CN220810972U - Sampling device for sampling inspection of sensor - Google Patents

Abstract

The utility model relates to the technical field of sensor detection equipment, and particularly discloses a sensor sampling device, wherein a roller conveying part is arranged at a position between two conveying belts, a first bracket and a second bracket are respectively fixed on two sides of the roller conveying part, a rotary material taking mechanism comprises a horizontal rotating shaft sleeved at the top of the first bracket, a support plate fixed on the peripheral wall of the horizontal rotating shaft, a support rod fixed on the outer end of the support plate, a ring body with the inner edge fixed on the outer end of the support rod, a connecting rod fixed on the peripheral wall of the ring body and an arc-shaped rod with one end fixed on the outer end of the connecting rod, the distance between the arc-shaped rods is the same as that between rollers, a guide mechanism comprises an arc-shaped plate and a plurality of guide rods uniformly fixed on the top end of the arc-shaped plate and extending along the tangential direction of the ring body, the top ends of the guide rods are positioned between two adjacent ring bodies, a material placing groove is fixed at the top of the second bracket, and the bottom end of the arc-shaped plate is tangent with one end of an inner cavity bottom plate of the material placing groove; the problem of inefficiency and unsafe when sampling the sensor is solved.

Description

Sampling device for sampling inspection of sensor

Technical Field

The utility model relates to the technical field of sensor detection equipment, in particular to a sampling device for sampling sensor.

Background

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. The current sensor is a detecting device, can sense the information of the detected current, and can convert the information sensed by detection into an electric signal or other information output in a required form meeting certain standard according to a certain rule so as to meet the requirements of information transmission, processing, storage, display, recording, control and the like.

In the sensor production and manufacturing process, in order to ensure the quality of the sensor, the produced sensor needs to be sampled and detected. Traditionally, the way sensors are sample-detected is: and in the process of conveying the finished product sensor along the conveying belt mechanism, an operator randomly selects and samples the sensor on the conveying belt and uniformly conveys the sensor to a detection station for detection. This sampling is not only inefficient, but also presents a potential hazard that can cause injury to the operator's hands.

Disclosure of utility model

The utility model designs a sampling device for sampling sensor sampling aiming at solving the problems of low efficiency and unsafe sensor sampling at present.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the sensor spot check sampling device, the position between two conveyer belts is installed to cylinder conveying portion, the top of cylinder conveying portion evenly is equipped with the roller that carries the sensor along the fore-and-aft direction, the bottom of support one is fixed in one side of cylinder conveying portion, rotatory feeding mechanism including rotate set in support one top end just is located the horizontal pivot directly over the cylinder conveying portion middle part, along being fixed in along the radial a plurality of extension boards of horizontal pivot peripheral wall, along the axial evenly be fixed in a plurality of branches of extension board outer end, the inner edge be fixed in the branch outer end and with the ring body of horizontal pivot coaxial center, be fixed in ring body outer peripheral wall's connecting rod and one end be fixed in the arc pole of connecting rod outer end, the interval of arc pole with the interval of roller is the same, guiding mechanism include the arc and evenly be fixed in the arc top and follow the tangential direction of ring body extends, the top of guide arm is located adjacent two between the extension board, support two the support conveying portion be fixed in the bottom plate is fixed in two the bottom of support is tangent to the bottom plate, the bottom of cylinder is fixed in the bottom plate is put to the bottom.

Preferably, the cylinder conveying part comprises longitudinal beams which are arranged in parallel in pairs, supporting legs with the top ends fixed to the bottom surfaces of the longitudinal beams and a conveying motor fixed to the outer side wall of one longitudinal beam, two ends of the cylinder are respectively sleeved on the inner sides of the longitudinal beams in a rotating mode, a power output shaft of the conveying motor is in transmission connection with one end of the corresponding cylinder, belt wheels are respectively fixedly sleeved at the corresponding ends of the cylinder, belt wheels are in transmission connection with a transmission belt, and the bottom ends of the first bracket and the second bracket are respectively fixed to the top surfaces of the longitudinal beams on two sides.

Preferably, the connecting rod is fixed on the peripheral wall of the ring body along the radial direction of the ring body, and the arc-shaped rod is concentric with the ring body.

Preferably, six support plates are uniformly fixed on the peripheral wall of the horizontal rotating shaft along the circumferential direction.

Preferably, the outer walls of the arc-shaped rod, the connecting rod and the ring body are all coated with rubber layers.

Compared with the prior art, the utility model has the beneficial effects that:

According to the sensor sampling device, the rotary picking mechanism is driven to rotate by the rotary motor, so that the arc-shaped rod lifts the sensor passing through the roller conveying part from the roller, the lifted sensor is retained on the guide rod along with the integral rotation of the rotary picking mechanism and slides into the storage groove along the guide rod and the arc-shaped plate in sequence, sampling cycle of sampling of one sensor is completed, sampling efficiency is guaranteed, and safety is improved.

Drawings

FIG. 1 is a schematic diagram of the overall front view structure of the present utility model;

FIG. 2 is a schematic perspective view of a rotary take off mechanism according to the present utility model;

Fig. 3 is a schematic perspective view of the guide mechanism of the present utility model.

In the figure: 1-a roller conveying part; 11-stringers; 12-supporting legs; 13-a roller; 14-a conveying motor; 15-pulleys; 16-a transmission belt;

2-a first bracket; 21-a rotating electric machine;

3-rotating the material taking mechanism; 31-a horizontal rotating shaft; 32-supporting plates; 33-supporting rod; 34-ring body; 35-connecting rod; 36-arc-shaped rod;

4-a guiding mechanism; 41-arc-shaped plate; 42-a guide rod;

5-a second bracket;

6-a storage groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1, the utility model provides a technical scheme, a sensor sampling device, a roller conveying part 1 is installed at a position between two conveying belts, the roller conveying part 1 comprises longitudinal beams 11 which are arranged in parallel in pairs, supporting legs 12 with top ends fixed on the bottom surfaces of the longitudinal beams 11, and a conveying motor 14 fixed on the outer side wall of one of the longitudinal beams 11, two ends of a roller 13 are respectively and rotatably sleeved on the inner side of the longitudinal beam 11, a power output shaft of the conveying motor 14 is in transmission connection with one end of a corresponding roller 13, corresponding end parts of the roller 13 are respectively and fixedly sleeved with a belt pulley 15, the belt pulley 15 is in transmission connection with a driving belt 16, and bottom ends of a first bracket 2 and a second bracket 5 are respectively fixed on the top surfaces of the longitudinal beams 11 on two sides. The processed sensor is conveyed along the conveying belt, the sensor is conveyed onto the rollers 13 from the conveying belt on one side of the roller conveying part 1, and all the rollers 13 are driven to synchronously rotate by the conveying motor 14 through the transmission relation of the belt wheels 15 and the transmission belt 16, so that the continuous conveying of the sensor is realized, and the sensor is conveyed onto the conveying belt on the other side to continue conveying.

The bottom of the first bracket 2 is fixed on one side of the roller conveying part 1, the rotary material taking mechanism 3 is rotatably arranged at the end of the top of the first bracket 2, a central shaft of the rotary material taking mechanism 3 is positioned right above the central line of the roller conveying part 1, a rotary motor 21 for driving the rotary material taking mechanism 3 to rotate is arranged on the first bracket 2, the rotary motor 21 adopts a servo motor and uses a PLC (programmable logic controller) for rotation control, the servo motor intermittently rotates, and the motor gap period is adapted to the sampling frequency of sampling of sensor sampling.

The second bracket 5 is fixed on the other side of the roller conveying part 1, and the object placing groove 6 is fixed on the top of the second bracket 5. The storage groove 6 is used for storing sensors for sampling.

Referring to fig. 2-3, the rotary material taking mechanism 3 comprises a horizontal rotating shaft 31 rotatably sleeved at the top end of a bracket 2 and positioned right above the middle part of a roller conveying part 1, a plurality of support plates 32 radially fixed on the outer peripheral wall of the horizontal rotating shaft 31, a plurality of support rods 33 axially and uniformly fixed on the outer ends of the support plates 32, a ring body 34 with the inner edge fixed on the outer ends of the support rods 33 and coaxial with the horizontal rotating shaft 31, a connecting rod 35 fixed on the outer peripheral wall of the ring body 34, and an arc-shaped rod 36 with one end fixed on the outer end of the connecting rod 35, wherein the distance between the arc-shaped rods 36 is the same as the distance between rollers 13;

The guide mechanism 4 comprises an arc-shaped plate 41 and a plurality of guide rods 42 which are uniformly fixed at the top ends of the arc-shaped plate 41 and extend along the tangential direction of the ring bodies 34, and the top ends of the guide rods 42 are positioned between two adjacent ring bodies 34;

The connecting rod 35 is fixed on the peripheral wall of the ring body (34) along the radial direction of the ring body 34, the arc-shaped rod 36 is concentric with the ring body 34, and six support plates 32 are uniformly fixed on the peripheral wall of the horizontal rotating shaft 31 along the circumferential direction.

In summary, the rotating motor 21 directly drives the horizontal rotating shaft 31 to rotate, so that the arc rod 36 rotates, when the arc rod 36 rotates from the gap between the rollers 13 to pass, the sensor located on the rollers 13 is just lifted, and along with the supporting actions of the arc rod 36, the connecting rod 35 and the ring 34, the sensor is rotated to the highest point of the ring 34, and at this time, the sensor slides downwards along the guide rod 42 extending from the gap between the ring 34 and the supporting rod 33; and arc rod 36, link 35, ring 34 continue to rotate through the gaps between guide rods 42, respectively.

The bottom end of the arc-shaped plate 41 is tangent with one end of the bottom plate of the inner cavity of the storage groove 6. The sensor sliding down the arcuate plate 41 eventually slides into the storage slot 6 for further detection for safe access.

In order to avoid scraping and damaging the sensor during sampling of the spot check, the outer walls of the arc-shaped rod 36, the connecting rod 35 and the ring 34 are all coated with rubber layers.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. Sensor sampling device of checking a subset, its characterized in that includes:

A roller conveying part (1), wherein the roller conveying part (1) is arranged at a position between two conveying belts, and rollers (13) for conveying sensors are uniformly arranged at the top of the roller conveying part (1) along the front-back direction;

The first support (2) is fixed at the bottom end of the first support (2) on one side of the roller conveying part (1);

The rotary material taking mechanism (3), the rotary material taking mechanism (3) comprises a horizontal rotating shaft (31) sleeved at the top end of the first bracket (2) in a rotating way and positioned right above the middle part of the roller conveying part (1), a plurality of support plates (32) radially fixed on the outer peripheral wall of the horizontal rotating shaft (31), a plurality of support rods (33) axially and uniformly fixed on the outer ends of the support plates (32), a ring body (34) with the inner edge fixed on the outer ends of the support rods (33) and coaxial with the horizontal rotating shaft (31), a connecting rod (35) fixed on the outer peripheral wall of the ring body (34) and an arc-shaped rod (36) with one end fixed on the outer ends of the connecting rod (35), and the distance between the arc-shaped rods (36) and the distance between the rollers (13) are the same;

The guide mechanism (4) comprises an arc-shaped plate (41) and a plurality of guide rods (42) which are uniformly fixed at the top ends of the arc-shaped plate (41) and extend along the tangential direction of the ring bodies (34), and the top ends of the guide rods (42) are positioned between two adjacent ring bodies (34);

The second bracket (5) is fixed on the other side of the roller conveying part (1); and

The storage groove (6), the storage groove (6) is fixed at the top of the second bracket (5), and the bottom end of the arc plate (41) is tangent with one end of the bottom plate of the inner cavity of the storage groove (6);

And a rotating motor (21) in transmission connection with the horizontal rotating shaft (31) is arranged on the first bracket (2).

2. The sensor spot-check sampling device of claim 1, wherein: the roller conveying part (1) comprises longitudinal beams (11) which are arranged in parallel in pairs, supporting legs (12) with the top ends fixed on the bottom surfaces of the longitudinal beams (11) and conveying motors (14) fixed on the outer side walls of one longitudinal beam (11), two ends of each roller (13) are respectively and rotationally sleeved on the inner sides of the longitudinal beams (11), power output shafts of the conveying motors (14) are in transmission connection with one ends of the corresponding rollers (13), belt wheels (15) are respectively and fixedly sleeved on the corresponding ends of the rollers (13), driving belts (16) are in transmission connection with the belt wheels (15), and the bottom ends of a first bracket (2) and a second bracket (5) are respectively fixed on the top surfaces of the longitudinal beams (11) on two sides.

3. The sensor spot-check sampling device of claim 1, wherein: the connecting rod (35) is fixed on the peripheral wall of the ring body (34) along the radial direction of the ring body (34), and the arc-shaped rod (36) is concentric with the ring body (34).

4. The sensor spot-check sampling device of claim 1, wherein: six support plates (32) are uniformly fixed on the peripheral wall of the horizontal rotating shaft (31) along the circumferential direction.

5. The sensor spot-check sampling device of claim 3, wherein: the outer walls of the arc-shaped rod (36), the connecting rod (35) and the ring body (34) are all coated with rubber layers.