CN117191202A - Wireless collection calculator device - Google Patents

Abstract

The invention relates to the field of temperature acquisition and discloses a wireless acquisition calculator device, which comprises data acquisition units and calculation units, wherein the data acquisition units are in wireless connection with the calculation units; the data acquisition unit comprises a support frame, a plurality of acquisition components are mounted on the support frame, each acquisition component is connected with an adjusting component, and the adjusting component is used for adjusting the wireless acquisition calculator device provided by the invention to be close to the surface to be measured of the piece to be measured one by one in a fitting way or far away from the piece to be measured.

Description

Wireless collection calculator device

Technical Field

The invention relates to the field of temperature acquisition, in particular to a wireless acquisition calculator device.

Background

The existing temperature acquisition means are various, in order to improve the accuracy of temperature data, a temperature sensor is often adopted to detect after a detection probe is positioned in an object to be detected, when accurate temperature acquisition is carried out on some high-temperature or ultra-high-temperature workpieces, a high-temperature resistant probe is often adopted to be attached to the surface of the workpiece to carry out real-time continuous detection, but the temperature of the workpiece is too high, so that the probe can be damaged or the temperature detection sensitivity is reduced after long-time use, and the existing use requirement cannot be met.

Disclosure of Invention

In order to solve the technical problems, the invention provides a wireless acquisition calculator device.

A wireless acquisition calculator device comprises data acquisition units and calculation units, wherein the data acquisition units and the calculation units are in wireless connection;

the data acquisition unit comprises a support frame, a plurality of acquisition components are mounted on the support frame, each acquisition component is connected with an adjusting component, and the adjusting component is used for adjusting each acquisition component to be close to the surface to be measured of the fitting or far away from the piece to be measured one by one.

Further: the collection assembly is installed on the supporting assembly, and the supporting assembly comprises a supporting shaft, the supporting shaft is fixedly installed on the supporting frame, each collection assembly is fixedly connected with the supporting shaft, and each collection assembly is distributed in a circumferential array around the supporting shaft.

Further: the acquisition assembly comprises a support and a rotating shaft, the support is fixedly connected with the supporting shaft, the rotating shaft is rotatably arranged on the support, the rotating shaft and the supporting shaft are distributed in a vertical mode, one end of the rotating shaft is connected with the acquisition module, the other end of the rotating shaft is connected with the transmission assembly, and the transmission assembly and the adjusting assembly are correspondingly arranged.

Further: the transmission assembly comprises a gear and a rack, the gear is fixedly connected with the end part of the rotating shaft, the rack is meshed with the gear, the rack, the rotating shaft and the supporting shaft are vertically distributed, the rack is slidably mounted on the support along the length direction of the rack, one end of the rack is connected with a spring, the spring is used for applying elastic force pointing to the supporting shaft to the rack, and the rack and the adjusting assembly are correspondingly arranged.

Further: the rack is far away from spring one end and has the passive piece, and passive piece and adjusting part correspond to arrange.

Further: the acquisition module comprises an elastic telescopic rod group, the elastic telescopic rod group comprises a fixed sleeve rod, the fixed sleeve rod is fixedly arranged at the end part of the rotating shaft, the fixed sleeve rod and the rotating shaft are distributed in a vertical mode, the fixed sleeve rod is internally arranged on a telescopic rod, two ends of the telescopic rod extend out of the fixed sleeve rod, one end of the telescopic rod is arranged on a sensor, and the fixed sleeve rod and the adjusting assembly are correspondingly arranged.

Further: the adjusting component comprises a sleeve shaft, the sleeve shaft is sleeved on the supporting shaft, an A triggering piece and a B triggering piece are arranged on the sleeve shaft, the A triggering piece and the driven piece are correspondingly arranged, the B triggering piece and the end part of the telescopic rod are correspondingly arranged, the A triggering piece is used for propping against the driven piece to drive the driven piece to be far away from the supporting shaft, and the B triggering piece is used for propping against the telescopic rod to drive the telescopic rod to move downwards.

Further: the A trigger piece is provided with an abutting inclined surface and an A maintaining surface, wherein the abutting inclined surface is used for abutting the driven piece to drive the driven piece to move along the direction away from the supporting shaft, and the A maintaining surface is used for maintaining the driven piece to be in a state away from the supporting shaft. Preferably: the passive element has a ramp surface that mates with the abutment ramp surface.

Further: the trigger piece B comprises a pressing inclined surface and a maintaining surface B, the pressing inclined surface is used for propping against the end part of the telescopic rod to drive the telescopic rod to move downwards, and the maintaining surface B is used for maintaining the telescopic rod to be in a pressing state.

The invention has the beneficial effects that: the wireless acquisition calculator device provided by the invention can realize the alternate lamination type detection of the high-temperature and ultra-high-temperature to-be-detected piece, can accurately detect the temperature data of the to-be-detected piece, and simultaneously can avoid the problem that the sensor is damaged or scrapped due to the fact that the sensor is alternately far away from the to-be-detected piece by adjusting the sensor.

Drawings

Fig. 1 is a schematic structural diagram of a data acquisition unit in a wireless acquisition calculator device according to the present invention;

FIG. 2 is a schematic diagram of the structure of an acquisition component in a wireless acquisition calculator device according to the present invention;

FIG. 3 is a schematic diagram of a transmission assembly in a collection assembly of a wireless collection calculator device according to the present invention;

FIG. 4 is a schematic top view of a B trigger in a collection assembly of a wireless collection calculator device according to the present invention;

fig. 5 is a schematic top view of an a trigger in an acquisition assembly in a wireless acquisition calculator device according to the present invention.

In the figure: 100. a support frame; 110. a drive assembly; 200. an adjustment assembly; 210. a support assembly; 220. a support shaft; 230. a sleeve shaft; 231. a trigger piece A; 232. a trigger piece B; 300. a collection assembly; 310. a bracket; 320. a rotating shaft; 330. fixing the loop bar; 340. a telescopic rod; 350. a sensor; 360. a passive member; 370. a rack; 380. a gear; 390. and (3) a spring.

Detailed Description

The subject matter described herein will now be discussed with reference to example embodiments. It should be appreciated that these embodiments are discussed so that those skilled in the art will better understand and realize the subject matter described herein. Changes may be made in the function and arrangement of elements discussed without departing from the scope of the disclosure as set forth in the specification. Various examples may omit, replace, or add various procedures or components as desired. In addition, features described with respect to some examples may be combined in other examples as well.

Example 1

Referring to fig. 1 to 5, in this embodiment, a wireless acquisition calculator device is provided, which includes data acquisition units and calculation units, where the data acquisition units and the calculation units are connected wirelessly;

the data acquisition unit comprises a support frame 100, a plurality of acquisition assemblies 300 are mounted on the support frame 100, each acquisition assembly 300 is connected with an adjusting assembly 200, and the adjusting assembly 200 is used for adjusting each acquisition assembly 300 to be close to a surface to be measured of a fitting piece or away from the surface to be measured one by one.

The collection assemblies 300 are mounted on the support assemblies 210, the support assemblies 210 comprise support shafts 220, the support shafts 220 are fixedly mounted on the support frame 100, the collection assemblies 300 are fixedly connected with the support shafts 220, and the collection assemblies 300 are distributed in a circumferential array around the support shafts 220.

The collection assembly 300 comprises a support 310 and a rotating shaft 320, the support 310 is fixedly connected with the supporting shaft 220, the rotating shaft 320 is rotatably installed on the support 310, the rotating shaft 320 and the supporting shaft 220 are vertically distributed, one end of the rotating shaft 320 is connected with the collection module, the other end of the rotating shaft 320 is connected with the transmission assembly, and the transmission assembly and the adjusting assembly 200 are correspondingly arranged.

The transmission assembly comprises a gear 380 and a rack 370, the gear 380 is fixedly connected with the end part of the rotating shaft 320, the rack 370 is meshed with the gear 380, the rack 370, the rotating shaft 320 and the supporting shaft 220 are vertically distributed, the rack 370 is slidably mounted on the bracket 310 along the length direction of the rack 370, one end of the rack 370 is connected with a spring 390, the spring 390 is used for applying elastic force pointing to the supporting shaft 220 to the rack 370, and the rack 370 and the adjusting assembly 200 are correspondingly arranged.

The end of the rack 370 remote from the spring 390 has a passive member 360, the passive member 360 being disposed in correspondence with the adjustment assembly 200.

The collection module comprises an elastic telescopic rod group, the elastic telescopic rod group comprises a fixed sleeve rod 330, the fixed sleeve rod 330 is fixedly arranged at the end part of the rotating shaft 320, the fixed sleeve rod 330 and the rotating shaft 320 are vertically distributed, the fixed sleeve rod 330 is internally provided with a telescopic rod 340, two ends of the telescopic rod 340 extend out of the fixed sleeve rod 330, one end of the telescopic rod 340 is provided with a sensor 350, and the fixed sleeve rod 330 and the adjusting assembly 200 are correspondingly arranged.

The adjusting assembly 200 comprises a sleeve shaft 230, the sleeve shaft 230 is sleeved on the supporting shaft 220, an A trigger piece 231 and a B trigger piece 232 are installed on the sleeve shaft 230, the A trigger piece 231 and a driven piece 360 are correspondingly arranged, the B trigger piece 232 and the end part of the telescopic rod 340 are correspondingly arranged, the A trigger piece 231 is used for abutting against the driven piece 360 to drive the driven piece 360 to be far away from the supporting shaft 220, the B trigger piece 232 is used for abutting against the telescopic rod 340, and the telescopic rod 340 is driven to move downwards. The sleeve shaft 230 is connected to the driving assembly 110, the driving assembly 110 is mounted on the supporting frame 100, and the driving assembly 110 is used for driving the sleeve shaft 230 to rotate.

The a trigger 231 has an abutment inclined surface for abutting against the passive member 360 to drive the passive member 360 to move in a direction away from the support shaft 220, and an a maintaining surface for maintaining the passive member 360 in a state away from the support shaft 220. Preferably: the passive element has a ramp surface that mates with the abutment ramp surface.

The B trigger 232 includes a push-down ramp for urging the telescoping rod 340 downward against the end of the telescoping rod 340 and a B retaining surface for retaining the telescoping rod 340 in a depressed state.

In this embodiment, the supporting frame 100 is mounted on a mechanical arm, the workpiece to be tested is a high-temperature workpiece, and continuous temperature data acquisition work needs to be performed on a side plane of the workpiece to be tested, and the specific working process is as follows:

firstly, the mechanical arm transfers the support frame 100 to the vicinity of the plane to be measured of the workpiece to be measured, adjusts the support shaft 220 to be perpendicular to the plane to be measured of the workpiece to be measured, and then adjusts the support frame 100 to be close to the plane to be measured, so that the sensor thereon is attached to the plane to be measured, and it should be noted that: in this case, one of the collection assemblies 300 is that the sensor 350 is located on a side far from the support 100, and the sensor 350 is attached to the plane to be measured.

Then, the driving assembly 110 is started to drive the sleeve shaft 230 to rotate, the sleeve shaft 230 drives the A trigger piece 231 and the B trigger piece 232 to rotate at a constant speed, firstly, the A trigger piece 231 contacts with the passive piece 360 in the next group of collecting assemblies 300 and abuts against the passive piece 360, the passive piece 360 drives the rack 370 to synchronously move, the rack 370 compresses the spring 390, the rack 370 drives the gear 380 to rotate, the gear 380 drives the rotating shaft 320 to rotate, after the rotating shaft 320 rotates 180 degrees, the sensor 350 rotates to a position close to a plane to be measured, at the moment, the passive piece 360 contacts with the maintaining surface of the A trigger piece 231, the rack 370 maintains a motionless state, at the moment, the sensor 350 is in a state close to the plane to be measured, the telescopic rod 340 is in a state perpendicular to the plane to be measured, along with the rotation of the sleeve shaft 230, the end of the B trigger piece 232 contacts with the telescopic rod 340 and abuts against the telescopic rod 340, the telescopic rod 340 moves downwards to drive the sensor 350 to be close to and abut against the plane to be measured, and after the sensor 350 abuts against the plane to be measured, the maintaining surface of the B trigger piece 232 contacts with the telescopic rod 340 to maintain an abutting state.

It should be noted that: after the collection assembly 300 is turned over by the sensor 350 and attached to the plane to be tested, the previous group of sensors 350 is separated from the trigger A231 and the trigger B232, the sensor 350 is far away from the plane to be tested under the restoring action of the elastic telescopic rod group, and the rotating shaft 320 is regulated to rotate by the rack 370 and the gear 380 under the restoring force of the spring 390, so that the purpose that the sensor 350 is far away from the plane to be tested is realized, and the sensor 350 is far away from the plane as far as possible Wen Daice for heat dissipation and cooling treatment.

The above steps are repeated, so that the sensors 340 can be adjusted one by one and are turned over and attached to the plane to be measured, and the sensors 350 can be adjusted one by one and turned over and away from the plane to be measured, thereby not only ensuring real-time collection of temperature data of the plane to be measured, but also avoiding the problem that the sensors 350 are damaged due to long-time contact between the sensors 350 and the high-temperature plane.

Example 2

The difference between this embodiment and embodiment 1 is that the telescopic rod 340 is an elastic rod, and when detecting an irregular surface to be detected of the piece to be detected, the purpose that each sensor 340 can be attached to the surface to be detected after being turned over is achieved through elastic expansion and contraction of the elastic rod.

The embodiment of the present embodiment has been described above with reference to the accompanying drawings, but the embodiment is not limited to the above-described specific implementation, which is merely illustrative and not restrictive, and many forms may be made by those of ordinary skill in the art without departing from the spirit of the embodiment and the scope of the protection of the claims, which fall within the protection of the embodiment.

Claims (10)

1. A wireless acquisition calculator device comprises data acquisition units and calculation units, wherein the data acquisition units and the calculation units are in wireless connection; the data acquisition unit is characterized by comprising a support frame (100), wherein a plurality of acquisition assemblies (300) are arranged on the support frame (100), each acquisition assembly (300) is connected with an adjusting assembly (200), and the adjusting assembly (200) is used for adjusting each acquisition assembly (300) to be close to a surface to be measured, which is attached to or far away from a piece to be measured, one by one.

2. The wireless acquisition calculator device according to claim 1, wherein the acquisition assemblies (300) are mounted on a support assembly (210), the support assembly (210) comprises a support shaft (220), the support shaft (220) is fixedly mounted on the support frame (100), each acquisition assembly (300) is fixedly connected with the support shaft (220), and each acquisition assembly (300) is distributed in a circumferential array around the support shaft (220).

3. The wireless acquisition calculator device according to claim 2, wherein the acquisition assembly (300) comprises a bracket (310) and a rotating shaft (320), the bracket (310) is fixedly connected with the supporting shaft (220), the rotating shaft (320) is rotatably installed on the bracket (310), the rotating shaft (320) and the supporting shaft (220) are vertically distributed, one end of the rotating shaft (320) is connected with the acquisition module, the other end of the rotating shaft (320) is connected with the transmission assembly, and the transmission assembly and the adjusting assembly (200) are correspondingly arranged.

4. A wireless acquisition calculator device according to claim 3, wherein the transmission assembly comprises a gear (380) and a rack (370), the gear (380) is fixedly connected with the end part of the rotating shaft (320), the rack (370) is meshed with the gear (380), the rack (370) is vertically distributed with the rotating shaft (320) and the supporting shaft (220), the rack (370) is slidably mounted on the bracket (310) along the length direction of the rack, one end of the rack (370) is connected with a spring (390), the spring (390) is used for applying an elastic force pointing to the supporting shaft (220) to the rack (370), and the rack (370) and the adjusting assembly (200) are correspondingly arranged.

5. The wireless acquisition calculator device according to claim 4, wherein the end of the rack (370) far away from the spring (390) is provided with a passive member (360), and the passive member (360) and the adjusting assembly (200) are correspondingly arranged.

6. The wireless acquisition calculator device according to claim 5, wherein the acquisition module comprises an elastic telescopic rod group, the elastic telescopic rod group comprises a fixed sleeve rod (330), the fixed sleeve rod (330) is fixedly arranged at the end part of the rotating shaft (320), the fixed sleeve rod (330) and the rotating shaft (320) are vertically distributed, the fixed sleeve rod (330) is internally arranged on a telescopic rod (340), two ends of the telescopic rod (340) extend out of the fixed sleeve rod (330), one end of the telescopic rod (340) is arranged on the sensor (350), and the fixed sleeve rod (330) and the adjusting assembly (200) are correspondingly arranged.

7. The wireless acquisition calculator device according to claim 6, wherein the adjusting assembly (200) comprises a sleeve shaft (230), the sleeve shaft (230) is sleeved on the supporting shaft (220), an A trigger piece (231) and a B trigger piece (232) are installed on the sleeve shaft (230), the A trigger piece (231) and the driven piece (360) are correspondingly arranged, the B trigger piece (232) and the end part of the telescopic rod (340) are correspondingly arranged, the A trigger piece (231) is used for abutting against the driven piece (360), the driven piece (360) is driven to be far away from the supporting shaft (220), the B trigger piece (232) is used for abutting against the telescopic rod (340), and the telescopic rod (340) is driven to move downwards. The sleeve shaft (230) is connected with the driving assembly (110), the driving assembly (110) is arranged on the supporting frame (100), and the driving assembly (110) is used for driving the sleeve shaft (230) to rotate.

8. The wireless acquisition calculator device of claim 7, wherein the a trigger (231) has an abutment ramp for urging the passive member (360) against the passive member (360) in a direction away from the support shaft (220), and an a-maintaining surface for maintaining the passive member (360) in a state away from the support shaft (220).

9. The wireless acquisition calculator device of claim 8, wherein the passive member has a ramp that mates with the abutment ramp.

10. The wireless acquisition calculator device of claim 7, wherein the B trigger (232) includes a push down ramp for urging the telescoping rod (340) downward against an end of the telescoping rod (340) and a B holding surface for holding the telescoping rod (340) in a depressed state.