CN219043655U - Improved generation super precision numerical control lathe - Google Patents

Abstract

The application discloses improved generation super precision numerical control lathe, including hollow structure's lathe body, a processing agency for processing spare part sets up inside the lathe body, adsorption equipment includes the storage box, the storage box sets up at lathe body top, the storage box right side is connected with the fan through first gas tube, the second trachea sets up at storage box left side wall, the one end that the storage box was kept away from to the second trachea runs through the lathe body and extends to lathe body inside and be connected with the adsorption port, the adsorption port is located the processing agency top, when processing spare part, the suction of fan passes through first trachea and second trachea and transmits to the adsorption port, can inhale the storage box with the miniature metal particle that processing produced, will float the miniature metal particle that will inhale in lathe body when avoiding the staff to take the product after having processed, thereby staff's health and safety have been protected.

Description

Improved generation super precision numerical control lathe

Technical Field

The disclosure relates to the technical field of numerically controlled lathes, in particular to an improved super-precision numerically controlled lathe.

Background

The ultra-precision numerical control lathe is widely used, but the existing ultra-precision numerical control lathe can generate a plurality of micro metal particles in the processing process, so that staff can suck some micro metal particles floating in the lathe into the body of the staff in the process of taking processed products, and hidden danger is brought to the health and safety of the staff.

Disclosure of Invention

In view of the foregoing drawbacks and deficiencies of the prior art, it is desirable to provide an improved super precision numerically controlled lathe.

In a first aspect, the present application provides an improved ultra-precision numerically controlled lathe comprising:

the lathe comprises a lathe body, a pressing mechanism and a pressing mechanism, wherein the lathe body is of a hollow structure, and a processing mechanism is arranged inside the lathe body;

the adsorption mechanism comprises a storage box, the storage box is arranged at the top of the lathe body, a fan is connected to the right side of the storage box through a first air pipe, a second air pipe is arranged on the left side wall of the storage box, one end, away from the storage box, of the second air pipe penetrates through the lathe body and is connected with an adsorption port, and the adsorption port is located above the processing mechanism.

According to the technical scheme that this application embodiment provided, still include cooling body, cooling body includes the water tank, the water tank sets up lathe body top, water tank right side wall is provided with the water pipe, the water pipe is kept away from the one end of water tank runs through lathe body extends to lathe body internal connection has the shower head, just the shower head is located the processing mechanism top, be provided with the valve on the water pipe.

According to the technical scheme that this application embodiment provided, be provided with the support on the lathe body left side wall, the support top is provided with the motor, the motor has the drive end, the drive end level runs through left the lathe body left side wall extends to inside the lathe body to coaxial coupling has the three chuck that changes.

According to the technical scheme that this application embodiment provided, be provided with first slide rail and fixed plate on the inner wall of lathe body bottom, the fixed plate is close to lathe body right side wall sets up, the fixed plate top is provided with the pneumatic cylinder, the pneumatic cylinder has the pushing end, pushing end level is connected with the slider left, the slider slides and sets up on the first slide rail, the slider top is provided with electric telescopic handle, electric telescopic handle has the flexible end, the flexible end is vertical upwards to be set up, and is connected with the handle of a knife along the horizontal direction, handle of a knife left end coaxial coupling has the processing sword.

According to the technical scheme that this application embodiment provided, the discharge gate is seted up to lathe body bottom, the discharge gate bottom is provided with the receiver, the inside drainage plate that still is provided with of lathe body, drainage plate one end is connected with lathe body left side inner wall, the other end with the discharge gate left side wall is connected, lathe body bottom still is provided with two landing legs, two the landing leg is located respectively both ends about the lathe body bottom.

According to the technical scheme that this application embodiment provided, the drain hole has been seted up on a lathe body lateral wall, both ends are provided with respectively along the second slide rail of horizontal direction about the drain hole, two slidable mounting has the glass door between the second slide rail, still be provided with control panel on the lathe body lateral wall, control panel with the motor pneumatic cylinder and electric telescopic handle electricity is connected.

To sum up, this technical scheme specifically discloses an improved generation super precision numerical control lathe, including the lathe body, it is hollow structure, its inside is provided with processing agency, be used for processing spare part, be provided with adsorption facility on the lathe body, adsorption facility includes the bin, the bin sets up at lathe body top, bin right side wall is connected with the fan through first gas tube, bin left side wall sets up the second trachea, the one end that the bin was kept away from to the second trachea runs through the lathe body and extends to lathe body inside and be connected with the adsorption port, the adsorption port is located the processing agency top, thereby, when processing spare part, through the suction of fan, can inhale the storage incasement through adsorption port and second trachea with the miniature metal granule that produces because of processing spare part, the miniature metal granule that will float in the lathe body when avoiding the staff to take the product after processing, staff's health safety has been protected.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments, made with reference to the following drawings, in which:

FIG. 1 is a schematic diagram of the internal structure of an improved ultra-precision numerical control lathe.

Fig. 2 is a front view of an improved super precision numerically controlled lathe.

Fig. 3 is a schematic view of the internal structure of the storage box.

Reference numerals in the drawings: 1. a lathe body; 2. a motor; 3. a three-turn chuck; 4. an adsorption mechanism; 401. a storage box; 402. a blower; 403. a first air tube; 404. a screen cover; 405. a second air pipe; 406. an adsorption port; 5. a connecting rod; 6. a drainage plate; 7. a fixing plate; 8. a processing mechanism; 801. a hydraulic cylinder; 802. a knife handle; 803. a slide block; 804. an electric telescopic rod; 9. a cooling mechanism; 901. a water tank; 902. a water pipe; 903. a valve; 904. a spray header; 10. a second slide rail; 11. a glass door; 12. a control panel; 13. a storage box; 14. a first slide rail.

Detailed Description

The present application is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting of the utility model. It should be noted that, for convenience of description, only the portions related to the utility model are shown in the drawings.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Example 1

Please refer to an improved generation super precision numerical control lathe inner structure schematic diagram that fig. 1 shows, including lathe body 1, the support sets up on lathe body 1 left side wall, motor 2 sets up at the support top, motor 2 has the drive end, drive end level runs through lathe body 1 left side wall coaxial coupling has three-turn chuck 3 to the left, fixed plate 7 and first slide rail 14 all set up on lathe body 1 inside diapire, and fixed plate 7 is close to lathe body 1 right side wall setting, processing mechanism 8 includes pneumatic cylinder 801, pneumatic cylinder 801 has stiff end and pushing end, the stiff end sets up at fixed plate 7 top, pushing end level is connected with slider 803 to the left, slider 803 slides and sets up on first slide rail 14, electric telescopic handle 804 sets up at slider 803 top, electric telescopic handle 804 has the flexible end, the vertical upward connection of flexible end has handle 802, handle 802 sets up along the horizontal direction, the coaxial setting of processing sword is at handle 802 left end.

As shown in fig. 1 to 3, the adsorption mechanism 4 includes a storage box 401, the storage box 401 and a fan 402 are all disposed at the top of the lathe body 1, the fan 402 is located on the right side of the storage box 401, an air suction inlet is formed on the right side wall of the storage box 401, a filter screen cover 404 is disposed on the right side inner wall of the storage box 401 and covers the air suction inlet, the fan 402 has an input end, one end of a first air pipe 403 is connected with the input end, and the other end is connected with the air suction inlet.

The adsorption port 406 is arranged inside the lathe body 1 and is located above the cutter handle 802, the adsorption port 406 is provided with an adsorption end, the left end of the adsorption port 406 is higher than the right end of the adsorption port 406, the adsorption end can face the processing cutter, the adsorption port 406 is connected with the lathe body 1 through the connecting rod 5, the second air pipe 405 is arranged on the left side wall of the storage box 401, and one end, far away from the storage box 401, of the second air pipe 405 penetrates through the lathe body 1 to extend into the lathe body 1 and is communicated with the adsorption port 406.

The cooling mechanism 9 sets up in adsorption equipment 4 left side, and cooling mechanism 9 includes water tank 901, and water tank 901 sets up at lathe body 1 top, and the delivery port is seted up at water tank 901 right side wall, and water pipe 902 sets up at the delivery port, and water pipe 902 keep away from the one end of water tank 901 and run through lathe body 1 and extend to lathe body 1 inside, and be connected with shower head 904, shower head 904 slope setting, its left end height is higher than right-hand member height, and left end and lathe body 1 top inner wall are connected, and shower head 904 is located the processing sword top, and valve 903 sets up on water pipe 902.

The discharge gate is offered in lathe body 1 bottom, and the discharge gate is located first slide rail 14 left side, and receiver 13 sets up in lathe body 1 bottom, and is linked together through discharge gate and lathe body 1 inside, and drainage plate 6 one end is connected with lathe body 1 left side inner wall, and the other end is connected with discharge gate left side wall, and both ends are controlled at lathe body 1 bottom respectively to two landing legs setting.

The drain hole is offered on a lateral wall of lathe body 1, and two second slide rails 10 along the horizontal direction set up respectively at drain hole upper and lower both ends, and glass door 11 slides and sets up between two second slide rails 10, and control panel 12 sets up on a lateral wall of lathe body 1, and motor 2, pneumatic cylinder 801 and electric telescopic handle 804 all are connected with control panel 12 electricity.

When the automatic iron scrap iron collecting device is used, firstly, the glass door 11 is pushed to open the discharge hole, then, parts to be processed are placed on the three-rotation chuck 3, the three-rotation chuck 3 clamps the parts, then, the glass door 11 is closed, the motor 2 is controlled by the control panel 12 to be started, the motor 2 driving end drives the three-rotation chuck 3 to rotate, then, the hydraulic cylinder 801 and the electric telescopic rod 804 are started by the control panel 12, the pushing end of the hydraulic cylinder 801 can push the sliding block 803 to move left and right on the first sliding rail 14, the telescopic end of the electric telescopic rod 804 can drive the cutter handle 802 to move up and down, under the coordination of the hydraulic cylinder 801 and the electric telescopic rod 804, the processing cutter on the cutter handle 802 can rapidly and accurately complete the processing of the parts, the fan 402 and the valve 903 are started during the processing, the suction generated by the fan 402 can be conveyed to the adsorption port 406 through the second air pipe 405, the adsorption port 406 can absorb micro metal particles floating in the lathe, and the micro metal particles are collected through the storage box 401, the water inside the water in the water tank 901 can be conveyed to the spray head 904 through the water pipe 902, the cutter handle 802 is cooled down by the cutter handle 802, the cutter is prevented from being broken down, the cutter is convenient to be placed in the storage box 13, and the storage box is convenient to store in the processing box 13, and the iron scrap iron 13 is set up and the iron scrap iron 13 is convenient to be processed.

After processing is finished, the glass door 11 is pushed to open the discharging hole, a worker takes the processed parts, and micro metal particles floating in the lathe are absorbed by the absorbed mechanism, so that the worker cannot inhale the micro metal particles floating in the lathe to the body, the health and safety of the worker are protected, meanwhile, the setting of the glass door 11 facilitates the worker to observe the processing condition of the parts and the conditions of all mechanism parts in the lathe body, the hidden danger of processing is avoided, and the worker is convenient to operate.

The foregoing description is only of the preferred embodiments of the present application and is presented as a description of the principles of the technology being utilized. It will be appreciated by persons skilled in the art that the scope of the utility model referred to in this application is not limited to the specific combinations of features described above, but it is intended to cover other embodiments in which any combination of features described above or equivalents thereof is possible without departing from the spirit of the utility model. Such as the above-described features and technical features having similar functions (but not limited to) disclosed in the present application are replaced with each other.

Claims (6)

1. An improved super-precision numerical control lathe is characterized by comprising:

the lathe comprises a lathe body (1) which is of a hollow structure, wherein a processing mechanism (8) is arranged inside the lathe body (1);

adsorption equipment (4), adsorption equipment (4) are including storage box (401), storage box (401) set up at the top of lathe body (1), storage box (401) right side is connected with fan (402) through first gas tube (403), storage box (401) left side wall is provided with second trachea (405), second trachea (405) keep away from one end of storage box (401) runs through lathe body (1) is connected with adsorption port (406), adsorption port (406) are located processing agency (8) top.

2. The improved super precision numerical control lathe according to claim 1, further comprising a cooling mechanism (9), wherein the cooling mechanism (9) comprises a water tank (901), the water tank (901) is arranged at the top of the lathe body (1), a water pipe (902) is arranged on the right side wall of the water tank (901), one end, far away from the water tank (901), of the water pipe (902) penetrates through the lathe body (1) and extends to the lathe body (1) and is internally connected with a spray head (904), the spray head (904) is arranged above the processing mechanism (8), and a valve (903) is arranged on the water pipe (902).

3. The improved super-precision numerical control lathe according to claim 2, wherein a support is arranged on the left side wall of the lathe body (1), a motor (2) is arranged at the top of the support, the motor (2) is provided with a driving end, and the driving end horizontally penetrates through the left side wall of the lathe body (1) to extend into the lathe body (1) leftwards and is coaxially connected with a three-rotation chuck (3).

4. The improved super-precision numerical control lathe according to claim 3, wherein a first sliding rail (14) and a fixed plate (7) are arranged on the inner wall of the bottom of the lathe body (1), the fixed plate (7) is arranged close to the right side wall of the lathe body (1), a hydraulic cylinder (801) is arranged at the top of the fixed plate (7), the hydraulic cylinder (801) is provided with a pushing end, the pushing end is horizontally connected with a sliding block (803) leftwards, the sliding block (803) is slidingly arranged on the first sliding rail (14), an electric telescopic rod (804) is arranged at the top of the sliding block (803), the electric telescopic rod (804) is provided with a telescopic end, the telescopic end is vertically upwards arranged and is connected with a tool holder (802) along the horizontal direction, and the left end of the tool holder (802) is coaxially connected with a processing tool.

5. The improved super-precision numerical control lathe is characterized in that a discharge hole is formed in the bottom of the lathe body (1), a storage box (13) is arranged at the bottom of the discharge hole, a drainage plate (6) is further arranged in the lathe body (1), one end of the drainage plate (6) is connected with the left inner wall of the lathe body (1), the other end of the drainage plate is connected with the left side wall of the discharge hole, two supporting legs are further arranged at the bottom of the lathe body (1), and the two supporting legs are respectively located at the left end and the right end of the bottom of the lathe body (1).

6. The improved super-precision numerical control lathe according to claim 5, wherein a discharging hole is formed in one side wall of the lathe body (1), second sliding rails (10) along the horizontal direction are respectively arranged at the upper end and the lower end of the discharging hole, a glass door (11) is slidably arranged between the two second sliding rails (10), a control panel (12) is further arranged on one side wall of the lathe body (1), and the control panel (12) is electrically connected with the motor (2), the hydraulic cylinder (801) and the electric telescopic rod (804).

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