CN220407850U - Can realize high-speed counterpoint slip table - Google Patents
Can realize high-speed counterpoint slip table Download PDFInfo
- Publication number
- CN220407850U CN220407850U CN202321801368.9U CN202321801368U CN220407850U CN 220407850 U CN220407850 U CN 220407850U CN 202321801368 U CN202321801368 U CN 202321801368U CN 220407850 U CN220407850 U CN 220407850U
- Authority
- CN
- China
- Prior art keywords
- sliding
- base
- plate
- block
- double
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
- 230000000712 assembly Effects 0.000 claims abstract description 25
- 238000000429 assembly Methods 0.000 claims abstract description 25
- 238000006073 displacement reaction Methods 0.000 claims description 15
- 230000010365 information processing Effects 0.000 claims description 7
- 230000007547 defect Effects 0.000 abstract description 3
- 238000000034 method Methods 0.000 description 12
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000002457 bidirectional effect Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 230000002349 favourable effect Effects 0.000 description 1
Landscapes
- Machine Tool Units (AREA)
Abstract
The utility model relates to the technical field of sliding tables, in particular to a sliding table capable of realizing high-speed alignment, which comprises the following components: a base; four double-layer sliding components are respectively arranged at four corners of the base; a slide plate; the transverse driving assembly is arranged on the base, is positioned between the adjacent double-layer sliding assemblies, and the output end of the transverse driving assembly acts on the double-layer sliding assemblies, so that the sliding plate can transversely slide relative to the base; and the longitudinal driving assembly is arranged on the base, is positioned between the adjacent double-layer sliding assemblies, and the output end of the longitudinal driving assembly acts on the double-layer sliding assemblies, so that the sliding plate can longitudinally slide relative to the base. According to the utility model, the middle rotating block is replaced by the four double-layer sliding components, so that a space for installing the transverse driving component and the longitudinal driving component is formed between the base and the sliding plate, the defect of overall structure bulkiness caused by the fact that the driving component needs to be externally arranged is further overcome, and the occupied space of the sliding table is reduced.
Description
Technical Field
The utility model relates to the technical field of sliding tables, in particular to a sliding table capable of achieving high-speed alignment.
Background
The sliding table is a device for linear motion and is generally used for automatic equipment, detection equipment and the like.
In the prior art, in order to make the slip table realize two-way slip, utilize transfer piece to connect base and slide, include by the bottom-up base that stacks in proper order, transfer piece, slide, the bottom and the top of transfer piece are equipped with the spout respectively, still include drive unit, drive unit passes through transmission structure drive transfer piece and slides for the base to and the slide slides for the transfer piece to realize two-way slip, but this kind of structure has following not enough: the size of the transfer block is the same as that of the base and the sliding block, and the driving part can only be arranged outside the sliding table and needs to be fixed by using the support, so that the whole structure is bulky and the occupied space is large.
Disclosure of Invention
In order to overcome the defects in the prior art, the utility model aims to provide a high-speed alignment sliding table.
In order to achieve the above purpose, the technical scheme of the utility model is as follows:
a slide table capable of achieving high-speed alignment, comprising:
a base;
four double-layer sliding components are respectively arranged at four corners of the base;
the sliding plate is connected with the base in a sliding way through four double-layer sliding assemblies;
the transverse driving assembly is arranged on the base, is positioned between the adjacent double-layer sliding assemblies, and the output end of the transverse driving assembly acts on the double-layer sliding assemblies, so that the sliding plate can transversely slide relative to the base;
and the longitudinal driving assembly is arranged on the base, is positioned between the adjacent double-layer sliding assemblies, and the output end of the longitudinal driving assembly acts on the double-layer sliding assemblies, so that the sliding plate can longitudinally slide relative to the base.
Preferably, the double-layered sliding assembly includes:
the lower sliding group comprises a first guide block and a first sliding block, and the first sliding block is in sliding connection with the first guide block and can slide transversely or longitudinally relative to the first guide block; the first guide block is arranged at the top of the base;
the upper sliding group comprises a second guide block and a second sliding block, the second sliding block is in sliding connection with the second guide block, the second guide block is arranged at the top of the first sliding block, and the sliding direction of the second sliding block is mutually perpendicular to the sliding direction of the first sliding block;
the two double-layer sliding assemblies are arranged on the left side of the base in the same arrangement direction, the two double-layer sliding assemblies are arranged on the right side of the base in the same arrangement direction, and the sliding direction of the first sliding block on the left side of the base is perpendicular to the sliding direction of the first sliding block on the right side of the base.
Preferably, the lateral drive assembly comprises:
the first rotor is fixedly arranged on the base and provided with a plurality of first coils;
the first stator plate is arranged at the top of the first rotor and provided with a plurality of first magnets;
one end of the first connecting plate is connected with the first stator plate, and the other end of the first connecting plate is connected with the first sliding block positioned on the right side of the base;
the longitudinal drive assembly includes:
the second rotor is fixedly arranged on the base and provided with a plurality of second coils;
the second stator plate is arranged at the top of the second rotor and provided with a plurality of second magnets;
and one end of the second connecting plate is connected with the second stator plate, and the other end of the second connecting plate is connected with the first sliding block which is positioned outside the left side of the base.
Preferably, the first connection plate includes:
the top end of the first vertical section part is connected with the first stator plate;
the inner end of the first transverse section part is connected with the bottom end of the first vertical section part, and the outer end of the first transverse section part is connected with the first sliding block positioned on the right side of the base;
the second connection plate includes:
the top end of the second vertical section part is connected with the second stator plate;
and the inner end of the second transverse section part is connected with the bottom end of the second vertical section part, and the outer end of the second transverse section part is connected with the first sliding block positioned on the left side of the base.
Preferably, the method further comprises:
the first groove is formed in the base and can be matched with the bottom of the first rotor;
the second groove is formed in the base and can be matched with the bottom of the second rotor.
Preferably, the method further comprises:
the first notch is concavely arranged on the right side of the bottom of the sliding plate upwards and can be matched with the second sliding block positioned on the right side of the sliding plate;
the second notch is concavely arranged on the left side of the bottom of the sliding plate upwards and can be matched with the second sliding block positioned on the left side of the sliding plate.
Preferably, the method further comprises:
the first cross roller guide rail is arranged at the top of the first guide block, and the first sliding block is in sliding connection with the first guide block through the first cross roller guide rail;
the second cross roller guide rail is arranged at the top of the second guide block, and the second sliding block is in sliding connection with the second guide block through the second cross roller guide rail.
Preferably, the method further comprises:
the displacement sensor is used for detecting the displacement of the sliding plate;
and the information processing assembly is electrically connected with the displacement sensor, and the transverse driving assembly and the longitudinal driving assembly are electrically connected with a power supply through the information processing assembly.
Preferably, the displacement sensor includes:
the grating main scale is arranged on the base;
and the reading head is arranged on the sliding plate, and can slide relative to the grating main scale when the sliding plate slides relative to the base.
Preferably, the method further comprises:
the first assembly hole is arranged on the base;
and the second assembly hole is arranged on the sliding plate.
The utility model has the beneficial effects that: when the sliding plate needs to transversely slide relative to the base, the transverse driving assembly acts on the double-layer sliding assembly and drives the sliding plate to transversely slide relative to the base; when the sliding plate needs to longitudinally slide relative to the base, the longitudinal driving component acts on the double-layer sliding component and drives the sliding plate to longitudinally slide relative to the base.
According to the utility model, the middle rotating block is replaced by the four double-layer sliding components, so that a space for installing the transverse driving component and the longitudinal driving component is formed between the base and the sliding plate, the defect of overall structure bulkiness caused by the fact that the driving component needs to be externally arranged is further overcome, and the occupied space of the sliding table is reduced.
Drawings
FIG. 1 is a schematic diagram of an embodiment of the present utility model;
FIG. 2 is an exploded view of an embodiment of the present utility model;
FIG. 3 is a schematic view of a lateral sliding of a skateboard according to an embodiment of the present utility model;
FIG. 4 is a schematic view of a slide plate longitudinally sliding according to an embodiment of the present utility model;
FIG. 5 is a schematic view of bi-directional sliding of a skateboard according to an embodiment of the present utility model.
The figure shows:
1-a base, 11-a first groove, 12-a second groove and 13-a first assembly hole;
2-double layer slide assembly;
21-lower slide group, 211-first guide block, 212-first slide block, 213-first cross roller guide rail;
22-upper slide set, 221-second guide block, 222-second slide block, 223-second cross roller guide rail;
3-sliding plates, 31-first gaps, 32-second gaps and 33-second assembly holes;
4-a transverse driving assembly, 41-a first mover, 42-a first stator plate, 43-a first connecting plate, 431-a first vertical section, 432-a first transverse section;
5-longitudinal drive assembly, 51-second mover, 52-second stator plate, 53-second connection plate, 531-second vertical section, 532-second horizontal section.
Detailed Description
Embodiments of the present utility model will now be described in detail with reference to the drawings, which are intended to be used as references and illustrations only, and are not intended to limit the scope of the utility model.
Referring to fig. 1 to 5, in this embodiment, a sliding table capable of implementing high-speed alignment includes:
a base 1;
four double-layer sliding components 2 are respectively arranged at four corners of the base 1;
the sliding plate 3 is in sliding connection with the base 1 through four double-layer sliding assemblies 2;
a transverse driving component 4, which is arranged on the base 1, is positioned between the adjacent double-layer sliding components 2, and the output end of the transverse driving component acts on the double-layer sliding components 2, so that the sliding plate 3 can transversely slide relative to the base 1;
and a longitudinal driving unit 5, which is disposed on the base 1, is disposed between the adjacent double-layer sliding units 2, and has an output end acting on the double-layer sliding units 2, and is capable of sliding the sliding plate 3 longitudinally with respect to the base 1.
In the embodiment, the base 1 and the sliding plate 3 are square plate-shaped bodies, and the four double-layer sliding assemblies 2 are respectively arranged at four right angles of the base 1; when the sliding plate 3 needs to transversely slide relative to the base 1, the transverse driving component 4 acts on the double-layer sliding component 2 and drives the sliding plate 3 to transversely slide relative to the base 1; when the sliding plate 3 needs to longitudinally slide relative to the base 1, the longitudinal driving component 5 acts on the double-layer sliding component 2 and drives the sliding plate 3 to longitudinally slide relative to the base 1.
Preferably, the double-layered sliding assembly 2 includes:
the lower slide group 21 includes a first guide block 211 and a first slide block 212, and the first slide block 212 is slidably connected to the first guide block 211 and can slide laterally or longitudinally with respect to the first guide block 211; the first guide block 211 is arranged at the top of the base 1;
the upper sliding group 22 comprises a second guiding block 221 and a second sliding block 222, the second sliding block 222 is slidably connected with the second guiding block 221, the second guiding block 221 is arranged at the top of the first sliding block 212, and the sliding direction of the second sliding block 222 is perpendicular to the sliding direction of the first sliding block 212;
the two double-layer sliding assemblies 2 disposed on the left side of the base 1 have the same placement direction, the two double-layer sliding assemblies 2 disposed on the right side of the base 1 have the same placement direction, and the sliding direction of the first sliding block 212 disposed on the left side of the base 1 is perpendicular to the sliding direction of the first sliding block 212 disposed on the right side of the base 1.
In this embodiment, four lower sliding groups 21 and four upper sliding groups 22 are respectively provided, a single-group double-layer sliding assembly 2 is composed of 1 lower sliding group 21 and 1 upper sliding group 22, and the sliding directions of the two groups are mutually perpendicular, if the lower sliding group 21 can realize the transverse sliding, the upper sliding group 22 can realize the longitudinal sliding, or if the lower sliding group 21 can realize the longitudinal sliding, the upper sliding group 22 can realize the transverse sliding, as for the arrangement direction of the double-layer sliding assembly 2, the arrangement direction of the 2 groups of double-layer sliding assemblies 2 positioned on the same side is the same, the arrangement direction of the other 2 groups of double-layer sliding assemblies 2 positioned on the other side is opposite to the arrangement direction, and then the bidirectional sliding of the sliding plate 3 is realized by using the four groups of double-layer sliding assemblies 2, and the first sliding plate is fixedly connected with the second guide block 221 through screws; compared with the prior art, the space for assembling the transverse driving component 4 and the longitudinal driving component 5 can be formed between the base 1 and the sliding plate 3, so that built-in driving components are realized, and the occupied space of the whole structure is reduced.
Preferably, the transverse driving assembly 4 comprises:
the first mover 41 is fixedly arranged on the base 1 and is provided with a plurality of first coils;
the first stator plate 42 is arranged at the top of the first rotor 41 and provided with a plurality of first magnets;
a first connection plate 43 having one end connected to the first stator plate 42 and the other end connected to the first slider 212 positioned on the right side of the base 1;
the longitudinal drive assembly 5 comprises:
the second mover 51 is fixedly arranged on the base 1 and is provided with a plurality of second coils;
the second stator plate 52 is arranged at the top of the second rotor 51 and provided with a plurality of second magnets;
and a second connection plate 53 having one end connected to the second stator plate 52 and the other end connected to the first slider 212 positioned outside the left side of the base 1.
In the embodiment, the driving force directly acts on the first sliding block 212 and the second sliding block 222 by using the magnetomotive force, compared with the prior art, the driving structure between the driving part and the driving part is saved, and the response efficiency is improved; during operation, the first mover 41 is externally connected with a power supply and is electrified, after the first mover 41 is electrified, the first stator plate 42 can drive the first sliding block 212 positioned on the right side of the base 1 through the first connecting plate 43 to realize transverse sliding, or the second mover 51 is externally connected with the power supply and is electrified, after the second mover 51 is electrified, the second stator plate 52 can drive the first sliding block 212 positioned on the left side of the base 1 through the second connection to realize longitudinal sliding, and it is required to explain that the driving assembly of the embodiment is a linear motor in the prior art, so that the working principle and specific structure of the driving assembly are not repeated.
Preferably, the first connection plate 43 includes:
a first vertical section 431 having a top end connected to the first stator plate 42;
a first transverse section 432, the inner end of which is connected to the bottom end of the first vertical section 431, and the outer end of which is connected to the first sliding block 212 located on the right side of the base 1;
the second connection plate 53 includes:
a second vertical section 531 having a top end connected to the second stator plate 52;
a second transverse section 532 has an inner end connected to a bottom end of the second vertical section 531 and an outer end connected to the first slider 212 positioned on the left side of the base 1.
In this embodiment, the first connection plate 43 and the second connection plate 53 are both L-shaped, the first vertical section 431 is fixedly connected with the first stator plate 42 by a screw, the first horizontal section 432 is connected with the first sliding block 212 located on the right side of the base 1 by a screw, the second vertical section 531 is fixedly connected with the second stator plate 52 by a screw, and the second horizontal section 532 is connected with the first sliding block 212 located on the left side of the base 1 by a screw.
Preferably, the method further comprises:
the first groove 11 is formed in the base 1 and can be matched with the bottom of the first rotor 41;
the second groove 12 is formed in the base 1 and can be matched with the bottom of the second mover 51.
In this embodiment, the bottom of the first mover 41 is fixed with the base 1 by a screw and can be matched with the first groove 11, and the first groove 11 is used for limiting the first mover 41, so that the situation that the first mover 41 and the base 1 relatively move in the working process is reduced; the bottom of the second rotor 51 is fixed with the base 1 through a screw and can be matched with the second groove 12, and the second rotor 51 is limited by the second groove 12, so that the situation that the second rotor 51 and the base 1 relatively move in work is reduced.
Preferably, the method further comprises:
the first notch 31 is concavely arranged on the right side of the bottom of the sliding plate 3, and can be matched with the second sliding block 222 positioned on the right side of the sliding plate 3;
the second notch 32 is concavely arranged on the left side of the bottom of the sliding plate 3, and can be matched with the second sliding block 222 positioned on the left side of the sliding plate 3.
In this embodiment, the second sliding plate located on the right side of the sliding plate 3 is fixed by the screw sliding plate 3 and can be matched with the first notch 31, and the second sliding plate located on the right side of the sliding plate 3 is limited by the first notch 31, which is favorable for reducing the situation that the second sliding plate and the sliding plate 3 relatively move in the working process, and the function of the second notch 32 in this embodiment is the same as that of the first notch 31, and will not be repeated here.
Preferably, the method further comprises:
the first cross roller guide rail 213 is arranged at the top of the first guide block 211, and the first sliding block 212 is slidably connected with the first guide block 211 through the first cross roller guide rail 213;
the second cross roller guide rail 223 is arranged at the top of the second guide block 221, and the second sliding block 222 is slidably connected with the second guide block 221 through the second cross roller guide rail 223.
In this embodiment, the first cross roller rail 213 is utilized to improve the smoothness of the sliding fit of the first sliding plate relative to the first guide block 211, and the second cross roller rail 223 of this embodiment has the same function as the first cross roller rail 213, and will not be described here.
Preferably, the method further comprises:
a displacement sensor for detecting the displacement of the slide plate 3;
the information processing component is electrically connected with the displacement sensor, and the transverse driving component 4 and the longitudinal driving component 5 are electrically connected with a power supply through the information processing component.
In this embodiment, the displacement sensor is a grating ruler, and is configured to detect displacement information of the sliding plate 3, convert the displacement information into an electrical number, and transmit the electrical number to the information processing component, thereby improving the sliding precision of the sliding plate 3.
Preferably, the displacement sensor includes:
the grating main scale is arranged on the base 1;
and the reading head is arranged on the sliding plate 3, and can slide relative to the grating main scale when the sliding plate 3 slides relative to the base 1.
Preferably, the method further comprises:
a first assembly hole 13 provided on the base 1;
a second fitting hole 33 is provided in the slide plate 3.
In this embodiment, the base 1 is fixed to the external device by screws passing through the first fitting holes 13, and the tray is fixed to the slide plate 3 by screws passing through the tray and the second fitting holes 33.
The above disclosure is illustrative of the preferred embodiments of the present utility model and should not be construed as limiting the scope of the utility model, which is defined by the appended claims.
Claims (10)
1. Can realize high-speed counterpoint slip table, its characterized in that includes:
a base (1);
four double-layer sliding components (2) which are respectively arranged at four corners of the base (1);
the sliding plate (3) is connected with the base (1) in a sliding way through four double-layer sliding assemblies (2);
the transverse driving assembly (4) is arranged on the base (1), is positioned between the adjacent double-layer sliding assemblies (2), and the output end of the transverse driving assembly acts on the double-layer sliding assemblies (2) to enable the sliding plate (3) to transversely slide relative to the base (1);
and the longitudinal driving assembly (5) is arranged on the base (1), is positioned between the adjacent double-layer sliding assemblies (2), and the output end of the longitudinal driving assembly acts on the double-layer sliding assemblies (2) to enable the sliding plate (3) to longitudinally slide relative to the base (1).
2. A slide table capable of achieving high-speed alignment according to claim 1, characterized in that the double-layer slide assembly (2) comprises:
a lower slide group (21) including a first guide block (211) and a first slide block (212), the first slide block (212) being slidably connected to the first guide block (211) and capable of sliding laterally or longitudinally with respect to the first guide block (211); the first guide block (211) is arranged at the top of the base (1);
the upper sliding group (22) comprises a second guide block (221) and a second sliding block (222), wherein the second sliding block (222) is in sliding connection with the second guide block (221), the second guide block (221) is arranged at the top of the first sliding block (212), and the sliding direction of the second sliding block (222) is mutually perpendicular to the sliding direction of the first sliding block (212);
the two double-layer sliding assemblies (2) arranged on the left side of the base (1) are identical in arrangement direction, the two double-layer sliding assemblies (2) arranged on the right side of the base (1) are identical in arrangement direction, and the sliding direction of the first sliding block (212) arranged on the left side of the base (1) is perpendicular to the sliding direction of the first sliding block (212) arranged on the right side of the base (1).
3. A slide table capable of high-speed alignment according to claim 2, characterized in that the transverse driving assembly (4) comprises:
the first rotor (41) is fixedly arranged on the base (1) and is provided with a plurality of first coils;
the first stator plate (42) is arranged at the top of the first rotor (41) and is provided with a plurality of first magnets;
a first connecting plate (43) having one end connected to the first stator plate (42) and the other end connected to the first slider (212) located on the right side of the base (1);
the longitudinal drive assembly (5) comprises:
the second rotor (51) is fixedly arranged on the base (1) and is provided with a plurality of second coils;
the second stator plate (52) is arranged at the top of the second rotor (51) and is provided with a plurality of second magnets;
and one end of the second connecting plate (53) is connected with the second stator plate (52), and the other end of the second connecting plate is connected with the first sliding block (212) which is positioned on the left side of the base (1) outside.
4. A slide table capable of high-speed alignment according to claim 3, characterized in that the first connection plate (43) comprises:
a first vertical section (431) having a top end connected to the first stator plate (42);
a first transverse section (432) with an inner end connected to the bottom end of the first vertical section (431) and an outer end connected to the first slider (212) located on the right side of the base (1);
the second connection plate (53) includes:
a second vertical section (531) having a top end connected to the second stator plate (52);
and the inner end of the second transverse section part (532) is connected with the bottom end of the second vertical section part (531), and the outer end of the second transverse section part is connected with the first sliding block (212) positioned on the left side of the base (1).
5. A slide table capable of realizing high-speed alignment according to claim 3, further comprising:
the first groove (11) is formed in the base (1) and can be matched with the bottom of the first rotor (41);
the second groove (12) is formed in the base (1) and can be matched with the bottom of the second rotor (51).
6. The slide table capable of realizing high-speed alignment according to claim 2, further comprising:
the first notch (31) is concavely arranged on the right side of the bottom of the sliding plate (3) upwards and can be matched with the second sliding block (222) positioned on the right side of the sliding plate (3);
the second notch (32) is concavely arranged on the left side of the bottom of the sliding plate (3) upwards and can be matched with the second sliding block (222) positioned on the left side of the sliding plate (3).
7. The slide table capable of realizing high-speed alignment according to claim 2, further comprising:
the first cross roller guide rail (213) is arranged at the top of the first guide block (211), and the first sliding block (212) is in sliding connection with the first guide block (211) through the first cross roller guide rail (213);
and the second cross roller guide rail (223) is arranged at the top of the second guide block (221), and the second sliding block (222) is in sliding connection with the second guide block (221) through the second cross roller guide rail (223).
8. The slide table capable of realizing high-speed alignment according to claim 1, further comprising:
the displacement sensor is used for detecting the displacement of the sliding plate (3);
and the information processing assembly is electrically connected with the displacement sensor, and the transverse driving assembly (4) and the longitudinal driving assembly (5) are electrically connected with a power supply through the information processing assembly.
9. The slide table capable of achieving high-speed alignment according to claim 8, wherein the displacement sensor comprises:
the grating main scale is arranged on the base (1);
the reading head is arranged on the sliding plate (3), and when the sliding plate (3) slides relative to the base (1), the reading head can slide relative to the grating main scale.
10. The slide table capable of realizing high-speed alignment according to claim 1, further comprising:
the first assembly hole (13) is arranged on the base (1);
and the second assembly hole (33) is arranged on the sliding plate (3).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202321801368.9U CN220407850U (en) | 2023-07-11 | 2023-07-11 | Can realize high-speed counterpoint slip table |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202321801368.9U CN220407850U (en) | 2023-07-11 | 2023-07-11 | Can realize high-speed counterpoint slip table |
Publications (1)
Publication Number | Publication Date |
---|---|
CN220407850U true CN220407850U (en) | 2024-01-30 |
Family
ID=89641312
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202321801368.9U Active CN220407850U (en) | 2023-07-11 | 2023-07-11 | Can realize high-speed counterpoint slip table |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN220407850U (en) |
-
2023
- 2023-07-11 CN CN202321801368.9U patent/CN220407850U/en active Active
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN105353296B (en) | Using the flying probe tester of planar motor | |
CN109795887B (en) | Double-station battery feeding equipment | |
CN201432120Y (en) | Drilling machine | |
CN220407850U (en) | Can realize high-speed counterpoint slip table | |
CN204761957U (en) | U type slot type actuating mechanism of chip mounter paster module | |
CN217521377U (en) | Motor stator core oil through hole connectivity detection device | |
CN218079101U (en) | Hardness detection device is used in circuit board production | |
CN206302324U (en) | A kind of high efficiency XY reversible straight-line motors | |
CN216794821U (en) | Linear motor device of linear rail grinder | |
CN215988419U (en) | Positioning stacking table for transformer core stacking | |
CN110316948B (en) | High-precision glass upper and lower cutter bisection structure | |
CN210982666U (en) | Flexible line way board XY step-by-step test support plate feed mechanism | |
CN219967086U (en) | Double-side guide rail for milling machine | |
CN217427951U (en) | Position-adjustable double-side linear motor module | |
CN209792663U (en) | Long-distance long guide rail drilling machine | |
CN204116899U (en) | Stacked two-dimentional load orientation worktable | |
CN210314000U (en) | High-precision glass upper and lower cutter beveling structure | |
CN211530985U (en) | Linear motor | |
CN202815998U (en) | Coin temporary storage mechanism | |
CN216904648U (en) | Motion module and motion device with same | |
CN210444155U (en) | Narrow type multilayer structure Z-axis linear motor module | |
CN220022585U (en) | Linear motor module with iron core | |
CN113691098B (en) | Coplanar motion device driven by single-side linear motor for packaging optoelectronic device | |
CN210412696U (en) | Sliding device of point drilling machine | |
CN220273500U (en) | Integrated direct-drive module |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant |