CN220871778U - Mounting structure of production facility data acquisition sensor - Google Patents

Abstract

The utility model relates to a mounting structure of a data acquisition sensor of production equipment, which comprises a mounting block, a mounting groove arranged on the front surface of the mounting block, a data acquisition sensor arranged in the mounting groove, a lifting component arranged on the back surface of the mounting block and used for adjusting the height of the mounting block, a quick fixing component arranged in the mounting block and with two ends of an output end penetrating into the mounting groove and the outside of the back surface of the mounting block respectively and used for quickly fixing the data acquisition sensor and connected with the driving end of the lifting component, and a heat dissipation component arranged on two sides of the output end of the data acquisition sensor opposite to the quick fixing component and used for dissipating heat; according to the utility model, the rapid fixing assembly is arranged, so that the data acquisition sensor can be more rapidly installed and detached, the threaded rod does not need to be rotated for installation and detachment, and the efficiency is improved.

Description

Mounting structure of production facility data acquisition sensor

Technical Field

The utility model relates to the field of equipment data acquisition sensors, in particular to a mounting structure of a production equipment data acquisition sensor.

Background

Currently, there are various types of sensors on the market that are applied in various fields. The sensor is a detecting device, which can sense the information to be measured and convert the sensed information into electric signals or other information output in the required form according to a certain rule so as to meet the requirements of information transmission, processing, storage, display, recording, control and the like.

When production equipment works, various data acquisition sensors are required to acquire data of corresponding articles in production, so that the platform is convenient for storing the data, but the existing data acquisition sensors are inconvenient to install and detach, and the overall efficiency of data acquisition of the production equipment is low for workers.

In the prior art, a quick mounting structure of a production equipment data acquisition sensor is disclosed, and although the problem is solved, the quick mounting structure is still inconvenient when being mounted and dismounted more complicated through screw rotation, so that the efficiency is not greatly improved.

Disclosure of utility model

The utility model aims to overcome the defects of the prior art and provide a mounting structure of a data acquisition sensor of production equipment.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a production facility data acquisition sensor's mounting structure, contain the installation piece, set up at the positive mounting groove of installation piece, set up the data acquisition sensor in the mounting groove, set up at the installation piece back be used for adjusting the lifting unit of installation piece height, set up in the installation piece and the output both ends run through respectively to the mounting groove and the installation piece back outside be used for the quick fixed data acquisition sensor and with the quick fixed subassembly that lifting unit drive end is connected, set up at the data acquisition sensor just to be used for radiating subassembly to quick fixed subassembly output both sides.

Preferably, the quick fixing assembly comprises two first sliding grooves arranged in the mounting block and positioned at two sides of the mounting groove, two fixing sliding blocks, two second sliding grooves and four telescopic rods, wherein one end of each fixing sliding block is arranged in the two first sliding grooves in a sliding manner, the other end of each fixing sliding block penetrates through the back surface of the mounting block and is opposite to the driving end of the lifting assembly in a flat U shape, the two second sliding grooves are arranged in the mounting block and positioned between the two first sliding grooves, and the other ends of the middle parts of the inner walls of the two fixing sliding blocks respectively penetrate through the second sliding grooves and are opposite to each other; two tension springs for pulling the four telescopic rods inwards to the second sliding groove are arranged between the two telescopic rods which are opposite to each other; two telescopic rods on the same side of the four telescopic rods are connected with one end of the telescopic rods, which is positioned in the second sliding chute, through a connecting rod; a driving rod is vertically arranged in the middle part between the two connecting rods in the second sliding groove, and the other end of the driving rod penetrates through the top surface of the mounting block; a connecting plate is hinged between two sides of the driving rod and the two connecting rods respectively; the driving rod is arranged at one end of the top surface of the mounting block and can rotate, and limiting blocks are arranged on two sides of the driving rod; arc-shaped fixing seats are arranged on the top surface of the mounting block and positioned on two sides of the driving rod; one surface of the two arc-shaped fixing seats, which is opposite to the driving rod, is provided with a limiting chute for inserting and rotating the two limiting blocks in an L shape; the upper ends of the rotation end points of the two limiting sliding grooves are provided with limiting clamping grooves for clamping the two limiting blocks; the two groups of heat dissipation components are respectively and correspondingly provided with a first fixing slot for inserting the two fixing sliding blocks.

Preferably, the lifting assembly comprises a bottom plate, a threaded rod vertically arranged in the middle of the top surface of the bottom plate, guide rods vertically arranged on the top surface of the bottom plate and positioned on two sides of the threaded rod, a top plate arranged on the top ends of the two guide rods and mutually parallel to the bottom plate, lifting sliding blocks connected to the threaded rod in a threaded manner and sleeved on the two guide rods at two ends, and second fixing slots arranged on the end surfaces of two sides of the lifting sliding blocks and used for inserting the two fixing sliding blocks; one end of the threaded rod penetrates through the top plate and is provided with a hand wheel.

Preferably, the heat dissipation assembly comprises two heat dissipation plates arranged on two sides of the data acquisition sensor opposite to the two fixed sliding blocks and two heat dissipation silica gel arranged on the data acquisition sensor and the two heat dissipation plates respectively; a plurality of ventilation pore channels are arranged on the two radiating plates and are communicated with each other; the two radiating plates are correspondingly provided with first fixing slots for inserting the two fixing sliding blocks.

Preferably, a plurality of arc-shaped grooves are formed at one end of each of the two fixed sliding blocks, which is inserted into the first fixed slot; and anti-skid patterns are arranged on two sides, which are attached to the inner wall of the second fixed slot, of one end of the two fixed sliding blocks, which are inserted into the second fixed slot.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages:

According to the utility model, the rapid fixing assembly is arranged, so that the data acquisition sensor can be more rapidly installed and detached, the threaded rod does not need to be rotated for installation and detachment, and the efficiency is improved.

Drawings

The technical scheme of the utility model is further described below with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of the overall structure of a production facility data acquisition sensor mounting structure of the present utility model when the data acquisition sensor is fixed;

FIG. 2 is a schematic cross-sectional top view of the installation structure of the data acquisition sensor of the production facility according to the present utility model;

FIG. 3 is a schematic structural view of a quick fixing assembly for a mounting structure of a data acquisition sensor of a production facility according to the present utility model;

FIG. 4 is a schematic diagram showing the overall structure of the installation structure loosening data acquisition sensor of the production equipment according to the present utility model;

fig. 5 is a schematic view of a partial enlarged structure at a position a of an installation structure diagram of a data acquisition sensor of a production facility according to the present utility model.

Wherein: 1. a mounting block; 2. a mounting groove; 3. a data acquisition sensor; 4. a lifting assembly; 41. a bottom plate; 42. a threaded rod; 43. a guide rod; 44. a top plate; 45. a lifting slide block; 46. a second fixed slot; 47. a hand wheel; 5. a quick-fix assembly; 5a, a first chute; 5b, fixing a sliding block; 5c, a second chute; 5d, a telescopic rod; 5e, a tension spring; 5f, connecting rods; 5g, driving rod; 5h, connecting the plates; 5i, limiting blocks; 5j, an arc-shaped fixing seat; 5k, limiting sliding grooves; 5l, limiting clamping grooves; 6. a heat dissipation assembly; 61. a heat dissipation plate; 62. radiating silica gel; 63. a ventilation duct; 7. a first fixed slot; 8. an arc-shaped groove; 9. anti-skid lines.

Detailed Description

The utility model will be described in further detail with reference to the accompanying drawings and specific examples.

Fig. 1-5 are mounting structures of data acquisition sensors of production equipment, which are disclosed by the utility model, and comprise a mounting block 1, a mounting groove 2 arranged on the front surface of the mounting block 1, a data acquisition sensor 3 arranged in the mounting groove 2, a lifting component 4 arranged on the back surface of the mounting block 1 and used for adjusting the height of the mounting block 1, a quick fixing component 5 arranged in the mounting block 1 and penetrating through the mounting groove 2 and the outer part of the back surface of the mounting block 1 at two ends of an output end respectively and used for quickly fixing the data acquisition sensor 3 and connected with the driving end of the lifting component 4, and a heat dissipation component 6 arranged on two sides of the output end of the data acquisition sensor 3 opposite to the quick fixing component 5 and used for dissipating heat; the quick fixing assembly 5 comprises two first sliding grooves 5a which are arranged in the mounting block 1 and are positioned at two sides of the mounting groove 2, two fixing sliding blocks 5b which are arranged in the two first sliding grooves 5a in a sliding manner, one end of the output end of the fixing sliding block is opposite to the other end of the mounting groove 2, and penetrates through the back surface of the mounting block 1, and is opposite to the driving end of the lifting assembly 4, two second sliding grooves 5c which are arranged in the mounting block 1 and are positioned between the two first sliding grooves 5a, and four telescopic rods 5d which are respectively and horizontally arranged at the other ends of the middle parts of the inner walls of the two fixing sliding blocks 5b, and are opposite to each other, and penetrate through the second sliding grooves 5 c; two tension springs 5e for pulling the four telescopic rods 5d inwards towards the second sliding groove 5c are arranged between the two telescopic rods 5d which are opposite to each other; two telescopic rods 5d on the same side are connected with one another through a connecting rod 5f, wherein the two telescopic rods are positioned at one end in the second chute 5 c; a driving rod 5g is vertically arranged in the middle part between the two connecting rods 5f in the second chute 5c, and the other end of the driving rod 5g penetrates through the top surface of the mounting block 1; a connecting plate 5h is hinged between two sides of the driving rod 5g and the two connecting rods 5f respectively; the driving rod 5g is positioned at one end of the top surface of the mounting block 1 and can rotate, and limiting blocks 5i are arranged on two sides of the driving rod; arc-shaped fixing seats 5j are arranged on the top surface of the mounting block 1 and positioned on two sides of the driving rod 5 g; one surface of the two arc-shaped fixing seats 5j, which is opposite to the driving rod 5g, is provided with a limiting chute 5k for inserting and rotating the two limiting blocks 5i into an L shape; the upper ends of the rotation end points of the two limiting sliding grooves 5k are provided with limiting clamping grooves 5l for clamping the two limiting blocks 5i; the two groups of heat dissipation assemblies 6 are respectively provided with a first fixed slot 7 for inserting the two fixed sliding blocks 5b correspondingly; the lifting assembly 4 comprises a bottom plate 41, a threaded rod 42 vertically arranged in the middle of the top surface of the bottom plate 41, guide rods 43 vertically arranged on the top surface of the bottom plate 41 and positioned on two sides of the threaded rod 42, top plates 44 arranged on the top ends of the two guide rods 43 and parallel to the bottom plate 41, lifting sliding blocks 45 connected to the threaded rod 42 in a threaded manner and sleeved on the two guide rods 43 at two ends, and second fixing slots 46 arranged on the end surfaces of two sides of the lifting sliding blocks 45 and used for inserting the two fixing sliding blocks 5 b; one end of the threaded rod 42 penetrates through the top plate 44 and is provided with a hand wheel 47; the heat dissipation assembly 6 comprises two heat dissipation plates 61 arranged on two sides of the data acquisition sensor 3 opposite to the two fixed sliding blocks 5b and two heat dissipation silica gel 62 respectively arranged on the data acquisition sensor 3 and the two heat dissipation plates 61; a plurality of ventilation holes 63 are formed in the two radiating plates 61, and the ventilation holes 63 are communicated with each other; the two heat dissipation plates 61 are correspondingly provided with first fixing slots 7 for inserting the two fixing sliders 5 b.

Further, a plurality of arc-shaped grooves 8 are formed at one end of each of the two fixed sliding blocks 5b inserted into the first fixed slot 7; the two sides of one end of the two fixed sliding blocks 5b inserted into the second fixed slot 46, which are attached to the inner wall of the second fixed slot 46, are provided with anti-skid patterns 9, so that ventilation pore channels are prevented from being blocked and anti-skid is prevented.

When in use, the utility model is characterized in that: by pressing down the driving rod 5g, the driving rod 5g drives the connecting plate 5h to push the connecting rod 5f to two sides, the connecting rod 5f drives the telescopic rod 5d to move, the telescopic rod 5d drives the fixed sliding block 5b to move in the direction away from the installation groove 2, when the limiting block 5i at the top of the driving rod 5g is moved to a designated position, the limiting block 5i is inserted into the limiting chute 5k of the arc-shaped fixed seat 5j, then the driving rod 5g is rotated to enable the limiting block 5i to be inserted into the terminal of the limiting chute 5k, because the driving rod 5g is extruded by the tension spring 5e to move upwards, the limiting block 5i is clamped into the limiting clamping groove 5l, then the data acquisition sensor 3 is placed into the installation groove 2, then the rotating end limiting block 5i of the driving rod 5g is separated from the limiting chute 5k, the fixed slide block 5b is reset by the tension of the tension spring 5e and is respectively inserted into the first fixed slot 7 of the radiating plate 61 and the second fixed slot 46 of the lifting slide block 45, so that the data acquisition sensor 3 is quickly fixed in the reinstallation groove 2, the heat of the data acquisition sensor 3 is absorbed through the heat radiation silica gel 62 during operation, and then the heat is dissipated through a plurality of ventilation holes 63 on the radiating plate 61, so that quick heat dissipation is realized, when the size of a product is reduced or increased and the height of the installation block 1 needs to be adjusted, the threaded rod 42 is driven to rotate by rotating the hand wheel, the lifting slide block 45 is driven to move by the threaded rod 42, the installation block 1 is driven to move by the lifting slide block 45 through the quick fixing component 5 which is mutually connected with the lifting slide block, and the hand wheel 47 is stopped rotating after the movement to a designated position.

The foregoing is merely a specific application example of the present utility model, and the protection scope of the present utility model is not limited in any way. All technical schemes formed by equivalent transformation or equivalent substitution fall within the protection scope of the utility model.

Claims (4)

1. The utility model provides a mounting structure of production facility data acquisition sensor which characterized in that: the device comprises a mounting block, a mounting groove arranged on the front surface of the mounting block, a data acquisition sensor arranged in the mounting groove, a lifting assembly arranged on the back surface of the mounting block and used for adjusting the height of the mounting block, a quick fixing assembly arranged in the mounting block and with two ends of an output end penetrating into the mounting groove and the outside of the back surface of the mounting block respectively and used for quickly fixing the data acquisition sensor and being connected with the driving end of the lifting assembly, and a heat dissipation assembly arranged on two sides of the output end of the data acquisition sensor and opposite to the quick fixing assembly and used for dissipating heat; the quick fixing assembly comprises two first sliding grooves which are arranged in the mounting block and are positioned on two sides of the mounting groove, two fixing sliding blocks which are arranged in the two first sliding grooves in a sliding manner, one end of the output end of the fixing sliding block is right opposite to the other end of the mounting groove, penetrates through the back surface of the mounting block and is right opposite to the driving end of the lifting assembly, two second sliding grooves which are arranged in the mounting block and are positioned between the two first sliding grooves, and four telescopic rods which are respectively and horizontally arranged in the middle of the inner walls of the two fixing sliding blocks, are all penetrated into the second sliding grooves and are right opposite to each other; two tension springs for pulling the four telescopic rods inwards to the second sliding groove are arranged between the two telescopic rods which are opposite to each other; two telescopic rods on the same side of the four telescopic rods are connected with one end of the telescopic rods, which is positioned in the second sliding chute, through a connecting rod; a driving rod is vertically arranged in the middle part between the two connecting rods in the second sliding groove, and the other end of the driving rod penetrates through the top surface of the mounting block; a connecting plate is hinged between two sides of the driving rod and the two connecting rods respectively; the driving rod is arranged at one end of the top surface of the mounting block and can rotate, and limiting blocks are arranged on two sides of the driving rod; arc-shaped fixing seats are arranged on the top surface of the mounting block and positioned on two sides of the driving rod; one surface of the two arc-shaped fixing seats, which is opposite to the driving rod, is provided with a limiting chute for inserting and rotating the two limiting blocks in an L shape; the upper ends of the rotation end points of the two limiting sliding grooves are provided with limiting clamping grooves for clamping the two limiting blocks; the two groups of heat dissipation components are respectively and correspondingly provided with a first fixing slot for inserting the two fixing sliding blocks.

2. The mounting structure of a production facility data acquisition sensor according to claim 1, wherein: the lifting assembly comprises a bottom plate, a threaded rod vertically arranged in the middle of the top surface of the bottom plate, guide rods vertically arranged on the top surface of the bottom plate and positioned on two sides of the threaded rod, a top plate arranged on the top ends of the two guide rods and mutually parallel to the bottom plate, lifting sliding blocks connected to the threaded rod in a threaded manner and sleeved on the two guide rods at two ends, and second fixing slots arranged on the end surfaces of two sides of the lifting sliding blocks and used for inserting the two fixing sliding blocks; one end of the threaded rod penetrates through the top plate and is provided with a hand wheel.

3. The mounting structure of a production facility data collection sensor according to claim 2, wherein: the heat dissipation assembly comprises two heat dissipation plates arranged on two sides of the data acquisition sensor opposite to the two fixed sliding blocks and two heat dissipation silica gel arranged on the data acquisition sensor and the two heat dissipation plates respectively; a plurality of ventilation pore channels are arranged on the two radiating plates and are communicated with each other; the two radiating plates are correspondingly provided with first fixing slots for inserting the two fixing sliding blocks.

4. A mounting structure of a production facility data acquisition sensor according to claim 3, characterized in that: a plurality of arc-shaped grooves are formed at one end of each of the two fixed sliding blocks, which is inserted into the first fixed slot; and anti-skid patterns are arranged on two sides, which are attached to the inner wall of the second fixed slot, of one end of the two fixed sliding blocks, which are inserted into the second fixed slot.