CN209706782U - A kind of measuring device for the parallel surface difference in height measuring workpiece - Google Patents
A kind of measuring device for the parallel surface difference in height measuring workpiece Download PDFInfo
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- CN209706782U CN209706782U CN201920891802.4U CN201920891802U CN209706782U CN 209706782 U CN209706782 U CN 209706782U CN 201920891802 U CN201920891802 U CN 201920891802U CN 209706782 U CN209706782 U CN 209706782U
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Abstract
The utility model discloses a kind of measuring devices of parallel surface difference in height for measuring workpiece, which includes: connecting shaft and spherical bearing, and spherical bearing is set in the lower end of connecting shaft;First measuring block, for the first of workpiece the face contact to be measured, the first measuring block is equipped with the first mounting hole, and spherical bearing is mounted in the first mounting hole;Second measuring block, for the second of workpiece the face contact to be measured, the second measuring block can be connected in the first measuring block up or down, and the second measuring block is than the first measuring block elder generation contact workpiece;Displacement sensor, shell are connected with the second measuring block, and detector is contacted with the first measuring block.The measuring device can be adaptively adjusted the state to coincide to the lower end surface of two measuring blocks and the tested surface of workpiece, it completely eliminates due to the lower end surface of measuring block and the not parallel caused measured deviation of the tested surface of workpiece side, also, eliminate the complicated procedures of forming for manually adjusting measuring device.
Description
Technical field
The utility model relates to the size detection technical fields of workpiece, high more particularly to a kind of parallel surface for measuring workpiece
Spend the measuring device of difference.
Background technique
When measuring the size of some workpiece (such as concave character type workpiece, convex workpiece etc.), it is parallel to need to measure workpiece two
Difference in height between face.
When measurement, two tested surfaces of the lower end surface and workpiece that need measuring mechanism are overlapped as far as possible, can just make to measure
Be worth closer to true value, but this point it is difficult to ensure that.When especially carrying out on-line measurement, the workpiece of measurement may have tens of thousands of, several
100000 is even millions of a, and the lower end surface of measuring mechanism is all overlapped with the tested surface of workpiece when not can guarantee each measurement.
In view of this, how to guarantee that the lower end surface of measuring mechanism is overlapped with the tested surface of workpiece always, to accurately measure
Difference in height between two parallel surface of workpiece out, is those skilled in the art's technical issues that need to address.
Utility model content
In order to solve the above technical problems, the utility model provides a kind of measurement dress of parallel surface difference in height for measuring workpiece
It sets, the measuring device includes:
Connecting shaft and spherical bearing, the spherical bearing are set in the lower end of the connecting shaft;
First measuring block, for the first of workpiece the face contact to be measured, first measuring block be equipped with the first mounting hole, institute
Spherical bearing is stated to be mounted in first mounting hole;
Second measuring block, for the second of workpiece the face contact to be measured, second measuring block can be connected in up or down
First measuring block, and second measuring block is than first measuring block elder generation contact workpiece;
Displacement sensor, shell are connected with second measuring block, and detector is contacted with first measuring block.
The measuring device has the following technical effect that: can be adaptively adjusted the lower end surface to two measuring blocks and workpiece
The state that tested surface coincides, so as to thoroughly eliminate due to the lower end surface of measuring block and the tested surface of workpiece side is not parallel leads
The measured deviation of cause to improve the accuracy of measurement, also, eliminates the complicated procedures of forming for manually adjusting measuring device, from
And improve measurement efficiency.
Measuring device as described above, first measuring block include matrix and the supporter that is located above described matrix,
First measuring block is additionally provided with the second mounting hole and through-hole, and second mounting hole is located at the lower end of described matrix, described logical
The top surface of hole from the supporter is penetrated through to second mounting hole, and second installation is protruded into the upper end of second measuring block
Hole;The measuring device further includes the connecting column for being through at the through-hole and the mounting portion for being supported in the supporter, the connection
The upper end of column is connected with the mounting portion, lower end is connected with second measuring block.
The hole wall of measuring device as described above, second mounting hole is equipped with First terrace, when second measurement
Block is moved upwards up to inconsistent with the First terrace when extreme position.
Measuring device as described above, the mounting portion include the mounting plate being supported on the supporter top surface and are located at
Mounting bracket below the mounting plate outer rim, the mounting plate are equipped with centre bore, and the connecting shaft passes through the centre bore, institute
The shell of displacement sensors is installed on the mounting bracket.
Measuring device as described above, the measuring device further include the first spring, and described matrix is equipped with spring base hole, institute
The lower end and second mounting hole for stating spring base hole penetrate through, and first spring is located at the spring base hole interior and upper end and institute
State the top surface contact of spring base hole, lower end is contacted with second measuring block.
Measuring device as described above, first mounting hole are located at the upper end of described matrix, first mounting hole
Hole wall is equipped with the second step face inconsistent with the outer ring lower end of the spherical bearing, and the measuring device further includes the first limit
Plate, first limit plate are fixed on described matrix and partially cover the upper aperture of first mounting hole;The measuring device
It further include the second limit plate, second limit plate is fixed on the connecting shaft and offsets with the inner ring lower end of the spherical bearing
Touching, and the periphery of the connecting shaft is equipped with the third step surface inconsistent with the inner ring upper end of the spherical bearing.
Measuring device as described above, first measuring block include multiple supporters, and each supporter is surround
The connecting shaft successively arranged for interval, first limit plate include central plate and are located at multiple points of the central plate outer rim
Plate, the scoreboard are protruded into correspondingly in the clearance space between the two adjacent supporters.
Measuring device as described above, the measuring device further include the interconnecting piece for connecting robot, the connection
Portion is connected in the upper end of the connecting shaft.
Measuring device as described above, the interconnecting piece include connector sleeve and connecting pin, and the connector sleeve is coated at described
Connecting shaft, the peripheral wall two sides of the connector sleeve are equipped with the elongated hole vertically extended, and the connecting shaft is equipped with pin
Hole, the connecting pin sequentially pass through an elongated hole, the pin hole and another elongated hole, the connecting shaft are enable to exist
It is moved up and down in the inner hole of the connector sleeve.
Measuring device as described above, the measuring device further include second spring, and the second spring is coated at described
Connecting shaft and between the interconnecting piece and first limit plate.
Detailed description of the invention
Fig. 1 is a kind of structural schematic diagram of specific embodiment of measuring device provided by the utility model;
Fig. 2 is the main view of Fig. 1;
Fig. 3 is the sectional view along A-A of Fig. 2 and the schematic diagram of concave workpiece;
Fig. 4 is the structural schematic diagram of the first measuring block in specific embodiment;
Fig. 5 is the cross-sectional view of the first measuring block in specific embodiment;
Fig. 6 is the structural schematic diagram of the second limited block in specific embodiment;
Fig. 7 is the structural schematic diagram of connector sleeve in specific embodiment.
Wherein, the reference numerals are as follows into Fig. 7 by Fig. 1:
01 concave workpiece;
101 connecting shafts, 102 spherical bearings, 103 first measuring blocks, 1031 matrixes, 1032 supporters, 104 second measurements
Block, 105 displacement sensors, 1051 shells, 1052 detectors, 106 connecting columns, 107 mounting portions, 1071 mounting plates, 1072 installations
Bracket, 108 first limit plates, 1081 central plates, 1082 scoreboards, 109 second limit plates, 110 first springs, 111 interconnecting pieces,
1111 connector sleeves, 1112 connecting pins, 112 second springs, 113 clump weights;
The first mounting hole of a, the second mounting hole of b, c connecting hole, d through-hole, e spring base hole, f elongated hole;
S1 First terrace, S2 second step face, S3 third step surface.
Specific embodiment
In order to make those skilled in the art more fully understand the technical solution of the utility model, with reference to the accompanying drawing
The technical solution of the utility model is described in further detail with specific embodiment.
Please refer to figs. 1 to 4, and Fig. 1 is a kind of specific embodiment of measuring device provided by the utility model and concave work
The structural schematic diagram of part;Fig. 2 is the main view of Fig. 1;Fig. 3 is the sectional view along A-A of Fig. 2 and the schematic diagram of concave workpiece;Fig. 4 is
The structural schematic diagram of first measuring block in specific embodiment;Fig. 5 is the cross-sectional view of the first measuring block in specific embodiment;Fig. 6 is
The structural schematic diagram of second limited block in specific embodiment;Fig. 7 is the structural schematic diagram of connector sleeve in specific embodiment.
The measuring device includes connecting shaft 101, spherical bearing 102, the first measuring block 103, the second measuring block 104 and displacement
Sensor 105.
Wherein, the first measuring block 103 is for the first face contact to be measured with workpiece, and the first measuring block 103 is equipped with the
One mounting hole a.In figure, workpiece is concave workpiece 01, and the first tested surface of concave workpiece is higher-height in its two parallel surface
Face.It should be noted that workpiece is not limited to concave workpiece, for example it can also be convex workpiece or other tools there are two flat
The workpiece in row face.
Wherein, spherical bearing 102 is set in the lower end of connecting shaft 101 and is mounted in the first mounting hole a, specifically,
The inner ring and connecting shaft 101 of spherical bearing 102 are connected, and the outer ring of spherical bearing 102 and the first measuring block 103 are connected.Spherical axis
A certain amount of opposite swing can be generated by holding between 102 outer rings and inner ring, be that those skilled in the art are ripe in view of spherical bearing 102
The component known, its structure that details are not described herein.
Wherein, the second measuring block 104 can be connected in the first measuring block 103 up or down, and the second measuring block 104 is used for
With the second face contact to be measured of workpiece.In figure, the second tested surface of concave workpiece 01 is a lower height of face in its two parallel surface.
Also, the first contact workpiece of 104 to the first measuring block of the second measuring block 103, this specifically can be by according to workpiece shapes adjustment the
The height of the lower end surface of the height of the lower end surface of one measuring block 103 and the second measuring block 104 is realized, for example, when workpiece for measurement is
When the concave workpiece 01 of diagram, make the lower end surface of the second measuring block 104 lower than 103 lower end surface preset distance of the first measuring block
Make the first contact workpiece of the second measuring block 104.
Wherein, displacement sensor 105 is detection part well known to those skilled in the art comprising shell 1051 and from shell
The detector 1052 that body 1051 extends out.The detector 1052 of displacement sensor 105 is contacted with the first measuring block 103, shell
1051 are connected with the second measuring block 104, in this way, when opposite first measuring block 103 of the second measuring block 104 moves up and down, detection
First 1052 also can be flexible with respect to shell 1051 therewith, so that the internal signal for triggering displacement sensor 105 changes, displacement is passed
The internal control unit of sensor 105 knows the displacement of detector 1052 according to the variation of internal signal.
Illustrate the measurement process of measuring device by taking Fig. 3 as an example:
Workpiece is located at the lower section of measuring device, and driving measuring device moves down, when moving down into certain altitude, the second measurement
Second face contact to be measured of block 104 and workpiece, under the conflict effect of workpiece, the second measuring block 104 is moved up, and makes the second survey
Relative displacement variation is generated between gauge block 104 and the first measuring block 103, correspondingly, being respectively connected to the displacement sensor 105 of the two
Shell 1051 and detector 1052 between also generate relative displacement variation, so that the registration of displacement sensor 105 be made to start to become
Change.
As measuring device continues to move down, the first face contact to be measured of the first measuring block 103 and workpiece, due to first
The right side of tested surface be higher than left side, so the right side stress of the first measuring block 103 be greater than left side, force the first measuring block 103 with
And each component being connected with the first measuring block 103 is (including the second measuring block 104, displacement sensor 105 and spherical bearing 102
Outer ring) it deflects to the left together, when the lower end surface for deflecting into the first measuring block 103 is overlapped with the first tested surface of workpiece, first is surveyed
The left and right sides stress of gauge block 103 reaches balance, no longer deflects.
When due to the deflection of the first measuring block 103, the second measuring block 104 also synchronous deflection therewith, so when the first measuring block
When 103 lower end surface is overlapped with the first tested surface, the lower end surface of the second measuring block 104 is also to be overlapped with the second tested surface, this
When, under the restriction effect of two coincidence faces, relative displacement is no longer generated between the second measuring block 104 and the first measuring block 103
Variation, correspondingly, being respectively connected to also no longer generate phase between the shell 1051 and detector 1052 of the displacement sensor 105 of the two
The registration of change in displacement, thus displacement sensor 105 is maintained in a stable registration, the stable registration and displacement sensor
The absolute value of the difference of 105 initial registration is the difference in height of two parallel surface of workpiece.
It should be noted that the initial registration of displacement sensor 105 can return to zero, and in the state of zeroing, displacement sensor
The absolute value of 105 aforementioned stable registration is the difference in height of two parallel surface of workpiece.
As above, which can be adaptively adjusted to the lower end surface of two measuring blocks and the tested surface of workpiece and coincide
State, so as to thoroughly eliminate since measurement caused by the lower end surface of measuring block and the tested surface of workpiece side are not parallel is inclined
Difference to improve the accuracy of measurement, also, eliminates the complicated procedures of forming for manually adjusting measuring device, to improve survey
Amount efficiency.
Specifically, as shown in Figure 3 and Figure 5, the first measuring block 103 includes matrix 1031, the first mounting hole a is located at matrix
The hole wall of 1031 upper end, the first mounting hole a is equipped with second step face S2, the outer ring of second step face S2 and spherical bearing 102
Lower end is inconsistent.Also, measuring device further includes the first limit plate 108, and the first limit plate 108 is fixed on matrix 1031 and part
Cover the upper aperture of the first mounting hole a.In this way, the first limit plate 108 and second step face S2 cooperation, can limit spherical bearing
The axial position of 102 outer ring.In specific scheme, the first limit plate 108 is connected in the top surface of matrix 1031 by screw.
Specifically, second limit plate 109 is fixed on connection as shown in figure 3, measuring device further includes the second limit plate 109
Axis 101 is simultaneously inconsistent with the inner ring lower end of spherical bearing 102.Also, the periphery of connecting shaft 101 is equipped with and spherical bearing 102
The inconsistent third step surface S3 in inner ring upper end.In this way, the second limit plate 109 and third step surface S3 cooperates, ball can be limited
The axial position of the inner ring of spherical bearing 102.In specific scheme, the second limit plate 109 is connected in connecting shaft 101 by screw
Bottom surface.
Specifically, as shown in Figure 3 and Figure 5, the first measuring block 103 further includes the supporter for being located at 1031 top of matrix
1032.First measuring block 103 is additionally provided with the second mounting hole b and through-hole d, the second mounting hole b are located at the lower end of matrix 1031, through-hole
The top surface of d self-supporter 1032 penetrates through downwards to the second mounting hole b, and the second mounting hole b is protruded into the upper end of the second measuring block 104
It is interior.Also, measuring device further includes connecting column 106 and mounting portion 107, and mounting portion 107 is supported in supporter 1032, connecting column
106 are through at through-hole d and upper end is connected with mounting portion 107, lower end is connected with the second measuring block 104.In this way, making the second measuring block
104 can be connected in the first measuring block 103 up or down.
In specific implementation, connecting column 106 and through-hole d are vertically extended, also, the aperture of through-hole d and connecting column
106 it is substantially uniform-diameter, but the moving up and down in through-hole d of connecting column 106 is not influenced, in this way, through-hole d and connecting column 106
Cooperation, can be oriented to the moving direction of the second measuring block 104.
In specific scheme, as shown in Figure 1 and Figure 4, the first measuring block 103 includes that multiple supporters 1032 (are three in figure
It is a), each supporter 1032 surround the successively arranged for interval of connecting shaft 101.As shown in figures 1 to 6, during the first limit plate 108 includes
Core 1081 and the multiple scoreboards 1082 for being located at 1081 outer rim of central plate, each scoreboard 1082 protrude into two adjacent supports correspondingly
In clearance space between body 1032.So set, being convenient for the arrangement of the first limit plate 108, conducive to the collection of lifting measurement device
Cheng Du.
In specific scheme, as shown in figure 5, the hole wall of the second mounting hole b is equipped with First terrace S1 directed downwardly, when second
When measuring block 104 is moved upwards up to extreme position, First terrace S1 and the upper end of the second measuring block 104 are inconsistent, to prevent
Second measuring block, 104 the second mounting hole of prolapse upwards b.In specific implementation, the lower end surface of First terrace S1 and matrix 1031 it
Between the distance depth of the second mounting hole b (in figure be) can be according to the height of two parallel surfaces of the same size workpiece for measurement estimated
The fluctuation tolerance setting of difference specifically should be greater than being equal to fluctuation tolerance, for example, estimating the difference in height of workpiece for measurement in x-3mm to x+
When fluctuating within the scope of 3mm, then the distance can be set to 6mm.In this way, both ensure that the smooth implementation of measurement, it is additionally favorable for being promoted and surveys
Measure the compactedness of device.
In specific scheme, as shown in figure 5, the second mounting hole b and the first mounting hole a is penetrated through by connecting hole c, also,
The aperture of connecting hole c makes First terrace S1 be formed in second less than the aperture in the first aperture mounting hole a and the second mounting hole b
The junction of mounting hole b and connecting hole c, second step face S2 are formed in the junction of the first mounting hole a and connecting hole c.
In specific scheme, as shown in Figure 1, mounting portion 107 includes the mounting plate being supported on 1032 top surface of supporter
1071 and the mounting bracket 1072 that is located at below 1071 outer rim of mounting plate, mounting plate 1071 be equipped with centre bore, connecting shaft 101 passes through
Centre bore.It is circumferentially spaced to set there are three mounting bracket 1072 in figure, wherein a mounting bracket 1072 installs displacement sensing
The shell 1051 of device 105, another two mounting bracket 1072 are equipped with clump weight 113, with the weight of equilibrium displacement sensor 105.
In figure, two mounting brackets 1072 are L bracket.By the way that mounting portion 107 is arranged, the first measurement of connection on the one hand can be played
On the other hand the effect of block 103 and the second measuring block 104 can also be played the role of installing displacement sensor 105.
Specifically, matrix 1031 is equipped with spring base hole e, spring as shown in figure 3, measuring device further includes the first spring 110
The lower end of bore e and the second mounting hole b are penetrated through, and the first spring 110 is located in spring base hole e and the top of upper end and spring base hole e
Face contact, lower end are contacted with the second measuring block 104.In this way, on the one hand when the second measuring block 104 is contacted with workpiece, the first bullet
Spring 110 can play the role of shock absorbing, on the other hand, when the second measuring block 104 is disengaged with workpiece, the first spring
110 can provide reset force to the second measuring block 104.
Specifically, as shown in figure 3, measuring device further includes the interconnecting piece 111 for being connected in 101 upper end of connecting shaft, for connecting
Robot is moved down or is resetted upwards will pass through robotically-driven measuring mechanism.
In specific scheme, interconnecting piece 111 includes connector sleeve 1111 and connecting pin 1112, and connector sleeve 1111 is coated at connection
Axis 101, the peripheral wall two sides of connector sleeve 1111 are equipped with the elongated hole f vertically extended, and connecting shaft 101 is equipped with pin
Hole, connecting pin 1112 sequentially pass through an elongated hole f, pin hole and another elongated hole f.In this way, moving up and down measuring device when measurement
When, connector sleeve 1111 can be made to remain stationary, connecting shaft 101 moves in the inner hole of connector sleeve 1111.
In specific implementation, the inner hole of connecting shaft 101 and connector sleeve 1111 is vertically extended, connector sleeve 1111 it is interior
Hole aperture is substantially uniform-diameter with connecting shaft 101, but do not influence connecting shaft 101 in the inner hole of connector sleeve 1111 on move down
It is dynamic, in this way, the inner hole of connector sleeve 1111 and connecting shaft 101 cooperate, the moving direction of the first measuring block 103 can be oriented to.
Specifically, second spring 112 is coated at connecting shaft 101 as shown in figure 3, measuring device further includes second spring 112
And between connector sleeve 1111 and the first limit plate 108, in this way, on the one hand when the first measuring block 103 is contacted with workpiece, the
Two springs 112 can play the role of shock absorbing, on the other hand, when the first measuring block 103 is disengaged with workpiece, second
Spring 112 can provide reset force to the first measuring block 103.
In addition, it should be noted that, the structure of the first measuring block 103 and the second measuring block 104 can root in specific implementation
It can be according to the structure of the connecting pin of robot according to the structure of the adjustment of the structure progress adaptability of workpiece for measurement, interconnecting piece 111
It is adaptively adjusted.Moreover, realizing the knot that opposite can move up and down connection of the first measuring block 103 and the second measuring block 104
Structure is not limited to above structure, for example, sliding slot can also be arranged on the hole wall of the mounting hole of the first measuring block 103, by second
Measuring block 104 is slidably mounted in the sliding slot.
A kind of measuring device of parallel surface difference in height for measuring workpiece provided by the utility model has been carried out in detail above
It is thin to introduce.Specific case used herein is expounded the principles of the present invention and embodiment, above embodiments
Explanation be merely used to help understand the method and its core concept of the utility model.It should be pointed out that for the art
For those of ordinary skill, without departing from the principle of this utility model, several change can also be carried out to the utility model
Into and modification, modifications and modifications also fall within the protection scope of the claims of the utility model.
Claims (10)
1. a kind of measuring device for the parallel surface difference in height for measuring workpiece, which is characterized in that the measuring device includes:
Connecting shaft (101) and spherical bearing (102), the spherical bearing (102) are set in the lower end of the connecting shaft (101);
First measuring block (103), for the first of workpiece the face contact to be measured, first measuring block (103) be equipped with first peace
It fills hole (a), the spherical bearing (102) is mounted in first mounting hole (a);
Second measuring block (104), for the second of workpiece the face contact to be measured, second measuring block (104) can move up and down
Ground is connected in first measuring block (103), and second measuring block (104) first contacts work than first measuring block (103)
Part;
Displacement sensor (105), shell (1051) are connected with second measuring block (104), detector (1052) and institute
The first measuring block (103) are stated to be connected.
2. measuring device according to claim 1, which is characterized in that first measuring block (103) includes matrix
(1031) and the supporter (1032) that is located above described matrix (1031), first measuring block (103) are additionally provided with the second peace
Hole (b) and through-hole (d) are filled, second mounting hole (b) is located at the lower end of described matrix (1031), and the through-hole (d) is described in
The top surface of supporter (1032) is penetrated through to second mounting hole (b), and the upper end of second measuring block (104) protrudes into described
Two mounting holes (b);The measuring device further includes being through at the connecting column (106) of the through-hole (d) and being supported in the supporter
(1032) mounting portion (107), the upper end of the connecting column (106) is connected with the mounting portion (107), lower end and described second
Measuring block (104) is connected.
3. measuring device according to claim 2, which is characterized in that the hole wall of second mounting hole (b) is equipped with first
Step surface (S1) offsets when second measuring block (104) is moved upwards up to extreme position with the First terrace (S1)
Touching.
4. measuring device according to claim 2, which is characterized in that the mounting portion (107) includes being supported on the branch
Mounting plate (1071) on support body (1032) top surface and the mounting bracket (1072) being located at below the mounting plate (1071) outer rim,
The mounting plate (1071) is equipped with centre bore, and the connecting shaft (101) passes through the centre bore, institute's displacement sensors (105)
Shell (1051) be installed on the mounting bracket (1072).
5. measuring device according to claim 2, which is characterized in that the measuring device further includes the first spring (110),
Described matrix (1031) is equipped with spring base hole (e), and the lower end of the spring base hole (e) and second mounting hole (b) penetrate through, institute
State the first spring (110) be located in the spring base hole (e) and upper end contacted with the top surface of the spring base hole (e), lower end and
Second measuring block (104) contact.
6. according to the described in any item measuring devices of claim 2-5, which is characterized in that first mounting hole (a) is located at institute
The upper end of matrix (1031) is stated, the hole wall of first mounting hole (a) is equipped with the outer ring lower end phase with the spherical bearing (102)
The second step face (S2) of conflict, the measuring device further include the first limit plate (108), and first limit plate (108) is solid
It is connected in described matrix (1031) and partially covers the upper aperture of first mounting hole (a);The measuring device further includes second
Limit plate (109), second limit plate (109) are fixed on the connecting shaft (101) and interior with the spherical bearing (102)
It is inconsistent to enclose lower end, and the periphery of the connecting shaft (101) is equipped with inconsistent with the inner ring upper end of the spherical bearing (102)
Third step surface (S3).
7. measuring device according to claim 6, which is characterized in that first measuring block (103) includes multiple described
Supporter (1032), each supporter (1032) surround the connecting shaft (101) successively arranged for interval, first limit plate
It (108) include central plate (1081) and the multiple scoreboards (1082) for being located at the central plate (1081) outer rim, the scoreboard
(1082) it protrudes into the clearance space between the two adjacent supporters (1032) correspondingly.
8. measuring device according to claim 6, which is characterized in that the measuring device further includes for connecting robot
Interconnecting piece (111), the interconnecting piece (111) is connected in the upper end of the connecting shaft (101).
9. measuring device according to claim 8, which is characterized in that the interconnecting piece (111) includes connector sleeve (1111)
With connecting pin (1112), the connector sleeve (1111) is coated at the connecting shaft (101), the peripheral wall two of the connector sleeve (1111)
Side is equipped with the elongated hole (f) vertically extended, and the connecting shaft (101) is equipped with pin hole, the connecting pin
(1112) elongated hole (f), the pin hole and another elongated hole (f) are sequentially passed through, the connecting shaft (101) energy is made
It is enough to be moved up and down in the inner hole of the connector sleeve (1111).
10. measuring device according to claim 8, which is characterized in that the measuring device further includes second spring
(112), the second spring (112) is coated at the connecting shaft (101) and is located at the interconnecting piece (111) and first limit
Between position plate (108).
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CN201920891802.4U CN209706782U (en) | 2019-06-13 | 2019-06-13 | A kind of measuring device for the parallel surface difference in height measuring workpiece |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110132204A (en) * | 2019-06-13 | 2019-08-16 | 湖北航嘉麦格纳座椅系统有限公司 | A kind of measuring device for the parallel surface difference in height measuring workpiece |
CN112414262A (en) * | 2020-11-16 | 2021-02-26 | 科奇汽车传动系统(中国)有限公司 | Detection tool for detecting height of counter bore step |
-
2019
- 2019-06-13 CN CN201920891802.4U patent/CN209706782U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110132204A (en) * | 2019-06-13 | 2019-08-16 | 湖北航嘉麦格纳座椅系统有限公司 | A kind of measuring device for the parallel surface difference in height measuring workpiece |
CN112414262A (en) * | 2020-11-16 | 2021-02-26 | 科奇汽车传动系统(中国)有限公司 | Detection tool for detecting height of counter bore step |
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