CN216398950U

CN216398950U - Cutting fluid sharing control system

Info

Publication number: CN216398950U
Application number: CN202122834199.6U
Authority: CN
Inventors: 唐海洋
Original assignee: Shaanxi Lianzong Technology Industry Co ltd
Current assignee: Shaanxi Lianzong Technology Industry Co ltd
Priority date: 2021-11-18
Filing date: 2021-11-18
Publication date: 2022-04-29
Anticipated expiration: 2031-11-18

Abstract

The utility model discloses a cutting fluid sharing control system, which comprises an equipment body, a cooling circulation system, a flow monitoring assembly and a fixing assembly, wherein all cutting fluids of production line equipment can be communicated through a pipeline or a groove, a cutting fluid turnover pool and a cooling room are arranged in the middle, the cutting fluids of the equipment are shared, the turnover pool is arranged in the middle, a flow meter is arranged in the middle section of a shared pipeline, the using amount of the cutting fluids of the shared pipeline is monitored through the flow meter, when the using amount of the equipment is larger, the cutting fluids are output from the turnover pool to enter a cutting fluid sharing system, the cutting fluids are supplemented for the equipment, and when the using amount of the equipment is less, the cutting fluids of the sharing system are excessive, so that the cutting fluids enter the turnover pool. According to theoretical analysis, can practice thrift about 50% cutting fluid, rotate the flowmeter pipeline segmentation and connect through the screw thread simultaneously, seal and fix the flowmeter kneck through splint spacing, conveniently carry out dismouting and change to the flowmeter.

Description

Cutting fluid sharing control system

Technical Field

The utility model relates to the technical field of cutting fluid sharing control systems, in particular to a cutting fluid sharing control system.

Background

The cutting fluid (coolant) is an industrial liquid used for cooling and lubricating cutters and workpieces in the metal cutting and grinding process, is formed by scientifically compounding and matching various super-strong functional additives, and has the characteristics of good cooling performance, lubricating performance, antirust performance, oil removal and cleaning functions, anticorrosion function and easiness in dilution.

The existing numerical control machine tool has a cooling function, each machine tool is provided with a box (a part of machine tool parts) for storing cutting fluid, but the cutting fluid of each machine tool is independently used, so that the cutting fluid must be filled into each machine tool, but the machine tools do not work simultaneously, so that the cutting fluid must be supplemented frequently for some machine tools, the cutting fluid is easy to deteriorate due to the fact that the machine tools are not frequently used or the use amount is small, and finally the new cutting fluid must be replaced, so that waste is caused, the cost for purchasing the cutting fluid of enterprises is increased, the deteriorated cutting fluid belongs to industrial hazardous waste, the processing of qualified hazardous waste processing enterprises is required, the enterprises need to pay additional hazardous waste transfer and processing cost, and the production cost is increased.

SUMMERY OF THE UTILITY MODEL

This section is for the purpose of summarizing some aspects of embodiments of the utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the abstract of the specification and the title of the application to avoid obscuring the purpose of this section, the abstract of the specification and the title of the application, and such simplifications or omissions are not intended to limit the scope of the utility model.

The present invention has been made in view of the above and/or other problems occurring in the conventional cutting fluid sharing control system.

Therefore, the utility model aims to provide a cutting fluid sharing control system, which can be used for communicating all cutting fluids of production line equipment through a pipeline or a groove, meanwhile, a cutting fluid turnover pool and a cooling room are arranged in the middle of the cutting fluid sharing control system, the cutting fluids of the equipment are shared, a turnover pool is arranged in the middle of the cutting fluid sharing control system, a flowmeter is arranged in the middle section of a shared pipeline, the using amount of the cutting fluids of the shared pipeline is monitored through the flowmeter, when the using amount of the equipment is large, the cutting fluids are output from the turnover pool and enter a cutting fluid sharing system to supplement the cutting fluids for the equipment, and when the using amount of the equipment is small, the cutting fluids of the sharing system are excessive and then enter the turnover pool. According to theoretical analysis, can practice thrift about 50% cutting fluid, rotate the flowmeter pipeline segmentation and connect through the screw thread simultaneously, seal and fix the flowmeter kneck through splint spacing, conveniently carry out dismouting and change to the flowmeter.

To solve the above technical problem, according to an aspect of the present invention, the present invention provides the following technical solutions:

a cutting fluid sharing control system, comprising:

an apparatus body;

the cooling circulation system comprises a first conveying pipe arranged on the side wall of the equipment body, a shared conveying pipe connected to the other end of the first conveying pipe, a cooling chamber arranged on a pipe body of the shared conveying pipe, a turnover pool arranged at the other end of the shared conveying pipe, a second conveying pipe arranged on the side wall of the turnover pool and an electric pump arranged on the pipe body of the second conveying pipe, wherein the other end of the second conveying pipe is connected to the side wall of the equipment body;

the flow monitoring assembly comprises a first flange plate arranged on the pipe body of the shared conveying pipe, a first connecting pipe arranged on the side wall of the first flange plate, a monitoring pipe arranged at the other end of the first connecting pipe, a second connecting pipe arranged at the other end of the monitoring pipe, a second flange plate arranged on the side wall of the second connecting pipe and a display arranged on the side wall of the monitoring pipe.

As a preferable aspect of the cutting fluid sharing control system, sealing rings are disposed at joints of the first flange, the second flange and the sharing conveying pipe.

As a preferable scheme of the cutting fluid sharing control system, the flow monitoring assembly further includes a first external thread bushing installed at an opening of the first connection pipe, a first internal thread bushing installed at an opening of a left side of the monitoring pipe, a second internal thread bushing installed at an opening of a right side of the monitoring pipe, and a second external thread bushing installed at an opening of the second connection pipe.

As a preferable aspect of the cutting fluid sharing control system of the present invention, the diameter of the outer wall of the first external thread bushing is the same as the diameter of the inner wall of the first internal thread bushing, the thread of the outer wall of the first external thread bushing is the same as the thread of the inner wall of the first internal thread bushing, the diameter of the outer wall of the second external thread bushing is the same as the diameter of the inner wall of the second internal thread bushing, the thread of the outer wall of the second external thread bushing is the same as the thread of the inner wall of the second internal thread bushing, the first external thread bushing is embedded in the first internal thread bushing and is rotatably connected to the first internal thread bushing, and the second external thread bushing is embedded in the second internal thread bushing and is rotatably connected to the second internal thread bushing.

As a preferable scheme of the cutting fluid sharing control system, the cutting fluid sharing control system further comprises a fixing assembly, wherein the fixing assembly comprises a first arc-shaped plate, first fixing plates installed at two ends of the first arc-shaped plate, a first threaded hole formed in the top of the first fixing plate, a second arc-shaped plate located right above the first arc-shaped plate, second fixing plates installed at two ends of the second arc-shaped plate, a second threaded hole formed in the top of the second fixing plate, and a threaded rod penetrating through the second threaded hole and the first threaded hole.

As a preferable aspect of the cutting fluid sharing control system, when the second arc-shaped plate and the first arc-shaped plate are closed, the second arc-shaped plate and the first arc-shaped plate form a circular cavity, and the diameter of the circular cavity is the same as the diameter of the outer wall of the first internal thread sleeve.

Compared with the prior art: can get up the cutting fluid of each production line equipment is whole through pipeline or slot UNICOM, set up cutting fluid turnover pond and cooling room in the middle of simultaneously, get up the cutting fluid sharing of each equipment, the middle turnover pond that sets up, the flowmeter is installed in the sharing pipeline middle section, share pipeline cutting fluid usage through the flowmeter monitoring, when equipment usage is great, from turnover pond output cutting fluid entering cutting fluid sharing system, supply the cutting fluid, supply equipment uses, when equipment uses less, sharing system cutting fluid is surplus, make the cutting fluid get into the turnover pond. According to theoretical analysis, can practice thrift about 50% cutting fluid, rotate the flowmeter pipeline segmentation and connect through the screw thread simultaneously, seal and fix the flowmeter kneck through splint spacing, conveniently carry out dismouting and change to the flowmeter.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and detailed embodiments, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive exercise. Wherein:

FIG. 1 is a general structural diagram of a cutting fluid sharing control system according to the present invention;

FIG. 2 is an internal view of a turnover tank of the cutting fluid sharing control system of the present invention;

FIG. 3 is a schematic diagram of a flow monitoring assembly of a cutting fluid sharing control system according to the present invention;

FIG. 4 is a diagram of a fixture assembly of a cutting fluid sharing control system according to the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

Next, the present invention will be described in detail with reference to the drawings, wherein for convenience of illustration, the cross-sectional view of the device structure is not enlarged partially according to the general scale, and the drawings are only examples, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in the actual fabrication.

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The utility model provides a cutting fluid sharing control system, which can be used for communicating all cutting fluids of production line equipment through a pipeline or a groove, meanwhile, a cutting fluid turnover pool and a cooling room are arranged in the middle, the cutting fluids of the equipment are shared, a turnover pool is arranged in the middle, a flowmeter is arranged in the middle section of a shared pipeline, the using amount of the cutting fluids of the shared pipeline is monitored through the flowmeter, when the using amount of the equipment is large, the cutting fluids are output from the turnover pool and enter a cutting fluid sharing system to supplement the cutting fluids for the equipment, and when the using amount of the equipment is small, the cutting fluids of the sharing system are excessive and then enter the turnover pool. According to theoretical analysis, can practice thrift about 50% cutting fluid, rotate the flowmeter pipeline segmentation and connect through the screw thread simultaneously, seal and fix the flowmeter kneck through splint spacing, conveniently carry out dismouting and change to the flowmeter.

Fig. 1-2 are first structural schematic diagrams illustrating a cutting fluid sharing control system according to an embodiment of the present invention, and referring to fig. 1-2, the cutting fluid sharing control system according to the embodiment includes an apparatus body 100, a cooling circulation system 200, and a flow monitoring assembly 300.

The cooling circulation system 200 includes a first delivery pipe 210 installed at a side wall of the equipment body 100, a shared delivery pipe 220 connected to the other end of the first delivery pipe 210, a cooling chamber 230 installed at a pipe body of the shared delivery pipe 220, a turnover tank 240 installed at the other end of the shared delivery pipe 220, a second delivery pipe 250 installed at a side wall of the turnover tank 240, and an electric pump 260 installed at a pipe body of the second delivery pipe 250, wherein the other end of the second delivery pipe 250 is connected to the side wall of the equipment body 100, the cutting fluid inside the equipment body 100 is collected into the shared delivery pipe 220 through the first delivery pipe 210, and flows into the cooling chamber 230 through the shared delivery pipe 220 to cool the cutting fluid, and the cooled cutting fluid is delivered from the turnover tank 240 into the second delivery pipe 250 to be collected, and is delivered into the plurality of equipment bodies 100 through the electric pump 260.

The flow monitoring assembly 300 comprises a first flange plate 310 installed on the pipe body of the shared conveying pipe 220, a first connecting pipe 320 installed on the side wall of the first flange plate 310, a monitoring pipe 330 installed at the other end of the first connecting pipe 320, a second connecting pipe 340 installed at the other end of the monitoring pipe 330, a second flange plate 350 installed on the side wall of the second connecting pipe 340 and a display 360 installed on the side wall of the monitoring pipe 330, wherein the first flange plate 310 and the second flange plate 350 are respectively connected with the shared conveying pipe 220, cutting fluid is conveyed to the monitoring pipe 330 through the first connecting pipe 320, the monitoring pipe 330 monitors the flow of the cutting fluid, the monitoring result is displayed through the display 360, signals are transmitted to the electric pump 260, and the electric pump 260 is controlled to convey the cutting fluid in the turnover pool 240 to the interior of the second conveying pipe 250.

Referring to fig. 1-2, in the cutting fluid sharing control system of the present embodiment, when in use, the cooling fluid in the plurality of apparatus bodies 100 is collected into the shared delivery pipe 220 through the first delivery pipe 210, the cutting fluid in the shared delivery pipe 220 passes through the monitoring pipe 330, the monitoring pipe 330 monitors the flow rate of the internal cutting fluid and displays the monitoring result through the display 360, the cutting fluid passes through the cooling chamber 230 of the body of the shared delivery pipe 220 and completes cooling in the cooling chamber 230, the cutting fluid after cooling is continuously delivered into the turnover tank 240 through the shared delivery pipe 220 to complete turnover, the display 360 sends the monitored signal to the electric pump 260, the electric pump 260 delivers the cutting fluid with different volumes from the second delivery pipe 250 to the inside of the apparatus bodies 100 through the flow rate detection result, the consumption of the cutting fluid in the shared pipeline is monitored through the monitoring pipe 330, when the equipment use amount is large, the cutting fluid is output from the turnover tank 240 and enters the cutting fluid sharing system to supplement the cutting fluid for the equipment use, and when the equipment use amount is small, the cutting fluid of the sharing system is excessive, so that the cutting fluid enters the turnover tank 240. According to theoretical analysis, the cutting fluid can be saved by about 50%.

Fig. 3-4 are second structural diagrams illustrating a cutting fluid sharing control system according to an embodiment of the present invention, and referring to fig. 3-4, unlike the above embodiment, the cutting fluid sharing control system according to the embodiment includes a fixing assembly 400.

A first external thread sleeve 321 is installed at an opening of the first connecting pipe 320, a first internal thread sleeve 331 is installed at an opening of the left side of the monitoring pipe 330, a second internal thread sleeve 332 is installed at an opening of the right side of the monitoring pipe 330, a second external thread sleeve 341 is installed at an opening of the second connecting pipe 340, the diameter of the outer wall of the first external thread sleeve 321 is the same as that of the inner wall of the first internal thread sleeve 331, the thread of the outer wall of the first external thread sleeve 321 is consistent with that of the inner wall of the first internal thread sleeve 331, the diameter of the outer wall of the second external thread sleeve 341 is the same as that of the inner wall of the second internal thread sleeve 332, the thread of the outer wall of the second external thread sleeve 341 is consistent with that of the inner wall of the second internal thread sleeve 332, the first external thread sleeve 321 is embedded inside the first internal thread sleeve 331 and is rotatably connected with the first internal thread sleeve 331, and the second external thread sleeve 341 is embedded inside the second internal thread sleeve 332.

The fixing assembly 400 includes a first arc plate 410, first fixing plates 420 installed at both ends of the first arc plate 410, first screw holes 421 opened at the top of the first fixing plates 420, a second arc plate 430 positioned right above the first arc plate 410, second fixing plates 440 installed at both ends of the second arc plate 430, second screw holes 441 opened at the top of the second fixing plates 440, and a screw rod 450 penetrating the second screw holes 441 and the first screw holes 421, when the second arc-shaped plate 430 is closed with the first arc-shaped plate 410, the second arc-shaped plate 430 and the first arc-shaped plate 410 form a circular cavity, the diameter of the circular cavity is the same as the diameter of the outer wall of the first internal thread sleeve 331, the threaded rod 450 penetrates through the first threaded hole 421 and the second threaded hole 441, the body thread of the threaded rod 450 and the second threaded hole 441 are in threaded fit with the inner part of the first threaded hole 421, and the second arc-shaped plate 430 and the first arc-shaped plate 410 are driven to approach and fit with each other by the screw rod structure.

Referring to fig. 3 to 4, in the cutting fluid sharing control system of this embodiment, by rotating the monitoring tube 330, the first external thread bushing 321 rotates inside the first internal thread bushing 331, the first connection tube 320 and the monitoring tube 330 are rotatably connected by thread fit, the second external thread bushing 341 rotates inside the second internal thread bushing 332, the second connection tube 340 and the monitoring tube 330 are rotatably connected by thread fit, the monitoring tube 330 is conveniently mounted and dismounted, by placing the first external thread bushing 321 and the second external thread bushing 341 between the first arc plate 410 and the second arc plate 430, the threaded rod 450 penetrates through the first threaded hole 421 and the second threaded hole 441, the threaded rod 450 is rotated, the threaded rod 450 rotates inside the second threaded hole 441 and the first threaded hole 421, the first arc plate 410 and the second arc plate 430 are driven to approach each other by the lead screw structure, the inner walls of the first arc plate 410 and the second arc plate 430 tightly attach the outer walls of the first external thread bushing 321 and the second external thread bushing 341, the sealing and tightening operations at the connection of the first connection pipe 320, the monitoring pipe 330 and the second connection pipe 340 are completed.

While the utility model has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the various features of the disclosed embodiments of the utility model may be used in any combination, provided that no structural conflict exists, and the combinations are not exhaustively described in this specification merely for the sake of brevity and resource conservation. Therefore, it is intended that the utility model not be limited to the particular embodiments disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims

1. A cutting fluid sharing control system, comprising:

an apparatus body (100);

a cooling circulation system (200) including a first delivery pipe (210) installed at a side wall of the apparatus body (100), a shared delivery pipe (220) connected to the other end of the first delivery pipe (210), a cooling chamber (230) installed at a pipe body of the shared delivery pipe (220), a circulation tank (240) installed at the other end of the shared delivery pipe (220), a second delivery pipe (250) installed at a side wall of the circulation tank (240), and an electric pump (260) installed at a pipe body of the second delivery pipe (250), the other end of the second delivery pipe (250) being connected to the side wall of the apparatus body (100);

flow monitoring subassembly (300), including installing first ring flange (310) of sharing conveyer pipe (220) shaft, install first connecting pipe (320) of first ring flange (310) lateral wall, install monitoring pipe (330) of first connecting pipe (320) other end, install second connecting pipe (340) of monitoring pipe (330) other end, install second ring flange (350) of second connecting pipe (340) lateral wall and install monitor (360) of pipe (330) lateral wall.

2. The cutting fluid sharing control system according to claim 1, wherein sealing rings are arranged at the joints of the first flange plate (310) and the second flange plate (350) and the sharing delivery pipe (220).

3. The cutting fluid sharing control system according to claim 1, wherein the flow rate monitoring assembly (300) further comprises a first externally threaded sleeve (321) installed at the opening of the first connection pipe (320), a first internally threaded sleeve (331) installed at the opening of the left side of the monitoring pipe (330), a second internally threaded sleeve (332) installed at the opening of the right side of the monitoring pipe (330), and a second externally threaded sleeve (341) installed at the opening of the second connection pipe (340).

4. A cutting fluid sharing control system according to claim 3, wherein the outer wall diameter of the first external thread bushing (321) is the same as the inner wall diameter of the first internal thread bushing (331), the outer wall thread of the first external thread bushing (321) is the same as the inner wall thread of the first internal thread bushing (331), the outer wall diameter of the second external thread bushing (341) is the same as the inner wall diameter of the second internal thread bushing (332), the outer wall thread of the second external thread bushing (341) is the same as the inner wall thread of the second internal thread bushing (332), the first external thread bushing (321) is embedded in the first internal thread bushing (331) and is rotatably connected with the first internal thread bushing (331), and the second external thread bushing (341) is embedded in the second internal thread bushing (332) and is rotatably connected with the second internal thread bushing (332).

5. The cutting fluid sharing control system according to claim 4, further comprising a fixing assembly (400), wherein the fixing assembly (400) comprises a first arc-shaped plate (410), first fixing plates (420) installed at both ends of the first arc-shaped plate (410), a first threaded hole (421) opened at the top of the first fixing plate (420), a second arc-shaped plate (430) located right above the first arc-shaped plate (410), second fixing plates (440) installed at both ends of the second arc-shaped plate (430), a second threaded hole (441) opened at the top of the second fixing plate (440), and a threaded rod (450) penetrating through the second threaded hole (441) and the first threaded hole (421).

6. The cutting fluid sharing control system according to claim 5, wherein when the second arc-shaped plate (430) and the first arc-shaped plate (410) are closed, the second arc-shaped plate (430) and the first arc-shaped plate (410) form a circular cavity, and the diameter of the circular cavity is the same as that of the outer wall of the first internal thread sleeve (331).