KR102632601B1 - Vacuum circulation pump system - Google Patents

Abstract

The present invention relates to a vacuum circulation pump system that filters out foreign substances mixed in cutting oil and reuses it.

Description

Vacuum circulation pump system {Vacuum circulation pump system}

The present invention relates to a vacuum circulation pump system, and more specifically, to a vacuum circulation pump system to protect the vacuum pump by filtering out foreign substances mixed in the cutting oil and reusing it, and to prevent moisture from flowing into the pump side. will be.

Generally, cutting oil is used for cutting metal.

Cutting oil is a metal processing oil used in metal processing such as cutting, grinding, polishing, drawing, pressing, and rolling. It reduces friction and tool wear due to lubrication, and improves tool life by cooling the tool or workpiece. , suppresses build-up edges and quickly ejects chips, improving the dimensional accuracy of the machined part and extending the life of the tool, and using tools such as bites or cutters to prevent rust on the machined surface. The cutting tool is supplied to the machining area in contact with the material to be cut.

This cutting oil is discharged as a mixture of large and small chips and fine cutting powder, so when reused, the chips and cutting powder act on the machined surface, resulting in machining defects and decreased machining efficiency. Because there are none, they are discarded without being recovered.

Typically, in cutting operations, a large amount of cutting oil is used as the cutting oil is continuously supplied to the machining surface in contact with the tool, so the cost due to cutting oil that cannot be recovered is relatively high. In addition, large amounts of waste cutting oil cause economic losses due to waste oil disposal.

Therefore, a means is needed to filter, recover, and recycle the cutting sludge.

Republic of Korea Patent Publication No. 10-2009-0130966

The purpose of the present invention is to protect the vacuum pump by filtering out foreign substances mixed in cutting oil and reusing it.

Additionally, the purpose is to prevent moisture from passing to the pump side.

The present invention is characterized as a vacuum circulation pump system that protects the vacuum pump by filtering out foreign substances mixed in the cutting oil and reusing it.

In one embodiment, the vacuum circulation pump system includes a chamber seating frame formed as a square box to seat the vacuum tank and the control switchboard, a plurality of frame supports formed on the lower surface of the chamber seating frame to support the chamber seating frame, and , a frame inner panel formed inside the chamber seating frame so that the cutting oil pump can be seated, a vacuum tank formed on one side of the upper part of the chamber seating frame so that the cutting oil flowing through the cutting oil inlet pipe can be filtered and stored through the cutting oil filter, and , a cutting oil inflow pipe formed on one side of the upper part of the vacuum tank to receive cutting oil from an external cutting oil tank, a cutting oil filter formed on one side of the cutting oil inflow pipe to filter out foreign substances mixed in the incoming cutting oil, and a cutting oil inflow pipe that flows into the cutting oil inflow pipe. A cutting oil inflow valve is formed to open and close on one side of the cutting oil filter to control the flow rate of cutting oil, or to smoothly block or inflow, and a vacuum pump is connected to an external vacuum pump to suck in and discharge the air inside the incoming vacuum tank. An air discharge pipe formed on the other side of the upper part of the tank, an air discharge valve formed to open and close on one side of the air discharge pipe to control the amount of air sucked and discharged, block the air sucked and discharged, or allow smooth discharge, and stored in a vacuum tank. A leveling pipe is formed so that one side is connected to the upper part of one side of the vacuum tank and the other side is connected to the lower side of the vacuum tank so that the amount of cutting fluid stored inside the vacuum tank can be checked, and the cutting fluid stored in the vacuum tank is supplied to the cutting fluid pump. A cutting oil discharge pipe is formed in the center of the bottom of the vacuum tank to discharge it using a coolant discharge pipe, a coolant pump is mounted on the upper surface of the frame inner panel so that the coolant can be re-supplied to the initial coolant tank through the coolant discharge pipe, and a control switchboard is installed in the chamber seating frame. It is characterized in that it includes a distribution board seating plate formed on the other side of the upper part of the chamber seating frame so that it can be installed in the chamber seating frame, and a control distribution board mounted on the upper part of the distribution panel seating plate to drive the vacuum pump and the cutting oil pump installed externally.

In another embodiment, the vacuum circulation pump system further includes a seismic fixing part at a certain distance from the ground to prevent vibration generated from the ground from being transmitted to the vacuum tank, and the seismic fixing part includes a seating plate. A support plate is formed to sit on the ground to support the machine, a plurality of earthquake-resistant pads are formed on the bottom of the support plate to absorb vibrations generated from the coolant pump, and the chamber seating frame is connected by an air tube at a certain distance from the support plate to be seated. A seating plate is formed, a support fixing groove is formed on the upper surface of the seating plate so that the frame support can be inserted, and a number corresponding to the frame support is formed, and a contact member is formed on both sides of the upper side of the seating plate to adhere the contact member to the frame support chamber seating frame side. A close contact cylinder and a close contact member that is connected to the cylinder axis of the close cylinder so that it can be fixed on the seat plate without causing vibration of the chamber seat frame and is closely attached to both sides of the chamber seat frame by the drive of the close cylinder, and to prevent vibration. A plurality of air tubes are formed between the seating plate and the support plate for damping, an air injection nozzle is formed on one side of the air tube to inject air into the air tube, and an air injection nozzle is formed on one side of the air tube to sense the pressure inside the air tube. It is characterized by including a pressure sensor and a shock absorbing spring formed to support the seating plate inside the air tube to support the load applied to the seating plate and attenuate vibration.

As mentioned above, the cutting oil used in the machine is recovered and filtered to protect the vacuum pump by filtering out foreign substances, providing the effect of preventing moisture from passing into the pump, and storing the cutting oil in a vacuum to prevent discoloration. It provides the effect of recirculating the cutting oil into the machine and making it reusable.

1 is a diagram of the vacuum circulation pump system of the present invention.
2A to 2B are product photos of the present invention.
Figure 3 is a diagram of an earthquake-resistant fixing unit, which is another embodiment of the present invention.
Figure 4 is a detailed view of Figure 3.
Figure 5 is a diagram of a variable raising and lowering unit, which is another embodiment of the present invention.
Figure 6 is a detailed view of Figure 5.
Figure 7 is a view of a waste oil treatment unit, which is another embodiment of the present invention.
Figure 8 is a detailed view of Figure 7.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

Hereinafter, the present invention will be described in detail with reference to the drawings.

Figure 1 is a diagram of the vacuum circulation pump system 100 of the present invention, and Figures 2a and 2b are product photos of the present invention.

As shown in the drawing, the vacuum circulation pump system 100 of the present invention is characterized in that it protects the vacuum pump by filtering out foreign substances mixed in the cutting oil and reusing it.

The vacuum circulation pump system 100 includes a chamber seating frame 110, frame support 111, frame inner panel 112, vacuum tank 113, cutting oil inlet pipe 114, cutting oil filter 115, and cutting oil. Inlet valve (116), air discharge pipe (117), air discharge valve (118), leveling pipe (119), cutting oil discharge pipe (120), coolant pump (121), distribution board seating plate (122), and control distribution board (123). It is characterized by including.

The chamber seating frame 110 is formed to seat the vacuum tank 113 and the control switchboard 123, and the chamber seating frame 110 is characterized in that it is formed as a square box.

The frame support 111 is formed to support the chamber seating frame 110, and a plurality of frame supports 111 are formed on the lower surface of the chamber seating frame 110.

The frame inner panel 112 is formed so that the cutting oil pump 121 can be seated, and the frame inner panel 112 is formed inside the chamber seating frame 110.

The vacuum tank 113 is formed so that the cutting oil flowing in through the cutting oil inlet pipe 114 can be filtered and stored through the cutting oil filter 115. The vacuum tank 113 is located at the upper part of the chamber seating frame 110. It is characterized by being formed on one side.

The cutting oil inlet pipe 114 is formed to receive cutting oil from an external cutting oil tank, and the cutting oil inlet pipe 114 is formed on one side of the upper part of the vacuum tank 113.

The cutting oil filter 115 is formed to filter out foreign substances mixed in the incoming cutting oil. The cutting oil filter 115 is formed on one side of the cutting oil inflow pipe 114.

The cutting oil inlet valve 116 is formed to regulate the flow rate of cutting oil flowing into the cutting oil inlet pipe 114, or to ensure smooth blocking or inflow. The cutting oil inlet valve 116 is connected to the cutting oil filter 115. It is characterized in that it is formed to be openable and closed on one side.

The air discharge pipe 117 is connected to an external vacuum pump and is formed to suck in and discharge the air inside the vacuum tank 113 flowing in. The air discharge pipe 117 is formed on the other upper side of the vacuum tank 113. It is characterized by

The air discharge valve 118 is formed to control the amount of air inhaled and discharged, or to block or smoothly discharge the air inhaled and discharged. The air discharge valve 118 opens and closes on one side of the air discharge pipe 117. It is characterized in that it is formed so as to be possible.

The leveling pipe 119 is formed to check the amount of cutting oil stored in the vacuum tank 113 inside the vacuum tank 113. One side of the leveling pipe 119 is the vacuum tank 113. It is connected to the upper side of the side, and the other side is connected to the lower side of the vacuum tank 113.

The cutting oil discharge pipe 120 is formed to discharge the cutting oil stored in the vacuum tank 113 using the cutting oil pump 121. The cutting oil discharge pipe 120 is formed in the lower center of the vacuum tank 113. It is characterized by

The cutting oil pump 121 is formed so that cutting oil can be re-supplied to the initial cutting oil tank through the cutting oil discharge pipe 120. The cutting oil pump 121 is characterized by being seated on the upper surface of the frame inner panel 112. do.

The distribution board seating plate 122 is formed so that the control distribution board 123 can be installed on the chamber seating frame 110, and the distribution board seating plate 122 is formed on the other upper side of the chamber seating frame 110. Do it as

The control switchboard 123 is formed to drive a cutting oil pump 121 installed externally, and the control switchboard 123 is mounted on the top of the switchboard seating plate 122.

Figure 3 is a diagram of a seismic fixing unit 200, which is another embodiment of the present invention, and Figure 4 is a detailed view of Figure 3.

As shown in the drawing, the seismic fixing unit 200 is a configuration further included in the vacuum circulation pump system 100 of the present invention, and the seismic fixing unit 200 is a component that generates energy on the ground at a certain distance from the ground. This is to prevent vibration from being transmitted to the vacuum tank 113.

The seismic fixing part 200 includes a support plate 210, a seismic pad 211, a seating plate 212, a support fixing groove 213, a close cylinder 214, a close contact member 215, and an air tube 216. , It is characterized by including an air injection nozzle (217), a pressure sensor (218), and a buffer spring (219).

The support plate 210 is formed to support the seating plate 212, and the support plate 210 is formed to be seated on the ground.

The seismic pad 211 is formed to absorb vibration generated from the cutting oil pump 121, and a plurality of seismic pads 211 are formed on the lower surface of the support plate 210.

The seating plate 212 is formed to seat the chamber seating frame 110, and the seating plate 212 is connected to the support plate 210 by an air tube 216 at a certain distance. do.

The support fixing grooves 213 are formed so that the frame support 111 can be inserted, and the support fixing grooves 213 are formed on the upper surface of the seating plate 212 in a number corresponding to the frame support 111. It is characterized by

The adhesion cylinder 214 is formed to adhere the adhesion member 215 to the chamber seating frame 110 of the frame support 111. The adhesion cylinder 214 is formed on both sides of the upper part of the seating plate 212. It is characterized by

The adhesion member 215 is formed in close contact with both sides of the chamber seating frame by driving the adhesion cylinder 214 so that it can be fixed on the seating plate 212 without causing shaking of the chamber seating frame 110, The adhesion member 215 is characterized in that it is connected to the cylinder shaft of the adhesion cylinder 214.

The air tube 216 is formed to attenuate vibration, and a plurality of air tubes 216 are formed between the seating plate 212 and the support plate 210.

The air injection nozzle 217 is formed to inject air into the air tube 216, and the air injection nozzle 217 is formed on one side of the air tube 216.

The pressure sensor 218 is formed to sense the pressure inside the air tube 216, and the pressure sensor 218 is formed on one side of the air tube 216.

The buffer spring 219 supports the load applied to the seating plate 212 and is formed to dampen vibration. The buffer spring 219 supports the seating plate 212 inside the air tube 216. It is characterized in that it is formed to do so.

Figure 5 is a diagram of the variable raising and lowering unit 300, which is another embodiment of the present invention, and Figure 6 is a detailed view of Figure 5.

As shown in the drawing, the variable raising and lowering unit 300 is a configuration further included in the vacuum circulation pump system 100 of the present invention, and the variable raising and lowering unit 300 raises and lowers the chamber seating frame 110. It is characterized by adjusting the height of the vacuum chamber.

The variable raising and lowering unit 300 includes a variable box 310, a raising and lowering motor 311, a raising and lowering screw 312, a raising and lowering plate 313, a shaft motor 314, a soccer bar 315, and a shaft fixing bar. (316), a guide bar (317), a bar fixing groove (318), a seating fixing member (319), and a seating sensor (320).

The variable box 310 supports the load of the vacuum chamber being raised and lowered, and is formed to support the raising and lowering plate 313 so that it can be raised and lowered. The variable box 310 is formed to be seated on the ground. It is characterized by

The elevating motor 311 is formed to rotate the elevating screw 312 formed on both sides, and the elevating motor 311 is formed on both sides of the inner bottom surface of the variable box 310. Do it as

The lifting screw 312 is coupled to penetrate both sides of the lifting plate so that the lifting plate 313 can be raised and lowered when rotated. The lifting screw 312 is located at the upper part of the lifting motor 311. It is characterized by being connected to.

The elevation plate 313 is seated on the upper surface of the variable box 310 and is formed to be raised and lowered when rotated by the elevation screw 312. The elevation plate 313 is formed on both sides of the elevation screw ( 312) is characterized in that it is formed by bonding.

The shaft motor 314 is formed to rotate the soccer bar 315, and the shaft motor 314 is formed in the center of the lowering plate 313.

The soccer movable bar 315 is formed to move the coupled shaft fixing bar 316 in one direction or the other by rotating when the shaft motor 314 is driven. The soccer movable bar 315 is the shaft motor 314 ) It is characterized by being formed on both sides.

The shaft fixing bar 316 moves toward the chamber seating frame 110 when the soccer bar 315 rotates and is formed to closely fix the chamber seating frame 110. The shaft fixing bar 316 has one side. It is characterized in that it is coupled to the soccer bar 315 and formed so that the central side is coupled to the guide bar 317.

The guide bar 317 is formed to prevent shaking of the moving shaft fixing bar 316. The guide bar 317 is formed on the bar fixing groove 318 so that the shaft fixing bar 316 penetrates. It is characterized by being formed.

The bar fixing groove 318 is formed so that the guide bar 317 can be installed, and the bar fixing groove 318 is formed on both sides of the raising and lowering plate 313.

The seating and fixing member 319 is formed so that the chamber seating frame 110 can be seated and fixed. The seating and fixing member 319 is formed at the center of the upper surface of the raising and lowering plate 313.

The seating sensor 320 is formed to detect the seating of the chamber seating frame 110 and provide the detected information to the shaft motor 314. The seating sensor 320 is positioned on the upper surface of the chamber seating frame 110. It is characterized by being formed.

Figure 7 is a diagram of a waste oil treatment unit 400, which is another embodiment of the present invention, and Figure 8 is a detailed view of Figure 7.

As shown in the drawing, the waste oil treatment unit 400 is further included in the vacuum circulation pump system 100 of the present invention, and the waste oil treatment unit 400 contains residual cutting oil and foreign matter remaining in the cutting oil filter 115. to remove It is characterized by

The waste oil treatment unit 400 includes a coupling member 410, a coupling groove 411, a magnetic 412, a waste oil box 413, a metal member 414, an opening/closing cover 415, an opening/closing hinge 416, and an opening/closing handle. (417), an internal confirmation window (418), a filter fixture (419), a strainer (420), a discharge pipe (421), and a discharge valve (422).

The coupling member 410 is formed to form a coupling groove 411 into which the metal member 414 can be seated, and the coupling member 410 is formed on one side of the vacuum chamber.

The coupling groove 411 is formed so that the metal member 414 can be seated and fixed inside the coupling member 410.

The magnetic 412 is formed so that the metal member 414 can be attached by magnetism when the metal member 414 is seated and fixed in the coupling groove 411. The magnetic 412 is formed on the inner surface of the coupling groove 411. It is characterized by being formed on one side.

The waste oil box 413 is formed to filter out residual cutting oil remaining in the cutting oil filter 115. The waste oil box 413 is formed to be detachable from one side of the vacuum chamber by a metal member 414. Do it as

The metal member 414 is seated and fixed in the coupling groove 411 and is formed to be attached by the magnetism of the magnet 412. The metal member 414 is formed on one side of the outer surface of the waste oil box 413. do.

The opening/closing cover 415 is formed to introduce the cutting oil filter 115, and the opening/closing cover 415 is connected to an opening/closing hinge 416 to enable opening/closing at the top of the waste oil box 413. .

The opening and closing hinge 416 is formed so that the opening and closing cover 415 can be opened and closed by rotation based on the waste oil box 413. The opening and closing hinge 416 is formed on one side of the upper part of the waste oil box 413. do.

The opening and closing handle 417 is formed to open or close the opening and closing cover 415 by rotating it, and the opening and closing handle 417 is formed on one upper side of the opening and closing cover 415.

The internal confirmation window 418 is formed to check the condition of the inside of the waste oil box 413. The internal confirmation window 418 is formed on one side of the waste oil box 413 with transparent glass or transparent plastic. Do it as

The filter holder 419 is formed so that the cutting oil filter 115 can be fixed inside the waste oil box 413. The filter holder 419 is formed on one side of the inside of the waste oil box 413.

The filtering net 420 is formed to filter out foreign substances mixed in the cutting oil discharged from the cutting oil filter 115 mounted on the filter holder 419. The filtering net 420 is formed on one side of the inside of the waste oil box 413. It is characterized by

The discharge pipe 421 is formed so that the cutting oil filtered through the strainer 420 can be discharged to the outside. The discharge pipe 421 is formed on one side of the lower part of the waste oil box 413.

The discharge valve 422 is formed to discharge or block cutting oil discharged through the discharge pipe 421, and the discharge valve 422 is formed on the discharge pipe 421.

The above-described embodiments are for illustrative purposes, and those skilled in the art will recognize that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, the above-described embodiments should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope sought to be protected through this specification is indicated by the patent claims described later rather than the detailed description above, and should be interpreted to include the meaning and scope of the claims and all changes or modified forms derived from the equivalent concept. .

100: Vacuum circulation pump system
110: Chamber seating frame 111: Frame support
112: frame inner panel 113: vacuum tank
114: Cutting oil inlet pipe 115: Cutting oil filter
116: Cutting oil inlet valve 117: Air discharge pipe
118: air discharge valve 119: leveling pipe
120: Cutting oil discharge pipe 121: Cutting oil pump
122: Distribution board seating plate 123: Control distribution board
200: Earthquake-resistant fixing unit 210: Support plate
211: Earthquake-resistant pad 212: Seating plate
213: Support fixing groove 214: Close cylinder
215: Adhesion member 216: Air tube
217: air injection nozzle 218: pressure sensor
219: Buffer spring
300: Variable raising and lowering unit 310: Variable
311: Elevating and lowering motor 312: Elevating and lowering screw
313: Raising and lowering plate 314: Shaft motor
315: Soccer club bar 316: Axis fixing bar
317: Guide bar 318: Bar fixing groove
319: Seating fixing member 320: Seating sensor
400: Waste oil disposal unit 410: Coupling member
411: Coupling groove 412: Magnetic
413: Waste oil box 414: Metal member
415: Opening/closing cover 416: Opening/closing hinge
417: Opening/closing handle 418: Internal confirmation window
419: Filter holder 420: Filter net
421: discharge pipe 422: discharge valve

Claims (3)

In the vacuum circulation pump system that protects the vacuum pump by filtering out foreign substances mixed in the cutting oil and reusing it,
The vacuum circulation pump system is,
A chamber seating frame formed of a square enclosure to seat the vacuum tank and control switchboard,
A plurality of frame supports formed on the bottom of the chamber seating frame to support the chamber seating frame,
A frame inner panel formed inside the chamber seating frame so that the cutting oil pump can be seated,
A vacuum tank formed on one side of the upper part of the chamber seating frame so that the cutting oil flowing in through the cutting oil inlet pipe can be filtered and stored through the cutting oil filter,
A cutting oil inflow pipe formed on one side of the upper part of the vacuum tank to receive cutting oil from an external cutting oil tank,
A cutting oil filter formed on one side of the cutting oil inlet pipe to filter out foreign substances mixed in the incoming cutting oil,
A cutting oil inlet valve configured to open and close on one side of the coolant filter to control the flow rate of cutting oil flowing into the cutting oil inlet pipe, or to block or smoothly inflow,
An air discharge pipe formed on the other side of the upper part of the vacuum tank to suck in and discharge the air inside the vacuum tank that is connected to the external vacuum pump and flows in;
An air discharge valve formed to open and close on one side of the air discharge pipe to control the amount of air sucked and discharged, block the air sucked and discharged, or allow smooth discharge,
A leveling pipe formed so that one side is connected to the upper part of one side of the vacuum tank and the other side is connected to the lower side of the vacuum tank so that the amount of cutting oil stored in the vacuum tank can be checked,
A cutting oil discharge pipe formed at the bottom center of the vacuum tank to discharge the cutting oil stored in the vacuum tank using a cutting oil pump,
A cutting oil pump mounted on the upper surface of the frame inner panel so that cutting oil can be re-supplied to the initial cutting oil tank through the cutting oil discharge pipe,
A distribution board seating plate formed on the other side of the upper part of the chamber seating frame so that the control distribution board can be installed on the chamber seating frame,
It includes a control switchboard mounted on the upper part of the switchboard seating plate to drive the externally installed vacuum pump and the cutting oil pump,

The vacuum circulation pump system is,
It further includes a seismic fixing part at a certain distance from the ground to prevent vibration generated from the ground from being transmitted to the vacuum tank,
The seismic fixing part is,
A support plate mounted on the ground to support the seating plate,
A plurality of earthquake-resistant pads formed on the bottom of the support plate to absorb vibration generated from the cutting oil pump,
A seating plate connected by an air tube at a certain distance from the support plate so that the chamber seating frame is seated,
Support fixing grooves formed in a number corresponding to the frame supports on the upper surface of the seating plate so that the frame supports can be inserted,
Adhesion cylinders formed on both sides of the upper part of the seating plate to adhere the adhesion member to the frame support chamber seating frame side,
A close contact member that is connected to the cylinder axis of the close cylinder so that it can be fixed on the seat plate without causing shaking of the chamber seat frame and is in close contact with both sides of the chamber seat frame due to the driving of the close cylinder;
A plurality of air tubes formed between the seating plate and the support plate to attenuate vibration,
An air injection nozzle formed on one side of the air tube to inject air into the air tube,
A pressure sensor formed on one side of the air tube to detect the pressure inside the air tube,
A vacuum circulation pump system that supports the load applied to the seating plate and includes a buffer spring formed inside the air tube to support the seating plate to attenuate vibration.

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