KR102208784B1 - Oil tank with viscosity control system - Google Patents

Abstract

The present invention relates to an oil tank having a viscosity control system. According to the present invention, the oil tank having a viscosity control system comprises: a housing (130) having an inlet formed on an upper portion of one side thereof; a first viscosity sensor (S1) provided on an inner wall surface of the housing (130); a second viscosity sensor (S2); a first oil inlet pipe (P1); a second oil inlet pipe (P2); a three-way valve (120); and a control unit. According to the present invention, the viscosity of oil in the oil tank can be constantly maintained.

Description

Oil tank with viscosity control system

The present invention relates to an oil tank, and specifically, when the viscosity of the oil in the existing oil tank and the viscosity of the oil supplied when replenishing the consumed oil are different, the viscosity of the oil in the oil tank is kept constant. , To an oil tank equipped with a viscosity control system.

In general, a mechanical device is operated organically by interconnecting a number of parts. These parts often rub at high speed while being subjected to a fairly large load, and friction between parts naturally wears the parts, shortening the lifespan and deteriorating the performance of the mechanical device.

In order to prevent such friction, a separate oil tank for supplying oil is provided in the mechanical device, and oil is supplied to organically operated parts or molded products to prevent friction and abrasion accordingly.

The oil in the above oil tank has a high viscosity due to low temperature in winter, so that smooth supply to the machinery cannot be achieved, and friction and abrasion between each part occurs due to the high viscosity, so a device that increases the temperature of the oil is known. have.

1 is a cross-sectional view of a conventional oil preheating device for an oil tank.

As shown, the conventional oil preheating device 1 is composed of a water tank 2, a heating device 4, and a temperature sensor 5.

The water tank 2 is made of metal and is formed in a circular or rectangular cylindrical shape with a space formed therein, and a water inlet 21 is formed on the upper surface of the water tank 2, so that the inside of the water tank 2 It is filled with water (W) and heated to replenish the evaporated water.

A protrusion 24 is formed in the lower part of the water tank 2 to form the overall water tank in a "b" shape, thereby increasing the heat transfer area and preheating the oil (O) in the oil tank. While reducing the temperature of the preheated oil (O) for a long time.

Can be maintained.

The heating device (4) is installed in the water tank (2) to heat the filled water (W) to a certain temperature, and transmits a signal from the temperature sensor 4 and a heating wire that generates heat by receiving external power. It is composed of a control unit that receives and controls the heating wire.

This temperature sensor 5 detects the temperature of the water (W) heated by the heating wire and transmits the signal to the control unit of the heating device 4 when a temperature higher than the set temperature (70°C~80°C) is detected. do. At this time, it is known that the temperature of the water (W) in the water tank 2 is maintained at 70°C to 80°C, and the oil temperature in the oil tank 2 is maintained at 40°C to 50°C by the water tank 2.

However, since the above-described device for maintaining the oil viscosity only has a configuration that maintains the viscosity by increasing the temperature of the oil, when the viscosity of the oil in the existing oil tank and the viscosity of the oil supplementing the consumed oil are different However, there was a problem in that the viscosity of the oil supplied to the machinery could not be kept constant.

Unexamined Patent Publication No. 10-2010-0067907 (published on 22 June 2010)

The present invention is to solve the above problems, and when the viscosity of the oil in the existing oil tank and the viscosity of the oil supplied to supplement the consumed oil are different, the viscosity of the oil in the oil tank is kept constant. It is intended to provide an oil tank equipped with a viscosity control system that can be supplied to the device.

The oil tank equipped with the viscosity control system of the present invention has a hollow cylindrical or box-shaped structure in which a hollow part is formed, and an inlet for replenishing new oil is formed in the upper part of one side, and oil is supplied with a mechanical device in the lower part of the other side. A circulation outlet for supplying is formed, and a circulation inlet for recovering circulated oil is formed at the top of the other side, and is provided on the inner wall surface of the housing to measure the viscosity of the oil filled in the housing and transmit the measured value to the control unit. The first viscosity sensor, a second viscosity sensor that is provided on the inner wall of the inlet to fill new oil into the housing, measures the viscosity of the incoming oil, and transmits the measured value to the control unit, and the oil with high viscosity connected to the inlet It is installed at the intersection of the first oil inlet pipe, the second oil inlet pipe through which oil of low viscosity flows in, and the first oil inlet pipe and the second oil inlet pipe and the inlet are connected to the inlet. A three-way valve that selectively closes or opens the inlet pipe and the second oil inlet pipe or adjusts the opening rate, and the reference viscosity of the oil in the housing is set and built-in, and if the value measured by the first viscosity sensor is lower than the reference viscosity , By controlling the three-way valve, oil with high viscosity is introduced from the first oil inlet pipe, and the measured value measured by the viscosity of the oil flowing in from the second viscosity sensor is received, and the measured value and the second viscosity are measured by the first viscosity sensor. When the measured values from the sensor are mixed, it is determined whether or not the reference viscosity is achieved, and the opening rate of the first oil inlet pipe (P1) of the three-way valve 120 is controlled, and the value measured by the first viscosity sensor is the reference viscosity. If it is higher, the three-way valve is controlled to introduce the oil with low viscosity from the second oil inlet pipe, and the measured value measured by the viscosity of the oil flowing in from the second viscosity sensor is received, and the measured value and the measured value from the first viscosity sensor are determined. It characterized in that it comprises a control unit for controlling the opening rate of the second oil inlet pipe of the three-way valve by determining whether or not when the measured value of the two viscosity sensor is mixed.

In addition, the control unit is characterized in that the oil viscosity in the oil tank housing is transmitted to the server in real time using the lot terminal, and the transmitted details can be checked on a mobile or desktop through the web.

In addition, a stirring device is further provided: The stirring device includes a hydraulic cylinder having a multi-stage cylinder vertically penetrating the upper surface of the housing, a stirring blade provided at the lower end of the hydraulic cylinder, and exposed to the outside of the housing. It is characterized in that it comprises a gear tooth formed on the outer surface of the hydraulic cylinder and a spur gear engaged with the gear tooth formed on the outer surface of the hydraulic cylinder, and shaft-coupled with a motor.

In addition, the stirring blade includes a first stirring blade provided on one side and a second stirring blade provided on the other side,

The first inclination angle of the first stirring blade and the second inclination angle of the second stirring blade are formed in opposite directions.

In addition, a level sensor is further provided; The level sensor has a cylindrical structure, a case fitted into a through hole formed on the upper part of the housing, a support plate provided on the upper surface of the case, and a through hole formed in the center, so that the case of the level sensor is fitted and coupled, and the support plate is combined. It is characterized in that it comprises a frame fastened by means, and a horizontally adjustable hydraulic cylinder each provided in a manner protruding from the front, rear, left and right of the through hole formed in the housing, and the upper end of the frame is coupled to the bottom surface.

In addition, a transparent cover is installed at the lower end of the level sensor.

In addition, the horizontal adjustment hydraulic cylinder is connected to the control unit, and the control unit adjusts the height of the horizontal adjustment hydraulic cylinder when the level sensor's horizontal reference value is preset and built-in, and when the level sensor is assembled in a state of inclination, It is characterized in that the level sensor controls to maintain the level with the oil in the housing.

In addition, the impact damping structure is further provided; The impact attenuating structure includes upper and lower intermediate walls horizontally across the housing, left and right intermediate walls, and corrugated portions provided on the upper and lower intermediate walls and left and right intermediate walls. It characterized in that it comprises a through hole provided in the upper and lower intermediate walls and the left and right intermediate walls.

The present invention has the effect of maintaining a constant viscosity of the oil in the oil tank.

In addition, it has the effect of accurately measuring the level of oil by maintaining the level of the level sensor and reducing the vibration and impact of the housing.

1 is a cross-sectional view of a conventional oil preheating device for an oil tank.
Figure 2 is a cross-sectional view of an oil tank equipped with the present invention viscosity control system.
3 is an enlarged view of the stirring device.
4 is an enlarged view of the level sensor.
5 is a state diagram of measuring oil high and low values before and after correction of an incorrectly assembled level sensor.
6 is a cross-sectional view of a shock absorber.
7 is a cross-sectional view of an operating state of the first buffer device.
Figure 8 is a cross-sectional view of the operating state of the second buffer device.
9 is a schematic cross-sectional view of an oil tank equipped with an impact damping structure.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. For reference, the size of the constituent elements shown in the drawings referred to in describing the present invention, the thickness of the line, etc. may be somewhat exaggerated for convenience of understanding.

In addition, terms used in the description of the present invention are defined in consideration of functions in the present invention, and thus may vary according to user, operator intention, custom, and the like. Therefore, the definition of this term should be made based on the contents of the entire specification.

And in the present application, terms such as'include' and'have' refer to the existence of specific numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other It is to be understood that the presence or addition of features or numbers, steps, actions, components, parts, or combinations thereof, does not preclude the possibility of preliminary exclusion.

In addition, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiment makes the disclosure of the present invention complete, and the scope of the invention to those of ordinary skill in the art. It is provided to be fully informed.

Therefore, in the present invention, various changes can be made and various forms can be obtained, and implementation examples (aspects) (or embodiments) will be described in detail in the specification. However, this is not intended to limit the present invention to a specific form of disclosure, and should be understood to include all changes, equivalents, or substitutes included in the technical idea of the present invention, and the expression of the singular number used in the present specification is clearly different from the context. Includes plural expressions unless they are meant to be.

However, in describing the present invention, detailed descriptions of well-known or known functions or configurations will be omitted in order to clarify the subject matter of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

2 is a cross-sectional view of an oil tank equipped with a viscosity control system of the present invention.

This embodiment relates to a viscosity control system, as shown in the'oil tank equipped with a viscosity control system' (100, hereinafter referred to as'oil tank'), the housing 130, the first viscosity sensor (S1) , A second viscosity sensor (S2), a first oil inlet pipe (P1), a second oil inlet pipe (P2), a three-way valve 120, and a control unit.

The housing 130 has a hollow cylindrical shape or a box-shaped structure having a hexahedron having a hollow portion formed therein, and can store oil therein, and an inlet for replenishing new oil is formed at an upper portion of one side, A circulation outlet for supplying oil to the machine is formed in the lower part of the other side, and a circulation inlet for recovering the circulated oil is formed in the upper part of the other side.

The first viscosity sensor S1 is provided on the inner wall surface of the housing 130, measures the viscosity of oil filled in the housing 130, and transmits the measured value to the control unit.

The second viscosity sensor S2 is provided on the inner wall surface of the inlet for filling new oil into the housing when a certain portion of the oil in the housing 130 is consumed, and measures the viscosity of the introduced oil and measures the measured value. It functions to transmit to the control unit.

The first oil inlet pipe P1 is connected to the inlet and is a pipe through which oil having a high viscosity flows.

The second oil inlet pipe P2 is connected to the inlet and is a pipe through which oil having a low viscosity flows.

The three-way valve 120 is an electromagnetic valve that is operated by a signal from the control unit, and is installed at a point where the first oil inlet pipe P1, the second oil inlet pipe P2, and the inlet intersect, and the first oil inflow It has a function of selectively closing or opening the pipe (P1) and the second oil inlet pipe (P2) and a function of adjusting the opening rate.

The control unit is equipped with a reference viscosity of the oil in the housing 130 is set, and if the value measured by the first viscosity sensor S1 is lower than the reference viscosity,

The three-way valve 120 is controlled to introduce high-viscosity oil from the first oil inlet pipe P1, and receives the measured value obtained by measuring the viscosity of the oil flowing in from the second viscosity sensor S2, and receives the first viscosity. When the measured value from the sensor (S1) and the measured value from the second viscosity sensor (S2) are mixed, it is determined whether or not it becomes the reference viscosity, and the opening rate of the first oil inlet pipe (P1) by the three-way valve 120 Control.

In addition, when the value measured by the first viscosity sensor S1 is higher than the reference viscosity, the three-way valve 120 is controlled to introduce oil with low viscosity from the second oil inlet pipe P2, and the second viscosity sensor ( When the measured viscosity of the oil flowing in S2) is received and the measured value of the first viscosity sensor S1 and the measured value of the second viscosity sensor S2 are mixed, it is determined whether or not the reference viscosity is obtained. The opening rate of the second oil inlet pipe P2 is controlled by the three-way valve 120.

Meanwhile, it goes without saying that the control unit transmits the oil viscosity in the oil tank housing 130 to the server in real time using the lot terminal, and can check the transmitted details on the mobile or desktop through the web.

Looking at the operating relationship of the oil tank 100 as described above, the controller measures the viscosity of the oil filled in the oil tank 100 and the housing 130 with the first viscosity sensor S1, and takes the measured value as a reference. By adjusting the directional valve 120, the oil of the first oil inlet pipe P1 having high viscosity is introduced, or the oil of the second oil inlet pipe P2 having low viscosity is introduced, and the second viscosity sensor S2 ), when the inflowing oil and the existing oil are mixed, it is determined whether the viscosity of the reference oil can be reached, and the opening rate of the three-way valve 120 is adjusted. By doing this, the viscosity of the oil in the housing can be kept constant.

In the following embodiments, a configuration for stirring the oil in the oil tank housing will be described.

Since the viscosity of the oil filled in the housing 130 of the oil tank 100 changes due to temperature change, evaporation, and loss in the process of being consumed and recovered from the mechanical device, the viscosity is different from the oil newly introduced from the inlet. It has to be different.

Therefore, when the newly introduced oil flows into the existing oil in the housing 130, the oil is not uniformly mixed due to the difference in viscosity.Therefore, an error may occur when measuring the viscosity. It is necessary to mix the oil in 130, but in this embodiment, it is intended to provide a stirring device for mixing so that the viscosity of the oil in the housing 130 is uniform.

Figure 2 is a cross-sectional view of an oil tank equipped with the viscosity control system of the present invention, Figure 3 is an enlarged view of the stirring device.

As shown, the stirring device 110 of the present embodiment includes a hydraulic cylinder 111, a stirring blade 112, a gear tooth 113, and a spur gear 114.

The hydraulic cylinder 111 has a multi-stage cylinder vertically penetrating the upper surface of the housing 130, and the multi-stage cylinder is withdrawn or drawn in by a driving means not shown, so that the lower end of the hydraulic cylinder 111 The stirring blade 112 provided in the housing 130 has a function of improving the stirring efficiency of the stirring blade 112 by moving up and down while impregnated with the oil filled in the housing 130.

The stirring blade 112 is provided at the lower end of the hydraulic cylinder 111, a first stirring blade 112a is formed on one side, and a second stirring blade 112b is formed on the other side in the opposite direction. .

The first stirring blade 112a forms a first inclination angle β based on a horizontal plane formed by oil, and the second stirring blade 112b has a second inclination angle based on a horizontal plane formed by oil. (α) is formed.

That is, since the first inclination angle β and the second inclination angle α are formed in opposite directions, when the stirring blade 112 rotates, when the first stirring blade 112a pushes the oil upward, the opposite side The second stirring blade (112b) is to push down the oil.

Of course, when the stirring blade rotates in the reverse direction, the functions of the first and second stirring blades are performed in opposite directions.

Therefore, the oil is rotated and mixed by the centrifugal force of the stirring blade 112, and the oil flows upward and downward by the first stirring blade 112a and the second stirring blade 112b to be mixed, It has the function and effect of making it easier to mix to make the viscosity of oil uniform.

The gear tooth 113 is formed on the outer surface of the hydraulic cylinder 111 exposed to the outside of the housing 130, and has a function of rotating the hydraulic cylinder 111 in connection with a spur gear 114 to be described later.

The spur gear 114 is meshed with the gear teeth 113 formed on the outer surface of the hydraulic cylinder 111, and is axially coupled with the motor M, so that the spur gear 114 rotates by driving the motor, and eventually the hydraulic cylinder 111 Is to rotate.

Looking at the operating relationship of the stirring device 110 as described above, when new oil is filled into the housing 130 of the oil tank, the motor M is driven. When the motor (M) is driven, the spur gear 114 that is axially coupled with the motor (M) rotates, and when the spur gear 114 rotates, the hydraulic cylinder 111 that is pressed against the spur gear 114 rotates. do,

When the hydraulic cylinder 111 rotates, the stirring blade 112 rotates and the oil is smoothly mixed by the centrifugal force and the force pushing the oil up and down from the first and second stirring blades 112a and 112b. .

At this time, by repeating the driving of the hydraulic cylinder 111 in the up/down direction by a driving means (not shown), the stirring blades immersed in the oil move in the up and down directions, further increasing the efficiency of stirring. It can be improved.

In the following embodiments, a horizontal adjustment structure of a level sensor will be described.

A level sensor LS is installed on the inside of the housing 130 of the oil tank to measure the level of the oil in order to prevent overflow of oil.

The level sensor LS irradiates ultrasonic waves or lasers, measures the ultrasonic waves or lasers reflected and received, and measures the high and low values of the oil in the housing 130. When the level sensor LS is assembled in an inclined manner, the housing (130) Since an error occurs in measuring the high and low values of the oil, in the present embodiment, a horizontal adjustment structure capable of maintaining the level of the level sensor LS is proposed.

4 is an enlarged view of the level sensor, and FIG. 5 is a state diagram of measuring oil high and low values before and after correction of an incorrectly assembled level sensor.

The horizontal adjustment structure as shown includes a level sensor (LS), a horizontal adjustment hydraulic cylinder 140, a frame 141, a case 142, and a support plate 143.

The level sensor LS includes a case 142 having a cylindrical structure, and is fitted into a through hole formed in the upper portion of the housing 130, and a transparent cover is installed at the lower end of the level sensor LS. , It has a function of preventing foreign substances from entering the'ultrasonic or laser irradiation unit' (not shown) of the built-in level sensor LS or being contaminated by scattering oil.

A support plate 143 is provided on the upper surface of the case 142 of the level sensor LS, and is coupled to the frame 141 to be described later by a coupling means such as a fastening bolt.

The frame 141 is formed with a through hole (not shown) in the center, so that the case 142 of the level sensor LS is fitted and coupled, and the horizontally adjustable hydraulic cylinder 140 is at the bottom of the frame 141 ) Is combined.

It goes without saying that the frame 141 and the support plate 143 are fastened by coupling means such as fastening bolts.

The horizontal adjustment hydraulic cylinder 140 is provided in a manner protruding from the front, rear, left, and right of the through hole formed in the housing 130, and the upper end of the horizontal adjustment hydraulic cylinder 140 is on the bottom of the frame 141 Are combined.

The horizontal adjustment hydraulic cylinder 140 is connected to the control unit, and the horizontal reference value of the level sensor LS is preset and built in the control unit, so when the level sensor LS is assembled in a state of having an inclined structure, it is shown. By controlling the protruding length of each horizontal adjustment hydraulic cylinder 140 by a driving means that is not used, the level sensor LS is controlled so that it can be accurately leveled with the oil in the housing 130, so that the level sensor LS By irradiating the irradiated ultrasound or laser perpendicularly to the oil in the housing 130, it is possible to accurately measure the oil level.

In the following embodiments, a shock absorber provided in the oil tank housing will be described.

Since the housing 130 of the oil tank is installed in a place adjacent to the machinery, the oil in the housing 130 is caused by vibrations generated by the machinery or the vibrations generated when heavy equipment etc. move around the place where the housing 130 is installed. In some cases, an error may occur in measuring the high and low values of the oil due to the occurrence of a wave shape.In this embodiment, a buffer that minimizes the occurrence of waves in the oil in the housing 130 by attenuating the vibration transmitted to the housing 130 I would like to present the device.

6 is a cross-sectional view of the shock absorber, FIG. 7 is a cross-sectional view of an operating state of the first buffer device, and FIG. 8 is a cross-sectional view of an operating state of the second buffer device.

As shown, the shock absorber formed on the bottom of the housing 130 is roughly divided into a first shock absorber 150 and a second shock absorber 160.

The first buffer device 150 includes a case 151, a partition wall 152, a protruding rod 153, a piston 154, and a distribution hole 155.

The case 151 has a cylindrical structure in which a hollow portion is formed, and a through hole is formed on an upper surface thereof, so that the protruding rod 153 to be described later is coupled to allow a slide movement.

The protruding rod 153 is fixed to the bottom surface of the housing 130 and provided in a protruding state, and is fitted and coupled to a through hole formed on the upper surface of the casing 151.

The piston 154 has a disk shape that is larger than the diameter of the protruding rod 153 and has a constant thickness, and is fixed to the lower end of the protruding rod 153.

In addition, a packing is provided on the outer side of the piston 154, so that when the outer surface of the piston is in sliding contact with the inner wall surface of the case 151 and moves up and down, it has a function of sealing to prevent air from leaking.

The partition wall 152 is provided in an inner middle portion of the casing 151 and divides the interior of the case 151 into an upper chamber and a lower chamber.

The distribution hole 155 is provided in the shape of a through hole through the central portion of the partition wall 152, and has a function of a passage through which air in the upper chamber and the lower chamber flow.

Looking at the operating relationship of the first buffer device 150 having the above structure,

When vibration is applied to the housing 130, the protruding rod 153 provided on the lower surface of the housing 130 vibrates up and down, and when the protruding rod 153 vibrates, it is coupled to the lower end of the protruding rod 153. The piston 154 also vibrates.

When the piston 154 vibrates and moves up and down, the air flows into the upper chamber or the lower chamber through the circulation hole 155 of the partition wall 152, so that the compression resistance and air to which the air is compressed are passed through the circulation hole ( Vibration can be attenuated by fluid resistance passing through 155).

The second buffering device 160 includes a shell 161, an injection port 162, an intermediate wall 163, a first conical coil spring 164a, a second conical coil spring 164b, and a first guide mountain 165a. , It contains a second guide acid (165b).

The outer shell 161 has a conical structure having a triangular vertical cross section, is formed of a material having elasticity, and the upper surface is fixed to the bottom surface of the housing 130.

In addition, since the outer shell 161 is expanded by air injected through the inlet 162 to be described later, it has a function of attenuating vibration by the pressure of air injected into the inner shell 161.

Since the outer shell 161 has a triangular shape in its vertical cross section, the bottom surface is supported by a large area on the bottom surface to have structural stability, and the horizontal vibration imparted to the housing 130 is lateral elasticity of the outer shell 161 It has the function and effect to attenuate by deformation force.

The injection port 162 is provided in a shape penetrating through one side of the shell 161 and has a function of injecting air into the interior of the shell.

The intermediate wall 163 is provided in the middle portion of the inner shell 161 and has a function of dividing the shell 161 into an upper chamber and a lower chamber, and the outer end of the intermediate wall 163 and the inner surface of the outer shell 161 A circulation space is formed therebetween, and has a function of allowing air to flow between the upper chamber and the lower chamber.

The first guide mountain 165a is provided on an upper surface of the intermediate wall 163 and has a conical structure having a triangular vertical cross section.

The second guide mountain 165b is provided on the inner bottom of the outer shell 161 and has a conical structure having a triangular vertical cross section.

The first conical coil spring 164a has a structure coupled between the inner upper surface of the outer shell 161 and the first guide mountain 165a.

The second conical coil spring 164b has a structure coupled between the lower surface of the intermediate wall 163 and the second guide mountain 165b.

Looking at the operating relationship of the second buffer device 160 having the above structure, when the housing 130 vibrates in the horizontal direction, the horizontal vibration is attenuated by the horizontal elastic restoring force due to the pneumatic pressure inside the shell 161.

When the housing 130 vibrates in the vertical direction, the air in the upper chamber inside the outer shell 161 flows to the upper chamber and the lower chamber through the circulation space, so that the vibration can be attenuated by the compression resistance of air and the fluid resistance.

In addition, when vertical vibration occurs, vibration is attenuated by the elastic restoring force of the first and second conical coil springs 164a, 164b, and the first and second conical coil springs 164a and 164b are each wound coil. Since it has a conical shape, when the coil is compressed, the upper and lower coils do not contact, and the amount of compression deformation increases, so that the upper and lower vibrations can be more efficiently attenuated by the amount of compression deformation.

In addition, the first and second guide peaks 165a and 165b support the inner surfaces of the first and second conical coil springs when the first and second conical coil springs are compressed, so that the first and second conical coil springs It can prevent buckling in the horizontal direction.

It goes without saying that the horizontal vibration can be attenuated by the elastic outer shell 161 and the compressed air inside the outer shell.

In the following embodiments, a structure for reducing the impact of the oil tank housing will be described.

When an impact is applied to the housing of the oil tank, the housing is damaged and the oil spills out, resulting in environmental pollution or a risk of fire.In this embodiment, a structure is proposed to minimize damage to the oil tank by reducing the impact force. do.

9 is a schematic cross-sectional view of an oil tank equipped with an impact damping structure

As shown, the impact attenuating structure 170 of the present embodiment has the upper and lower intermediate walls 170b horizontally crossing the housing 130 and the left and right intermediate walls 170b vertically crossing the housing 130. 170a) is formed, a corrugated portion 171 is formed at a predetermined portion of each of the intermediate walls 170b and 170a, and through holes are formed in the intermediate walls 170b and 170a.

Looking at the operating relationship of the impact reduction structure 170, when an external impact is applied to the housing 130, the folds of the intermediate walls 170b and 170a formed inside the housing 130 are folded, thereby reducing the impact force. As a result, damage to the housing 130 can be minimized, and since the oil flows through the through hole formed in the intermediate wall, the impact force can be further attenuated by the flow resistance of the oil.

The present invention as described above has the effect of keeping the viscosity of the oil in the oil tank constant, and in addition, the effect of accurately measuring the oil level by maintaining the level of the level sensor, and reducing the vibration and impact of the housing. It has a letting effect.

100: oil tank 110: stirring device
111: hydraulic cylinder 112: stirring blade
112a: first stirring wing 112b: second stirring wing
113: gear 114: spur gear
120: three-way valve 130: housing
140: horizontal adjustment hydraulic cylinder 141: frame
142: case 143: support plate
150: first buffer device 151: case
152: bulkhead 153: protruding peak
154: piston 155: distribution hole
160: second buffer device 161: shell
162: injection port 163: middle wall
164a: first conical coil spring 164b: second conical coil spring
165a: first guide acid 165b: second guide acid
170: shock attenuation structure 170a: left and right middle walls
170b: upper and lower intermediate walls 171: wrinkles
S1: first viscosity sensor S2: second viscosity sensor
P1: first oil inlet pipe P2: second oil inlet pipe
LS: Level sensor M: Motor

Claims (8)

It is a hollow cylindrical or box-shaped structure in which a hollow part is formed, and an inlet for replenishing new oil is formed at the top of one side, and a circulation outlet for supplying oil to a mechanical device is formed at the lower side of the other side, and circulation at the top of the other A housing 130 having a circulation inlet for recovering the used oil,
A first viscosity sensor (S1) provided on the inner wall surface of the housing 130 to measure the viscosity of oil filled in the housing 130 and transmit the measured value to the control unit,
A second viscosity sensor (S2) provided on the inner wall surface of the inlet for filling new oil into the housing, measuring the viscosity of the introduced oil, and transmitting the measured value to the control unit,
The first oil inlet pipe (P1) connected to the inlet and through which oil with high viscosity flows,
A second oil inlet pipe (P2) connected to the inlet and into which oil with low viscosity flows,
Installed at the intersection of the first oil inlet pipe (P1) and the second oil inlet pipe (P2) and the inlet, selectively closing or opening the first oil inlet pipe (P1) and the second oil inlet pipe (P2) A three-way valve 120 that adjusts the opening rate or
The reference viscosity of the oil in the housing 130 is set and built,
If the value measured by the first viscosity sensor S1 is lower than the reference viscosity,
The three-way valve 120 is controlled to introduce high-viscosity oil from the first oil inlet pipe P1, and receives the measured value obtained by measuring the viscosity of the oil flowing in from the second viscosity sensor S2, and receives the first viscosity. When the measured value from the sensor (S1) and the measured value from the second viscosity sensor (S2) are mixed, it is determined whether or not it becomes the reference viscosity, and the opening rate of the first oil inlet pipe (P1) of the three-way valve 120 is determined. Control,
If the value measured by the first viscosity sensor (S1) is higher than the reference viscosity,
The three-way valve 120 is controlled to introduce low-viscosity oil from the second oil inlet pipe P2, and the second viscosity sensor S2 receives the measured viscosity of the oil flowing in, and receives the first viscosity. When the measured value from the sensor (S1) and the measured value from the second viscosity sensor (S2) are mixed, it is determined whether or not it becomes the reference viscosity, and the opening rate of the second oil inlet pipe (P2) of the three-way valve 120 is determined. It includes a control unit to control,
The control unit transmits the oil viscosity in the oil tank housing 130 to the server in real time using the lot terminal, and the transmitted details can be checked on the mobile or desktop through the web,
The stirring device 110 is further provided:
The stirring device 110,
A hydraulic cylinder 111 having a multistage cylinder vertically penetrating the upper surface of the housing 130,
The stirring blade 112 provided at the lower end of the hydraulic cylinder 111,
A gear tooth 113 formed on the outer surface of the hydraulic cylinder 111 exposed to the outside of the housing 130,
It is engaged with the gear teeth 113 formed on the outer surface of the hydraulic cylinder 111, and includes a spur gear 114 axially coupled with the motor (M),
The stirring blade 112 includes a first stirring blade 112a provided on one side and a second stirring blade 112b provided on the other side,
The first inclination angle β of the first stirring blade 112a and the second inclination angle α of the second stirring blade 112b are formed in opposite directions,
The level sensor (LS) is further provided;
The level sensor LS,
A case 142 having a cylindrical structure and fitted into a through hole formed on the upper portion of the housing 130,
A support plate 143 provided on the upper surface of the case 142,
A through hole is formed in the center, the case 142 of the level sensor LS is fitted and coupled, and the frame 141 for fastening the support plate 143 by a coupling means,
It includes a horizontal adjustment hydraulic cylinder 140, which is provided in a protruding manner to the front, rear, left, and right of the through hole formed in the housing 130, and has an upper end coupled to the bottom of the frame 141,
A transparent cover is installed at the bottom of the level sensor (LS),
The horizontal adjustment hydraulic cylinder 140 is connected to the control unit, and the control unit is built-in by setting the horizontal reference value of the level sensor LS, and when the level sensor LS is assembled in a state of having an inclined structure, the horizontal adjustment hydraulic cylinder By adjusting the protruding length of the 140, the level sensor LS is controlled to maintain the level with the oil in the housing 130,
The impact damping structure 170 is further provided;
The impact damping structure 170,
The upper and lower intermediate walls 170b horizontally crossing the housing 130 and,
The left and right intermediate walls 170a crossing the housing 130 vertically,
A wrinkle portion 171 provided in the upper and lower intermediate walls 170b and the left and right intermediate walls 170a,
Includes through holes provided in the upper and lower intermediate walls 170b and the left and right intermediate walls 170a,
A first buffer device 150 and a second buffer device 160 are further provided on the bottom of the housing 130;
The first buffer device 150,
It is a cylindrical structure in which a hollow part is formed, and a case 151 having a through hole formed on the upper surface thereof,
A protruding rod 153 that is fixed to the bottom of the housing 130 and provided in a protruding state, and fitted into a through hole formed on the upper surface of the case 151,
A piston 154 fixed to the lower end of the protruding rod 153 and provided with a packing on the outer side thereof,
A partition wall 152 provided in the middle of the case 151 to divide the interior of the case 151 into an upper chamber and a lower chamber,
It is provided in the shape of a through hole through the central portion of the partition wall 152, and includes a distribution hole 155 through which air in the upper chamber and the lower chamber flow,
The second buffering device 160,
The upper surface is fixed to the bottom surface of the housing 130, has a conical structure having a triangular vertical cross section, and an outer shell 161 formed of a material having elasticity,
An injection port 162 provided in a shape penetrating through one side of the outer shell 161 to inject air into the outer shell,
It is provided in the middle portion of the inner shell 161, divides the outer shell 161 into an upper chamber and a lower chamber, and an intermediate wall 163 having a circulation space between the outer end and the inner surface of the outer shell 161
A first guide mountain 165a provided on the upper surface of the intermediate wall 163 and having a conical structure having a triangular vertical cross section,
A second guide mountain 165b provided on the inner bottom of the outer shell 161 and having a conical structure having a triangular vertical cross section,
A first conical coil spring (164a) coupled between the inner upper surface of the shell 161 and the first guide mountain (165a),
Oil tank with a viscosity control system, characterized in that it comprises a second conical coil spring (164b) coupled between the lower surface of the intermediate wall (163) and the second guide acid (165b). delete delete delete delete delete delete delete

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