CN117490888B - Temperature probe detection device and method for epoxy resin composition - Google Patents

Abstract

The invention relates to the technical field of detection, in particular to a temperature probe detection device for an epoxy resin composition and a method thereof; the invention provides a temperature probe detection device for an epoxy resin composition, which comprises the following components: the device comprises a positioning cylinder, a driving assembly and a clamping and oiling assembly, wherein the inside of the positioning cylinder is hollow, and a placing opening is formed in the side wall of the positioning cylinder; the driving component is arranged at the upper end of the positioning cylinder in a lifting manner; the clamping and oiling assembly is arranged below the driving assembly in a sliding manner and is suitable for limiting the probe head; after the temperature probe is inserted into the positioning cylinder, the clamping oiling component is suitable for clamping the outer wall of the probe head from two sides; the clamping and oiling assembly is suitable for driving the probe head to move downwards so as to squeeze the compression spring; when the clamping oiling component moves away from the probe head, the compression spring pushes the probe head to move upwards, and the temperature probe with qualified elasticity can push the driving component to move upwards.

Description

Temperature probe detection device and method for epoxy resin composition

Technical Field

The invention relates to the technical field of detection, in particular to a temperature probe detection device and a temperature probe detection method for an epoxy resin composition.

Background

Before the epoxy resin composition is used, the epoxy resin composition needs to be detected, and a temperature probe used for detection needs to ensure the accuracy of the temperature probe in detection. Therefore, detection of the probe is required. Traditional check out test set, when detecting temperature probe's spring property, the condition that is worn and torn can appear in the probe head outer wall, has influenced temperature probe's life. Meanwhile, the spring of the probe is repeatedly extruded in the using and detecting process, the elasticity of the spring can be attenuated, the telescopic stroke of the probe head can be reduced due to the attenuation of the elasticity, and the use of the probe head is affected. It is therefore necessary to develop a temperature probe detecting device for an epoxy resin composition and a method thereof.

Disclosure of Invention

The invention aims to provide a temperature probe detection device and a temperature probe detection method for an epoxy resin composition.

In order to solve the above technical problems, the present invention provides a temperature probe detection device for an epoxy resin composition, comprising:

the device comprises a positioning cylinder, a driving assembly and a clamping and oiling assembly, wherein the inside of the positioning cylinder is hollow, and a placing opening is formed in the side wall of the positioning cylinder;

the driving component is arranged at the upper end of the positioning cylinder in a lifting manner;

the clamping and oiling assembly is arranged below the driving assembly in a sliding manner and is suitable for limiting the probe head;

after the temperature probe is inserted into the positioning cylinder, the clamping oiling component is suitable for clamping the outer wall of the probe head from two sides;

the clamping and oiling assembly is suitable for driving the probe head to move downwards so as to squeeze the compression spring;

when the clamping oiling component moves away from the probe head, the compression spring pushes the probe head to move upwards, and the temperature probe with qualified elasticity can push the driving component to move upwards.

Preferably, the driving assembly includes: the device comprises a driving disc, an upper connecting rod, a cross beam, a lower connecting rod and two limiting pieces, wherein the two limiting pieces are symmetrically arranged, the limiting pieces are slidably arranged on the inner wall of a positioning cylinder, and the clamping oiling assembly is slidably matched with the limiting pieces;

the lower connecting rod is vertically fixed at the upper end of the limiting piece;

the cross beam is horizontally arranged and fixed on the two lower connecting rods;

the upper connecting rod is fixed above two ends of the cross beam, and the driving disc is vertically fixed on the upper connecting rod.

Preferably, the cross beam is provided with a conical hole, and the tip of the probe head is suitable for being inserted into the conical hole.

Preferably, a vertical groove is formed in the inner wall of the positioning cylinder along the axial direction, a sliding block matched with the vertical groove is arranged on the limiting piece, and the sliding block is suitable for vertically moving in the vertical groove.

Preferably, two sides of the outer wall of the positioning cylinder are symmetrically fixed with a liquid storage column, the liquid storage column is hollow, and the liquid storage column is internally suitable for storing conductive liquid;

the inner wall of the positioning cylinder is provided with a communication groove matched with the liquid storage column, and the clamping and oiling component is suitable for being inserted into the communication groove;

when the clamping and oiling assembly moves downwards to the communicating groove, the clamping and oiling assembly is suitable for moving into the communicating groove, and the conductive liquid is suitable for entering the clamping and oiling assembly.

Preferably, the clamping and oiling assembly comprises: the limiting piece is provided with a through groove matched with the horizontal rod, and the horizontal rod is arranged in the through groove in a sliding manner;

the clamping block is fixed on one side of the horizontal rod, which is far away from the positioning cylinder, and is matched with the probe head;

the reset spring is sleeved on the outer wall of the horizontal rod, one end of the reset spring is fixed on the side wall of the limiting piece, and the reset spring is suitable for pushing the horizontal rod to move towards the inner wall of the positioning cylinder.

Preferably, a diversion hole is formed in the horizontal rod along the length direction, one end of the diversion hole is formed in one side, close to the probe head, of the clamping block, and the other end of the diversion hole is communicated with the liquid storage column.

Preferably, the temperature probe includes: the probe comprises a receiving rod, a probe head, a needle body and a compression spring, wherein the interior of the needle body is hollow, and the probe head is retractably arranged in the needle body;

the receiving rod is fixed at one end of the needle body far away from the probe head;

the two ends of the compression spring are respectively fixed on the receiving rod and the side wall of the probe head.

Preferably, the probe head is pointed and tapered, the probe head being adapted for insertion into a test composition.

Preferably, a fixing hole matched with the needle body is formed in the inner bottom of the positioning cylinder, and the needle body is suitable for being vertically inserted into the fixing hole.

Preferably, the positioning cylinder is fixed on a workbench, and a conveying belt is arranged on one side of the workbench and is suitable for conveying the temperature probe;

the workbench is provided with a carrying clamp, and the carrying clamp is suitable for clamping the temperature probe so that the temperature probe can be inserted into the positioning cylinder.

On the other hand, the invention also provides a detection method of the temperature probe detection device for the epoxy resin composition, which comprises the following steps:

the conveying belt is suitable for driving the temperature probe to horizontally move until the temperature probe is positioned below the conveying clamp, and the conveying clamp is suitable for clamping the temperature probe and inserting the temperature probe into the fixing hole in the fixing cylinder;

after the temperature probe is inserted into the positioning cylinder, the driving assembly is pushed to move downwards, and the clamping oiling assembly is suitable for clamping the outer wall of the probe head from two sides;

the clamping and oiling assembly is suitable for driving the probe head to move downwards so as to squeeze the compression spring;

when the clamping oiling component moves away from the probe head, the compression spring pushes the probe head to move upwards, and the temperature probe with qualified elasticity can push the driving component to move upwards.

The temperature probe detection device for the epoxy resin composition has the beneficial effects that through the arrangement of the probe detection device, whether the probe is qualified or not is detected when the temperature probe detects the test composition each time, and the accuracy of the temperature probe detection is improved; meanwhile, the oiling component can also smear conductive liquid on the outer wall of the probe head, so that the sensitivity of the probe head to the detection of the composition is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

In order to make the above objects, features and advantages of the present invention more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of a temperature probe detection device for an epoxy resin composition according to the present invention;

FIG. 2 is an internal perspective view of the positioning cartridge of the present invention;

FIG. 3 is a perspective view of a temperature probe of the present invention;

FIG. 4 is an internal perspective view of the temperature probe of the present invention;

fig. 5 is a perspective view of the carrying grip and the conveyor belt of the present invention.

In the figure:

1. a probe head; 2. a needle body; 3. a receiving rod; 4. a compression spring;

5. a probe detection device;

51. a positioning cylinder; 510. a communication groove; 511. a liquid storage column; 512. a fixing hole;

52. a drive assembly; 521. a drive plate; 522. an upper connecting rod; 523. a cross beam; 524. a lower connecting rod; 525. a limiting piece; 526. a tapered bore;

53. clamping the oiling component; 531. a horizontal bar; 532. a clamping block; 533. a deflector aperture;

6. a work table; 7. a conveyor belt; 8. and carrying the clamping hand.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 5, the present invention provides a temperature probe detection device for an epoxy resin composition, comprising: the device comprises a positioning cylinder 51, a driving assembly 52 and a clamping and oiling assembly 53, wherein the positioning cylinder 51 is hollow, and a placing opening is formed in the side wall of the positioning cylinder 51; the placement opening is axially formed along the positioning cylinder 51, and the height of the placement opening is not smaller than the height of the temperature probe. A fixing hole 512 adapted to the temperature probe is formed in the bottom of the positioning cylinder 51; the temperature probe is adapted to be inserted into the fixing hole 512 in the positioning cylinder 51 through the placement port, and the probe head 1 is disposed upward. The driving component 52 is arranged at the upper end of the positioning cylinder 51 in a lifting manner; the clamping and oiling assembly 53 is arranged below the driving assembly 52 in a sliding manner, and the clamping and oiling assembly 53 is suitable for limiting the probe head 1; after the receiving rod 3 is inserted into the fixing hole 512, two clamping blocks 532 are adapted to clamp the probe head 1 from both sides. In order to avoid damaging the outer wall of the probe head 1, the inner side wall of the clamping block 532 is provided with a flexible member, and the flexible member is abutted with the outer wall of the probe head 1, so as to avoid damaging the outer wall of the probe head 1 when clamping the outer wall of the probe head 1. Wherein, after the temperature probe is inserted into the positioning cylinder 51, the clamping and oiling component 53 is suitable for clamping the outer wall of the probe head 1 from two sides; pressing the driving component 52 to move downwards, wherein the driving component 52 is suitable for driving the clamping and oiling component 53 to synchronously move downwards, and the clamping and oiling component 53 is suitable for driving the probe head 1 to move downwards so as to squeeze the compression spring 4; when the clamping and oiling assembly 53 moves to the communicating groove 510, the return spring is suitable for pushing the horizontal rod 531 to move outwards until the horizontal rod 531 is inserted into the communicating groove 510; the side walls of the upper and lower sides of the communication groove 510 are provided with arc chamfers so that the horizontal bar 531 is inserted into or separated from the communication groove 510. At this time, the two clamping blocks 532 are far away from the outer wall of the probe head 1 under the action of the elastic force of the reset spring, and the probe head 1 moves upwards under the action of the elastic force of the compression spring 4; when the clamping oiling component 53 moves away from the probe head 1, the compression spring 4 pushes the probe head 1 to move upwards, and the temperature probe with qualified elasticity can push the driving component 52 to move upwards. The fact that the elasticity is acceptable means that the elasticity of the compression spring 4 of the temperature probe is not attenuated. When the compression spring 4 of the temperature probe pushes the probe head 1 to move upwards after the elasticity of the compression spring 4 is attenuated, the probe head 1 cannot push the beam 523 to move upwards. When the compression spring 4 of the temperature probe attenuates, and the compression spring 4 pushes the probe head 1 to move upwards, the upward movement stroke of the probe head 1 becomes smaller, and the probe head 1 cannot push the beam 523 to move upwards.

Referring to fig. 2, the driving assembly 52 includes: the driving plate 521, the upper connecting rod 522, the cross beam 523, the lower connecting rod 524 and the two limiting pieces 525 are symmetrically arranged, the limiting pieces 525 are slidably arranged on the inner wall of the positioning cylinder 51, and the clamping oiling component 53 is slidably matched with the limiting pieces 525; the inner wall of the positioning cylinder 51 is provided with a vertical groove along the axial direction, the limiting piece 525 is provided with a sliding block matched with the vertical groove, and the sliding block is suitable for vertically moving in the vertical groove. The limiting tab 525 is adapted to slide vertically within the chute. The lower connecting rod 524 is vertically fixed at the upper end of the limiting piece 525; the cross beam 523 is horizontally arranged, and the cross beam 523 is fixed on two lower connecting rods 524; the beam 523 is disposed above the probe head 1. The probe head 1 is adapted to be inserted into the tapered bore 526 as the compression spring 4 drives the probe head 1 upward. The upper connecting rod 522 is fixed above both ends of the cross beam 523, and the driving plate 521 is vertically fixed on the upper connecting rod 522; the beam 523 is provided with a tapered hole 526, and the inner wall of the tapered hole 526 is flexible, so that the outer wall of the probe head 1 is prevented from being damaged. The tip of the probe head 1 is adapted to be inserted into the tapered hole 526. The driving plate 521 is disposed above the positioning cylinder 51, and the diameter of the driving plate 521 is not smaller than the diameter of the positioning cylinder 51, and is adapted to drive the beam 523 and the horizontal bar 531 to move downward synchronously when the driving plate 521 is pressed; the clamping blocks 532 clamp the probe head 1 from both sides so that the probe head 1 can be retracted into the needle body 2. During detection, the temperature probe is inserted into the positioning cylinder 51 through the placement opening, the needle body 2 is suitable for being inserted into the fixing hole 512, the probe head 1 faces the cross beam 523, and at the moment, the horizontal rod 531 is positioned above the probe head 1; pressing the driving plate 521, the driving plate 521 drives the horizontal rod 531 to synchronously move downwards until the two clamping blocks 532 clamp the outer wall of the probe head 1 from two sides, and the clamping blocks 532 are suitable for pushing the probe head 1 to shrink inwards towards the needle body 2 along with the continuous vertical downwards movement of the clamping blocks 532 along the axial direction of the inner wall of the positioning cylinder 51, so that the compression spring 4 is extruded and deformed. When the horizontal rod 531 moves to the communicating groove 510, the return spring pushes the horizontal rod 531 to move towards the communicating groove 510, and at this time, the two clamping blocks 532 are far away from the outer wall of the probe head 1 under the action of the elastic force of the return spring; the clamping block 532 is separated from the probe head 1, the probe head 1 moves upwards under the action of the elasticity of the compression spring 4 until the upper end of the probe head 1 is inserted into the conical hole 526, the aperture of the conical hole 526 is smaller than that of the outer wall of the probe head 1, the probe head 1 is suitable for pushing the cross beam 523 to move upwards, the cross beam 523 is suitable for driving the horizontal rod 531 to separate from the communicating groove 510 in the upward moving process, and when the outer wall of the horizontal rod 531 is abutted with the inner wall of the positioning cylinder 51, the inner wall of the clamping block 532 is suitable for being abutted with the outer wall of the probe head 1; simultaneously, two clamping blocks 532 clamp the spacing probe head 1 from both sides.

In order to improve the detection effect of the probe head 1, two sides of the outer wall of the positioning cylinder 51 are symmetrically fixed with a liquid storage column 511, the inside of the liquid storage column 511 is hollow, and the inside of the liquid storage column 511 is suitable for storing conductive liquid; the upper end of the liquid storage column 511 is provided with a liquid injection pipe, and the liquid injection pipe is suitable for conveying conductive liquid into the liquid storage column 511; the liquid storage column 511 is provided with a one-way valve at one side near the communication groove 510, and when the horizontal rod 531 moves outwards to be inserted into the communication groove 510, the one-way valve is opened, and the conductive liquid in the liquid storage column 511 is suitable for flowing into the flow guide hole 533. The inner wall of the positioning cylinder 51 is provided with a communication groove 510 matched with the liquid storage column 511, and the clamping and oiling component 53 is suitable for being inserted into the communication groove 510; the side of the communication groove 510, which is close to the horizontal bar 531, is provided with an arc chamfer, so that the horizontal bar 531 is convenient to separate from the communication groove 510. Preferably, the outer end of the horizontal bar 531 is provided with a circular arc chamfer to reduce friction when the horizontal bar 531 is disengaged from the inside of the communication groove 510. Wherein, when the clamping and oiling assembly 53 moves downwards to the position of the communicating groove 510, the clamping and oiling assembly 53 is suitable for moving into the communicating groove 510, and the conductive liquid is suitable for entering the clamping and oiling assembly 53.

The clamping and oiling assembly 53 comprises: the limiting piece 525 is provided with a through groove matched with the horizontal rod 531, and the horizontal rod 531 is arranged in the through groove in a sliding manner; the clamping block 532 is fixed on one side of the horizontal rod 531 away from the positioning cylinder 51, and the clamping block 532 is matched with the probe head 1; when the two clamping blocks 532 are abutted against the outer wall of the probe head 1 from two sides, the two clamping blocks 532 are suitable for clamping the limiting probe head 1, and when the horizontal rod 531 moves downwards, the probe head 1 is driven to synchronously move downwards. The reset spring is sleeved on the outer wall of the horizontal rod 531, one end of the reset spring is fixed on the side wall of the limiting piece 525, the other end of the reset spring is fixed on the outer wall of the horizontal rod 531, and the reset spring is suitable for pushing the horizontal rod 531 to move towards the inner wall of the positioning cylinder 51, so that the outer end of the horizontal rod 531 is abutted to the inner wall of the positioning cylinder 51. I.e. the return spring is adapted to push the horizontal bar 531 to move away from the probe head 1. A diversion hole 533 is formed in the horizontal bar 531 along the length direction, one end of the diversion hole 533 is formed on one side of the clamping block 532 close to the probe head 1, and the other end of the diversion hole 533 is communicated with the liquid storage column 511. The arrangement of the diversion holes 533 facilitates the smearing of the conductive liquid on the outer wall of the probe head 1 by the clamping blocks 532, so as to improve the sensitivity of the probe head 1 during detection. After the detection of the probe head 1 is finished, the liquid storage column 511 flows into the conductive liquid in the guide hole 533, and is suitable for being contacted with the next probe head 1.

Referring to fig. 3 and 4, the temperature probe includes: the probe comprises a receiving rod 3, a probe head 1, a needle body 2 and a compression spring 4, wherein the interior of the needle body 2 is hollow, and the probe head 1 is retractably arranged in the needle body 2; and the pointed cone end of the probe head 1 protrudes out of the needle body 2; the receiving rod 3 is fixed at one end of the needle body 2 far away from the probe head 1; the two ends of the compression spring 4 are respectively fixed on the side walls of the receiving rod 3 and the probe head 1. The probe head 1 is pointed and tapered and is adapted to be inserted into a test composition. The test composition provided by the invention is an epoxy resin composition to be detected. The probe head 1 is electrically connected with the receiving rod 3, and the receiving rod 3 can transmit temperature data detected by the probe head 1 to the display screen.

Referring to fig. 5, in order to realize automatic detection of the temperature probe, the positioning cylinder 51 is fixed on the workbench 6, and a conveyor belt 7 is arranged on one side of the workbench 6, and the conveyor belt 7 is suitable for conveying the temperature probe; the workbench 6 is provided with a carrying clamp 8, the workbench 6 is provided with a bracket, and the carrying clamp 8 is suitable for sliding on the side wall of the bracket; the carrying grip 8 is adapted to grip the temperature probe so that the temperature probe can be inserted into the positioning cylinder 51.

An embodiment two, the present embodiment also provides a method for detecting a temperature probe for an epoxy resin composition based on the embodiment one, which includes a temperature probe for an epoxy resin composition according to the embodiment one, and the specific structure is the same as the embodiment one, and the specific method for detecting a temperature probe for an epoxy resin composition is not described here again as follows: the conveyer belt 7 is suitable for driving the temperature probe to horizontally move until the temperature probe is positioned below the carrying clamp 8, and the carrying clamp 8 is suitable for clamping the temperature probe and inserting the temperature probe into the fixing hole 512 in the fixing barrel;

after the temperature probe is inserted into the positioning cylinder 51, the driving component 52 is pushed to move downwards, and the clamping oiling component 53 is suitable for clamping the outer wall of the probe head 1 from two sides;

the clamping and oiling assembly 53 is adapted to drive the probe head 1 to move downwards to compress the compression spring 4;

when the clamping oiling component 53 moves away from the probe head 1, the compression spring 4 pushes the probe head 1 to move upwards, and the temperature probe with qualified elasticity can push the driving component 52 to move upwards.

The components (components not illustrating specific structures) selected in the application are all common standard components or components known to those skilled in the art, and the structures and principles of the components are all known to those skilled in the art through technical manuals or through routine experimental methods. Moreover, the software programs referred to in the present application are all prior art, and the present application does not relate to any improvement of the software programs.

In the description of embodiments of the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided in this application, it should be understood that the disclosed systems, devices, and methods may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of the units is merely a logical function division, and there may be other manners of division in actual implementation, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some communication interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in the embodiments of the present invention may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit.

With the above-described preferred embodiments according to the present invention as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present invention. The technical scope of the present invention is not limited to the description, but must be determined according to the scope of claims.

Claims (9)

1. A temperature probe detection device for an epoxy resin composition, comprising:

the device comprises a positioning cylinder (51), a driving assembly (52) and a clamping and oiling assembly (53), wherein the inside of the positioning cylinder (51) is hollow, and a placing opening is formed in the side wall of the positioning cylinder (51);

the driving component (52) is arranged at the upper end of the positioning cylinder (51) in a lifting manner;

the clamping and oiling assembly (53) is arranged below the driving assembly (52) in a sliding manner, and the clamping and oiling assembly (53) is suitable for limiting the probe head (1);

wherein, after the temperature probe is inserted into the positioning cylinder (51), the clamping oiling component (53) is suitable for clamping the outer wall of the probe head (1) from two sides;

the clamping and oiling assembly (53) is suitable for driving the probe head (1) to move downwards so as to squeeze the compression spring (4);

when the clamping oiling component (53) moves away from the probe head (1), the compression spring (4) pushes the probe head (1) to move upwards, and the temperature probe with qualified elasticity can push the driving component (52) to move upwards;

the drive assembly (52) includes: the device comprises a driving disc (521), an upper connecting rod (522), a cross beam (523), a lower connecting rod (524) and two limiting pieces (525), wherein the two limiting pieces (525) are symmetrically arranged, the limiting pieces (525) are slidably arranged on the inner wall of a positioning cylinder (51), and the clamping oiling component (53) is slidably matched with the limiting pieces (525);

the lower connecting rod (524) is vertically fixed at the upper end of the limiting piece (525);

the cross beam (523) is horizontally arranged, and the cross beam (523) is fixed on the two lower connecting rods (524);

the upper connecting rod (522) is fixed above two ends of the cross beam (523), and the driving disc (521) is vertically fixed on the upper connecting rod (522);

the clamping and oiling assembly (53) comprises: the limiting piece (525) is provided with a through groove matched with the horizontal rod (531), and the horizontal rod (531) is arranged in the through groove in a sliding manner;

the clamping block (532) is fixed on one side of the horizontal rod (531) far away from the positioning cylinder (51), and the clamping block (532) is matched with the probe head (1);

the reset spring is sleeved on the outer wall of the horizontal rod (531), one end of the reset spring is fixed on the side wall of the limiting piece (525), and the other end of the reset spring is fixed on the outer wall of the horizontal rod (531); the reset spring is suitable for pushing the horizontal rod (531) to move towards the inner wall of the positioning cylinder (51);

the temperature probe includes: the probe comprises a receiving rod (3), a probe head (1), a needle body (2) and a compression spring (4), wherein the interior of the needle body (2) is hollow, and the probe head (1) is telescopically arranged in the needle body (2);

the receiving rod (3) is fixed at one end of the needle body (2) far away from the probe head (1);

the two ends of the compression spring (4) are respectively fixed on the side walls of the receiving rod (3) and the probe head (1).

2. A temperature probe detecting apparatus for an epoxy resin composition according to claim 1, wherein:

the cross beam (523) is provided with a conical hole (526), and the tip of the probe head (1) is suitable for being inserted into the conical hole (526).

3. A temperature probe detecting apparatus for an epoxy resin composition according to claim 2, wherein:

a vertical groove is formed in the inner wall of the positioning barrel (51) along the axial direction, a sliding block matched with the vertical groove is arranged on the limiting piece (525), and the sliding block is suitable for vertically moving in the vertical groove.

4. A temperature probe detection device for an epoxy resin composition according to claim 3, wherein:

a liquid storage column (511) is symmetrically fixed on two sides of the outer wall of the positioning cylinder (51), the liquid storage column (511) is hollow, and the liquid storage column (511) is internally suitable for storing conductive liquid;

a communication groove (510) matched with the liquid storage column (511) is formed in the inner wall of the positioning cylinder (51), and the clamping and oiling component (53) is suitable for being inserted into the communication groove (510);

when the clamping and oiling assembly (53) moves downwards to the communicating groove (510), the clamping and oiling assembly (53) is suitable for moving into the communicating groove (510), and conductive liquid is suitable for entering the clamping and oiling assembly (53).

5. A temperature probe detecting apparatus for an epoxy resin composition according to claim 4, wherein:

a diversion hole (533) is formed in the horizontal rod (531) along the length direction, one end of the diversion hole (533) is formed in one side, close to the probe head (1), of the clamping block (532), and the other end of the diversion hole (533) is communicated with the liquid storage column (511).

6. A temperature probe detection device for an epoxy resin composition according to claim 5, wherein:

the probe head (1) is pointed and tapered and is adapted to be inserted into a test composition.

7. A temperature probe detecting apparatus for an epoxy resin composition according to claim 6, wherein:

a fixing hole (512) matched with the needle body (2) is formed in the inner bottom of the positioning cylinder (51), and the needle body (2) is suitable for being vertically inserted into the fixing hole (512).

8. A temperature probe detecting apparatus for an epoxy resin composition according to claim 7, wherein:

the positioning cylinder (51) is fixed on the workbench (6), one side of the workbench (6) is provided with a conveying belt (7), and the conveying belt (7) is suitable for conveying the temperature probe;

the workbench (6) is provided with a carrying clamp (8), and the carrying clamp (8) is suitable for clamping the temperature probe so that the temperature probe can be inserted into the positioning cylinder (51).

9. A method of detecting a temperature probe for an epoxy resin composition using the temperature probe for an epoxy resin composition according to any one of claims 1 to 8, comprising the steps of:

the conveying belt (7) is suitable for driving the temperature probe to horizontally move until the temperature probe is positioned below the conveying clamp hand (8), and the conveying clamp hand (8) is suitable for clamping the temperature probe and inserting the temperature probe into the fixing hole (512) in the fixing barrel;

after the temperature probe is inserted into the positioning cylinder (51), the driving component (52) is pushed to move downwards, and the clamping oiling component (53) is suitable for clamping the outer wall of the probe head (1) from two sides;

the clamping and oiling assembly (53) is suitable for driving the probe head (1) to move downwards so as to squeeze the compression spring (4);

when the clamping oiling component (53) moves away from the probe head (1), the compression spring (4) pushes the probe head (1) to move upwards, and the temperature probe with qualified elasticity can push the driving component (52) to move upwards.