CN114609200A

CN114609200A - Electrolyte analyzer acquisition and test device

Info

Publication number: CN114609200A
Application number: CN202210227952.1A
Authority: CN
Inventors: 廖永富
Original assignee: Nanjing Diannuo Biotechnology Co ltd
Current assignee: Nanjing Diannuo Biotechnology Co ltd
Priority date: 2022-03-10
Filing date: 2022-03-10
Publication date: 2022-06-10
Anticipated expiration: 2042-03-10
Also published as: CN114609200B

Abstract

The invention discloses an electrolyte analyzer acquisition and test device, and relates to the technical field of electrolyte detection. The device comprises a carrying platform, a collecting pipe, a coarse adjusting component, a fine adjusting component and a power component, wherein an assembling block is bonded on the bottom side wall of the carrying platform, the collecting pipe is inserted in the center of the carrying platform, an output component is inserted in the side wall of the collecting pipe, a fixing frame is arranged right above the collecting pipe, the coarse adjusting component is mounted on the carrying platform on one side of the collecting pipe, the fine adjusting component is mounted on the carrying platform on the other side of the collecting pipe, and the power component is mounted on the side of the fine adjusting component. According to the invention, the coarse adjustment component and the fine adjustment component are utilized to prevent collected samples from being excessively retained in the collection pipe, and the problem that analysis and test work is influenced due to too low collection speed is also avoided; meanwhile, the force arms between the components are mutually matched by effectively reducing the power components, so that the problem that the collecting pipe is unstable in shaking caused by a long force arm is avoided.

Description

Electrolyte analyzer acquisition and test device

Technical Field

The invention belongs to the technical field of electrolyte detection, and particularly relates to an electrolyte analyzer acquisition and test device.

Background

The electrolyte detection technology is one of modern biological science technologies, is widely applied to the medical field and is also of great importance in the chemical and biological industry fields, the embodiment of the electrolyte detection technology is an electrolyte analyzer, and the electrolyte analyzer can be used for analyzing the electrolyte of a substance to be detected and analyzing the component and the content of the electrolyte, so that data technical support is provided for the medical, chemical and biological fields.

The prior publication, CN 106526211A-sampling device and electrolyte analyzer, discloses a sampling device and an electrolyte analyzer. The sampling device comprises a sampling arm assembly and a guide shaft, wherein the sampling arm assembly comprises a sample sucking needle and a sampling arm, the sample sucking needle is arranged on the sampling arm, and the sampling device also comprises a horizontal driving mechanism and a vertical driving mechanism; the horizontal driving mechanism is used for driving the sampling arm component to do linear reciprocating motion in the horizontal direction; the vertical driving mechanism is used for driving the sampling arm assembly to vertically move along the guide shaft. Compared with the existing sampling device, the sampling arm assembly of the sampling device provided by the invention can simultaneously make linear reciprocating motion in the horizontal direction and linear reciprocating motion in the vertical direction along the guide shaft under the driving of the horizontal driving mechanism and the vertical driving mechanism.

However, the sampling device and the electrolyte analyzer have the following disadvantages in the practical use process;

1. the sampling device and the electrolyte analyzer are additionally provided with the sampling device and comprise a sampling arm assembly and a guide shaft, wherein the sampling arm assembly comprises a sample suction needle and a sampling arm, the sample suction needle is arranged on the sampling arm, and the sampling device further comprises a horizontal driving mechanism and a vertical driving mechanism; the horizontal driving mechanism is used for driving the sampling arm component to do linear reciprocating motion in the horizontal direction; the vertical driving mechanism is used for driving the sampling arm assembly to vertically move along the guide shaft; however, when the sampling displacement of the sampling device is performed, horizontal shaking and shaking in the vertical direction still occur, so that the problem of sample scattering phenomenon is caused;

2. in the above sampling device and the electrolyte analyzer, generally, the electrolyte analyzer needs to be equipped with six different kinds of electrodes for electrolyte analysis, including sodium, potassium, chloride, ionized calcium, lithium and reference electrode, and the sampling device and the electrolyte analyzer can be placed at any position outside the sample tray by using the sealing plate, so that the actions of the sample tray are reduced, the efficiency of the instrument test is improved, meanwhile, the positioning accuracy of the sample sucking needle and the sealing plate is also ensured, the action of the sample tray does not affect the sample placed in the sample tray to change, and therefore, the mode of improving the efficiency and the accuracy is very little.

Disclosure of Invention

The invention aims to provide a collecting and testing device of an electrolyte analyzer, which can avoid excessive collected samples from being retained in a collecting pipe by utilizing a coarse adjusting component and a fine adjusting component and also avoid the problem that the analysis and test work is influenced by too low collecting speed; meanwhile, the force arm between the components matched with each other is effectively reduced, so that the problem that the collection pipe is unstable due to the fact that the long force arm is not shaken is solved, and the problems of the sampling device and the electrolyte analyzer are solved.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to an electrolyte analyzer acquisition testing device, which comprises an erection table, an acquisition pipe, a coarse adjustment component, a fine adjustment component and a power component, wherein an assembly block is bonded on the side wall of the bottom of the erection table, the acquisition pipe is inserted in the center of the erection table, an output component is inserted in the side wall of the acquisition pipe, a fixed frame is arranged right above the acquisition pipe, the coarse adjustment component is arranged on the erection table on one side of the acquisition pipe, the fine adjustment component is arranged on the erection table on the other side of the acquisition pipe, and the power component is arranged beside the fine adjustment component;

the output assembly comprises a hard pipe, an electronic on-off valve and an output hose, wherein the hard pipe is communicated with the output hose through the electronic on-off valve;

the rough adjusting assembly comprises a rough adjusting motor, a motor frame and a rough adjusting gear, the rough adjusting motor is connected with the upper side wall of the erection table through the motor frame, and the rough adjusting gear is assembled at the tail end of a rotating shaft of the rough adjusting motor; specifically, the coarse adjustment motor is vertically arranged towards the carrying platform structure, a spiral groove is formed in the outer wall of the connecting ring on the collecting pipe, and the coarse adjustment motor can drive the connecting ring and the collecting pipe to move up and down through a coarse adjustment gear and a pipe gear;

the fine adjustment assembly comprises a fine adjustment gear, a linkage rod, a linkage gear and a supporting disc, the linkage rod is inserted in the center of the fine adjustment gear, the supporting discs are sleeved at two ends of the linkage rod, and the linkage gear is sleeved on the outer sides of the supporting discs;

the power assembly comprises a base, a fine adjustment motor and a motor gear, the fine adjustment motor is connected with the upper side wall of the lapping table through the base, and the motor gear is sleeved on a rotating shaft of the fine adjustment motor; specifically, the motor gear and the fine adjustment motor rotate synchronously, and power of the fine adjustment motor can be transmitted to the fine adjustment assembly through the motor gear.

Furthermore, a pipe head is arranged at the bottom of the collecting pipe and is connected with a liquid storage pipe through threads, an anti-collision ring is sleeved on the middle position of the liquid storage pipe, a connecting ring is sleeved on the upper position of the liquid storage pipe, a pipe gear is sleeved outside the connecting ring, and a bottom column is bonded on the side wall of the bottom of the pipe gear; specifically, the bottom pillar is the setting of cylindric structure, and the maximum diameter of bottom pillar is the same with the groove width size of ring channel, and the bottom pillar is that the annular array structure is provided with four altogether.

Further, the inside of depositing the liquid pipe is provided with sealed head, the periphery lateral wall of sealed head is connected with the inner wall cooperation of depositing the liquid pipe, the last lateral wall center department of sealed head bonds and has the insection post.

Furthermore, a pipe groove is formed in the center of the carrying platform, a rotating groove is formed above the pipe groove, annular grooves are formed in the side wall of the bottom of the rotating groove and the outer side of the pipe groove, a fluted disc groove is formed in the side of the rotating groove and the inner portion of the carrying platform, and a penetrating hole is formed above the center of the fluted disc groove.

Furthermore, the pipe groove and the fluted disc groove are communicated with each other, a coarse adjusting gear in the coarse adjusting assembly is arranged inside the fluted disc groove, the coarse adjusting gear extends out of the fluted disc groove, enters the rotating groove and is meshed with the pipe gears in the fluted disc groove, and the inner side wall of the annular groove is connected with a bottom column at the bottom of the pipe gears in a matched mode.

Furthermore, the fixed frame is composed of a cross frame, a stand column and a fixed block, the bottom side walls at the two ends of the cross frame are connected with the stand column in a riveting mode, the bottom side walls of the stand column are connected with the upper side wall of the erection table through the fixed block, a slotted hole is formed in the center of the cross frame, and the cross frame is connected with the insection column on the acquisition tube in a nesting mode through the slotted hole.

Furthermore, a linkage rod in the fine adjustment assembly is meshed with a motor gear in the power assembly through a linkage gear, and the linkage rod is connected with the upper side wall of the erection table through supporting plates on two sides.

Furthermore, meshing teeth are formed in the outer wall, facing one side of the fine adjustment assembly, of the insection column in the collection tube, the fine adjustment gear in the fine adjustment assembly is meshed with the insection column in the collection tube, and the fine adjustment gear and the insection column are arranged in a coaxial surface structure.

The invention has the following beneficial effects:

1. according to the sampling device and the electrolyte analyzer, the power assembly and the coarse adjustment motor are arranged, when the sampling device is used, the power assembly can provide power support for the fine adjustment assembly, the coarse adjustment motor provides power support for the coarse adjustment assembly, the force arms between the assemblies which are matched with each other are effectively reduced, and the problem of unstable shaking of the sampling tube caused by the long force arms is solved; the horizontal driving mechanism is used for driving the sampling arm component to do linear reciprocating motion in the horizontal direction; the vertical driving mechanism is used for driving the sampling arm assembly to vertically move along the guide shaft; however, when the sampling device is used for sampling displacement, horizontal shaking and vertical shaking still occur, and thus the sample is spilled.

2. The invention realizes the control of the sample collection amount and the collection process of the collection pipe by the coarse adjustment component and the coarse adjustment component when in use, thereby avoiding the collected sample from being excessively retained in the collection pipe and simultaneously avoiding the problem that the collection speed is too slow to influence the analysis and test work, solving the problems that one sampling device and one electrolyte analyzer in the prior art are required to be provided with six different types of electrodes for electrolyte analysis, namely sodium, potassium, chlorine, ionized calcium, lithium and a reference electrode, and the sampling device and the electrolyte analyzer can be placed at any position outside a sample tray by utilizing the sealing plate, achieving the purposes of reducing the actions of the sample tray, improving the efficiency of instrument test and simultaneously ensuring the positioning precision of the sample suction needle and the sealing plate, the movement of the sample plate does not affect any change in the sample placed therein, and therefore the efficiency and accuracy of this method is minimal.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

FIG. 3 is a first diagram illustrating the structure of the mounting platform of the present invention;

FIG. 4 is a second diagram illustrating the structure of the mounting table of the present invention;

FIG. 5 is a schematic diagram of a coarse tuning assembly according to the present invention;

FIG. 6 is a schematic view of a collection tube and holder configuration of the present invention;

FIG. 7 is an exploded view of the collection tube and mounting structure of the present invention;

FIG. 8 is a schematic view of a tube gear configuration of the present invention;

FIG. 9 is a schematic view of the fine adjustment assembly and the power assembly of the present invention;

FIG. 10 is an exploded view of the fine tuning assembly and power assembly configuration of the present invention;

in the drawings, the components represented by the respective reference numerals are listed below:

1. building a platform; 101. a pipe groove; 102. a rotating tank; 103. an annular groove; 104. a through hole; 105. a fluted disc groove; 2. assembling the block; 3. a collection tube; 301. a pipe head; 302. a liquid storage tube; 303. an anti-collision ring; 304. a tube gear; 3041. a bottom pillar; 305. a joining loop; 306. a sealing head; 307. insection columns; 4. an output component; 401. a rigid tube; 402. an electronic on-off valve; 403. an output hose; 5. a fixed mount; 501. a cross frame; 502. a column; 503. a fixed block; 6. a coarse tuning component; 601. coarse adjustment of a motor; 602. a motor frame; 603. coarse gear adjustment; 7. a fine adjustment component; 701. finely adjusting the gear; 7011. a linkage rod; 702. a linkage gear; 703. a support plate; 8. a power assembly; 801. a base; 802. finely adjusting the motor; 803. a motor gear.

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.

Referring to fig. 1-10, the invention relates to an electrolyte analyzer collecting and testing device, which comprises a carrying platform 1, a collecting tube 3, a coarse adjusting component 6, a fine adjusting component 7 and a power component 8, wherein an assembling block 2 is bonded on the bottom side wall of the carrying platform 1, the collecting tube 3 is inserted in the center of the carrying platform 1, an output component 4 is inserted in the side wall of the collecting tube 3, a fixing frame 5 is arranged right above the collecting tube 3, the coarse adjusting component 6 is mounted on the carrying platform 1 on one side of the collecting tube 3, the fine adjusting component 7 is mounted on the carrying platform 1 on the other side of the collecting tube 3, and the power component 8 is mounted on the side of the fine adjusting component 7;

the output assembly 4 comprises a hard pipe 401, an electronic on-off valve 402 and an output hose 403, wherein the hard pipe 401 is communicated with the output hose 403 through the electronic on-off valve 402;

the coarse adjustment component 6 comprises a coarse adjustment motor 601, a motor frame 602 and a coarse adjustment gear 603, wherein the coarse adjustment motor 601 is connected with the upper side wall of the mounting platform 1 through the motor frame 602, and the coarse adjustment gear 603 is arranged at the tail end of a rotating shaft of the coarse adjustment motor 601;

the fine adjustment assembly 7 comprises a fine adjustment gear 701, a linkage rod 7011, a linkage gear 702 and a supporting disc 703, the linkage rod 7011 is inserted in the center of the fine adjustment gear 701, the supporting disc 703 is sleeved at both ends of the linkage rod 7011, and the linkage gear 702 is sleeved at the outer side of the supporting disc 703;

the power assembly 8 comprises a base 801, a fine adjustment motor 802 and a motor gear 803, the fine adjustment motor 802 is connected with the upper side wall of the carrying platform 1 through the base 801, and the motor gear 803 is sleeved on a rotating shaft of the fine adjustment motor 802.

Referring to fig. 1, 3 and 4, a pipe groove 101 is formed at the center of the mounting table 1, a rotary groove 102 is formed above the pipe groove 101, an annular groove 103 is formed on the bottom side wall of the rotary groove 102 and the outer side of the pipe groove 101, a gear plate groove 105 is formed beside the rotary groove 102 and inside the mounting table 1, and a through hole 104 is formed above the center of the gear plate groove 105.

Referring to fig. 1 and 5, the pipe chute 101 is disposed in communication with the toothed disc 105, the rough adjusting gear 603 of the rough adjusting assembly 6 is disposed inside the toothed disc 105, the rough adjusting gear 603 extends out of the toothed disc 105 into the rotary trough 102 and is engaged with the pipe gears 304 in the toothed disc 105, and the inner sidewall of the annular groove 103 is engaged with the bottom pillar 3041 at the bottom of the pipe gears 304; specifically, the coarse adjustment motor 601 is vertically arranged towards the mounting table 1, and a spiral groove is formed in the outer wall of the connecting ring 305 on the collection tube 3, so that the coarse adjustment motor 601 can drive the connecting ring 305 and the collection tube 3 to move up and down through the coarse adjustment gear 603 and the tube gear 304.

Referring to fig. 6-8, a tube head 301 is disposed at the bottom of the collecting tube 3, the tube head 301 is connected to a liquid storage tube 302 through a screw thread, an anti-collision ring 303 is sleeved on the middle position of the liquid storage tube 302, a connection ring 305 is sleeved on the upper position of the liquid storage tube 302, a tube gear 304 is sleeved outside the connection ring 305, and a bottom column 3041 is bonded to the bottom sidewall of the tube gear 304; the bottom pillars 3041 are arranged in a cylindrical structure, the maximum diameter of the bottom pillars 3041 is the same as the groove width of the annular groove 103, and the number of the bottom pillars 3041 is four in an annular array structure; a sealing head 306 is arranged inside the liquid storage tube 302, the peripheral side wall of the sealing head 306 is matched and connected with the inner wall of the liquid storage tube 302, and a insection column 307 is bonded at the center of the upper side wall of the sealing head 306; the fixing frame 5 is composed of a cross frame 501, a vertical column 502 and a fixing block 503, the bottom side walls at two ends of the cross frame 501 are connected with the vertical column 502 in a riveting mode, the bottom side wall of the vertical column 502 is connected with the upper side wall of the erection table 1 through the fixing block 503, a slotted hole is formed in the center of the cross frame 501, and the cross frame 501 is connected with the insection column 307 on the acquisition tube 3 in a nesting mode through the slotted hole.

Referring to fig. 9-10, a linkage bar 7011 in the fine adjustment assembly 7 is engaged with a motor gear 803 in the power assembly 8 through a linkage gear 702, and the linkage bar 7011 is connected with the upper side wall of the erection table 1 through support plates 703 on both sides; specifically, the motor gear 803 and the fine adjustment motor 802 rotate synchronously, so that the power of the fine adjustment motor 802 can be transmitted to the fine adjustment assembly 7 through the motor gear 803 and the linkage gear 702; the outer wall of one side, facing the fine adjustment assembly 7, of the insection column 307 in the collection pipe 3 is provided with meshing teeth, the fine adjustment gear 701 in the fine adjustment assembly 7 is meshed with the insection column 307 in the collection pipe 3, and the fine adjustment gear 701 and the insection column 307 are arranged in a coaxial surface structure.

The above are only preferred embodiments of the present invention, and the present invention is not limited thereto, and any modification, equivalent replacement, and improvement made to the technical solutions described in the above embodiments, and to some of the technical features thereof, are included in the scope of the present invention.

Claims

1. The utility model provides an electrolyte analyzer gathers testing arrangement, includes set up platform (1), gathers pipe (3), coarse adjusting subassembly (6), fine tuning subassembly (7) and power component (8), its characterized in that: an assembly block (2) is bonded on the bottom side wall of the erection table (1), an acquisition pipe (3) is inserted in the center of the erection table (1), an output assembly (4) is inserted in the side wall of the acquisition pipe (3), a fixing frame (5) is arranged right above the acquisition pipe (3), a rough adjustment assembly (6) is mounted on the erection table (1) on one side of the acquisition pipe (3), a fine adjustment assembly (7) is mounted on the erection table (1) on the other side of the acquisition pipe (3), and a power assembly (8) is mounted beside the fine adjustment assembly (7);

the output assembly (4) comprises a hard pipe (401), an electronic on-off valve (402) and an output hose (403), and the hard pipe (401) is communicated with the output hose (403) through the electronic on-off valve (402);

the rough adjusting assembly (6) comprises a rough adjusting motor (601), a motor frame (602) and a rough adjusting gear (603), the rough adjusting motor (601) is connected with the upper side wall of the carrying platform (1) through the motor frame (602), and the rough adjusting gear (603) is assembled at the tail end of a rotating shaft of the rough adjusting motor (601);

the fine adjustment assembly (7) comprises a fine adjustment gear (701), a linkage rod (7011), a linkage gear (702) and a supporting disc (703), the linkage rod (7011) is inserted in the center of the fine adjustment gear (701), the supporting disc (703) is sleeved at two ends of the linkage rod (7011), and the linkage gear (702) is sleeved at the outer side of the supporting disc (703);

the power assembly (8) comprises a base (801), a fine adjustment motor (802) and a motor gear (803), the fine adjustment motor (802) is connected with the upper side wall of the carrying platform (1) through the base (801), and the motor gear (803) is sleeved on a rotating shaft of the fine adjustment motor (802).

2. The electrolyte analyzer collection testing device as claimed in claim 1, wherein a pipe head (301) is arranged at the bottom of the collection pipe (3), the pipe head (301) is connected with the liquid storage pipe (302) through a thread, an anti-collision ring (303) is sleeved on the middle position of the liquid storage pipe (302), a connection ring (305) is sleeved on the upper position of the liquid storage pipe (302), a pipe gear (304) is sleeved outside the connection ring (305), and a bottom column (3041) is bonded on the bottom side wall of the pipe gear (304).

3. The electrolyte analyzer collection and test device as recited in claim 2, wherein a sealing head (306) is disposed inside the liquid storage tube (302), a peripheral sidewall of the sealing head (306) is connected with an inner wall of the liquid storage tube (302) in a fitting manner, and a serrated column (307) is bonded to a center of an upper sidewall of the sealing head (306).

4. The electrolyte analyzer collecting and testing device as claimed in claim 1, wherein a pipe groove (101) is formed at the center of the mounting table (1), a rotating groove (102) is formed above the pipe groove (101), an annular groove (103) is formed on the bottom side wall of the rotating groove (102) and the outer side of the pipe groove (101), a gear plate groove (105) is formed on the side of the rotating groove (102) and inside the mounting table (1), and a through hole (104) is formed above the center of the gear plate groove (105).

5. The electrolyte analyzer collection testing device of claim 4, wherein the pipe groove (101) and the gear plate groove (105) are arranged in communication, the rough adjusting gear (603) in the rough adjusting assembly (6) is arranged inside the gear plate groove (105), the rough adjusting gear (603) extends out of the gear plate groove (105) into the rotating groove (102) and is in meshed connection with the pipe gear (304) in the gear plate groove (105), and the inner side wall of the annular groove (103) is in matched connection with the bottom column (3041) at the bottom of the pipe gear (304).

6. The electrolyte analyzer acquisition testing device as claimed in claim 1, wherein the fixed frame (5) is composed of a cross frame (501), a vertical column (502) and a fixed block (503), the bottom side walls of two ends of the cross frame (501) are connected with the vertical column (502) in a riveting mode, the bottom side wall of the vertical column (502) is connected with the upper side wall of the erection table (1) through the fixed block (503), a slotted hole is formed in the center of the cross frame (501), and the cross frame (501) is connected with a toothed column (307) on the acquisition tube (3) in a nesting mode through the slotted hole.

7. The electrolyte analyzer acquisition and test device as claimed in claim 1, wherein the linkage rod (7011) in the fine adjustment assembly (7) is meshed with the motor gear (803) in the power assembly (8) through a linkage gear (702), and the linkage rod (7011) is connected with the upper side wall of the carrying platform (1) through supporting plates (703) on two sides.

8. The electrolyte analyzer collection testing device of claim 3, wherein the outer wall of the side, facing the fine adjustment assembly (7), of the insection column (307) in the collection tube (3) is provided with meshing teeth, the fine adjustment gear (701) in the fine adjustment assembly (7) is meshed with the insection column (307) in the collection tube (3) to be connected, and the fine adjustment gear (701) and the insection column (307) are arranged in a coaxial surface structure.