CN218856635U - Numerically controlled grinder convenient to increase emery wheel cooling efficiency - Google Patents

Abstract

The utility model belongs to the technical field of the numerically control grinder, especially, be a numerically control grinder field convenient to increase emery wheel cooling efficiency, including device body and backup pad, the water pump is installed on the right side of storage water tank, water pipe and nozzle, and the internally mounted of device body has motor one, gearbox, transmission shaft, emery wheel body, and fixed plate, guide pillar, spring one and spring two are installed in the outside of transmission shaft, and the inner wall welding of mounting panel has coolant tank, and motor two, axis of rotation, gear, rack are installed to the inner wall of backup pad, and the top of rack is installed and is put thing board and electro-magnet, and the internally mounted who puts the thing board has clamp splice and pneumatic cylinder, the beneficial effects of the utility model are that: carry the inside water of storage water tank to the inside of water pipe through the water pump, spout water or coolant liquid to emery wheel body top through the nozzle from emery wheel body top and cool down to emery wheel body, can cool down the emery wheel body through coolant tank, can reach the purpose that convenient quick cooled down to the emery wheel body.

Description

Numerically controlled grinder convenient to increase emery wheel cooling efficiency

Technical Field

The utility model belongs to the technical field of the numerically control grinder, concretely relates to numerically control grinder convenient to increase emery wheel cooling efficiency.

Background

A numerically controlled grinder is a machine tool that grinds the surface of a workpiece using a grinding tool by a numerical control technique. Most grinding machines use a grinding wheel body rotating at a high speed for grinding, a numerical control machine tool is a product combining an information technology and a mechanical manufacturing technology, the technical level and the development trend of modern basic machinery are represented, and the grinding machine can process materials with higher hardness, such as hardened steel, hard alloy and the like; the grinding machine can also process brittle materials such as glass and granite, and can grind with high precision and small surface roughness, and can grind with high efficiency such as strong grinding and the like. The existing numerical control grinding machine is generally cooled at the position where a grinding wheel body is contacted with a workpiece in the using process, the grinding wheel body and the workpiece can be cooled simultaneously in the mode, but the grinding wheel body is generally positioned at an upper position, water can fall off from the grinding wheel body rapidly under the rotation of gravity and the grinding wheel body, and the cooling effect is poor.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model aims to: the utility model provides a numerically control grinder convenient to increase emery wheel cooling efficiency, solve current numerically control grinder in the use, generally cool down in the position of emery wheel body and work piece contact, this kind of mode can cool down emery wheel body and work piece simultaneously, but because emery wheel body generally is in the epistasis, water can drop from emery wheel body rapidly under gravity and emery wheel body's rotation, and the cooling effect is poor.

For the purpose of realizing above, the utility model discloses a technical scheme: the utility model provides a numerically control grinder convenient to increase emery wheel cooling efficiency, includes device body and backup pad, the storage water tank is installed to the bottom of device body, and the top of storage water tank installs the end cover, the water pump is installed on the right side of storage water tank, and the top of water pump installs water pipe and nozzle, the internally mounted of device body has motor one, and the right side of motor one installs the gearbox, the transmission shaft is installed to the top of gearbox, and the right side of transmission shaft installs the emery wheel body, the mounting panel is installed on the right side of device body, and the right side of mounting panel has the protection casing through the bolt fastening, the fixed plate is installed in the outside of transmission shaft, and the top of fixed plate installs the guide pillar, supreme spring one and spring two is installed in proper order down in the outside of guide pillar, the inner wall welding of mounting panel has cooling tank, the backup pad is installed in the inside of device body, and the inner wall of backup pad installs motor two, the axis of rotation is installed on the right side of motor two, and the outside of axis of rotation installs the gear, the rack, and the top of rack is installed and is put the thing board, put the bottom of thing board and the bottom is installed the electro-magnet, put the top of thing board and install the spout, put the internally mounted the hydraulic cylinder.

The utility model has the advantages that: carry the inside water of storage water tank to the inside of water pipe through the water pump to spout water or coolant liquid to emery wheel body top through the nozzle from emery wheel body top and cool down to emery wheel body, set up the nozzle through the water pipe below and cool down emery wheel body and work piece contact point, can cool down the emery wheel body once more through cooling water tank, can reach the purpose that convenient quick cooled down the emery wheel body.

To facilitate the installation of the nozzle and the water pipe:

as a further improvement of the above technical solution: the water pipe is in threaded connection with the nozzles, and the nozzles are distributed on the top end of the water pipe at equal intervals.

The beneficial effect of this improvement does: threaded connection can make the leakproofness of junction between nozzle and the water pipe, and the equidistant distribution of nozzle is in the top of water pipe, can make the nozzle more comprehensive reliable to the cooling of emery wheel body.

In order to facilitate the grinding of the workpiece:

as a further improvement of the above technical solution: the grinding wheel body and the mounting plate form a rotating mounting structure through a transmission shaft, and the grinding wheel body and the transmission shaft are arranged in an axis overlapping mode.

The beneficial effect of this improvement does: the grinding wheel body is driven to rotate through the transmission shaft, so that the workpiece can be ground, and the grinding wheel body can rotate more stably due to the fact that the axis is overlapped.

In order to facilitate the height adjustment of the fixing plate:

as a further improvement of the technical scheme: the fixed plate and the mounting plate form a lifting mounting structure through a first spring and a second spring, and the first spring and the guide pillar are arranged in an axis overlapping mode.

The beneficial effect of this improvement does: the height of the fixing plate can be adjusted through the first spring and the second spring, the device is convenient to install, and the transmission of the pair of guide pillars of the springs can be more accurate and reliable due to the fact that the axes are overlapped.

In order to facilitate the cooling of the grinding wheel body:

as a further improvement of the above technical solution: and the cooling water tank and the mounting plate are integrally welded.

The beneficial effect of this improvement does: welding integration sets up and to make the connection between cooling water tank and the mounting panel more firm reliable, can cool down the emery wheel body through cooling water tank.

In order to facilitate the transmission of the gear to the rack:

as a further improvement of the above technical solution: the gear and the rotating shaft are arranged in a mode of overlapping axes, and the gear and the rack are connected in a meshed mode.

The beneficial effect of this improvement does: the axis coincidence sets up can make the transmission of axis of rotation to the gear more accurate reliable, and the meshing connection can make the transmission of gear to the rack more accurate reliable.

In order to facilitate the supporting of the supporting plate to the device body:

as a further improvement of the above technical solution: the object placing plate and the supporting plate form a sliding installation structure through the sliding grooves, and the supporting plate and the device body are arranged in a mutually perpendicular mode.

The beneficial effect of this improvement does: the sliding direction of the object placing plate can be limited by the sliding of the sliding groove, and the supporting plate can support the device body more stably due to the fact that the object placing plate is arranged vertically.

For clamping and fixing the workpiece:

as a further improvement of the technical scheme: the clamping blocks and the object placing plates form a sliding installation structure through hydraulic cylinders, and the clamping blocks and the object placing plates are arranged in a mutually perpendicular mode.

The beneficial effect of this improvement does: the clamping blocks are driven by the hydraulic cylinders to slide so as to fix the workpiece, and the clamping blocks are arranged perpendicular to each other so as to fix the workpiece stably.

Drawings

FIG. 1 is a schematic overall front view structure;

FIG. 2 is a schematic left-side view of the whole structure;

FIG. 3 is an enlarged schematic view of the transmission shaft and the grinding wheel body axis;

FIG. 4 is an enlarged view of the structure at A in FIG. 1;

in the figure: 1. a device body; 2. a water storage tank; 3. an end cap; 4. a water pump; 5. a water pipe; 6. a nozzle; 7. a first motor; 8. a gearbox; 9. a drive shaft; 10. a grinding wheel body; 11. mounting a plate; 12. a protective cover; 13. a fixing plate; 14. a guide post; 15. a first spring; 16. a second spring; 17. a cooling water tank; 18. a support plate; 19. a second motor; 20. a rotating shaft; 21. a gear; 22. a rack; 23. a storage plate; 24. an electromagnet; 25. a chute; 26. a clamping block; 27. and a hydraulic cylinder.

Detailed Description

In order to make the technical solution of the present invention better understood, the present invention is described in detail below with reference to the accompanying drawings, and the description of the present invention is only exemplary and explanatory, and should not be construed as limiting the scope of the present invention.

Example 1:

as shown in fig. 1-4, a numerically controlled grinder convenient to increase grinding wheel cooling efficiency includes a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14 from bottom to top, a cooling water tank 17 is welded on the inner wall of the installation plate 11, the support plate 18 is installed inside the device body 1, a second motor 19 is installed on the right side of the support plate 19, a rotating shaft 20 is installed on the outer side of a gear 21, a rack 22 is installed on the top of a clamping block 23, and a clamping block 26 for placing a rack 23 is installed on the top of a clamping block 23, and an electromagnet 23 is installed on the clamping block 26, and an electromagnet 23, and an electromagnet block 26 for placing a rack 23 is installed on the top of the clamping block is installed on the clamping block for placing block 23.

Example 2:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a numerically controlled grinding machine convenient for increasing the cooling efficiency of a grinding wheel comprises a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, a support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall of the support plate 18, an object placing plate 20 is installed on the right side of a rotating shaft 19, a gear 21 is installed on the outer side of the gear, a rack 21 is installed on the rack 23, a clamping block 23 is installed on the rack 23, and a clamping block 23 is installed on the top of an electromagnet 23, and a clamping block 26 is installed on the clamping block 23, and a clamping block 26 is installed on the top of an electromagnet 23, and an electromagnet 23 installed on the top of the clamping block 23. The water pipe 5 is in threaded connection with the nozzle 6, and the nozzle 6 is distributed at the top end of the water pipe 5 at equal intervals.

Example 3:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a numerically controlled grinding machine convenient for increasing the cooling efficiency of a grinding wheel comprises a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, a support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall of the support plate 18, an object placing plate 20 is installed on the right side of a rotating shaft 19, a gear 21 is installed on the outer side of the gear, a rack 21 is installed on the rack 23, a clamping block 23 is installed on the rack 23, and a clamping block 23 is installed on the top of an electromagnet 23, and a clamping block 26 is installed on the clamping block 23, and a clamping block 26 is installed on the top of an electromagnet 23, and an electromagnet 23 installed on the top of the clamping block 23. A rotating installation structure is formed between the grinding wheel body 10 and the installation plate 11 through the transmission shaft 9, and the grinding wheel body 10 and the transmission shaft 9 are arranged in an axis overlapping mode.

Example 4:

as shown in fig. 1-4, as a further optimization of the above embodiment, a numerically controlled grinder convenient for increasing the cooling efficiency of a grinding wheel includes a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, the support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall, a rack 21 is installed on the outer side of a rotating shaft 19, a rack 23 is installed on the right side of the rack 23, and a clamping block 23 is installed on the top of the rack 23, and an electromagnet 23 is installed on the rack 23, and a clamping block 26 is installed on the top of the rack 23. The fixed plate 13 and the mounting plate 11 form a lifting mounting structure through a first spring 15 and a second spring 16, and the first spring 15 and the guide post 14 are arranged in an axis overlapping mode.

Example 5:

as shown in fig. 1-4, as a further optimization of the above embodiment, a numerically controlled grinder convenient for increasing the cooling efficiency of a grinding wheel includes a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, the support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall, a rack 21 is installed on the outer side of a rotating shaft 19, a rack 23 is installed on the right side of the rack 23, and a clamping block 23 is installed on the top of the rack 23, and an electromagnet 23 is installed on the rack 23, and a clamping block 26 is installed on the top of the rack 23. And the cooling water tank 17 and the mounting plate 11 are integrally welded.

Example 6:

as shown in fig. 1-4, as a further optimization of the above embodiment, a numerically controlled grinder convenient for increasing the cooling efficiency of a grinding wheel includes a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, the support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall, a rack 21 is installed on the outer side of a rotating shaft 19, a rack 23 is installed on the right side of the rack 23, and a clamping block 23 is installed on the top of the rack 23, and an electromagnet 23 is installed on the rack 23, and a clamping block 26 is installed on the top of the rack 23. The gear 21 and the rotating shaft 20 are arranged in an axis overlapping mode, and the gear 21 is in meshed connection with the rack 22.

Example 7:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a numerically controlled grinding machine convenient for increasing the cooling efficiency of a grinding wheel comprises a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, a support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall of the support plate 18, an object placing plate 20 is installed on the right side of a rotating shaft 19, a gear 21 is installed on the outer side of the gear, a rack 21 is installed on the rack 23, a clamping block 23 is installed on the rack 23, and a clamping block 23 is installed on the top of an electromagnet 23, and a clamping block 26 is installed on the clamping block 23, and a clamping block 26 is installed on the top of an electromagnet 23, and an electromagnet 23 installed on the top of the clamping block 23. The article placing plate 23 and the supporting plate 18 form a sliding installation structure through a sliding groove 25, and the supporting plate 18 and the device body 1 are arranged in a mutually perpendicular mode.

Example 8:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a numerically controlled grinding machine convenient for increasing the cooling efficiency of a grinding wheel comprises a device body 1 and a support plate 18, a water storage tank 2 is installed at the bottom of the device body 1, an end cover 3 is installed above the water storage tank 2, a water pump 4 is installed on the right side of the water storage tank 2, a water pipe 5 and a nozzle 6 are installed above the water pump 4, a first motor 7 is installed inside the device body 1, a gearbox 8 is installed on the right side of the first motor 7, a transmission shaft 9 is installed above the gearbox 8, a grinding wheel body 10 is installed on the right side of the transmission shaft 9, an installation plate 11 is installed on the right side of the device body 1, a protection cover 12 is fixed on the right side of the installation plate 11 through bolts, a fixing plate 13 is installed on the outer side of the transmission shaft 9, a guide pillar 14 is installed above the fixing plate 13, a first spring 15 and a second spring 16 are sequentially installed on the outer side of the guide pillar 14, a cooling water tank 17 is welded on the inner wall of the installation plate 11, a support plate 18 is installed inside the device body 1, a second motor 19 is installed on the inner wall of the support plate 18, an object placing plate 20 is installed on the right side of a rotating shaft 19, a gear 21 is installed on the outer side of the gear, a rack 21 is installed on the rack 23, a clamping block 23 is installed on the rack 23, and a clamping block 23 is installed on the top of an electromagnet 23, and a clamping block 26 is installed on the clamping block 23, and a clamping block 26 is installed on the top of an electromagnet 23, and an electromagnet 23 installed on the top of the clamping block 23. The clamping block 26 and the object placing plate 23 form a sliding installation structure through a hydraulic cylinder 27, and the clamping block 26 and the object placing plate 23 are arranged in a mutually perpendicular mode.

The utility model discloses a theory of operation does: when the numerically controlled grinder with the cooling function is used, the clamping block 26 is driven to slide through the hydraulic cylinder 27 and can be fixed to a workpiece, the workpiece can be fixed again through the electromagnet 24, the rotating shaft 20 is driven to rotate through the motor II 19, the gear 21 can be driven to rotate, the rack 22 and the object placing plate 23 can be driven to rotate, the object placing plate 23 is driven to slide through the rack 22 and can drive the workpiece to move below the grinding wheel body 10, the grinding wheel body 10 can be ground under the drive of the motor I7, in the process of grinding the workpiece, the water in the water storage tank 2 is sprayed to the grinding wheel body 10 from the upper side of the grinding wheel body 10 through the water pipe 5 and the nozzle 6, the grinding wheel body 10 is cooled through the water or cooling liquid, the nozzle 6 arranged below the water pipe 5 cools the grinding wheel body 10 and the workpiece contact point, the nozzle 6 is distributed on the top end of the water pipe 5 at equal intervals, the nozzle 6 can cool the grinding wheel body 10 more comprehensively and more reliably, the grinding wheel body 10 can be cooled through the cooling water tank 17, the purpose of cooling the grinding wheel body 10 can be achieved conveniently and quickly, the purpose of fixing the transmission shaft 9 can be achieved when the transmission shaft 9 and fixing of the transmission shaft which needs to be fixed conveniently and quickly.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present invention have been explained herein using specific examples, which are presented only to assist in understanding the methods and their core concepts. The foregoing are only preferred embodiments of the present invention, and it should be noted that there are practically unlimited specific structures due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes can be made without departing from the principle of the present invention, and the technical features described above can also be combined in a suitable manner; the application of these modifications, variations or combinations, or the application of the concepts and solutions of the present invention in other contexts without modification, is not intended to be considered as a limitation of the present invention.

Claims (8)

1. The utility model provides a numerically control grinder convenient to increase emery wheel cooling efficiency which characterized in that: the device comprises a device body (1) and a supporting plate (18), wherein a water storage tank (2) is installed at the bottom of the device body (1), an end cover (3) is installed above the water storage tank (2), a water pump (4) is installed on the right side of the water storage tank (2), a water pipe (5) and a nozzle (6) are installed above the water pump (4), a motor I (7) is installed inside the device body (1), a gearbox (8) is installed on the right side of the motor I (7), a transmission shaft (9) is installed above the gearbox (8), a grinding wheel body (10) is installed on the right side of the transmission shaft (9), a mounting plate (11) is installed on the right side of the device body (1), a protective cover (12) is fixed on the right side of the mounting plate (11) through bolts, a fixing plate (13) is installed on the outer side of the transmission shaft (9), a guide post (14) is installed above the fixing plate (13), a spring I (15) and a spring II (16) are sequentially installed on the outer side of the guide post (14), a cooling water tank (17) is installed on the inner wall of the mounting plate (11), a cooling water tank (18) is installed inside the device body (1), and a motor II (19) is welded on the supporting plate (19), rotation axis (20) are installed on the right side of motor two (19), and gear (21) are installed in the outside of rotation axis (20), rack (22) are installed to the top of gear (21), and the top of rack (22) is installed and is put thing board (23), it installs electro-magnet (24) to put the bottom of thing board (23), put the top of thing board (23) and install spout (25), the internally mounted who puts thing board (23) has clamp splice (26), and pneumatic cylinder (27) are installed on the right side of clamp splice (26).

2. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: the water pipe (5) is in threaded connection with the nozzle (6), and the nozzle (6) is distributed at the top end of the water pipe (5) at equal intervals.

3. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: a rotary mounting structure is formed between the grinding wheel body (10) and the mounting plate (11) through the transmission shaft (9), and the grinding wheel body (10) and the transmission shaft (9) are arranged in an axis overlapping mode.

4. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: a lifting mounting structure is formed between the fixing plate (13) and the mounting plate (11) through a first spring (15) and a second spring (16), and the first spring (15) and the guide post (14) are arranged in an axial superposition mode.

5. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: and the cooling water tank (17) and the mounting plate (11) are integrally welded.

6. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: the gear (21) and the rotating shaft (20) are arranged in an axis overlapping mode, and the gear (21) is in meshed connection with the rack (22).

7. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: the article placing plate (23) and the supporting plate (18) form a sliding installation structure through a sliding groove (25), and the supporting plate (18) and the device body (1) are arranged in a mutually perpendicular mode.

8. The numerically controlled grinder facilitating increased wheel cooling efficiency according to claim 1, wherein: the clamping block (26) and the object placing plate (23) form a sliding installation structure through a hydraulic cylinder (27), and the clamping block (26) and the object placing plate (23) are arranged in a mutually perpendicular mode.

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