CN115753912A - A analytical equipment for microorganism growth - Google Patents

Abstract

The invention discloses an analysis device for microbial growth, comprising: an alternating excitation signal generating unit for generating an alternating excitation signal; the excitation tube part is sleeved on the glass tube containing the microorganism culture solution and receives the alternating excitation signal; a receiving tube portion fitted over the glass tube and spaced apart from the excitation tube portion; a shield portion for shielding and isolating the excitation tube portion and the receiving tube portion; a signal analysis unit connected to the receiving tube part for analyzing the signal output from the receiving tube part and outputting a growth signal; the central control unit is connected with the signal analysis unit and used for receiving and analyzing the growth signal; and the output unit is connected with the central control unit and is used for outputting the analyzed information. The analysis device can accurately analyze the growth condition of microorganisms in the glass tube.

Description

A analytical equipment for microorganism growth

Technical Field

The invention relates to the technical field of microbial analysis, in particular to an analysis device for microbial growth.

Background

The method has important significance for measuring the growth curve/growth rate of microorganisms (such as bacteria) in various scientific researches, production, management and living activities such as growth dynamics research, typing, clinical examination, biological genetic engineering, food hygiene detection and the like.

Currently, various methods based on the principles of calorimetry, mass spectrometry, electrochemistry, and optics have been applied to the online, direct monitoring of microbial growth kinetics. However, when there are impurity substances in the liquid to be analyzed, the existing automated methods have problems that are difficult to overcome, respectively-either the object of measurement is limited (e.g., fluorescence method), or the sensitivity is low (e.g., micro-calorimetric method), or the reproducibility is poor (e.g., contact electrochemical method). Even when a relatively perfect turbidity method is adopted to measure the bacterial data in the ideal solution in a laboratory, better precision cannot be ensured, and the actual sample medium even contains complex substances such as silt, humus and the like. The traditional conductivity contact detection has the phenomena of electrode passivation and pollution, and the electrode is in contact detection with microorganisms for a long time, so that the surface microscopic condition and the clean state of the electrode can still be changed, and further the accuracy of the measurement is influenced. In addition, the cleaning and fixing work of the electrode is required to be high, so that the operation is complicated.

Disclosure of Invention

In order to solve the above technical problems, the present invention provides an analysis apparatus for microbial growth, which analyzes the growth process of microorganisms by detecting signals characterizing the growth of microorganisms based on a capacitive coupling non-contact measurement technique, wherein the analysis method does not directly contact with a microbial culture solution, the measurement result is accurate, and the analysis apparatus is not affected.

In order to realize the purpose of the invention, the invention is realized by adopting the following technical scheme:

the present application provides an analytical device for microbial growth, comprising:

an alternating excitation signal generating unit for generating an alternating excitation signal;

the excitation tube part is sleeved on the glass tube containing the microorganism culture solution and receives the alternating excitation signal;

a receiving tube portion fitted over the glass tube and spaced apart from the excitation tube portion;

a shield portion for shielding and isolating the excitation tube portion and the receiving tube portion;

the signal analysis unit is connected with the receiving pipe part and is used for analyzing the signal output by the receiving pipe part and outputting a growth signal, and the growth signal represents the growth condition of the microorganisms in the microorganism culture solution;

the central control unit is connected with the signal analysis unit and used for receiving and analyzing the production signal;

the output unit is connected with the central control unit and is used for outputting the analyzed information;

wherein the glass bottle is located in a constant temperature environment that satisfies the growth of microorganisms.

In some embodiments herein, the signal analysis unit comprises:

the current-voltage conversion circuit is used for receiving the current signal output by the receiving tube and converting the current signal into a voltage signal;

a peak detection circuit that receives the voltage signal and performs peak detection on the voltage signal;

a signal amplification circuit for amplifying the detected peak value, forming the growth signal.

And the analog-to-digital conversion unit receives the growth signal, converts the growth signal into a digital growth signal and outputs the digital growth signal to the central control unit.

In some embodiments of the present application, the output unit is a display screen displaying a growth curve representing a growth of the microorganism.

In some embodiments herein, the analysis device comprises:

at least one shelf, and each shelf is provided with a plurality of glass tubes; to each glass pipe, set up shielding part, excitation pipe portion and receiving pipe portion on the supporter.

In some embodiments of the present application, the shelf comprises

The device comprises a first mounting part and a second mounting part which are arranged at intervals in the transverse direction, wherein the first mounting part is provided with a plurality of first through parts at intervals in the transverse direction, the second mounting part is provided with a plurality of second through parts at positions corresponding to the first through parts respectively, the first through parts are provided with excitation pipe parts, and the second through parts are provided with receiving pipe parts;

the shielding part is arranged on the first mounting part and the second mounting part and at least provided with a transverse shielding plate, and the transverse shielding plate is arranged between the first mounting part and the second mounting part and is provided with a plurality of through holes corresponding to the first through parts;

the glass tubes are arranged on the shelf through the corresponding excitation tube parts, the receiving tube parts and the through holes.

In some embodiments of the present application, a plurality of alternating excitation signal generating units and a plurality of signal analyzing units for a plurality of glass tube analyses are integrated on a detection board.

In some embodiments herein, the detection plate is mounted to the first and second mounting portions; the commodity shelf includes:

the first circuit board is provided with first through holes corresponding to the positions of the first through parts, the first through holes are provided with excitation tube parts, and when the first circuit board is arranged corresponding to the first installation parts, the excitation tube parts extend into and are positioned at the first through parts;

and the second circuit board is provided with second through holes corresponding to the positions of the second through parts, the second through holes are provided with receiving pipe parts, when the second circuit board is arranged corresponding to the second mounting part, the receiving pipe parts extend into and are positioned at the second through parts, and the first circuit board and the second circuit board are mounted on the detection board.

In some embodiments herein, the shield further comprises:

the shielding device comprises a vertical shielding plate, wherein a first transverse plate, a transverse shielding plate and a second transverse plate are arranged on one side surface of the vertical shielding plate at intervals along the transverse direction;

the transverse shielding plate is arranged between the first transverse plate and the second transverse plate;

avoidance holes are formed in the positions, corresponding to the first through parts, of the first transverse plates and are installed on the first installation parts;

the second transverse plate is arranged on the second installation part and used for supporting the glass tube;

the vertical shielding plate and the detection plate are oppositely positioned at two sides of the first installation part and the second installation part.

In some embodiments in this application, when there are a plurality of supporter, a plurality of supporter are the interval setting each other, and the vertical shield plate on the adjacent supporter sets up the same side at corresponding supporter respectively.

In some embodiments herein, the analysis device further comprises a temperature control assembly for providing the constant temperature environment; the temperature control assembly includes:

the temperature control unit is connected with the central control unit;

the refrigeration module is connected with the temperature control unit and is used for generating cold energy for adjusting the temperature in the constant temperature environment;

an air duct assembly forming a circulating air duct for circulating an air flow within a constant temperature environment;

the heating module is connected with the temperature control unit and is used for generating heat for adjusting the temperature in the constant temperature environment;

a fan assembly that powers the circulating airflow;

and the temperature detection unit feeds back the temperature in the constant temperature environment to the temperature control unit so as to control the temperature of the constant temperature environment to be at a preset temperature.

Compare prior art, the analytical equipment for microorganism growth that this application provided has following advantage and beneficial effect:

(1) In the process of microbial growth conversion and decomposition, the conductivity in the microbial culture solution is increased, so that the growth trend of the microbes can be represented according to the change of the conductivity, an exciting pipe part and a receiving pipe part which are sleeved outside a glass pipe are adopted, an alternating current exciting signal is respectively sent to the exciting pipe part, and after the receiving pipe part receives the signal and detects the signal, a growth signal is generated;

(2) The growth signal can represent the growth process of microorganisms, and the growth condition is output in the output unit, so that the user can observe the growth signal visually.

Other features and advantages of the present invention will become more apparent from the following detailed description of the invention when taken in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic view of an embodiment of an analysis apparatus for the growth of microorganisms according to the present invention;

FIG. 2 is a block diagram of one embodiment of an analysis device for the growth of microorganisms in accordance with the present invention;

FIG. 3 is a block diagram of one embodiment of an analysis device for the growth of microorganisms in accordance with the present invention, with the housing removed;

FIG. 4 is an exploded view of one embodiment of an analysis device for the growth of microorganisms in accordance with the present invention, with the housing removed;

FIG. 5 is a partial structure view of the inner container and the base of an embodiment of the analysis apparatus for microorganism growth according to the present invention;

FIG. 6 is a view showing an assembled structure of a rack, a shield part and a detection plate in an embodiment of an analysis apparatus for microbial growth according to the present invention;

FIG. 7 is an exploded view of a rack, a shield part and a detection plate in an embodiment of the analyzing apparatus for microorganism growth according to the present invention;

FIG. 8 is a cross-sectional view of FIG. 3;

FIG. 9 is an electrical schematic diagram of one embodiment of the proposed analytical device for microbial growth.

Reference numerals are as follows:

100-an analysis device;

a-a central control unit; b-a temperature control unit; a C-output unit; SC-display screen; d-an openable cover; h-a housing; b-a glass tube;

110-a component; 111-a first mounting portion; 1111-a first through portion; 112-a second mounting portion; 1121-second through section; 113-a shield; 1131 — transverse shield plate; 11311-perforation; 1132-vertical shield plates; 1133 — a first transverse plate; 11331-avoiding holes; 1134 — a second transverse plate; 114-a first circuit board; 1141-a first through hole; 115-a second circuit board; 1151-a second through hole; 116-excitation tube portion; 117/117'/117' '/117' '' -a detection plate;

120-a base;

130-inner container; 131-a first side panel; 1311-a vent; 132-a second side panel; 1321-a second runner; 1322-air duct; 133-a third side panel; 134-fourth side panel; 135-top plate; 1351-top plate avoiding hole;

140-a temperature control assembly; 141-a refrigeration module; 1411-a first refrigeration module; 1412-a second refrigeration module; 142-a mounting bracket; 143-cold conduction block; 144-a first heating module; 144' -a second heating module; 144 "-a first mounting plate; 144' ' ' -a second mounting plate; 145/145' -heat conducting block; 146-a first airway plate; 146' -a second airway plate; 147-a fan support; 1471-air supply outlet;

148-a first fan; 148' -a second fan;

149/149' -temperature detection unit;

150-an electrical box; 151-RS232 interface; 152-RS485 interface; 153-power interface;

160-top guard plate; 161-access hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention. In the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

In the description of the present invention, it should be noted that the terms "mounted," "connected," and "connected" are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected unless otherwise explicitly stated or limited. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. In the foregoing description of embodiments, the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The application relates to an analysis device for microbial growth, which is based on a capacitive coupling non-contact measurement technology and realizes non-contact detection in the microbial growth process.

In the process of culturing microorganisms (such as escherichia coli), the microorganisms convert and decompose macromolecular nutrient substances (such as protein, fat, carbohydrate and the like) in a culture solution into micromolecular substances with better conductivity and ions through metabolism, so that the conductivity of the mixed solution is increased, the change rate of the conductivity is in positive correlation with the growth rate of the microorganisms, and therefore the growth curve of the microorganisms can be estimated.

In the present application, such a change in conductance can be detected by a capacitively coupled non-contact conductance detection technique.

The culture of the microorganism needs to ensure that the culture solution of the microorganism is placed in a suitable temperature-controlled environment (e.g., 37 ℃. + -. 0.05 ℃) to enable the microorganism to grow normally.

First, the detection principle of the capacitive coupling non-contact conductance detection technique is described.

The exciting pipe part and the receiving pipe part are sleeved on the glass pipe at intervals, and the exciting pipe part and the receiving pipe part can be arranged up and down or up and down to form an exciting end and a receiving end respectively.

In this way, the excitation tube portion and the receiving tube portion form coupling capacitances C1 and C2 with the culture medium in the glass tube through the tube walls, respectively, a leakage capacitance C3 is formed between the excitation tube portion and the receiving tube portion, and the culture medium therebetween forms an equivalent resistance R.

In this way, in order to avoid the influence of the leakage capacitance C3, a shielding portion, which is, for example, a faraday shield and is grounded, is provided between the excitation tube portion and the reception tube portion, so that the influence of the leakage capacitance C3 is greatly reduced and can be approximately ignored.

Based on the RC series network, when the excitation frequency is greater than the turning frequency, the total impedance of the RC network is basically equal to the resistance R, and the reciprocal relation between the resistance and the conductivity is combined, so that the change of the conductivity of the culture solution can be detected and reflected on the receiving tube part by sending an alternating excitation signal with a certain frequency to the excitation tube part.

Thus, a schematic diagram of the principle of detecting microbial growth is shown in FIG. 1.

Referring to fig. 1, the analysis device according to the present application includes an alternating excitation signal generation unit, an excitation tube portion A1, a reception tube portion A2, a shield portion A3, a signal analysis unit, a center control unit, and an output unit.

In the present application, the material of the excitation tube portion and the receiving tube portion is constantan, which is a copper-nickel alloy composed of 55% copper and 45% nickel (Cu 55Ni 45), and has characteristics that it is not easily changed in properties with temperature change and has high resistivity. Has a low temperature coefficient of resistivity and a medium resistivity (resistivity of 0.48 mu omega-m).

In an alternative embodiment, the excitation tube portion and the receiving tube portion may also be provided with tubular electrodes of the same material as the electrodes (e.g., pure copper, graphite, etc.).

In the present application, the exciting tube portion 116 and the receiving tube portion are mainly described as an example in which they are fitted to the outside of the glass tube b at an interval from each other.

The alternating excitation signal may be generated by an alternating excitation signal generating unit, which may employ an existing alternating excitation signal generator, for example, the alternating excitation signal generator disclosed in application No. 201220260819.8, which includes a microcontroller and a DA converter, the microcontroller outputting a sequence of values arranged in a certain rule and controlling the DA converter to output a fixed frequency and fixed amplitude alternating excitation signal.

Alternatively, the alternating excitation signal generating unit may employ an existing commercially available signal generator module.

When an alternating excitation signal is applied to the excitation tube section, a sensing signal of varying conductivity is received at the receiving tube section, which sensing signal is characterized as a current signal.

The signal analysis unit is connected with the receiving pipe part, receives the induction signal output by the receiving pipe part, and outputs a growth signal after analysis, wherein the growth signal represents the growth condition of microorganisms in the microorganism culture solution.

Since the voltage signal is convenient to process, in the present application, the growth signal may be the voltage signal analyzed and processed by the signal analysis unit.

In the present application, the signal analysis unit may include a current-voltage conversion unit (not shown), a peak detection unit (not shown), and a signal amplification unit (not shown).

The current-voltage conversion unit is used for converting the current signal output by the receiving tube part into a voltage signal.

The current-voltage conversion unit may be a sampling resistor connected in series to the receiving tube part, and may convert the current into the voltage through the sampling resistor.

Since the output voltage signal is an alternating signal and a weak signal, the signal needs to be amplified, and before amplification, peak detection needs to be performed on the signal to determine the input range of the signal.

Therefore, the peak detection unit is first required to perform peak detection on the converted voltage signal.

The peak detection unit may be an existing circuit, and for example, the peak detection circuit is generally composed of a voltage follower including an operational amplifier, a diode, a capacitor, a resistor, and the like.

The signal amplifying unit amplifies the detected peak value and outputs an amplified analog signal, which may be a growth signal.

In order to filter out signal interference, the signal amplification unit may select a differential amplification circuit.

Thus, the analysis and detection of the signal of the growth condition of the microorganism can be realized. To visually present the user or remotely transmit the detected growth signal, an analog-to-digital conversion unit (not shown) and a central control unit a are also involved.

And collecting the amplified analog signal by using an analog-to-digital conversion unit and converting the analog signal into a digital signal.

The digital signal can be sent to a central control unit, and information representing the growth condition of the microorganisms is output through an output unit connected with the central control unit.

The information may be text data information of growth conditions, or may be a growth curve of the microorganisms displayed on the display screen through the output unit, the growth curve representing a change in voltage value of the microorganisms with time.

In this application, this well accuse unit can select STM series chip, and this output unit can be non-touch display screen also can touch display screen.

The constant temperature environment as described above may also be achieved by a central control unit and temperature control assembly 140 (as will be described in detail below).

As above, the analytical detection of the growth of microorganisms in a thermostated environment is described.

To facilitate the detection of multiple glass tubes b, see fig. 2, the present application is directed to an assay device 100 for the growth of microorganisms.

The analysis device 100 according to the present application includes a casing H, a central control unit a, an inner container 130, an openable and closable cover D, a temperature control unit 140, at least one signal analysis unit, at least one laser tube portion A1, at least one receiving tube portion A2, at least one shielding portion A3, and an output unit C.

Referring to fig. 2, a case H forms an external appearance of the analysis apparatus 100, and is formed with an access opening (not shown) at which an openable cover D is provided, which is hinged to the case H for opening when it is required to place the glass tube b in the inner container 130 and closing the openable cover D when it is not in use or during inspection.

Referring to fig. 2, in the present application, the output unit C may be represented as a display screen SC for displaying the growth of output microorganisms for easy visual feedback to the user.

The central control unit A, the inner container 130, the temperature control assembly 140, the at least one signal analysis unit, the at least one laser tube part A1, the at least one receiving tube part A2 and the at least one shielding part A3 are respectively positioned in the shell H.

The detection of the growth of microorganisms in glass tubes containing a microbial culture broth is described in connection with the above description.

It should be noted that the glass tube b needs to be placed in the constant temperature environment of the inner container 130 to ensure the normal growth of microorganisms.

Referring to fig. 3 and 4, at least one glass tube is accommodated in the inner container 130, so that microorganisms in a plurality of glass tubes can be detected at the same time.

One signal detection channel needs to be designed for each glass tube.

The signal detection channel described above refers to the alternating excitation signal generation unit > the excitation tube portion A1 > the receiving tube portion A2 > the signal analysis unit (i.e., the current-voltage conversion unit > the peak detection unit > the signal amplification unit > the analog-to-digital conversion unit).

For the detection of a plurality of glass tubes b simultaneously, see fig. 5 to 7, at least one rack can be provided, the rack is also placed in the constant temperature environment of the inner container 130, and at least two or more glass tubes can be placed on each rack.

For each glass tube, an excitation tube portion 116, a shielding portion, and a receiving tube portion are provided on the corresponding rack, respectively.

Referring to fig. 7, the rack includes a first mounting portion 111 and a second mounting portion 112 that are transversely spaced apart from each other, and the first mounting portion 111 and the second mounting portion 112 may be identical in structure and may correspond up and down or up and down.

A plurality of first through parts 1111 are opened at intervals along the transverse direction of the first mounting part 111; a plurality of second through portions 1121 are opened at intervals in the lateral direction of the second mounting portion 112.

The number of the first through portions 1111 is the same as and aligned with the number of the second through portions 1121.

The excitation pipe portion 161 is provided at the first through portion 1111, and the receiving pipe portion is provided at the second through portion 1121.

The shield section 113 has a lateral shield plate 1131 disposed laterally between the first mounting section 111 and the second mounting section 112 for shielding and isolating the respective excitation tube sections 116 and the respective receiving tube sections.

A plurality of through holes 11311 are formed at intervals along the transverse direction of the transverse shielding plate 1131, and the through holes 11311, the corresponding first through portions 1111, and the corresponding second through portions 1121 are aligned.

Referring to fig. 7, the first mounting portion 111, the transverse shielding plate 1131 and the second mounting portion 112 are sequentially disposed up and down, and eight glass tubes can be placed on each rack.

The first mounting portion 111 has eight first through portions 1111 in the lateral direction, eight excitation tube portions 161 are provided at the eight first through portions 1111, the second mounting portion 112 has eight second through portions 1121 in the lateral direction, and eight receiving tube portions are provided at the eight second through portions 1121.

And the transverse shield 1131 has eight through holes 11311 transversely.

In the detection of the microbial culture, each glass tube is placed on the rack through the corresponding excitation tube portion 116, the perforation 11311, and the receiving tube portion in this order.

In the arrangement described above, the excitation tube sections 116 may be connected to the alternating excitation signal generation unit, respectively, and the reception tube sections may be connected to the signal analysis unit, respectively.

Thus, eight glass tubes can be placed on each shelf.

When a plurality of commodity shelves exist, the commodity shelves are arranged at intervals in the transverse direction, so that an airflow channel is formed between the adjacent commodity shelves.

The detection as described above can be performed for each glass tube based on the signal detection channel as described above to detect the growth of microorganisms in each glass tube.

When it is necessary to simultaneously detect the growth of microorganisms in a plurality of glass tubes, it is necessary to provide the above signal detection channel for each glass tube.

To facilitate the simultaneous detection of multiple glass tubes, referring to fig. 6 and 7, in some embodiments of the present application, the signal detection channels are integrated, i.e., multiple signal detection channels are integrated on one detection board.

That is, the alternating excitation signal generating unit and the signal analyzing unit in each signal detection channel are integrated on the detection board to form a plurality of detection channels on the detection board.

In this application, can correspond a pick-up plate by every supporter.

In the present application, eight signal detection channels of eight glass tubes are integrated on the detection plate, alternatively, other numbers of signal detection channels may be expanded depending on the loading capacity of the detection plate.

In the present application, with reference to fig. 4 to 7, four detection panels 117/117'/117 "' are provided for four racks.

As follows, referring to fig. 7, description will be given taking one of the detection plates 117 as an example.

In order to connect each excitation tube portion 116 and each receiving tube portion to the detection plate 117, a first circuit board 114 and a second circuit board 115 are provided.

The first circuit board 114 is disposed on the first mounting portion 111 and has a plurality of first through holes 1141 corresponding to the plurality of first through portions 1111 of the first mounting portion 111.

Each excitation tube portion 116 may be provided at the first through hole 1141, for example, by soldering, and when the first circuit board 114 is correspondingly provided on the first mounting portion 111, the excitation tube portion 116 extends and is located within the first through hole 1111.

The second circuit board 115 is provided with a plurality of second through holes 1151 corresponding to the plurality of second through holes 1121 in the second mounting portion 112.

Each receiving tube portion may be provided at the second through hole 1151, for example, by soldering, and extend and be located inside the second through hole 1121 when the second circuit board 115 is correspondingly provided on the second mounting portion 112.

The first circuit board 114 and the second circuit board 115 are mounted on the detection board 117 to realize signal connection, wherein all redundant spaces of the first circuit board 114 and the second circuit board 115 are covered with copper and grounded, so that the shielding and anti-interference capability is enhanced.

When detecting the microbial culture, each glass tube is placed on the rack by passing through the excitation tube 116 at the corresponding first through-hole 1141, the through-hole 11311 of the transverse shield 1131, and the receiving tube at the second through-hole 1151 in this order.

As above, the mounting integration of the rack and the detection plate 117 is realized.

In the present application, the specific structure of the shield portion 113 is described below.

When there are a plurality of shelves, in order to avoid mutual interference of each laser tube part 116 and each receiving tube part on adjacent shelves, the shielding part 113 includes a vertical shielding plate 1132.

On one side of the vertical shield 1132 there are laterally spaced first lateral plates 1133, lateral shields 1131 as described above and second lateral plates 1134.

The transverse shield 1131 is disposed between the first transverse plate 1133 and the second transverse plate 1134.

Along the transverse direction of the first transverse plate 1133, a plurality of avoiding holes 11331 corresponding to the first through portions 1111 are formed, and the number of the avoiding holes 11331 is the same as the number of the first through portions 1111 and is aligned with the first through portions 1111.

The shielding part 113 is mounted to the first and second mounting parts 111 and 112 such that the first transverse plate 1133 is located above the first mounting part 111, i.e., the relief hole 11331 on the first transverse plate 1133 is aligned up and down with the first through-hole 1111 on the first mounting part 111.

The transverse shield 1131 is interposed between the first mounting portion 111 and the second mounting portion 112.

The second transverse plate 1134 is located below the second mounting portion 112 and is used to support the bottom of the glass tube placed on the rack.

That is, the avoiding hole on the first transverse plate 1133, the first through hole on the first circuit board 114, the first through portion on the first mounting portion 111, the through hole 11311 on the transverse shielding plate 1131, the second through hole on the second circuit board 115, and the second through portion on the second mounting portion 112 are aligned up and down one by one, so that the glass tubes b can be inserted and pulled out conveniently.

The vertical shield plate 1132 and the detection plate 117 are located at both sides of the first and second mounting parts 111 and 112.

When there are a plurality of commodity shelves, vertical shield 1132 is used for shielding each excitation tube portion 116 and each receiving tube portion on a commodity shelf and each excitation tube portion 116 and each receiving tube portion on the commodity shelf adjacent to this commodity shelf, and therefore, vertical shield 1132 on the adjacent commodity shelf sets up the same side at each commodity shelf.

That is, the vertical shielding plates 1132 on adjacent shelves are not adjacently disposed.

As described above, when there are a plurality of shelves in the inner container 130, that is, there are a plurality of first mounting portions 111 and a plurality of second mounting portions 112, the shelves are spaced from each other, and the structure of each shelf is the same as that described above, and thus, the description thereof is omitted.

The inner container 130 is a metal inner container, and referring to fig. 4, the inner container 130 includes a top plate 135, a bottom plate (not shown), and peripheral side plates including a first side plate 131, a second side plate 132, a third side plate 133, and a fourth side plate 134.

At least one shelf is disposed in the inner container 130, and in particular, a shelf is installed in the inner container 130 as an example.

Referring to fig. 5 to 7, the same end a of the first and second mounting portions 111 and 112 is slidably mounted to an inner wall of the first side plate 131 of the inner container 130, and the other end a' of the first and second mounting portions 111 and 112 opposite to the same end a is slidably mounted to an inner wall of the second side plate 132 of the inner container 130.

For example, a first sliding slot (not shown) is formed on an inner wall of the first side plate 131, a first sliding block (not shown) adapted to the first sliding slot is correspondingly formed on the same end a of the first mounting portion 111 and the second mounting portion 112, a second sliding slot 1321 is formed on an inner wall of the second side plate 132, and a second sliding block (not shown) adapted to the second sliding slot 1321 is correspondingly formed on the same end a' of the first mounting portion 111 and the second mounting portion 112.

As described above, referring to fig. 6 and 7, when the shielding part 113, the first circuit board 114, the second circuit board 115, and the detection plate 117 are all mounted to the first mounting part 111 and the second mounting part 112 to form an integrated assembly, the detection plate 117 can be easily repaired by slidably mounting or removing the integrated assembly from the inner container 130 by sliding the integrated assembly up and down.

In addition, in order to facilitate maintenance of some electrical components, referring to fig. 3 to 5, a base 120 is further disposed below the inner container 130, an electrical box 150 is drawably disposed in the base 120, and a central control unit a and a switching power supply (not shown) for supplying a dc power to the electrical components may be disposed in the electrical box 150.

For convenience of communication with the outside and data output/printing, referring to fig. 4, a side plate (e.g., a front side plate) of the electrical box 150 is further provided with a power interface 153, a communication interface (e.g., an RS232 interface 151 and an RS485 interface 152), and a data transmission interface (e.g., a USB interface and a TF card interface), and the central control unit a is also reserved with a bluetooth printing port, a bluetooth communication port, and the like.

Can realize through RS232 interface 151 or RS485 interface 152 with the serial port communication of host computer, also can realize the wireless connection with the host computer through bluetooth communication port, make things convenient for data remote transmission.

The switching power supply described above can convert external ac power received through the power supply interface 153 into, for example, 24V DC power.

The switching power supply can provide DC power to the central control unit A, the detection board 117/117'/117' '/117' '', and the like.

Referring to fig. 9, the detection boards 117/117'/117' ″ are connected to the central control unit a, respectively.

As shown in fig. 4 and 5, four shelves are disposed in the inner container 130, and each shelf can hold eight glass tubes, so that the analysis device 100 can analyze the growth of microorganisms in thirty-two glass tubes.

Four shelves are adjacently disposed in the inner container 130 at intervals so that an air flow passage is formed between the adjacent shelves.

Referring to fig. 2 and 3, the openable cover D is disposed outside the top plate 135, and the glass tube can be inserted into or pulled out of the rack by the openable cover D.

Therefore, referring to fig. 4, top plate relief holes 1351 for facilitating insertion of the glass tubes are formed in the top plate 135, and the number of the top plate relief holes 1351 is equal to and aligned with the number of the first through portions 1111 formed in the first mounting portions 111.

Since it is necessary to secure a constant temperature environment of the inner container 130, referring to fig. 3 and 4, a top shielding plate 160 is provided above the top plate 135 and below the openable and closable lid body D, and the top shielding plate 160 serves to prevent the inner container 130 from conducting heat to the outside.

The top protection plate 160 may be made of plastic or silica gel, preferably plastic.

Correspondingly, the top protection plate 160 is also provided with pick-and-place holes 161 for facilitating insertion of the glass tubes, and the number of the pick-and-place holes 161 is the same as and aligned with the number of the top plate avoiding holes 1351 provided on the top plate 135.

So, can carry out pulling out fast of a plurality of glass pipes and insert, improve the efficiency that detects the microorganism growth condition.

The constant temperature environment of the analysis apparatus will be described below.

In the present application, a temperature control assembly 140 is employed to achieve a constant temperature environment of the inner bladder 130.

Referring to fig. 3 to 5 and 8 and 9, the temperature control assembly 140 includes a cooling module 141, a temperature control unit B, a heating module 144/144', a temperature detection unit 149/149', an air duct assembly and a fan assembly.

Referring to fig. 9, a temperature control unit B is connected to the central control unit a, and a temperature detection unit 149/149', a cooling module 141, and a heating module 144/144' are connected to the temperature control unit B, respectively.

A temperature detection unit 149/149' is arranged in the environment of the inner container 130 where the glass tube is positioned and is used for detecting the temperature in the inner container 130.

In the present application, referring to FIG. 8, temperature sensing units 149/149' are located within the two airflow channels as described above, respectively.

The average temperature acquired by the temperature detection unit 149/149' may be used as the detected temperature inside the inner container 130.

The number of the temperature detection units can be more than two, and the temperature detection units are uniformly distributed at different positions in the inner container 130, so that the detected temperature in the inner container 130 is measured by the average value of the temperatures fed back by the temperature detection units, and the detected temperature in the inner container 130 can be accurately obtained.

A preset temperature (e.g., 37 ℃) may be set in the central control unit a, and when the temperature detected by the temperature detecting unit 149/149' (which may be referred to herein as an average temperature obtained by the temperature detecting unit 149/149 ') is lower than the preset temperature, the central control unit a controls the heating module 144/144' to heat so as to provide the hot air flow into the inner container 130.

When the temperature detecting unit 149/149' detects that the temperature is higher than the preset temperature, the central control unit a controls the cooling module 141 to cool so as to provide the cold airflow into the inner container 130.

Referring to fig. 3-5 and 8, refrigeration module 141 may include first and second refrigeration modules 1411, 1412 arranged in parallel, and heating module 144/144 'may include first and second heating modules 144, 144' arranged in parallel.

The refrigerating module 141 and the heating module 144/144' which are designed redundantly can improve the reliability of the temperature control in the inner container 130.

The air duct assembly forms a circulating air duct for circulating hot air flow or cold air flow.

The fan assembly provides circulating power for hot air flow or cold air flow so that the hot air flow or the cold air flow circulates in the circulating air duct.

The fan assembly includes a first fan 148 and a second fan 148 'arranged in parallel, the first fan 148/148' also being of redundant design to enhance the reliability of the airflow cycle.

As described above, when a plurality of shelves are spaced apart from each other in the inner container 130, an airflow path is formed between the adjacent shelves, and for this purpose, in the present application, referring to fig. 5, the first fan 148 and the second fan 148' are juxtaposed by the fan bracket 147 at the outer side of the first side plate 131 of the inner container 130.

And a plurality of ventilation holes 1311 communicating with the airflow passage are opened on the first side plate 131, and are used for guiding the wind flowing through the airflow passage back to the fan assembly.

Referring to fig. 4, a cooling module 141 is disposed on a side of the first and second fans 148 and 148' away from the inner container 138.

The refrigeration module 141 is mounted to a fan bracket 147 by a mounting bracket 142.

The cooling module 141 may be selected as a semiconductor cooling plate, and the cold end thereof is in contact with a cold conduction block 143 (e.g., a copper block) provided on the blower bracket 147 to conduct the cooling energy to the first and second blowers 148 and 148'.

In the present application, the first fan 148 and the second fan 148' are both axial fans.

In the present application, referring to fig. 4 and 8, the air duct assembly includes a first air duct plate 146 and a second air duct plate 146' disposed outside the inner tub 130, which form a circulation air duct with the inner tub 130.

When hot air flow or cold air flow flows through the circulating air duct, the air flow in the inner container 130 can be cooled or heated, so that the temperature of the environment in the inner container 130 is reduced or increased.

Specifically, a first air duct plate 146 and a second air duct plate 146 'are respectively disposed at outer sides of the third side plate 134 and the fourth side plate 135 of the inner container 130, a first air duct is formed between an inner side wall of the first air duct plate 146 and an outer side wall of the third side plate 134 of the inner container 130, and a second air duct is formed between an inner side wall of the second air duct plate 146' and an outer side wall of the fourth side plate 135 of the inner container 130.

The first air duct and the second air duct are respectively communicated with the inner container 130, and specifically, a third air duct 1322 is formed on the second side plate 132 of the inner container 130.

The third air channel 1322 is respectively communicated with the air flow channel, the first air channel, the second air channel and the ventilation opening 1311 to form a circulating air channel.

The blower support 147 is provided with air supply ports at one end thereof adjacent to the first air passage and at one end thereof adjacent to the second air passage, only the air supply port 1471 adjacent to one end of the first air passage is shown, see fig. 5.

The air from the first fan 148 is blown into the first air passage through the air supply opening 1471, then enters the third air passage, enters the air flow passage and is guided back to the first air passage again by the first fan 148 through the air vent 1311, as shown by the solid arrows in fig. 8.

The air from the second fan 148 'is blown into the second air duct through the supply opening, then into the third air duct, and then into the air flow path and through the vent 1311 to be led back again to the second air duct by the second fan 148', as shown by the dashed arrow in fig. 8.

Therefore, air is uniformly supplied into the inner container 130, and the temperature in the inner container 130 is ensured to be uniform.

In the present application, a first heating module 144 and a second heating module 144' are provided in the first air duct and the second air duct, respectively.

Specifically, the first heating module 144 is mounted on the inner side wall of the first air duct plate 146 together with a heat conduction block 145 (e.g., a copper block) in contact with the first heating module 144 by a first mounting plate 144 ″, and the second heating module 144 'is mounted on the inner side wall of the second air duct plate 146' together with a heat conduction block 145 '(e.g., a copper block) in contact with the second heating module 144' by a second mounting plate 144 ″.

When the temperature of the environment in the inner container 130 needs to be raised, the first heating module 144 and the second heating module 144' both work, and the refrigeration module 141 does not work, so that the temperature of the air flow flowing through the first air duct rises and the temperature of the air flow flowing through the second air duct also rises, and therefore the temperature of the air flow entering the air flow channel through the third air duct also rises, and the temperature in the inner container 130 rises.

When the environment in the inner container 130 needs to be cooled, the first heating module 144 and the second heating module 144' do not work, and the refrigeration module 141 works, so that the temperature of the air flow flowing through the first air duct is reduced, the temperature of the air flow flowing through the second air duct is also reduced, the temperature of the air flow entering the air flow channel through the third air duct is also reduced, and the temperature in the inner container 130 is reduced.

So, temperature control assembly 140 can make the air current evenly circulate in inner bag 130, has ensured the homogeneity of temperature in the inner bag 130 internal environment, and can realize the interior high accuracy accuse temperature of inner bag 130 simultaneously, makes inner bag 130 ambient temperature invariable.

In addition, in order to improve the heat preservation and insulation effect of the inner container 130, the inner container 130 is wrapped in multiple layers, the outer layer of the metal inner container 130 is wrapped in a plate body (not shown) made of high-temperature resistant material (e.g., ceramic fiber) with low heat conductivity, the outer side of the third side plate 133 of the inner container 130 is wrapped in the first air duct plate 146, the outer side of the fourth side plate 134 is wrapped in the second air duct plate 146', and then the outermost layer is wrapped in heat preservation cotton.

Therefore, the influence caused by interaction with the external temperature in the refrigeration or heating process is greatly reduced, and the effects of heat preservation and heat insulation are achieved.

The refrigeration module 140, heating module 144/heating module 144 'and blower 148/148' can also be powered by a DC power supply, such as 24V DC, generated by a switching power supply as described above.

The analysis device 100 can be used for analyzing the growth conditions of microorganisms in a plurality of glass bottles, and the glass tubes can be conveniently inserted and pulled out, so that the analysis efficiency of the glass tubes in batches is improved.

When the growth of microorganisms in a culture solution of microorganisms is analyzed using the above-described analyzer 100, the analyzer 100 is calibrated.

The analysis device 100 is calibrated by adding different standard conductivity liquids to the glass tube in advance, so that the different standard conductivity liquids are in positive correlation with corresponding voltage values.

Therefore, after calibration, the analysis device 100 is used to analyze the growth curve of the detected voltage along with the growth time of the microorganism, so that the growth condition of the microorganism can be reliably measured.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (10)

1. An analytical device for microbial growth, comprising:

an alternating excitation signal generating unit for generating an alternating excitation signal;

the excitation tube part is sleeved on the glass tube containing the microorganism culture solution and receives the alternating excitation signal;

a receiving tube portion fitted over the glass tube and spaced apart from the excitation tube portion;

a shield portion for shielding and isolating the excitation tube portion and the receiving tube portion;

the signal analysis unit is connected with the receiving pipe part and is used for analyzing the signal output by the receiving pipe part and outputting a growth signal, and the growth signal represents the growth condition of the microorganisms in the microorganism culture solution;

the central control unit is connected with the signal analysis unit and used for receiving the growth signal and analyzing the growth signal;

the output unit is connected with the central control unit and is used for outputting the analyzed information;

wherein the glass bottle is located in a constant temperature environment that satisfies the growth of microorganisms.

2. The analysis device according to claim 1, wherein the signal analysis unit includes:

the current-voltage conversion circuit is used for receiving the current signal output by the receiving tube and converting the current signal into a voltage signal;

a peak detection circuit that receives the voltage signal and performs peak detection on the voltage signal;

a signal amplification circuit for amplifying the detected peak value to form the growth signal;

and the analog-to-digital conversion unit receives the growth signal, converts the growth signal into a digital growth signal and outputs the digital growth signal to the central control unit.

3. The analysis device according to claim 1, wherein the output unit is a display screen that displays a growth curve representing a growth condition of the microorganism.

4. The analysis device according to claim 1, characterized in that it comprises:

at least one shelf, and each shelf is provided with a plurality of glass tubes;

to each glass pipe, set up shielding part, excitation pipe portion and receiving pipe portion on the supporter.

5. The analysis device of claim 4, wherein the rack comprises:

the device comprises a first mounting part and a second mounting part which are arranged at intervals in the transverse direction, wherein the first mounting part is provided with a plurality of first through parts at intervals in the transverse direction, the second mounting part is provided with a plurality of second through parts at positions corresponding to the first through parts respectively, the first through parts are provided with excitation pipe parts, and the second through parts are provided with receiving pipe parts;

the shielding part is arranged on the first installation part and the second installation part and at least provided with a transverse shielding plate, and the transverse shielding plate is arranged between the first installation part and the second installation part and is provided with a plurality of through holes corresponding to the first through parts;

the glass tubes are arranged on the shelf through the corresponding excitation tube parts, the receiving tube parts and the through holes.

6. The analysis device according to claim 5,

a plurality of alternating excitation signal generating units and a plurality of signal analyzing units for analyzing a plurality of glass tubes are integrated on a detecting plate.

7. The device of claim 6, wherein the detection plate is mounted to the first and second mounting portions; the commodity shelf includes:

the first circuit board is provided with first through holes corresponding to the positions of the first through parts, excitation tube parts are arranged at the first through holes, and when the first circuit board is arranged corresponding to the first installation parts, the excitation tube parts extend into and are positioned at the first through parts;

and the second circuit board is provided with second through holes corresponding to the positions of the second through parts, receiving pipe parts are arranged at the second through holes, when the second circuit board is arranged corresponding to the second mounting part, the receiving pipe parts extend into and are positioned at the second through parts, and the first circuit board and the second circuit board are mounted on the detection board.

8. The analysis device of claim 7, wherein the shield further comprises:

the shielding device comprises a vertical shielding plate, wherein a first transverse plate, a transverse shielding plate and a second transverse plate are arranged on one side surface of the vertical shielding plate at intervals along the transverse direction;

the transverse shielding plate is arranged between the first transverse plate and the second transverse plate;

avoidance holes are formed in the positions, corresponding to the first through parts, of the first transverse plates and are installed on the first installation parts;

the second transverse plate is arranged on the second installation part and used for supporting the glass tube;

the vertical shielding plate and the detection plate are oppositely positioned on two sides of the first installation part and the second installation part.

9. The analysis device according to claim 8,

when there are a plurality of supporter, a plurality of supporter sets up at interval each other, and the vertical shield plate on the adjacent supporter sets up respectively in the same side that corresponds the supporter.

10. The device of claim 1, further comprising a temperature control assembly for providing the constant temperature environment; the temperature control assembly includes:

the temperature control unit is connected with the central control unit;

the refrigeration module is connected with the temperature control unit and is used for generating cold energy for adjusting the temperature in the constant temperature environment;

an air duct assembly forming a circulating air duct for circulating an air flow within a constant temperature environment;

the heating module is connected with the temperature control unit and is used for generating heat for adjusting the temperature in the constant temperature environment;

a fan assembly that powers the circulating airflow;

and the temperature detection unit feeds back the temperature in the constant temperature environment to the temperature control unit so as to control the temperature of the constant temperature environment to be at a preset temperature.

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