CN113939150A - Mounting socket for detector test - Google Patents

Abstract

The invention is suitable for the technical field of detection equipment, and provides a mounting socket for detector testing, which comprises a device body, a mounting mechanism and a placing mechanism for mounting a testing electronic assembly, and further comprises: dust removal cooling mechanism, with this body coupling of device for remove dust the cooling to test electronic assembly, dust removal cooling mechanism includes drive assembly, drive shaft, fan subassembly and conversion subassembly, the fan subassembly passes through coupling assembling and is connected with this body rotation of device, the conversion subassembly includes slider B and sets up at the epaxial spout B of drive, slider B and spout B sliding fit, slider B is connected with the fan subassembly. When the detector is installed, the detector can drive the fan component to remove dust and cool the test electronic assembly by utilizing the self gravity.

Description

Mounting socket for detector test

Technical Field

The invention belongs to the technical field of detection equipment, and particularly relates to an installation socket for detector testing.

Background

With the development of society, people do not depend on manual work to explore the external environment, but a detector which can adapt to various hard environments replaces manual work to survey.

The existing detector needs to be tested before being put into use, a mounting socket is needed to fix the detector during testing, and the existing mounting socket basically adopts a bolt or an electric telescopic rod to match with a clamping plate to fix the detector.

The existing installation socket can not effectively utilize the self physical property of the detector to remove dust and cool the detection electronic assembly when the detector is fixed, so that the resource waste is caused.

Disclosure of Invention

The embodiment of the invention aims to provide an installation socket for detector testing, and aims to solve the problem that the existing installation socket cannot effectively utilize the physical performance of a detector to remove dust and cool a detection electronic assembly when the detector is fixed, so that the resource is wasted.

The embodiment of the invention is realized in such a way that the mounting socket for the detector test comprises a device body, a mounting mechanism and a placing mechanism for mounting a test electronic assembly, and further comprises:

the dust removal and cooling mechanism is connected with the device body and used for removing dust and cooling the test electronic assembly, the dust removal and cooling mechanism comprises a driving assembly, a driving shaft, a fan assembly and a conversion assembly, the fan assembly is rotatably connected with the device body through a connecting assembly, the conversion assembly comprises a sliding piece B and a sliding groove B arranged on the driving shaft, the sliding piece B is in sliding fit with the sliding groove B, and the sliding piece B is connected with the fan assembly;

the driving component pushes the driving shaft to do linear reciprocating motion in the vertical direction, and the driving shaft extrudes the sliding piece B through the sliding groove B to drive the fan component to do rotary motion in the vertical direction so as to enable the fan component to do dust removal and cooling on the test electronic assembly.

On the basis of the technical scheme, the invention also provides the following optional technical scheme:

the further technical scheme is as follows: the placing mechanism comprises a supporting piece and a sleeve B, the supporting piece is connected with the sleeve B, the sleeve B is in sliding fit with the driving shaft, the supporting piece is connected with the device body, and the supporting piece is connected with the test electronic assembly.

The further technical scheme is as follows: drive assembly includes elastic component A and accepts the seat, accept the seat and be connected with the actuating shaft, elastic component A is located and accepts between seat and the sleeve B, still includes:

and the limiting assembly is connected with the bearing seat and the device body and is used for limiting the bearing seat.

The further technical scheme is as follows: the fan assembly comprises fan blades and a sleeve C, the fan blades are connected with the sleeve C, the sleeve C is rotatably connected with the device body through a connecting assembly, and the sleeve C is connected with the sliding piece B.

The further technical scheme is as follows: installation mechanism includes drive assembly, drive assembly includes driving medium A and pivot A, driving medium A rotates with the device body through pivot A to be connected, still includes:

and the self-adaptive assembly is connected with the transmission part A and is used for fastening the detector.

The further technical scheme is as follows: the limiting assembly comprises a sliding piece C and a sleeve D, an elastic piece C is arranged between the sliding piece C and the sleeve, and the sliding piece C is in sliding fit with a sliding groove D formed in the device body.

The further technical scheme is as follows: coupling assembling includes connecting piece B and roller, connecting piece B and sleeve C sliding fit, spout C has been seted up on the connecting piece B, the roller rotates with spout C to be connected.

The further technical scheme is as follows: the self-adaptation subassembly includes guide, sleeve A and holder, the guide is connected with driving medium A, sleeve A and guide sliding fit, the holder is connected with sleeve A, fixedly connected with slider A on the guide, slider A and sleeve A sliding fit, be provided with elastic component B between slider A and the sleeve A.

According to the mounting socket for the detector test, provided by the embodiment of the invention, the detector utilizes the self gravity to push the driving component to slide along the device body, the driving component further pushes the driving shaft to linearly reciprocate in the device body in the vertical direction, and the sliding chute B arranged on the driving shaft extrudes the sliding part B to drive the fan component to rotate in the vertical direction.

Drawings

FIG. 1 is a schematic view of the distribution of the components of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

FIG. 3 is an enlarged view of the part A structure of the present invention.

Fig. 4 is a schematic structural view of the connecting assembly of the present invention.

Fig. 5 is a schematic structural diagram of a fan assembly according to the present invention.

Notations for reference numerals: the device comprises a mounting mechanism 1, a driving assembly 2, a driving shaft 201, an elastic piece A202, a bearing seat 203, a limiting assembly 204, a transmission assembly 3, a transmission piece A301, a rotating shaft A302, an adaptive assembly 4, a guide piece 401, a sleeve A402, an elastic piece B403, a sliding piece A404, a placing mechanism 5, a support piece 501, a sleeve B502, a connecting piece A503, a dust removal and cooling mechanism 6, a fan assembly 7, fan blades 701, a sleeve C702, a sliding groove A703, a conversion assembly 8, a sliding groove B801, a sliding piece B802, a connecting assembly 9, a connecting piece B901, a rotating shaft B902, a roller 903, a sliding groove C904, a device body 10 and a detector 11.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

Referring to fig. 1 to 2, a mounting socket for a probe test according to an embodiment of the present invention includes a device body 10, a mounting mechanism 1, and a placement mechanism 5 for mounting a test electronic assembly, and further includes:

the dust removal and temperature reduction mechanism 6 is connected with the device body 10 and used for removing dust and reducing temperature of the test electronic assembly, the dust removal and temperature reduction mechanism 6 comprises a driving component 2, a driving shaft 201, a fan component 7 and a conversion component 8, the fan component 7 is rotatably connected with the device body 10 through a connecting component 9, the conversion component 8 comprises a sliding piece B802 and a sliding groove B801 arranged on the driving shaft 201, the sliding piece B802 is in sliding fit with the sliding groove B801, and the sliding piece B802 is connected with the fan component 7;

drive assembly 2 carries out linear sliding along device body 10 under the drive of 11 gravity of detector, and drive assembly 2 carries out linear reciprocating motion in vertical direction through promoting drive shaft 201, and drive shaft 201 extrudes slider B802 through spout B801 and drives fan subassembly 7 and carry out rotary motion's mode in vertical direction and impel fan subassembly 7 to remove dust the cooling to test electronic assembly.

Preferably, the sliding part B802 is spiral, the sliding groove B801 is a spiral groove, and the sliding part B802 is engaged with the sliding groove B801. The purpose of this arrangement is to convert the linear motion of the drive shaft 201 into rotational motion of the fan assembly.

In the embodiment of the present invention, the detector 11 utilizes its own gravity to push the driving component 2 to slide along the device body 10, the driving component 2 further pushes the driving shaft 201 to perform a linear reciprocating motion in the vertical direction in the device body 10, at this time, the sliding slot B801 opened on the driving shaft 201 presses the sliding piece B802 to make the sliding piece B802 drive the fan component 7 to rotate in the vertical direction, and this arrangement is intended to perform dust removal and temperature reduction on the test electronic assembly.

Referring to fig. 1-2, as an embodiment of the present invention, the placing mechanism 5 includes a supporting member 501 and a sleeve B502, the supporting member 501 is fixedly connected to the sleeve B502, the sleeve B502 is slidably engaged with the driving shaft 201, the supporting member 501 is fixedly connected to an inner wall of the apparatus body 10, and the supporting member 501 is fixedly connected to the test electronics assembly through a connecting member a 503.

Preferably, the connecting piece a503 is a bolt. The purpose of this arrangement is to make a detachable connection to the test electronics assembly.

Preferably, the support 501 is a connecting rod. The purpose of this arrangement is to test the electronic assembly for aeration and cooling.

In the embodiment of the invention, the purpose of the arrangement is to place the test electronic assembly, so that the detector 11 is convenient to detect, and meanwhile, the fan component 7 can be used for dedusting and cooling the test electronic assembly.

As an alternative to this embodiment, the placing mechanism 5 may further use a plurality of connecting rods fixedly connected to the inner wall of the device body 10 to fix the test electronic assembly.

Referring to fig. 1-2, as an embodiment of the present invention, the driving assembly 2 includes an elastic member a202 and a socket 203, the socket 203 is fixedly connected to the driving shaft 201, the elastic member a202 is located between the socket 203 and a sleeve B502, and further includes:

and a limiting component 204 connected with the bearing seat 203 and the device body 10 and used for limiting the bearing seat 203.

Preferably, the elastic member a202 is any one of a compression spring, a spring and an elastic steel plate. The purpose of this arrangement is to provide buffer protection for the detector 11.

Preferably, the limiting assembly 204 includes a sliding element C (not shown) and a sleeve (not shown), an elastic element C is disposed between the sliding element C and the sleeve D, and the sliding element C is in sliding fit with a sliding slot D (not shown) formed on the device body 10. The purpose of this arrangement is to limit the receptacle 203 by the engagement of the slider C and the chute D.

Preferably, the sliding member C is a sliding column. The purpose of this arrangement is to snap the slider C into the through hole provided in the chute D.

In the embodiment of the present invention, the bearing seat 203 slides linearly along the sliding slot D under the gravity of the detector 11, and this arrangement is to limit the bearing seat 203 to always slide along the sliding slot D, i.e. to ensure that the driving shaft 201 does not rotate in the vertical direction.

As an alternative of the present invention, the driving assembly 2 may also use the electric telescopic rod to cooperate with the socket 203 to push the driving shaft 201 to perform a linear reciprocating motion in the vertical direction.

Referring to fig. 1, fig. 2 and fig. 5, as an embodiment of the present invention, the blower assembly 7 includes a fan blade 701 and a sleeve C702, the fan blade 701 is fixedly connected to the sleeve C702, the sleeve C702 is rotatably connected to the device body 10 through a connecting assembly 9, and the sleeve C702 is fixedly connected to the sliding member B802.

Preferably, the slider B802 is helical. The purpose of this arrangement is to rotate the sleeve C702.

In the embodiment of the present invention, the fan blade 701 performing the linear reciprocating motion extrudes the sliding member B802 by using the sliding slot B801 arranged thereon, at this time, the sliding member B802 drives the sleeve C702 to perform the reciprocating rotation in the vertical direction, the rotating sleeve C702 further drives the fan blade 701 to perform the reciprocating rotation, when the detector 11 is close to the driving assembly 2, the fan blade 701 rotates forward, at this time, the fan blade 701 blows air to the electronic assembly to perform dust removal on the test electronic assembly, when the detector 11 is far from the driving assembly 2, the fan blade 701 rotates backward, and air in the device body 10 is discharged out of the device body 10 to cool the test electronic assembly.

Referring to fig. 1, 2, 4 and 5, as an embodiment of the present invention, the connecting assembly 9 includes a connecting member B901 and a roller 903, the connecting member B901 is slidably engaged with a sliding groove a703 formed on a sleeve C702, the connecting member B901 is formed with a sliding groove C904, and the roller 903 is rotatably connected to the roller 903 through a rotating shaft B902.

Preferably, the connecting member B901 and the sliding groove a703 are both T-shaped. The purpose of this arrangement is to limit the sleeve C702 from slipping off.

Preferably, the sliding groove C904 is an arc-shaped groove. This arrangement is intended to place the roller 903 and prevent the roller 903 from slipping off.

In the embodiment of the present invention, the purpose of this arrangement is to connect the sleeve C702 to the apparatus body 10 via the connector B901, and to convert the sliding friction between the connector B901 and the sleeve C702 into rolling friction using the roller 903.

Referring to fig. 1 to 3, as an embodiment of the present invention, the mounting mechanism 1 includes a transmission assembly 3, the transmission assembly 3 includes a transmission member a301 and a rotation shaft a302, the transmission member a301 is rotatably connected to the device body 10 through the rotation shaft a302, and further includes:

and the self-adaptive assembly 4 is connected with the transmission piece A301 and used for fastening the detector 11.

Preferably, the transmission member a301 is an L-shaped link. The purpose of this arrangement is to convert the thrust of the socket 203 into the thrust of the adaptive assembly.

In the embodiment of the present invention, the probe 11 presses down the socket 203 by its own weight, the socket 203 pushes the transmission member a301 to rotate around the central axis of the rotation shaft a302, and the two adaptive assemblies 4 clamp and fasten the probe 11, which is designed to mount the probe 11 quickly.

Referring to fig. 2 to 3, as an embodiment of the present invention, the adaptive assembly 4 includes a guide 401, a sleeve a402, and a clamping member 405, the guide 401 is fixedly connected to the transmission member a301, the sleeve a402 is in sliding fit with the guide 401, the clamping member 405 is fixedly connected to the sleeve a402, the guide 401 is fixedly connected to a sliding member a404, the sliding member a404 is in sliding fit with the sleeve a402, and an elastic member B403 is disposed between the sliding member a404 and the sleeve a 402.

Preferably, the guide 401 is a cylinder. The purpose of this arrangement is to reduce the friction between the guide a401 and the sleeve a 402.

Preferably, the sliding member a404 is ring-shaped and a sliding block is fixedly connected thereto. The purpose of this arrangement is to use the slide a404 as a stop for the compression spring B403 and to limit the position of the guide 401.

Preferably, the elastic member B403 is any one of a compression spring, a spring and an elastic steel plate.

Preferably, the clamping member 405 is an arc-shaped plate. The purpose of this arrangement is to increase the contact area of the holder 405 with the detector 11.

In the embodiment of the present invention, the two clamping members 405 move toward each other under the driving of the transmission member a301 to press the detector 11, and at this time, the sliding member a404 fixedly connected to the guide member 401 presses the elastic member B403 to buffer the guide member 401, which is configured to buffer and protect the detector 11.

As an alternative to this embodiment, the adaptive assembly may also use an electric telescopic rod to cooperate with the pressure sensor to clamp and fix the detector 11.

The invention provides the mounting socket for the detector test, the dust removal and cooling mechanism 6 and the mounting mechanism 1 are provided based on the mounting socket, and the technical effect of performing dust removal and cooling on the test electronic assembly by using the self gravity of the detector 11 is achieved by matching the dust removal and cooling mechanism 6 and the mounting mechanism 1.

The above description is only for the specific embodiments of the present disclosure, but the scope of the present disclosure is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present disclosure, and all the changes or substitutions should be covered within the scope of the present disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (8)

1. The utility model provides a probe test is with installation socket, includes device body and the mechanism of placing that is used for installation test electronic assembly, still includes:

the dust removal and cooling mechanism is connected with the device body and used for removing dust and cooling the test electronic assembly, the dust removal and cooling mechanism comprises a driving assembly, a driving shaft, a fan assembly and a conversion assembly, the fan assembly is rotatably connected with the device body through a connecting assembly, the conversion assembly comprises a sliding piece B and a sliding groove B arranged on the driving shaft, the sliding piece B is in sliding fit with the sliding groove B, and the sliding piece B is connected with the fan assembly;

the drive assembly slides linearly along the device body under the drive of the gravity of the detector, the drive assembly moves linearly and reciprocally in the vertical direction by pushing the drive shaft, and the drive shaft extrudes the sliding piece B through the sliding groove B to drive the fan assembly to rotate in the vertical direction so as to enable the fan assembly to remove dust and cool the test electronic assembly.

2. The socket as set forth in claim 1, wherein the placement mechanism comprises a support member and a sleeve B, the support member is connected to the sleeve B, the sleeve B is slidably engaged with the driving shaft, the support member is connected to the device body, and the support member is connected to the test electronics assembly.

3. The socket as claimed in claim 1, wherein the driving assembly includes an elastic member a and a socket, the socket is connected to the driving shaft, the elastic member a is located between the socket and the sleeve B, and further comprising:

and the limiting assembly is connected with the bearing seat and the device body and is used for limiting the bearing seat.

4. The mounting socket for the probe test according to claim 1, wherein the fan assembly comprises a fan blade and a sleeve C, the fan blade is connected with the sleeve C, the sleeve C is rotatably connected with the device body through a connecting assembly, and the sleeve C is connected with the sliding member B.

5. The socket as claimed in claim 1, wherein the mounting mechanism comprises a transmission assembly, the transmission assembly comprises a transmission member a and a rotation shaft a, the transmission member a is rotatably connected to the device body via the rotation shaft a, and the socket further comprises:

and the self-adaptive assembly is connected with the transmission part A and is used for fastening the detector.

6. The mounting socket for the probe test according to claim 3, wherein the limiting assembly comprises a sliding member C and a sleeve D, an elastic member C is arranged between the sliding member C and the sleeve, and the sliding member C is in sliding fit with a sliding groove D formed in the device body.

7. The mounting socket for the probe test according to claim 4, wherein the connecting assembly comprises a connecting member B and a roller, the connecting member B is slidably engaged with the sleeve C, the connecting member B is provided with a sliding groove C, and the roller is rotatably connected with the sliding groove C.

8. The mounting socket for the probe test according to claim 5, wherein the adaptive assembly comprises a guide member, a sleeve A and a clamping member, the guide member is connected with the transmission member A, the sleeve A is in sliding fit with the guide member, the clamping member is connected with the sleeve A, a sliding member A is fixedly connected to the guide member, the sliding member A is in sliding fit with the sleeve A, and an elastic member B is arranged between the sliding member A and the sleeve A.

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