CN220563702U - Test tube removing device of optical fiber probe - Google Patents

Abstract

The utility model relates to a test tube removing device of an optical fiber probe, which comprises an electric cylinder fixing plate, wherein two ends of the electric cylinder fixing plate in the length direction are connected with push blocks; an electric cylinder; the optical fiber probe fixing plate is connected with the telescopic rod of the electric cylinder, a plurality of optical fiber probes are arranged on the optical fiber probe fixing plate, and the lower end parts of the optical fiber probes are connected with test tubes; the optical fiber probe fixing plate is provided with a horizontal guide rod and a vertical guide rod, the horizontal guide rod is connected with a clamping head I, the lower end part of the vertical guide rod is connected with a clamping head II, and a test tube is arranged between the clamping head I and the clamping head II. According to the test tube removing device of the optical fiber probe, the optical fiber head sleeved with the test tubes is orderly placed on the optical fiber probe fixing plate, and the power is provided by the electric cylinder, so that a bidirectional movement effect can be achieved, after the clamping head I is opened, the test tubes are separated from the optical fiber probe through the clamping head II, and therefore separation of a plurality of test tubes is completed simultaneously, labor is saved, and working efficiency is improved.

Description

Test tube removing device of optical fiber probe

Technical Field

The utility model relates to the technical field of medical auxiliary instruments, in particular to a tube removing device of an optical fiber probe.

Background

In performing a medical reagent test, the reagent is stored in a test tube, and then a probe for the test is inserted into the test tube.

When the existing probe contacts with a sample to be detected in a test tube, in order to ensure the accuracy of probe detection, when the probe is pushed into the test tube, the outer wall of the probe is only clamped into the inner wall of the test tube, and a test tube port is sealed like a test tube plug. The accuracy of reagent detection has been guaranteed like this, but when carrying out multitube reagent and detecting, need pull out the probe one by one from the tube, this needs to spend the tester with great effort, takes longer just can separate probe and tube.

Thus, there is a need for a device that automatically separates the probe from the cuvette.

Disclosure of Invention

Therefore, the utility model aims to solve the technical problem that the probe is manually pulled out of the test tube in the prior art, and the time and the labor are wasted.

In order to solve the technical problems, the utility model provides a test tube removing device of an optical fiber probe, which comprises an electric cylinder fixing plate, wherein two ends of the electric cylinder fixing plate in the length direction are connected with push blocks; an electric cylinder fixedly provided on the electric cylinder fixing plate; the optical fiber probe fixing plate is connected with the telescopic rod of the electric cylinder, a plurality of optical fiber probes are arranged on the optical fiber probe fixing plate, and the lower end parts of the optical fiber probes are connected with test tubes; the optical fiber probe fixing plate is provided with two symmetrically arranged horizontal guide rods and two symmetrically arranged vertical guide rods, one end of each horizontal guide rod is in contact with the push block, the other end of each horizontal guide rod is connected with a chuck connecting plate, the lower end face of each chuck connecting plate is connected with a clamping head I, the upper end of each vertical guide rod is in contact with the electric cylinder fixing plate, the lower end of each vertical guide rod is connected with a clamping head II, and a test tube is arranged between the clamping head I and the clamping head II.

In one embodiment of the utility model, the first clamping head and the second clamping head are symmetrically arranged, a plurality of semicircular test tube accommodating grooves and a plurality of semicircular probe accommodating grooves are respectively arranged on the first clamping head and the second clamping head, the semicircular test tube accommodating grooves are communicated with the semicircular probe accommodating grooves, a boss is arranged between the semicircular test tube accommodating grooves and the semicircular probe accommodating grooves, the pipe orifice of the test tube is arranged in the semicircular test tube accommodating grooves, the lower end part of the optical fiber probe is arranged in the semicircular probe accommodating grooves, and the pipe orifice of the test tube is in contact with the boss.

In one embodiment of the utility model, the diameter of the semi-circular tube receiving slot is greater than the diameter of the semi-circular probe receiving slot.

In one embodiment of the utility model, the optical fiber probe fixing plate is provided with a plurality of first through holes, the optical fiber probes, the semicircular probe accommodating grooves and the through holes are arranged in a one-to-one correspondence, the first through holes are communicated with the semicircular probe accommodating grooves, and the lower end parts of the optical fiber probes penetrate through the first through holes.

In one embodiment of the utility model, the end surface of the push block opposite to the horizontal guide rod is provided with an inclined surface.

In one embodiment of the utility model, the horizontal guide rod is sleeved with a first spring, the end part of the horizontal guide rod, which is close to the pushing block, is connected with a first cam, and the first spring is positioned between the side wall of the optical fiber probe fixing plate and the first cam.

In one embodiment of the utility model, the vertical guide rod is sleeved with a second spring, the upper end part of the vertical guide rod is connected with a second cam, and the second spring is positioned between the upper end surface of the optical fiber probe fixing plate and the second cam.

In one embodiment of the utility model, the optical fiber probe fixing plate is connected with two guide rods III, the electric cylinder fixing plate is provided with two guide sleeves III, the two guide rods III and the two guide sleeves III are arranged in one-to-one correspondence, and the guide rods III and the guide sleeves III are connected in a sliding manner.

In one embodiment of the utility model, the optical fiber probe fixing plate is provided with two symmetrically arranged guide sleeves II, the two symmetrically arranged guide sleeves II and two symmetrically arranged vertical guide rods are arranged in one-to-one correspondence, and the vertical guide rods are in sliding connection with the guide sleeves II.

In one embodiment of the utility model, the horizontal and vertical guide bars are arranged vertically.

Compared with the prior art, the technical scheme of the utility model has the following advantages:

according to the test tube removing device of the optical fiber probe, the optical fiber head sleeved with the test tubes is orderly placed on the optical fiber probe fixing plate, and the power is provided by the electric cylinder, so that a bidirectional movement effect can be achieved, after the clamping head I is opened, the test tubes are separated from the optical fiber probe through the clamping head II, and therefore separation of a plurality of test tubes is completed simultaneously, labor is saved, and working efficiency is improved.

Drawings

In order that the utility model may be more readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof that are illustrated in the appended drawings, in which

FIG. 1 is a schematic diagram of the tube removing device of the fiber optic probe of the present utility model;

FIG. 2 is a schematic diagram of the structure of the tube removing device of the fiber optic probe of the present utility model in use.

Description of the specification reference numerals: the optical fiber probe comprises an electric cylinder fixing plate 1, a push block 11, an inclined surface 111, a guide sleeve III 12, an electric cylinder 2, an optical fiber probe fixing plate 3, a horizontal guide rod 31, a first spring 311, a first cam 312, a vertical guide rod 32, a second spring 321, a second cam 322, a chuck connecting plate 33, a first clamping head 34, a semicircular test tube accommodating groove 341, a semicircular probe accommodating groove 342, a boss 343, a second clamping head 35, a first through hole 36, a guide rod III 37, a second guide sleeve 38, an optical fiber probe 4 and a test tube 5.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the utility model and practice it.

Referring to fig. 1 and 2, the test tube removing device of the optical fiber probe comprises an electric cylinder fixing plate 1, an electric cylinder 2, an optical fiber probe fixing plate 3, a plurality of optical fiber probes 4 and a plurality of test tubes 5, wherein the electric cylinder fixing plate 1 is connected with push blocks 11 at two ends in the length direction; an electric cylinder 2 fixedly provided on the electric cylinder fixing plate 1; the optical fiber probe fixing plate 3 is connected with the telescopic rod of the electric cylinder 2, a plurality of optical fiber probes 4 are arranged on the optical fiber probe fixing plate 3, the optical fiber probes 4 are orderly arranged on the optical fiber probe fixing plate 3 according to a row, and the lower end part of the optical fiber probe 4 is connected with a test tube 5.

The mechanism for realizing the test tube removing 5 is that two symmetrically arranged horizontal guide rods 31 and two symmetrically arranged vertical guide rods 32 are arranged on the optical fiber probe fixing plate 3, the horizontal guide rods 31 and the vertical guide rods 32 are vertically arranged, one end of each horizontal guide rod 31 is contacted with the push block 11, the other end of each horizontal guide rod 31 is connected with a chuck connecting plate 33, a first clamping head 34 is connected to the lower end face of each chuck connecting plate 33, the upper end of each vertical guide rod 32 is contacted with the electric cylinder fixing plate 1, a second clamping head 35 is connected to the lower end of each vertical guide rod 32, and a test tube 5 is arranged between each first clamping head 34 and each second clamping head 35. When the telescopic rod of the electric cylinder 2 is taken as a power source, the optical fiber probe fixing plate 3 is driven to move upwards, meanwhile, the push block 11 is relatively close to the horizontal guide rod 31, an inclined surface 111 is arranged on the end surface of the push block 11 opposite to the horizontal guide rod 31, the inclined surface 111 is firstly contacted with the end part of the horizontal guide rod 31, the horizontal guide rod 31 is gradually pushed to move horizontally due to the arrangement of the inclined surface 111, the horizontal guide rod 31 pushes the chuck connecting plate 33 to be separated from the optical fiber probe fixing plate 3, the first clamping head 34 and the second clamping head 35 are gradually separated, clamping of the test tube 5 is released, then the vertical guide rod 32 is contacted with the electric cylinder fixing plate 1, so that the vertical guide rod 32 cannot move upwards continuously, the vertical guide rod 32 is pushed downwards, and the second clamping head 35 pushes the test tube 5 to be separated from the lower end part of the optical fiber probe 4 due to the fact that the lower end part of the vertical guide rod 32 is connected with the second clamping head 35.

The structure that is used for making test tube 5 break away from in clamping head one 34 and the clamping head two 35 is, clamping head one 34 and clamping head two 35 symmetry set up to all be equipped with a plurality of semicircle test tube holding tank 341 and a plurality of semicircle probe holding tank 342 on clamping head one 34 and the clamping head two 35, semicircle test tube holding tank 341 and semicircle probe holding tank 342 intercommunication, be equipped with boss 343 between semicircle test tube holding tank 341 and the semicircle probe holding tank 342, the mouth of pipe of test tube 5 sets up in semicircle test tube holding tank 341, the lower tip setting of fiber optic probe 4 is in semicircle probe holding tank 342, the mouth of pipe of test tube 5 contacts with boss 343. The diameter of the semicircular test tube receiving groove 341 is larger than the diameter of the semicircular probe receiving groove 342. The optical fiber probe fixing plate 3 is provided with a plurality of first through holes 36, the optical fiber probes 4, the semicircular probe accommodating grooves 342 and the first through holes 36 are arranged in a one-to-one correspondence manner, the first through holes 36 are communicated with the semicircular probe accommodating grooves 342, and the lower end parts of the optical fiber probes 4 penetrate through the first through holes 36.

In the above structure, the horizontal guide rod 31 is sleeved with the first spring 311, the end of the horizontal guide rod 31 near the push block 11 is connected with the first cam 312, and the first spring 311 is located between the side wall of the optical fiber probe fixing plate 3 and the first cam 312. After the horizontal guide rod 31 is pushed to have a certain horizontal displacement, the first spring 311 is compressed, and the first spring 311 enables the horizontal guide rod 31 to reset. The second spring 321 is sleeved on the vertical guide rod 32, the upper end part of the vertical guide rod 32 is connected with the second cam 322, and the second spring 321 is positioned between the upper end surface of the optical fiber probe fixing plate 3 and the second cam 322. After the vertical guide rod 32 has a certain vertical displacement, the second spring 321 is compressed, and the second spring 321 enables the vertical guide rod 32 to reset.

In the above structure, the optical fiber probe fixing plate 3 is connected with two guide rods three 37, the electric cylinder fixing plate 1 is provided with two guide sleeves three 12, the two guide rods three 37 and the two guide sleeves three 12 are arranged in one-to-one correspondence, and the guide rods three 37 and the guide sleeves three 12 are in sliding connection. The optical fiber probe fixing plate 3 is provided with two symmetrically arranged guide sleeves II 38, the two symmetrically arranged guide sleeves II 38 and the two symmetrically arranged vertical guide rods 32 are arranged in one-to-one correspondence, and the vertical guide rods 32 are in sliding connection with the guide sleeves II 38.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations and modifications of the present utility model will be apparent to those of ordinary skill in the art in light of the foregoing description. It is not necessary here nor is it exhaustive of all embodiments. And obvious variations or modifications thereof are contemplated as falling within the scope of the present utility model.

Claims (10)

1. The utility model provides a fiber optic probe's test tube device that takes off which characterized in that: comprising the steps of (a) a step of,

the two ends of the electric cylinder fixing plate in the length direction are connected with pushing blocks;

an electric cylinder fixedly provided on the electric cylinder fixing plate;

the optical fiber probe fixing plate is connected with the telescopic rod of the electric cylinder, a plurality of optical fiber probes are arranged on the optical fiber probe fixing plate, and the lower end parts of the optical fiber probes are connected with test tubes;

the optical fiber probe fixing plate is provided with two symmetrically arranged horizontal guide rods and two symmetrically arranged vertical guide rods, one end of each horizontal guide rod is in contact with the push block, the other end of each horizontal guide rod is connected with a chuck connecting plate, the lower end face of each chuck connecting plate is connected with a clamping head I, the upper end of each vertical guide rod is in contact with the electric cylinder fixing plate, the lower end of each vertical guide rod is connected with a clamping head II, and a test tube is arranged between the clamping head I and the clamping head II.

2. The fiber optic probe tube removal apparatus of claim 1, wherein: the optical fiber probe comprises a clamping head I, a clamping head II, a semicircular test tube accommodating groove, a semicircular probe accommodating groove and a boss, wherein the clamping head I and the clamping head II are symmetrically arranged, the clamping head I and the clamping head II are respectively provided with a plurality of semicircular test tube accommodating grooves and a plurality of semicircular probe accommodating grooves, the semicircular test tube accommodating grooves are communicated with the semicircular probe accommodating grooves, the boss is arranged between the semicircular test tube accommodating grooves and the semicircular probe accommodating grooves, the pipe orifice of the test tube is arranged in the semicircular test tube accommodating grooves, the lower end part of the optical fiber probe is arranged in the semicircular probe accommodating grooves, and the pipe orifice of the test tube is contacted with the boss.

3. The fiber optic probe tube removal apparatus of claim 2, wherein: the diameter of the semicircular test tube accommodating groove is larger than that of the semicircular probe accommodating groove.

4. The fiber optic probe tube removal apparatus of claim 2, wherein: the optical fiber probe fixing plate is provided with a plurality of first through holes, the optical fiber probes, the semicircular probe accommodating grooves and the through holes are arranged in one-to-one correspondence, the first through holes are communicated with the semicircular probe accommodating grooves, and the lower end parts of the optical fiber probes penetrate through the first through holes.

5. The fiber optic probe tube removal apparatus of claim 1, wherein: the end face of the push block, which is opposite to the horizontal guide rod, is provided with an inclined surface.

6. The fiber optic probe tube removal apparatus of claim 1, wherein: the optical fiber probe is characterized in that a first spring is sleeved on the horizontal guide rod, the end part, close to the push block, of the horizontal guide rod is connected with a first cam, and the first spring is located between the side wall of the optical fiber probe fixing plate and the first cam.

7. The fiber optic probe tube removal apparatus of claim 6, wherein: the spring II is sleeved on the vertical guide rod, the upper end part of the vertical guide rod is connected with the cam II, and the spring II is positioned between the upper end surface of the optical fiber probe fixing plate and the cam II.

8. The fiber optic probe tube removal apparatus of claim 1, wherein: the optical fiber probe fixing plate is connected with two guide rods III, the electric cylinder fixing plate is provided with two guide sleeves III, the two guide rods III and the two guide sleeves III are arranged in one-to-one correspondence, and the guide rods III are in sliding connection with the guide sleeves III.

9. The fiber optic probe tube removal apparatus of claim 1, wherein: the optical fiber probe fixing plate is provided with two symmetrically arranged guide sleeves II, the two symmetrically arranged guide sleeves II and two symmetrically arranged vertical guide rods are arranged in one-to-one correspondence, and the vertical guide rods are in sliding connection with the guide sleeves II.

10. The fiber optic probe tube removal apparatus of claim 1, wherein: the horizontal guide rod and the vertical guide rod are vertically arranged.