wire pipe, a monitoring terminal, a liquid outlet valve, an anti-drip cover, a circuit box and an assembly beam; the method is characterized in that:

the operating surface is used as a mechanism part for man-machine interaction supporting and operating, is in a rectangular structure made of stainless steel sheet materials, is attached to the back side of the top of the machine body, and faces forwards; the treatment tank is used as a machine body component for containing the treatment liquid of the target object, is of a 304 type stainless steel material cuboid groove-shaped structure and is assembled at the upper end part of the machine body; the material returning pipe is used as a machine body running component for circulating and homogenizing the treatment liquid, is in a 304 type stainless steel circular pipe structure, and is assembled in a cavity channel between the left wall of the machine shell on the left side of the machine body and the left wall of the treatment tank; the energy converter is used as an element for converting ultrasonic frequency electric energy into mechanical energy with the same frequency and is embedded and matched at the bottom of the outer wall of the treatment tank; the circulating pump is used as a device for driving and guiding the circulation and homogenization of the treatment liquid, is assembled on the inner wall of the shell on the left side of the machine body, and is arranged on the left lower side of the treatment tank; the material return pipe is used as a machine body running component for circulating and homogenizing the treatment fluid, is in a 304 type stainless steel circular pipe structure, is assembled below the treatment tank, and has the left end communicated with a fluid suction port of the circulating pump and the right end communicated with a front guide pipe of the fluid outlet valve; the machine body is used as a device framework of the whole system, is of a stainless steel rectangular section cylinder structure and is formed by wrapping a wall shell outside a four-corner column, and the bottom of the four-corner column is connected with an adjustable column base; the mechanism beam is used as a component for reinforcing the machine body and assembling and connecting the drip-proof cover and is of a structure of two stainless steel angle steel rods, and the two ends of each stainless steel angle steel rod are horizontally arranged at the middle lower parts of the left and right angle columns; the touch screen is used as a medium for man-machine interaction, is a rectangular electronic device and is assembled at the center of the operation surface; the power switch key is used as a power-on and power-off operating mechanism of a main power supply of the system, is a key-type electrical device with an indicator light and is assembled in the right middle position of the operating surface; the temperature controller is used as a matched device for controlling the temperature of the treatment liquid in the treatment tank through the refrigerator, is embedded at the rear part of the operation surface, is arranged above the treatment tank, is arranged in the machine shell at the right side of the machine body and is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller faces outwards and leaks out from an opening of the temperature controller operation surface of the machine shell; the refrigerator is used as a cooling device for system operation, is a semiconductor refrigeration device with a rectangular disc structure, and is embedded and adhered to the outer sides of the front wall and the rear wall of the treatment tank in pairs by using heat absorption and heat conduction linings of the semiconductor refrigeration device; the signal line pipe is used as a component for bearing and passing through the monitoring signal transmission line, is of a stainless steel long pipe-shaped structure, is coated on the inner side of the rear right corner post by the vertical section of the signal line pipe, and is connected with and communicated with the monitoring terminal wire outlet by the lower port of the horizontal section of the signal line pipe; the upper port of the right rear corner position is matched and connected with the top surface of the machine body and the rear lower surface of the operation surface; the monitoring terminal is used as a device for accommodating a monitoring object and a sensing device and is of a structure that an outer shell of an elliptic-section cylinder contains an inner pulp, a front guide pipe of the monitoring terminal is matched with a liquid outlet pipe of the processing tank, is assembled in a middle position at the lower right of the processing tank and is connected with a rear guide pipe in a downward connection mode; the liquid outlet valve is used as an accessory for discharging treatment liquid, is a 304 type stainless steel standard component, is matched with the monitoring terminal, the material return pipe and the right wall of the shell of the machine body, is assembled on the right wall of the shell of the machine body, and is positioned in the middle position at the lower right of the treatment tank; the drip-proof cover is used as a component for preventing liquid from dripping and protecting the circuit from drying, is of a rectangular dish structure which is made of stainless steel thin plates, and is applied and assembled below the two mechanism beams by the bottom of the dish; the circuit box is used as a device for assembling and supporting the circuit structure of the system and is assembled on the two assembling beams and below the anti-dripping cover.

2. The housing structure of a laboratory ultrasonic biological treatment apparatus as set forth in claim 1, wherein: the operation surface is attached to the back side of the top of the machine body, faces forwards and upwards, and inclines at an angle of 60 degrees with the plane of the top; the processing groove is assembled at the upper end of the machine body, the front part of the operation surface, and the upper outer edge of the processing groove is jointed with the upper inner edge of the top frame of the machine body framework through silica gel; the transducers are embedded and matched at the bottom of the outer wall of the treatment tank in three rows; the circulating pump is assembled on the inner wall of the shell on the left side of the machine body, the middle position at the lower left of the processing tank is provided with a liquid outlet communicated with the return pipe, and a liquid suction port communicated with the return pipe; the temperature controller is embedded in the rear part of the operation surface and above the processing tank, the inner side of the machine shell on the right side of the machine body is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller faces outwards and leaks out from an opening of the operation surface of the temperature controller of the machine shell; the heat absorbing surfaces of the refrigerators are embedded in pairs and are deviated from the outer sides of the front wall and the rear wall of the treatment tank; the lower port of the horizontal section of the signal line pipe is connected with and matched with the outlet of the monitoring terminal and is communicated with the outlet of the monitoring terminal; the liquid outlet valve is assembled on the right wall of the shell of the machine body, and the middle position of the right lower part of the processing groove.

3. The housing structure of a laboratory ultrasonic biological treatment apparatus as set forth in claim 1, wherein: the operation surface is attached to the back side of the top of the machine body, the operation surface faces forwards and upwards and inclines at an angle of 60 degrees with the plane of the top, and the upper top edge of the inclined plane is welded with the front edge of the top beam of the back frame of the machine body; the processing groove is assembled on the upper end surface of the machine body, and the upper outer edge of a front platform of the operation surface is jointed with the upper inner edge of a top frame of the machine body framework through silica gel; the return pipe is assembled in a cavity channel between the left wall of the shell on the left side of the machine body and the left wall of the processing tank; the circulating pump is assembled on the inner wall of the shell on the left side of the machine body, the liquid outlet of the left lower part of the processing tank is communicated with the return pipe, and the liquid suction port is communicated with the return pipe; the feed back pipe is assembled below the processing tank, the left end of the feed back pipe is communicated with a liquid suction port of the circulating pump, and the right end of the feed back pipe is communicated with a rear guide pipe of the monitoring terminal; the touch screen is assembled at the center of the operation surface; the power switch key is arranged in the right middle position of the operation surface; the temperature controller is embedded in the rear part of the operation surface and above the processing tank, the inner side of the machine shell on the right side of the machine body is tightly attached to the right wall of the machine shell, and the operation surface of the temperature controller faces outwards and leaks out from an opening of the operation surface of the temperature controller of the machine shell; the heat absorption and conduction linings of the refrigerators are embedded and attached to the outer sides of the front wall and the rear wall of the treatment tank in pairs; the lower port of the horizontal section of the signal line pipe is connected with and matched with the outlet of the monitoring terminal and is communicated with the outlet of the monitoring terminal; the rear section of the operation surface is led into a right rear corner position behind the operation surface; the monitoring terminal is matched with a liquid outlet pipe at the bottom opening of the processing tank through a front guide pipe of the monitoring terminal and is assembled in a middle position at the lower right of the processing tank; the lower end of the monitoring terminal is connected with a rear guide pipe in a penetrating way; the liquid outlet valve is matched with a rear guide pipe of the monitoring terminal, the right end of the material return pipe and the right wall of the shell of the machine body, and is assembled on the right wall of the shell of the machine body, and the middle position of the right lower part of the processing groove.

4. The housing structure of a laboratory ultrasonic biological treatment apparatus according to claim 1 or claim 2, wherein: the opening of the treatment tank is an upward fillet rectangular tank, and the notch is of an outer flash edge structure; the material returning pipe is assembled outside the left wall of the treatment tank, and the right turn at the upper end of the material returning pipe is communicated with the upper part of the left wall of the treatment tank; the energy transducers are staggered in three rows and three rows, so that the energy transmission surface is adhered and embedded at the bottom of the outer wall of the treatment tank by strong AB glue; the circulating pump is assembled at the left lower part of the processing tank, a liquid outlet of the circulating pump is communicated with the return pipe, and a liquid suction port of the circulating pump is communicated with the return pipe; the feed back pipe is assembled below the processing tank, the left end of the feed back pipe is communicated with a liquid suction port of the circulating pump, and the right end of the feed back pipe is communicated with a rear guide pipe of the monitoring terminal; the refrigerator uses the two-purpose strong AB glue of the heat absorption and conduction lining surface of the refrigerator to be pasted and embedded with the outer sides of the front wall and the rear wall of the processing tank.

5. The housing structure of a laboratory ultrasonic biological treatment apparatus according to claim 1 or claim 2, wherein: a fillet rectangular groove with an upward opening is formed in the treatment groove, the notch is of an outer flash edge structure, and the groove bottom is a 1.2mm thickened reinforcing plane; the energy transducers are staggered in three rows and are grouped at intervals of A, B, C three frequencies, so that the energy transmission surface is adhered and matched with the outer wall of the bottom of the treatment tank by strong AB glue; the circulating pump is assembled on the inner wall of the shell on the left side of the machine body, the liquid outlet of the left lower part of the processing tank is communicated with the return pipe, and the liquid suction port is communicated with the return pipe; the feed back pipe is assembled below the middle column of the energy converter under the processing tank, the left end of the feed back pipe is communicated with a liquid suction port of the circulating pump, and the right end of the feed back pipe is communicated with a rear guide pipe of the monitoring terminal; the refrigerator is adhered and embedded with the front and the rear wall of the processing tank by using the two-purpose strong AB glue of the heat absorption and conduction lining surface of the refrigerator; the lower port of the horizontal section of the signal line pipe is connected with and matched with the outlet of the monitoring terminal and is communicated with the outlet of the monitoring terminal; the monitoring terminal is matched with a liquid outlet pipe at the bottom opening of the processing tank through a front guide pipe of the monitoring terminal and is assembled in a middle position at the lower right of the processing tank; the lower end of the monitoring terminal is connected with a rear guide pipe in a penetrating way; the liquid outlet valve is communicated with an inner guide pipe of the monitoring terminal through an elbow pipe, is communicated with the bottom opening of the tank and is assembled in the middle position at the lower right side of the treatment tank.