CN210132400U - Grinding machine tool with random eccentric orbit motion speed detection - Google Patents

Abstract

The utility model discloses a grinding machine tool that utensil eccentric orbit velocity of motion detected at will, this grinding machine tool contain a body and a abrasive disc, and this body contains a drive shaft and one and connects this abrasive disc and this drive shaft has the instrument keeper of an eccentric distance relatively, and this abrasive disc grinds with an eccentric orbit motion at will when this drive shaft rotates. Wherein, the grinding disc is provided with at least one detected piece for detecting the speed of the random eccentric orbit motion on one side facing the body, and the at least one detected piece defines a detection area with a range larger than or equal to two times of the eccentric distance. Therefore, the accurate speed of the grinding disc during random eccentric orbit motion can be obtained, and the grinding operation can be controlled more accurately by the automatic precision grinding gradually.

Description

Grinding machine tool with random eccentric orbit motion speed detection

Technical Field

The present invention relates to a grinding machine tool, and more particularly to a grinding machine tool having a grinding pad defining a detection range for detecting a random eccentric orbit motion speed.

Background

A power tool for performing a grinding operation or a polishing operation is generally called a grinding machine tool, and the driving mode and the movement mode of a grinding disc belonging to the grinding machine tool can be mainly divided into three types, which will be explained below.

Referring to fig. 1, a first driving method is to directly connect a driving shaft 311 of a motor 31 to the polishing disc 30, and since direct driving is adopted, the number of Revolutions Per Minute (RPM) of the polishing disc 30 is equal to the rotation speed of the driving shaft 311, and only the rotation speed of the driving shaft 311 needs to be obtained when the rotation speed of the polishing disc 30 is to be detected. On the other hand, in this driving method, each point on the polishing disk 30 moves concentrically with respect to the drive shaft 311, and the movement locus is shown by an arrow 40 in fig. 2. Such a drive is also known from US 2005/0245183.

Referring to fig. 3, a second driving method is to mount the grinding disc 30 on an eccentric shaft 32 eccentric to the driving shaft 311, the eccentric shaft 32 has an eccentric distance 321 relative to the driving shaft 311, the eccentric shaft 32 is connected to the driving shaft 311 through a tool holder 33, wherein the tool holder 33 is a bearing. Furthermore, at least one Rotation restricting member 34 is further disposed between the polishing disc 30 and the driving shaft 311, the Rotation restricting member 34 is made of an elastic material, the Rotation restricting member 34 restricts the polishing disc 30 from performing only eccentric orbital Motion relative to the driving shaft 311 but not Free Rotation Motion (Free Rotation Motion), and a Motion trajectory of the polishing disc 30 is shown in fig. 4. Further, any point on the polishing disc 30 performs an eccentric orbit motion relative to the driving shaft 311, and the moving radius is equal to the eccentric distance 321. In this driving manner, the polishing disc 30 is synchronized with the driving shaft 311, that is, the speed of the polishing disc 30 is equal to the rotation speed of the driving shaft 311. Therefore, the number of eccentric movements per minute (OPM) of the polishing disc 30 to be obtained only needs to obtain the rotation speed of the driving shaft 311.

Referring to fig. 5, the third driving method is similar to the second driving method, but the third driving method does not have the rotation limiting member 34, and related patents can be found in U.S. Pat. nos. US6,004,197, US6,979,254, and US6,855,040. The grinding disc 30 and the driving shaft 311 do not have a direct linkage relationship, the rotation of the grinding disc 30 is realized by rotating the motor 31 to a certain speed, and an Inertial Centrifugal Force (inertia Centrifugal Force) is generated on the eccentric shaft 32 to drive the grinding disc 30 to rotate. The rotation speed of the grinding disc 30 increases with the rotation speed of the driving shaft 311, but does not exceed the maximum rotation speed of the driving shaft 311. However, when the rotation speed of the driving shaft 311 is reduced or stopped, the kinetic energy stored in the polishing disc 30 can still drive the polishing disc 30 to continue rotating until the stored kinetic energy is consumed. Furthermore, when the grinding disc 30 is driven to rotate by the inertial centrifugal force, in addition to performing a Rotation Motion (Rotation Motion) around the eccentric shaft 32, the eccentric distance 321 exists between the eccentric shaft 32 and the driving shaft 311, so that the grinding disc 30 simultaneously generates an eccentric orbit Motion (Orbital Motion), and the Motion trajectory formed by the two motions added together is shown in fig. 4. In addition, the grinding plate 30 performs a revolving Motion (Revolution Motion) relative to the driving shaft 311 substantially simultaneously, and the resultant Motion of the three motions is called a Random eccentric orbit Motion (Random Orbital Motion), and the Motion trajectory is shown in fig. 6. Accordingly, in this driving structure, the revolution motion and the eccentric orbit motion of the polishing disc 30 are always synchronized with the rotation speed of the driving shaft 311, but since the eccentric shaft 32 is eccentrically coupled to the driving shaft 311 via the tool holder 33, when the polishing disc 30 contacts the surface of the object to be polished, the rotation speed of the polishing disc 30 is reduced by the resistance generated by the contact. Furthermore, the shape of the surface of the object to be polished, the angular contact pressure between the polishing disc 30 and the surface of the object to be polished, and the polishing material used in the polishing disc 30 all generate different resistances, thereby reducing the rotation speed of the polishing disc 30. As a result, the rotation speed of the grinding disc 30 and the rotation speed of the eccentric orbit have a great difference compared to the rotation speed of the driving shaft 311 during the operation, and the difference changes continuously and rapidly during the operation, so it is very difficult to detect the Random Orbital motion times Per Minute (ROPM) of the grinding disc 30.

Further, although there are many polishing tools with rotation speed detection proposed by the manufacturers, in practice, the manufacturers regard the rotation speed of the driving shaft 311 as the rotation speed of the polishing disc 30. If the grinding machine tool is driven by the third driving method, the actual rotation speed of the grinding disk 30 cannot be accurately grasped, and the grinding operation is affected. Furthermore, with the advancement of technology, industrial precision polishing is being developed to be automated, i.e., the polishing machine tool is disposed on a robot, which is controlled accurately by precise values, so that the rotation speed of the driving shaft 311 is regarded as the rotation speed of the polishing disc 30, which cannot be precisely controlled.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main purpose, the problem of solving the current unable random eccentric orbit velocity of motion that detects the abrasive disc.

To achieve the above object, the present invention provides a grinding machine tool with random eccentric orbit motion speed detection, the grinding machine tool comprising a body and a grinding disc, the body comprising a driving shaft and a tool holder connected to the grinding disc and having an eccentric distance with respect to the driving shaft, the grinding disc being capable of grinding with a random eccentric orbit motion when the driving shaft rotates. Wherein, the grinding disc is provided with at least one detected piece for detecting the random eccentric orbit motion speed on one side facing the body, and the at least one detected piece defines a detection area with a range larger than or equal to two times of the eccentric distance.

In one embodiment, the polishing disk is provided with a single detected piece, and two opposite sides of the detected piece define a detection area with a range larger than or equal to two times of the eccentric distance.

In one embodiment, the detected pieces are located on the same extension line, one of the detected pieces is located in the center of the detection area, and two of the detected pieces are respectively arranged at intervals with the detected piece located in the center by the eccentric distance.

In one embodiment, the polishing tool has an active detecting member facing the polishing disc, and the active detecting member does not change position to detect the detected member and output a detection signal when the polishing disc performs the random eccentric orbit motion. Furthermore, the active detection part is arranged on one side of the body facing the grinding disc, or the active detection part is hung outside the body through a connecting part.

In one embodiment, the active detecting element has an output portion for emitting a detecting wave toward the detected element and a receiving portion for receiving the detecting wave reflected by the detected element and outputting the detecting signal, wherein the detecting wave is one selected from the group consisting of a light, a radio wave and a sound wave.

In one embodiment, the active detection element generates the detection signal based on the intensity of the magnetic field varied by the detection element.

In one embodiment, the grinding tool has an information processing module connected to the active detection element and generating a rotational speed data of random eccentric orbit motion per minute based on the detection signal. Furthermore, the information processing module comprises a waveform processing unit and an arithmetic processing unit connected with the waveform processing unit, and the arithmetic processing unit analyzes a detection waveform signal output by the waveform processing unit to generate the random eccentric orbit motion speed data per minute.

In one embodiment, the active detecting element is disposed on a side of the body facing the polishing disc, and the information processing module is disposed in the body and connected to the active detecting element.

Through the utility model discloses above-mentioned embodiment, compare in current following characteristics of having: the utility model discloses in order to locate this abrasive disc on at least should be defined out this detection area that the scope is greater than or equal to this eccentric distance of twice by the detection piece, make this abrasive disc carry out this random eccentric orbital motion's speed can be detected out, make automation equipment can obtain more accurate control on exquisite industry grinds, increase the executable grinding operation of automation equipment.

Drawings

FIG. 1 is a schematic diagram of a first type of conventional polishing tool drive configuration.

FIG. 2 is a schematic diagram of a motion trace of a polishing disc of a first type of driving structure of a conventional polishing tool.

FIG. 3 is a schematic diagram of a second type of conventional polishing tool.

FIG. 4 is a schematic diagram of a motion trace of a polishing disc of a second type of driving structure of a conventional polishing tool.

Fig. 5 is a schematic diagram of a third type of driving structure of a conventional polishing tool.

Fig. 6 is a schematic diagram of a motion track of a polishing disc of a third type of driving structure of a conventional polishing tool.

Fig. 7 is a schematic structural view (a) of the grinding machine tool of the present invention.

Fig. 8 is a schematic top view of the polishing disk of the present invention.

Fig. 9 is a schematic top view of the polishing disk of the present invention.

Fig. 10 is a schematic structural view of the grinding machine tool of the present invention (ii).

Fig. 11 is a schematic view (a) of the operation of the polishing disc of the present invention.

Fig. 12 is a schematic view (ii) of the operation of the polishing disc of the present invention.

Fig. 13 is a schematic unit view (one) of the grinding machine of the present invention.

Fig. 14 is a schematic diagram (ii) of a unit of the grinding machine tool of the present invention.

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Detailed Description

The detailed description and technical contents of the present invention are described below with reference to the accompanying drawings:

referring to fig. 7 and 8, the present invention provides a grinding machine tool 10, wherein the grinding machine tool 10 can be configured on an automated machine tool (not shown), such as a robot. Further, the grinding machine tool 10 of the present invention can be used for polishing operations as well as grinding operations. The grinding machine tool 10 includes a main body 11 and a grinding disc 12, the main body 11 includes a power assembly 111, a driving shaft 112 driven by the power assembly 111 and a tool holder 113 connected to the grinding disc 12, and the power assembly 111 may be implemented pneumatically or electrically. Further, the driving shaft 112 is formed with an eccentric mass 114, and the tool holder 113 is provided on the eccentric mass 114 to be eccentric with respect to the driving shaft 112. Specifically, the driving shaft 112 has a first axis 115, the tool holder 113 has a second axis 116 offset from the first axis 115, and an eccentric distance 117 is provided between the first axis 115 and the second axis 116. In this way, the abrasive disc 12 mounted on the tool holder 113 is eccentric with respect to the drive shaft 112. Furthermore, the tool holder 113 may be implemented by a single bearing or a combination of multiple bearings, the grinding disc 12 has a mounting member 121 assembled with the tool holder 113, and the mounting member 121 may be a cylindrical structure engaged with the tool holder 113. Accordingly, as the drive shaft 112 rotates, the grinding disk 12 rotates in a Random eccentric Orbital motion (Random Orbital motion).

Referring to fig. 7 and 8, the polishing disc 12 is provided with at least one detected member 122 on a side facing the main body 11, and the at least one detected member 122 defines a detection area 123 with a range greater than or equal to two times the eccentric distance 117. Accordingly, the number of the detected members 122 can be adjusted according to the implementation of the present invention. As shown in fig. 8, when only a single detected object 122 is disposed on the polishing platen 12, the detection area 123 is defined by two sides of the detected object 122. Referring to fig. 9, when the polishing platen 12 is provided with a plurality of the detected members 122, the range of the detection area 123 is defined based on two opposite edges of the detected members 122. Further, when there are a plurality of the detected elements 122, the detected elements 122 may be arranged and regularly distributed in the detection area 123. For example, as shown in fig. 9, the detected members 122 are located on the same extension line 124, one of the detected members 122 is located at the center of the detection area 123, and two of the detected members 122 are respectively spaced apart from the one of the detected members 122 located at the center by the eccentric distance 117.

Referring to fig. 7 and 13 again, the grinding machine tool 10 includes an active detecting element 118, the active detecting element 118 faces the grinding disc 12 to detect the detected element 122, and outputs a detecting signal 21. Furthermore, the active detecting element 118 of the present invention can be disposed on a robot arm, or be hung outside the body 11 by a connecting element, or be disposed on a side of the body 11 facing the polishing disc 12 (as shown in fig. 10). The active detecting element 118 does not change its position when the grinding disc 12 performs the random eccentric orbit motion, that is, the active detecting element 118 does not track the detected element 122 during the rotation of the grinding disc 12, but waits for the detected element 122 to pass in situ. Furthermore, when the polishing disc 12 is not rotated and the active detecting element 118 directly faces the detecting region 123, the projected position of the active detecting element 118 is located at the center of the detecting region 123. In one embodiment, the distance between the driving shaft 112 and the active detecting element 118 is equal to the distance between the mounting element 121 and the center point of the detecting area 123. In addition, the active detecting element 118 is designed to be located on the motion track of the detecting region 123, so that the detected element 122 can be detected by the active detecting element 118 every time the polishing disc 12 rotates one turn relative to the main body 11. Referring to fig. 10 and 11, when the polishing platen 12 is provided with a plurality of the detected objects 122, the position of the polishing platen 12 is not changed continuously during the random eccentric orbit motion of the polishing platen 12, and the active detecting element 118 does not always detect the same detected object 122, but randomly senses one of the detected objects 122 based on the current state of the polishing platen 12.

Referring to fig. 14, in an embodiment, the active detecting element 118 has an output portion 119 for emitting a detecting wave 20 toward the detected element 122 and a receiving portion 110 for receiving the detecting wave 20 reflected by the detected element 122 and outputting the detecting signal 21. Wherein the detection wave 20 is one selected from the group consisting of a light, a radio wave, and a sound wave.

In the embodiment, the at least one detected element 122 is a reflecting element, and the active detecting element 118 is an optical transceiver. Further, the detection wave 20 may be infrared or laser. In practice, the active detecting element 118 is controlled to project the light toward the polishing disc 12, when the polishing disc 12 rotates to the detecting area 123 facing the active detecting element 118, the detected element 122 in the detecting area 123 reflects the light, so that the active detecting element 118 can receive the reflected light and output the detecting signal 21. Accordingly, the present embodiment can be applied to a place without strong interference with the light source in the polishing environment. On the other hand, taking the detecting wave 20 as the Radio wave for explanation, the Radio wave may be referred to as Radio Frequency, so in this embodiment, the detected element 122 and the active detecting element 118 may be implemented in a Radio Frequency Identification (Radio Frequency Identification) architecture. Further, the detected element 122 is a radio frequency tag, and the active detecting element 118 is a radio frequency reader. In practice, the active detecting element 118 may be configured to send a radio frequency signal to the polishing disc 12 for a long time, and when the detected element 122, which is the radio frequency tag, enters the reading range of the active detecting element 118, the active detecting element 118 completes reading and outputs the detecting signal 21. The present embodiment can be applied to a place where there is no strong interference with radio waves during polishing work. Furthermore, when the detection wave 20 is the sound wave, the detected object 122 may be a structure causing the surface of the polishing platen 12 to be uneven, or an object having a different acoustic impedance from the polishing platen 12, and the active detecting element 118 is a sound wave detecting element. In operation, the active detector 118 emits the sound wave to the polishing platen 12 for a long time, the sound wave generates different reflected waves depending on the surface state of the polishing platen 12 or the acoustic impedance of the polishing platen 12, and the active detector 118 generates different signals based on the reflected waves and outputs the detection signal 21.

In addition to the above, the active detecting element 118 of the present invention can also generate the detecting signal 21 based on the magnetic field intensity changed by the detected element 122. For example, the detected element 122 is a magnet, and the active detecting element 118 is a hall detecting element. In practice, when the detected member 122 passes through the active detecting member 118, the detected member 122, which is the magnet, enables the active detecting member 118 to detect the magnetic field with increased intensity, and the active detecting member 118 converts the magnetic signal into an electrical signal and outputs the detection signal 21. Accordingly, the present embodiment can be applied to the polishing operation in which the polishing object is made of a non-metal material. In addition to the above, the detected element 122 and the active detecting element 118 can be implemented by a proximity Switch (proximity Switch) structure. Specifically, the detected member 122 is an iron sheet, and the active detecting member 118 is composed of an exciting coil and a magnetic field variation signal detecting unit. In practice, the exciting coil is energized to create a magnetic field, the detected object 122 will cause magnetic loss when passing through the magnetic field, and the magnetic field variation signal detection unit generates different detection signals 21 due to the impedance variation derived from the magnetic loss, and obtains the rotation speed of the random eccentric orbit motion according to the difference of the detection signals 21. In addition, the embodiment can be applied to places without other high-frequency signal interference in the grinding environment.

Referring to fig. 13, the grinding machine tool 10 may further include an information processing module 13 connected to the active detecting element 118 and generating a rotational speed data of random eccentric orbit motion per minute based on the detection signal 21, and the information processing module 13 may be disposed on the robot or in a control device for managing the operation of the robot. In addition, in the embodiment where the active detection element 118 is disposed in the body 11, the information processing module 13 can also be assembled in the body 11. Furthermore, in one embodiment, the information processing module 13 may be designed to have the ability to control the opening and closing of the active detection element 118. The information processing module 13 may be in information connection with an external electronic device in a wired or wireless manner, so as to transmit the random eccentric orbit per minute rotation speed data to the external electronic device, so that the external electronic device can perform relative work management based on the random eccentric orbit per minute movement rotation speed data, and the external electronic device may be the control device in one embodiment. Referring to fig. 13 again, in an embodiment, the information processing module 13 may include a waveform processing unit 131 and an operation processing unit 132 connected to the waveform processing unit 131, and the waveform processing unit 131 mainly functions to perform noise filtering on the detection signal 21 output by the active detection element 118 and output a detection waveform signal 133 to the operation processing unit 132. Further, the waveform processing unit 131 may be a digital filter. After the arithmetic processing unit 132 receives the detection waveform signal 133, the arithmetic processing unit 132 generates the random eccentric orbit motion speed data per minute based on the pre-written program operation. Accordingly, the information processing module 13 can be implemented by a plurality of electronic components that generate electrical connection relationships.

Therefore, the utility model provides a can carry out this technological means that random eccentric orbital motion's speed detected to this abrasive disc 12, solve present unable detection and only can estimate with this drive shaft 112 rotational speed probably, lead to the unable accurate control's of automation equipment on exquisite industry grinds problem.

Naturally, the present invention can be embodied in many other forms without departing from the spirit or essential attributes thereof, and it should be understood that various changes and modifications can be made by one skilled in the art without departing from the spirit or essential attributes thereof, and it is intended that all such changes and modifications be considered as within the scope of the appended claims.

Claims (18)

1. A grinding machine tool with random eccentric orbital motion speed detection, the grinding machine tool comprising a body and a grinding disk, the body comprising a drive shaft and a tool holder connected to the grinding disk and having an eccentric distance relative to the drive shaft, the grinding disk grinding in a random eccentric orbital motion as the drive shaft rotates, the grinding machine tool characterized by:

the grinding disc is provided with at least one detected piece for detecting the speed of the random eccentric orbit motion on one side facing the body, and the at least one detected piece defines a detection area with a range larger than or equal to two times of the eccentric distance.

2. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 1, wherein said grinding disc is provided with a single detected member, and two opposite sides of said detected member define a detection area with a range greater than or equal to two times said eccentric distance.

3. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 1, wherein said detected members are located on the same extension line, one of said detected members is located at the center of said detection area, and two of said detected members are spaced apart from one of said detected members located at the center by said eccentric distance, respectively.

4. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 1, 2 or 3, wherein said grinding machine tool has an active detection member facing said grinding disc, and said active detection member does not change position to detect said detected member and output a detection signal while said grinding disc performs said optionally eccentric orbital motion.

5. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 4, wherein the grinding machine tool has an information processing module coupled to the active detection element and generating an optionally eccentric orbital motion speed per minute data based on the detection signal.

6. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 4, wherein said active detection member has an output portion for emitting a detection wave toward said detected member and a receiving portion for receiving said detection wave reflected by said detected member and outputting said detection signal, said detection wave being one selected from the group consisting of a light, a radio wave and a sound wave.

7. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 4, wherein the projected position of said active detection member when said grinding disk is not rotating is located at the center of said detection area.

8. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 7, wherein said active detection member is disposed on said body on a side facing said grinding disk.

9. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 4, wherein the active detection element generates the detection signal based on the magnetic field strength changed by the detected element.

10. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 9 wherein said active detection member is disposed on said body on a side facing said grinding disk.

11. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 4, wherein said active detection member is disposed on said body on a side facing said grinding disk.

12. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 11, wherein said active detection member has an output portion for emitting a detection wave toward said detected member and a receiving portion for receiving said detection wave reflected by said detected member and outputting said detection signal, said detection wave being one selected from the group consisting of a light, a radio wave, and a sound wave.

13. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 11, wherein the active detection element generates the detection signal based on the magnetic field strength changed by the detected element.

14. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 12, wherein the grinding machine tool has an information processing module coupled to the active sensing element and generating an optionally eccentric orbital motion speed per minute data based on the sensing signal.

15. The grinding machine tool of claim 14 wherein the information processing module comprises a waveform processing unit and an arithmetic processing unit connected to the waveform processing unit, and the arithmetic processing unit analyzes a detected waveform signal outputted from the waveform processing unit to generate the random eccentric orbital motion speed per minute data.

16. The grinding machine tool with optionally eccentric orbital motion speed detection of claim 4 wherein said active detection member is externally suspended from said body by a connecting member.

17. The grinding machine tool with optionally eccentric orbital motion speed detection as claimed in claim 16, wherein said active detection member is disposed on a side of said body facing said grinding disc, said grinding machine tool having an information processing module connected to said active detection member and generating a rotational speed data of said optionally eccentric orbital motion per minute based on said detection signal, said information processing module being disposed in said body and connected to said active detection member.

18. The grinding machine tool of claim 17 wherein the information processing module comprises a waveform processing unit and an arithmetic processing unit connected to the waveform processing unit, and the arithmetic processing unit analyzes a detected waveform signal outputted from the waveform processing unit to generate the random eccentric orbital motion speed per minute data.

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