CN213419679U - Guide rail automation is with hollow straight line optical axis of high abrasion - Google Patents
Guide rail automation is with hollow straight line optical axis of high abrasion Download PDFInfo
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- CN213419679U CN213419679U CN202022078751.9U CN202022078751U CN213419679U CN 213419679 U CN213419679 U CN 213419679U CN 202022078751 U CN202022078751 U CN 202022078751U CN 213419679 U CN213419679 U CN 213419679U
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Abstract
The utility model discloses an automatic hollow straight line optical axis of high abrasion of using of guide rail, including hollow straight line optical axis body, hollow component ring and arc component clamp plate, the central point of hollow straight line optical axis body puts the department and is provided with hollow straight line optical axis through-hole. The utility model discloses install first chromium plating wearing layer, second chromium plating wearing layer and lubricated copper bisque, and evenly be provided with the heat dissipation round hole in the inboard of second chromium plating wearing layer, lubricated copper bisque can improve the smooth degree of device, make the ring-shaped thing can slide in the device outside, reduce frictional force, the wearability of device can be improved in the setting of first chromium plating wearing layer and second chromium plating wearing layer, the area of contact of second chromium plating wearing layer and air can be increased in the setting of heat dissipation round hole, improve the heat transfer efficiency of second chromium plating wearing layer and air, make the heat that the friction produced scatter and disappear fast, can prevent that the rigidity of temperature rising to the device from causing the influence.
Description
Technical Field
The utility model relates to a straight line optical axis technical field specifically is a guide rail is automatic with hollow straight line optical axis of high abrasion.
Background
The linear optical axis has the guiding function of a sliding bearing, so that a product which can perform linear motion can be widely applied to various linear motion systems such as a cylinder rod, an automatic precision printer, an automatic cutting machine, an industrial robot and the like, and the linear optical axis is also one of common parts for guide rail automation.
When the existing high-abrasion-resistance hollow linear optical axis for guide rail automation is used, the linear optical axis easily generates heat due to friction, the heat cannot be discharged quickly, the linear optical axis is abraded seriously, and the rigidity of the linear optical axis can be influenced due to temperature rise.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide an automatic hollow straight line optical axis of high abrasion that uses of guide rail to solve the problem that proposes among the above-mentioned background art.
In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an automatic hollow straight line optical axis of high abrasion of using of guide rail, includes hollow straight line optical axis body, hollow component ring and arc component clamp plate, the central point department of putting of hollow straight line optical axis body is provided with hollow straight line optical axis through-hole, and the central point department of putting of hollow straight line optical axis through-hole installs hollow component ring, arc component clamp plate is evenly installed to the inboard of hollow straight line optical axis through-hole, the outside of hollow straight line optical axis body is provided with second chromium plating wearing layer, and the outside of second chromium plating wearing layer is provided with first chromium plating wearing layer, the outside of first chromium plating wearing layer is provided with lubricated copper powder layer, hollow component ring all is connected with arc component clamp plate.
Preferably, the end of the arc component pressure plate, which is far away from the hollow component pressure ring, is uniformly provided with first component force pillars, the end of the first component force pillars, which is far away from the arc component pressure plate, is connected with the hollow linear optical axis through hole, the end of the arc component pressure plate, which is close to the hollow component pressure ring, is uniformly provided with second component force pillars, and the end of the second component force pillars, which is far away from the arc component pressure plate, is connected with the hollow component pressure ring.
Preferably, the inside of hollow straight line optical axis body evenly is provided with the heat dissipation through-hole, and the inboard of heat dissipation through-hole all installs the heat dissipation sheetmetal, the metal heat conduction post is all evenly installed in the outside of heat dissipation sheetmetal, the metal heat conduction post all passes hollow straight line optical axis body, and the one end that the heat dissipation sheetmetal was kept away from to the metal heat conduction post all is connected with the second chromium plating wearing layer.
Preferably, heat dissipation round holes are uniformly formed in the second chromium-plated wear-resistant layer.
Preferably, four groups of arc-shaped component force pressing plates are arranged, and the included angle between every two adjacent arc-shaped component force pressing plates is ninety degrees.
Preferably, both ends of the hollow linear optical axis body are provided with zinc-plated rust-proof layers.
Compared with the prior art, the beneficial effects of the utility model are that:
1. the high-abrasion-resistance hollow linear optical axis for the guide rail automation is provided with a first chromium-plated abrasion-resistant layer, a second chromium-plated abrasion-resistant layer and a lubricating copper powder layer, heat dissipation round holes are uniformly formed in the inner side of the second chromium-plated abrasion-resistant layer, the lubricating copper powder layer can improve the smoothness degree of the device, so that a ring-shaped object can slide on the outer side of the device, the friction force is reduced, the abrasion resistance of the device can be improved due to the arrangement of the first chromium-plated abrasion-resistant layer and the second chromium-plated abrasion-resistant layer, the contact area of the second chromium-plated abrasion-resistant layer and air can be increased due to the arrangement of the heat dissipation round holes, the heat transfer efficiency of the second chromium-plated abrasion-resistant layer and the air is;
2. the high-abrasion-resistance hollow linear optical axis for the guide rail automation is provided with a heat dissipation through hole and a heat dissipation metal sheet, and is provided with a metal heat conduction column for matching use, the metal heat conduction column can lead out heat inside the hollow linear optical axis body and the second chromium-plated wear-resistant layer and transfer the heat to the heat dissipation metal sheet, and the heat dissipation efficiency of the device can be further improved by carrying out heat transfer between the heat dissipation metal sheet and air;
3. the high-abrasion-resistance hollow linear optical axis for the guide rail automation is provided with a first component force support, a hollow component force ring, an arc component force pressing plate and a second component force support, when the hollow linear optical axis body is locally stressed by pressure and other stresses, the arc component force pressing plate can transmit the stresses to the hollow component force ring, the stresses are uniformly transmitted to other arc component force pressing plates through the hollow component force ring, the stresses are uniformly transmitted to the first component force support through the arc component force pressing plate, the stresses are uniformly transmitted to different positions of the hollow linear optical axis body through the first component force support, the stresses can be dispersed, the stresses locally stressed by the hollow linear optical axis body are reduced, the hollow linear optical axis body is prevented from being locally stressed greatly and being deformed and damaged, the structural strength of the hollow linear optical axis body is favorably improved, and the service life of the hollow linear optical axis body is prolonged.
Drawings
Fig. 1 is a schematic front sectional view of the present invention;
fig. 2 is a schematic front view of the present invention;
fig. 3 is a schematic side view of the arc component pressing plate of the present invention.
In the figure: 1. a hollow linear optical axis body; 2. a hollow linear optical axis through hole; 3. a first force-dividing strut; 4. a hollow component force circular ring; 5. an arc-shaped component force pressing plate; 6. a heat dissipating through hole; 7. a first chrome-plated wear layer; 8. a second chrome-plated wear layer; 9. a heat dissipating metal sheet; 10. a heat dissipation circular hole; 11. lubricating the copper powder layer; 12. a second force-dividing strut; 13. a metal heat-conducting post; 14. and (4) plating a zinc anti-rust layer.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-3, the present invention provides an embodiment: the utility model provides a hollow straight line optical axis of high abrasion is used in guide rail automation, including hollow straight line optical axis body 1, hollow component force ring 4 and arc component force clamp plate 5, the central point department of putting of hollow straight line optical axis body 1 is provided with hollow straight line optical axis through-hole 2, and the central point department of hollow straight line optical axis through-hole 2 installs hollow component force ring 4, arc component force clamp plate 5 is evenly installed to the inboard of hollow straight line optical axis through-hole 2, the outside of hollow straight line optical axis body 1 is provided with second chromium plating wearing layer 8, and the outside of second chromium plating wearing layer 8 is provided with first chromium plating wearing layer 7, the outside of first chromium plating wearing layer 7 is provided with lubricated copper powder layer 11, hollow component force ring 4 all is connected with arc component force clamp plate 5.
In this implementation:
furthermore, the ends of the arc component pressure plates 5 far away from the hollow component pressure ring 4 are all uniformly provided with first component force pillars 3, the ends of the first component force pillars 3 far away from the arc component pressure plates 5 are all connected with the hollow linear optical axis through holes 2, the ends of the arc component pressure plates 5 near the hollow component pressure ring 4 are all uniformly provided with second component force pillars 12, the ends of the second component force pillars 12 far away from the arc component pressure plates 5 are all connected with the hollow component pressure ring 4, when the hollow linear optical axis body 1 is locally stressed by pressure and the like, the arc component pressure plates 5 can transfer the stress to the hollow component pressure ring 4, the stress is uniformly transferred to other arc component pressure plates 5 through the hollow component pressure rings 4, the stress is uniformly transferred to the first component force pillars 3 through the arc component pressure plates 5, and the stress is uniformly transferred to different positions of the hollow linear optical axis body 1 through the first component force pillars 3, can reduce the stress that hollow straight line optical axis body 1 part received with stress dispersion, avoid hollow straight line optical axis body 1 part atress great and warp, damage, be favorable to improving hollow straight line optical axis body 1's structural strength, prolong hollow straight line optical axis body 1's life.
Further, the inside of hollow straight line optical axis body 1 evenly is provided with heat dissipation through-hole 6, and heat dissipation sheetmetal 9 is all installed to heat dissipation through-hole 6's inboard, metal heat conduction post 13 is all evenly installed in the outside of heat dissipation sheetmetal 9, metal heat conduction post 13 all passes hollow straight line optical axis body 1, and the one end that heat dissipation sheetmetal 9 was kept away from to metal heat conduction post 13 all is connected with second chromium plating wearing layer 8, metal heat conduction post 13 can derive the heat of hollow straight line optical axis body 1 and the inside of second chromium plating wearing layer 8, and with heat transfer to heat dissipation sheetmetal 9, carry out the heat transfer through heat dissipation sheetmetal 9 and air, can further improve device's radiating efficiency.
Further, the inside of the second chromium-plated wear-resistant layer 8 is uniformly provided with heat dissipation circular holes 10, the arrangement of the heat dissipation circular holes 10 can increase the contact area between the second chromium-plated wear-resistant layer 8 and air, and improve the heat transfer efficiency between the second chromium-plated wear-resistant layer 8 and the air, so that heat generated by friction can be dissipated rapidly.
Further, four groups of arc-shaped component force pressing plates 5 are arranged, and the included angle between every two adjacent arc-shaped component force pressing plates 5 is ninety degrees.
Furthermore, the two ends of the hollow linear optical axis body 1 are provided with the zinc-plated antirust layers 14, so that the antirust effect is good, and the service life of the hollow linear optical axis body 1 is prolonged.
The working principle is as follows: in the using process, the annular object slides outside the device, the lubricating copper powder layer 11 can improve the smoothness of the device and reduce the friction force between the annular object and the device, the arrangement of the first chromium-plated wear-resistant layer 7 and the second chromium-plated wear-resistant layer 8 can improve the wear resistance of the device, the arrangement of the heat dissipation round hole 10 can increase the contact area between the second chromium-plated wear-resistant layer 8 and air and improve the heat transfer efficiency between the second chromium-plated wear-resistant layer 8 and the air, so that heat generated by friction can be quickly dissipated, the metal heat conduction column 13 can lead out the heat inside the hollow linear optical axis body 1 and the second chromium-plated wear-resistant layer 8 and transfer the heat to the heat dissipation metal sheet 9, the heat dissipation efficiency of the device can be further improved by carrying out heat transfer between the heat dissipation metal sheet 9 and the air, when the local part of the hollow linear optical axis body 1 is subjected to stress such as pressure, the stress is transferred to the, the arc component force pressing plate 5 and the second component force supporting column 12 can transmit stress to the hollow component force circular ring 4, the stress is uniformly transmitted to other arc component force pressing plates 5 through the hollow component force circular ring 4, the stress can be dispersed through the arc frame structures of the multiple groups of arc component force pressing plates 5, the stress can be uniformly transmitted to the first component force supporting column 3, the stress is uniformly transmitted to different positions of the hollow linear optical axis body 1 through the first component force supporting column 3, the stress can be dispersed, the stress locally applied to the hollow linear optical axis body 1 is reduced, the hollow linear optical axis body 1 is prevented from being deformed and damaged due to large local stress, the structural strength of the hollow linear optical axis body 1 is improved, and the service life of the hollow linear optical axis body 1 is prolonged.
Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.
Claims (6)
1. The utility model provides an automatic hollow sharp optical axis of high abrasion of guide rail, includes hollow sharp optical axis body (1), hollow component force ring (4) and arc component force clamp plate (5), its characterized in that: the center position department of hollow sharp optical axis body (1) is provided with hollow sharp optical axis through-hole (2), and the center position department of hollow sharp optical axis through-hole (2) installs hollow component force ring (4), arc component force clamp plate (5) are evenly installed to the inboard of hollow sharp optical axis through-hole (2), the outside of hollow sharp optical axis body (1) is provided with second chromium plating wearing layer (8), and the outside of second chromium plating wearing layer (8) is provided with first chromium plating wearing layer (7), the outside of first chromium plating wearing layer (7) is provided with lubricated copper powder layer (11), hollow component force ring (4) all are connected with arc component force clamp plate (5).
2. The high-abrasion-resistance hollow linear optical axis for the guide rail automation as claimed in claim 1, wherein: first component force pillar (3) are all evenly installed to the one end that hollow component force ring (4) were kept away from in arc component force clamp plate (5), and the one end that arc component force clamp plate (5) were kept away from in first component force pillar (3) all is connected with hollow sharp optical axis through-hole (2), second component force pillar (12) are all evenly installed to the one end that arc component force clamp plate (5) are close to hollow component force ring (4), and the one end that arc component force clamp plate (5) were kept away from in second component force pillar (12) all is connected with hollow component force ring (4).
3. The high-abrasion-resistance hollow linear optical axis for the guide rail automation as claimed in claim 1, wherein: the inside of hollow sharp optical axis body (1) evenly is provided with heat dissipation through-hole (6), and all installs heat dissipation sheetmetal (9) in the inboard of heat dissipation through-hole (6), metal heat conduction post (13) are all evenly installed in the outside of heat dissipation sheetmetal (9), metal heat conduction post (13) all pass hollow sharp optical axis body (1), and metal heat conduction post (13) keep away from the one end of heat dissipation sheetmetal (9) all be connected with second chromium plating wearing layer (8).
4. The high-abrasion-resistance hollow linear optical axis for the guide rail automation as claimed in claim 1, wherein: and heat dissipation circular holes (10) are uniformly formed in the second chromium plating wear-resistant layer (8).
5. The high-abrasion-resistance hollow linear optical axis for the guide rail automation as claimed in claim 1, wherein: the arc-shaped component force pressing plates (5) are provided with four groups, and the included angle between every two adjacent arc-shaped component force pressing plates (5) is ninety degrees.
6. The high-abrasion-resistance hollow linear optical axis for the guide rail automation as claimed in claim 1, wherein: and two ends of the hollow linear optical axis body (1) are provided with galvanized anti-rust layers (14).
Priority Applications (1)
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CN202022078751.9U CN213419679U (en) | 2020-09-21 | 2020-09-21 | Guide rail automation is with hollow straight line optical axis of high abrasion |
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CN202022078751.9U CN213419679U (en) | 2020-09-21 | 2020-09-21 | Guide rail automation is with hollow straight line optical axis of high abrasion |
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CN213419679U true CN213419679U (en) | 2021-06-11 |
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