KR101074119B1 - Hydraulic tank - Google Patents

Abstract

The present invention relates to a hydraulic tank of a hydraulic unit, comprising: a temperature sensor for measuring a temperature of hydraulic oil in a hydraulic tank; The inlet is connected in series with the manifold return line so that the amount of hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil flowing directly into the hydraulic tank can be adjusted according to the temperature measured by the temperature sensor, and one end of the outlet is connected to the hydraulic oil cooler. The other side of the outlet is a solenoid valve connected to the hydraulic oil filter of the hydraulic tank; A line filter installed on the hydraulic oil cooler connection pipe of the solenoid valve and filtering foreign substances and bubbles of the hydraulic oil; A hydraulic oil cooler connected to the line filter to cool the hydraulic oil and return the hydraulic oil into the hydraulic tank; And a diffuser installed at the outlet of the return pipe inside the hydraulic tank and dispersing the return hydraulic oil in all directions so as not to float the sediment which has settled on the floor. By adjusting the valve according to the temperature, the flow rate of the hydraulic oil flowing into the hydraulic oil cooler is varied to protect the hydraulic oil cooler while maintaining the temperature of the hydraulic oil in the hydraulic tank below the appropriate temperature to protect the hydraulic line, and the air bubbles contained in the hydraulic oil in the return pipe and The present invention relates to a hydraulic tank that filters foreign substances to prevent bubbles and foreign substances from entering the hydraulic oil stored in the hydraulic tank, and minimizes generation of sediment such as dust or rust in the hydraulic oil in the hydraulic tank.

Description

Hydraulic tank

The present invention by measuring the temperature of the hydraulic oil in the hydraulic tank by controlling the valve to vary the flow rate of the hydraulic oil flowing into the hydraulic oil cooler to protect the hydraulic oil cooler while maintaining the hydraulic oil temperature in the hydraulic tank below the appropriate temperature It protects the line, filters bubbles and foreign substances contained in the hydraulic oil in the return line to prevent bubbles and foreign substances from entering the hydraulic oil stored in the hydraulic tank, and minimizes the occurrence of sediment such as dust or rust in the hydraulic oil in the hydraulic tank. It's about tanks.

The hydraulic unit is a combination of mechanical elements that supply high pressure energy by passing hydraulic oil with viscosity and lubricity through the pump, and induce this high pressure hydraulic oil to the hydraulic actuator to perform effective work. The hydraulic pump supplies high pressure to the hydraulic oil. And various valves for controlling high pressure hydraulic oil, hydraulic actuators for receiving high pressure hydraulic oil energy and converting them into mechanical kinetic energy, hydraulic tanks for storing low pressure hydraulic oil, and other accessories.

When the pressure energy of the high pressure hydraulic oil is converted into a linear motion, the hydraulic oil is heated to a high temperature, and in order to cool the hydraulic oil, a separate hydraulic oil cooler is installed on the circulation pipe between the hydraulic pump and the hydraulic tank, so that some hydraulic oil is high pressure. It is generally supplied to the hydraulic actuator and bypassed by a part of the hydraulic oil cooler, or it is generally installed on the low pressure oil return line between the hydraulic actuator and the hydraulic tank to supply the return hydraulic oil to the hydraulic oil cooler.

However, when the hydraulic oil cooler is installed on the circulation line between the hydraulic pump and the hydraulic tank to cool by the hydraulic oil cooler by bypass, a part of the pumped hydraulic oil flows into the hydraulic oil cooler, so that the cooling speed is not only slow, but also in the hydraulic pump. When the hydraulic pressure generating efficiency of the high pressure supplied to the hydraulic actuator is reduced, the hydraulic oil cooler is installed on the low pressure oil return line between the hydraulic actuator and the hydraulic tank to cool the return hydraulic oil. There was a problem that the capacity of the hydraulic oil cooler is increased or the expensive hydraulic oil cooler is damaged by a large amount of hydraulic oil having residual pressure.

In addition, when packing, gaskets, seals, etc. in the hydraulic circuit of the hydraulic unit are aging or the pressure change in the hydraulic circuit is severely repeated, or when the air is introduced by suction force when the pressure decreases rapidly in the hydraulic circuit, or the hydraulic oil in the hydraulic circuit When there is a part in contact with air, air may be introduced into the hydraulic oil to generate bubbles, and bubbles may be generated when a vortex (vortex) occurs in the hydraulic tank.

If the bubble oil is used as it is, there is a problem that the hydraulic unit system is unstable and damage to the hydraulic unit system, such as pressure drops or lubricity.

On the other hand, the hydraulic tank is not only a storage of the hydraulic oil but also a bar for conditioning the hydraulic oil after the operation, the sludge, metal chips, various impurities, etc. in the hydraulic tank may have a fatal effect on the hydraulic unit system. To prevent this, hydraulic tanks are generally designed to use baffle plates or to isolate the inlet and return lines so that the above impurities settle to the bottom.

In addition, when the hydraulic pump sucks hydraulic oil, the suction pipe inside the hydraulic tank is designed to be higher than the bottom of the hydraulic tank in order to prevent mixing of impurities that sink in the bottom of the hydraulic tank. In spite of the higher installation, when the hydraulic pump sucks hydraulic oil, it is more likely to flow into the suction pipe by stimulating impurities that sink to the bottom due to the generation of turbulence or vortex caused by the suction flow in the vicinity of the suction pipe in the hydraulic tank. There was this.

Therefore, the present invention was invented to solve the above problems, while measuring the temperature of the hydraulic oil in the hydraulic tank by controlling the valve to vary the flow rate of the hydraulic oil flowing into the hydraulic oil cooler while protecting the hydraulic oil cooler Maintain the hydraulic oil temperature in the hydraulic tank below the proper temperature to protect the hydraulic line, filter bubbles and foreign substances contained in the hydraulic oil in the return line to prevent bubbles and foreign substances from entering the hydraulic oil stored in the hydraulic tank, and hydraulic oil in the hydraulic tank The problem to be solved is to provide a hydraulic tank that can minimize the generation of sediment, such as dust or rust.

The present invention for solving the above problems, in the hydraulic tank of the hydraulic unit, a temperature sensor for measuring the temperature of the hydraulic oil in the hydraulic tank; The inlet is connected in series with the manifold return line so that the amount of hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil flowing directly into the hydraulic tank can be adjusted according to the temperature measured by the temperature sensor, and one end of the outlet is connected to the hydraulic oil cooler. The other side of the outlet is a solenoid valve connected to the hydraulic oil filter of the hydraulic tank; A line filter installed on the hydraulic oil cooler connection pipe of the solenoid valve and filtering foreign substances and bubbles of the hydraulic oil; A hydraulic oil cooler connected to the line filter to cool the hydraulic oil and return the hydraulic oil into the hydraulic tank; A hydraulic tank comprising a; a diffuser installed at the exit of the hydraulic tank inside the return pipe and dispersing the return hydraulic oil in all directions so as not to float the sediment sinking to the floor as a means for solving the problem.

The solenoid valve may include a valve core hole vertically penetrating the inside of the valve block; A valve core slide-operated within the valve core hole; A hydraulic oil passage horizontally intersecting with the valve core hole in the valve block and penetrating therein to form a hydraulic oil inlet on one side and a hydraulic tank connector and a hydraulic oil cooler connector on the other side; A valve core spring for elastically sliding the valve core; Solve the hydraulic tank comprising a; a valve control unit for operating the valve core to adjust the amount of the hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil directly flowing into the hydraulic tank according to the temperature measured by the temperature sensor By means.

In addition, the line filter is a cylindrical filter body; A hydraulic oil inlet formed at one side of the filter body; A hydraulic oil outlet formed on the opposite side of the hydraulic oil inlet; A cylindrical filter fitted inside the cylindrical body; Drain cock is formed on the cylindrical filter body to discharge the hydraulic oil containing bubbles; consisting of, the hydraulic oil introduced into the hydraulic oil inlet is filtered into the cylindrical filter from the outside of the cylindrical filter, the hydraulic oil is filtered air bubbles and foreign matter is hydraulic oil Hydraulic tank characterized in that the outlet to the outlet is a solution to the problem.

In addition, the diffuser is assembled in the opposite direction to maintain a constant gap between the inner steel plate bored at a 180-degree angle inside the outer steel plate pipe bored at a 180-degree angle and smaller than the outer steel pipe tube to return a constant hydraulic oil inside the diffuser The hydraulic tank characterized in that the flow to the outside is configured to prevent stimulation of vortex, bubble generation and sediment as a solution to the problem.

The hydraulic tank according to the present invention measures the temperature of the hydraulic oil in the hydraulic tank to adjust the valve according to the measured temperature to vary the flow rate of the hydraulic oil flowing into the hydraulic oil cooler to protect the hydraulic oil cooler while maintaining the hydraulic oil temperature in the hydraulic tank below the appropriate temperature To protect the hydraulic line, filter bubbles and foreign substances contained in the hydraulic oil in the return line to prevent bubbles and foreign substances from entering the hydraulic oil stored in the hydraulic tank, and minimize the occurrence of sediment such as dust or rust in the hydraulic oil in the hydraulic tank This has the effect of improving the durability of the hydraulic tank and hydraulic oil.

1 is a photograph showing the overall configuration of a conventional hydraulic tank
2 is a photograph showing a hydraulic oil cooler and a return line of a conventional hydraulic tank
3 is a conceptual view showing a conventional hydraulic tank plan view configuration
4 is a conceptual diagram showing a hydraulic tank top view configuration of the present invention
5 is a cross-sectional view showing the configuration of the solenoid valve of the present invention.
6 is a cross-sectional view showing the configuration of a line filter according to the present invention.
7 is a cross-sectional view showing the diffuser of the present invention.
8 is a cross-sectional view showing an example of the diffuser installation of the present invention.

The present invention relates to a hydraulic tank of a hydraulic unit, comprising: a temperature sensor for measuring a temperature of hydraulic oil in a hydraulic tank; The inlet is connected in series with the manifold return line so that the amount of hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil flowing directly into the hydraulic tank can be adjusted according to the temperature measured by the temperature sensor, and one end of the outlet is connected to the hydraulic oil cooler. The other side of the outlet is a solenoid valve connected to the hydraulic oil filter of the hydraulic tank; A line filter installed on the hydraulic oil cooler connection pipe of the solenoid valve and filtering foreign substances and bubbles of the hydraulic oil; A hydraulic oil cooler connected to the line filter to cool the hydraulic oil and return the hydraulic oil into the hydraulic tank; Hydraulic tank is installed at the inside of the hydraulic tank outlet exit and diffuser for dispersing the return hydraulic oil in all directions so as not to float the sediment sinking to the bottom; characterized in that the hydraulic tank comprising a technical configuration.

The solenoid valve may include a valve core hole vertically penetrating the inside of the valve block; A valve core slide-operated within the valve core hole; A hydraulic oil passage horizontally intersecting with the valve core hole in the valve block and penetrating therein to form a hydraulic oil inlet on one side and a hydraulic tank connector and a hydraulic oil cooler connector on the other side; A valve core spring for elastically sliding the valve core; The hydraulic tank configured to include a valve control unit for operating the valve core to adjust the amount of the hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil directly into the hydraulic tank according to the temperature measured by the temperature sensor It features.

In addition, the line filter is a cylindrical filter body; A hydraulic oil inlet formed at one side of the filter body; A hydraulic oil outlet formed on the opposite side of the hydraulic oil inlet; A cylindrical filter fitted inside the cylindrical body; Drain cock is formed on the cylindrical filter body to discharge the hydraulic oil containing bubbles; consisting of, the hydraulic oil introduced into the hydraulic oil inlet is filtered into the cylindrical filter from the outside of the cylindrical filter, the hydraulic oil is filtered air bubbles and foreign matter is hydraulic oil The hydraulic tank characterized in that the outlet to the outlet is characterized by a technical configuration.

In addition, the diffuser is assembled in the opposite direction to maintain a constant gap between the inner steel plate bored at a 180-degree angle inside the outer steel plate pipe bored at a 180-degree angle and smaller than the outer steel pipe tube to return a constant hydraulic oil inside the diffuser The hydraulic tank is characterized in that it is configured to prevent the flow to the outside to stimulate the vortex, bubble generation and sediment is characterized by a technical configuration.

Hereinafter will be described in detail with reference to the preferred embodiments and drawings of the present invention to be easily carried out by those skilled in the art. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a photograph showing a conventional hydraulic tank overall configuration, Figure 2 is a photograph showing a hydraulic oil cooler and a return line of a conventional hydraulic tank, Figure 3 is a conceptual diagram showing a conventional hydraulic tank plan view configuration, Figure 4 5 is a cross-sectional view showing a configuration of a solenoid valve of the present invention, FIG. 6 is a cross-sectional view showing a configuration of a line filter according to the present invention, and FIG. 7 is a diffuser of the present invention. 8 is a cross-sectional view showing a diffuser installation example of the present invention.

1 to 3, the configuration and operation of a conventional hydraulic tank will be described. The hydraulic oil inside the hydraulic tank 1 is operated by operating the motor 2 and the hydraulic pump 3 to supply hydraulic oil through the inlet 4. After pumping, the high pressure hydraulic oil is pumped through the pipe 5 to the manifold 9 connected to each hydraulic cylinder, and the high pressure hydraulic oil is operated through the manifold to operate each hydraulic cylinder. It returns to the hydraulic tank 1 via the hydraulic oil filter 10 via the return pipe and the return pipe 8 of the manifold 9.

On the other hand, when the pressure energy of the high-pressure hydraulic oil is converted to a linear motion or the like, the hydraulic oil is heated to a high temperature, in order to cool the hydraulic oil, the hydraulic oil cooler 6 to the circulation pipe between the hydraulic pump 3 and the hydraulic tank. (7) Some of the hydraulic oil is supplied to the hydraulic cylinder through the manifold at high pressure, and some are bypassed and cooled by the hydraulic oil cooler, but in this case, only a portion of the pumped hydraulic oil flows into the hydraulic oil cooler. In addition to the slowness, there was a problem in that the generation efficiency of the high pressure hydraulic flow rate supplied from the hydraulic pump to the hydraulic cylinder was lowered.

Therefore, in order to solve the above problem, as shown in FIG. 4, instead of installing the hydraulic oil cooler 6 on the circulation conduit 7, the hydraulic oil returned by connecting to the return conduit 8 is provided. The solenoid valve 100 is installed at the front end of the hydraulic oil cooler 6 and cooled by the hydraulic oil cooler 6, and the temperature of the hydraulic oil in the hydraulic tank is measured by a temperature sensor in the hydraulic tank. The valve 100 is configured to vary the flow rate of the hydraulic oil flowing into the hydraulic oil cooler 6 to protect the hydraulic oil cooler while maintaining the hydraulic oil temperature in the hydraulic tank below an appropriate temperature.

The solenoid valve 100, as shown in Figure 5, the valve core hole 102 vertically penetrates inside the valve block 101; A valve core (103) for sliding in the valve core hole; The hydraulic oil passage 104 which crosses the valve core hole horizontally in the valve block and is penetrated to form a hydraulic oil inlet A on one side and a hydraulic tank connector B and a hydraulic oil cooler connector B 'on the other side. ; A valve core spring (105) for elastically sliding the valve core; And a valve control unit 106 that operates the valve core to adjust the amount of hydraulic oil flowing into the hydraulic oil cooler and the amount of hydraulic oil directly flowing into the hydraulic tank according to the temperature measured by the temperature sensor.

Looking at the operation of the solenoid valve 100 with reference to Figure 5, in the pre-operation state, the return hydraulic oil flow through the hydraulic oil passage 104, the return pipe 8 and the hydraulic oil filter 10 of the solenoid valve hydraulic tank Returning to (1), when the flow oil temperature in the hydraulic tank (1) is high, the state after the operation by the temperature sensor, the valve core 103 is operated downwards, the hydraulic tank connector (B) is partially closed, the hydraulic oil The cooler connector B 'is partially opened, so that some hydraulic oil is moved to the hydraulic oil cooler 6, cooled, and then returned to the hydraulic tank 1, and some hydraulic oil is returned directly to the hydraulic tank 1 by the temperature sensor. The fluid oil temperature is kept below the optimum temperature.

In other words, when the hydraulic oil temperature in the hydraulic tank 1 is low, the solenoid valve does not operate so that no flow oil flows into the hydraulic oil cooler 6, thereby preventing breakage and leakage of the hydraulic oil cooler 6. Its durability and efficiency can be maximized.

On the other hand, as shown in Figure 4, on the hydraulic oil cooler connecting pipe line 22 of the solenoid valve is installed a line filter 23 for filtering foreign matter and bubbles of the hydraulic oil, the hydraulic oil flowing into the hydraulic oil cooler (6) Since the liquid flows into the hydraulic tank immediately after it is cooled, the hydraulic tank does not go through the hydraulic oil filter 10, and bubbles and foreign matter are introduced into the hydraulic tank, so that the cooled hydraulic oil passes through the line filter 23 to prevent this. do.

As shown in FIG. 6, the line filter 23 includes a cylindrical filter body 231; A hydraulic oil inlet 232 formed at one side of the filter body; A hydraulic oil outlet 233 formed on the opposite side of the hydraulic oil inlet; A cylindrical filter 234 fitted inside the cylindrical body; Drain cock 235 is formed on the cylindrical filter body to discharge the hydraulic oil containing bubbles; consisting of, the hydraulic oil introduced into the hydraulic oil inlet is filtered into the cylindrical filter from the outside of the cylindrical filter and the air bubbles and foreign matter filtered Hydraulic oil flows out to the hydraulic oil outlet to be moved to the hydraulic oil cooler (6).

In addition, in the hydraulic tank of the present invention, a diffuser is installed at the inside of the hydraulic tank exit pipe and disperses the return hydraulic oil in all directions so as not to float the sediment that has settled on the floor, as shown in FIG. The diffuser 200 is assembled in the opposite direction to each other to maintain a constant gap between the inner iron plate tube 202 bored at an angle of 180 degrees inside the outer iron plate 201 bored at a 180 degree angle and smaller than the outer iron plate tube The return hydraulic oil flows from the inside of the diffuser to the outside to be dispersed in all directions as shown in FIG. 8, thereby preventing stimulation of vortex, bubble generation, and sediment.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments and the drawings disclosed in the present invention are not intended to limit the technical spirit of the present invention but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

1: Hydraulic tank 2: Motor 3: Hydraulic pump
4: suction port 5: pipe 6: hydraulic oil cooler
7: circulation pipe 8: return pipe 9: manifold
10: hydraulic oil filter 23: line filter
100: solenoid valve 101: valve block 102: valve core ball
103: valve core 104: hydraulic oil passage 105: valve core spring
106: valve control unit
231: cylindrical filter body 232: hydraulic oil inlet 233: hydraulic oil outlet

Claims (4)

A hydraulic tank of a hydraulic unit, comprising: a temperature sensor for measuring a temperature of hydraulic oil in a hydraulic tank; The inlet is connected in series with the manifold return line so that the amount of hydraulic oil flowing into the hydraulic oil cooler and the hydraulic oil flowing directly into the hydraulic tank can be adjusted according to the temperature measured by the temperature sensor, and one end of the outlet is connected to the hydraulic oil cooler. The other side of the outlet is a solenoid valve connected to the hydraulic oil filter of the hydraulic tank; A line filter installed on the hydraulic oil cooler connection pipe of the solenoid valve and filtering foreign substances and bubbles of the hydraulic oil; A hydraulic oil cooler connected to the line filter to cool the hydraulic oil and return the hydraulic oil into the hydraulic tank; A diffuser installed at an outlet of the internal return pipe of the hydraulic tank and dispersing the return hydraulic oil in all directions so as not to float the sediment which has sunk on the bottom; the solenoid valve includes a valve core hole vertically penetrating the inside of the valve block; A valve core slide-operated within the valve core hole; A hydraulic oil passage horizontally intersecting with the valve core hole in the valve block and penetrating therein to form a hydraulic oil inlet on one side and a hydraulic tank connector and a hydraulic oil cooler connector on the other side; A valve core spring for elastically sliding the valve core; A hydraulic tank comprising: a valve control unit for operating a valve core to adjust the amount of hydraulic oil flowing into the hydraulic oil cooler and the amount of hydraulic oil directly flowing into the hydraulic tank according to the temperature measured by the temperature sensor.
delete The method of claim 1,
The line filter has a cylindrical filter body; A hydraulic oil inlet formed at one side of the filter body; A hydraulic oil outlet formed on the opposite side of the hydraulic oil inlet; A cylindrical filter fitted inside the cylindrical body; Drain cock is formed on the cylindrical filter body to discharge the hydraulic oil containing bubbles; consisting of, the hydraulic oil introduced into the hydraulic oil inlet is filtered into the cylindrical filter from the outside of the cylindrical filter, the hydraulic oil is filtered air bubbles and foreign matter is hydraulic oil Hydraulic tank characterized in that flows out of the outlet
The method of claim 1,
The diffuser is assembled at an angle of 180 degrees in an outer steel plate which is perforated at an angle of 180 degrees, and assembled in opposite directions so as to maintain a constant gap between inner steel plates having a diameter smaller than that of the outer steel plate so that the return hydraulic oil flows from the inside of the diffuser to the outside. A hydraulic tank configured to prevent stimulation of vortices, bubble generation and sediment by flowing

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