KR101344904B1 - Quantitative pump - Google Patents

Abstract

The present invention relates to a metering pump having a new structure for preventing heat from being applied to liquid transferred through a tube. The metering pump according to the present invention comprises a head (10), a driving motor (20), a driving shaft (21) connecting the head (10) and the driving motor (20), a waterproof housing (60) formed outside the driving shaft (21), a bushing (70) formed at a front end part inside the waterproof housing (60), and a heat radiation fin (80) formed at the peripheral part of the driving shaft (21), wherein the bushing (70) seals a gap between the waterproof housing (60) and the driving shaft (21) in order to prevent liquid from flowing into the waterproof housing (60). Therefore, the metering pump is capable of not only preventing the driving motor (20) from being damaged or burned by the liquid which flows in the driving motor (20) after being spilled from the damaged tube (30), but also radiating heat from the driving shaft (21) in order to prevent the heat generated in the driving motor (21) in operation from being transmitted to the liquid passing the tube (30) through the head (10).

Description

Quantitative pump

The present invention relates to a metering pump of a new structure which is adapted to prevent heat from being applied to the liquid conveyed through the tube.

In general, a metering pump used to transport a constant amount of liquid per unit time has been developed in various ways depending on the purpose or place of use.

1 and 2 show an example of such a fixed-quantity pump, the head 10 is arranged so that a plurality of rollers 11 in a circular shape on the circumferential surface, and connected to the head 10 through a drive shaft 21 And a drive motor 20 for rotating the head 10, a tube 30 disposed to pass through the outer circumference of the head 10, and a tube 30 disposed to surround the outside of the tube 30. Is composed of a support block 40 for supporting to be in close contact with the outer surface of the roller (11) of the head (10).

At this time, the head 10, the drive motor 20 and the support block 40 is provided on the inside or front of the case 50, the support block 40 is the head (circumferential surface of the tube 30) 10) to the roller 11, so that the middle portion of the tube 30 is blocked by the roller (11).

In addition, the drive motor 20 uses a reduction gear having a reduction gear integrated therein, or is provided with a separate reduction gear in the middle of the driving shaft.

Accordingly, when the head 10 is rotated by the driving motor 20, the roller 11 moves along the tube 30 while blocking the middle portion of the tube 30 and flows into the tube 30. The liquid is discharged to the discharge end of the tube (30).

While the metering pump configured as described above has a low amount of liquid use per unit time, it can not only control the amount of liquid transferred by the pump very precisely, but also because the liquid does not come into contact with structures other than the tube 30, It is mainly used in the laboratory, etc. for the purpose, or control the amount of liquid transfer very precisely, the detailed configuration is described in detail in a number of prior documents, including the Patent No. 10-1121222, further description of the detailed configuration and operation Is omitted.

However, such a drive motor 20 has a problem that heat generated from the drive motor 20 is transferred to the liquid passing through the tube 30 through the head 10 when used for a long time.

In particular, when the liquid passing through the tube 30 is sensitive to heat, there is a problem that the properties may be changed or altered by the liquid transferred through the head 10.

In addition, the metering pump is connected to the drive motor 20 to the head 10, when the tube 30 is damaged and the liquid inside the tube 30 is leaked to the outside, the liquid drive motor 20 Inflow to the drive motor 20, there was a problem that may cause a fire due to damage or short circuit.

Therefore, there is a need for a new method to solve such a problem.

The present invention is to solve the above problems, it is possible to prevent the heat generated from the motor to be transmitted to the tube through the head, and to prevent the liquid spilled by the tube from being introduced into the drive motor The purpose is to provide a metered pump of the structure.

The present invention for achieving the above object, the head 10 is arranged so that a plurality of rollers 11 in a circumferential surface, and the head 10 is connected to the head 10 through a drive shaft 21 A drive motor 20 for rotating the tube, a tube 30 disposed to pass through the outer circumference of the head 10, and a tube 30 disposed to surround the outside of the tube 30. In the fixed-quantity pump including a support block 40 for supporting the roller 11 in close contact with the outer surface of the roller 11, the through holes 61 and 62 to which the drive shaft 21 is coupled are formed to penetrate the front and rear surfaces. The waterproof housing 60 coupled to the outside of the drive shaft 21 and the through holes 61 and 62 are provided inside the sealed housing and seal the gap between the waterproof housing 60 and the drive shaft 21 to seal the waterproof housing 60. Bushing 70 for preventing the liquid from flowing into the inside of the) and the drive shaft 21 to be positioned inside the through holes 61 and 62. It further comprises a heat dissipation fin 80 is coupled to the circumference to release the heat of the drive shaft 21, the through holes (61, 62) is a small diameter portion 61 to which the bushing 70 is coupled, and the heat dissipation fin ( Provided is a metering pump, characterized in that consisting of a large diameter portion 62 is located 80.

According to another feature of the invention, the inlet port 63 and the exhaust port 64 is formed on the circumferential surface of the waterproof housing 60, the large diameter portion 62, the heat dissipation fin 80 is a thin metal plate The screw is wound around the drive shaft 21 in a helical direction. When the heat dissipation fin 80 is rotated together with the drive shaft 21, outside air passes through the inlet port 63 to form a large diameter part 62. After being introduced into the exhaust port 64 is discharged to the metering pump is provided, characterized in that for cooling the drive shaft 21 and the heat radiation fin (80).

According to another feature of the present invention, the air supply means 90 is connected to the inlet port 63 through the air supply pipe 91 to supply high-pressure air into the large diameter portion 62, and the drive shaft 21 A first temperature measuring sensor 100 connected to the drive shaft 21 to measure the temperature of the drive shaft 21 and a second temperature measuring sensor connected to the tube 30 to measure the temperature of the liquid passing through the tube 30. 110, a control valve 120 connected to the air supply pipe 91 to control the flow of air supplied through the air supply pipe 91, the first temperature sensor 100 and the second temperature measurement sensor. Receiving a signal of the 110 further includes a control unit 130 for controlling the operation of the control valve 120, the control unit 130 is the drive shaft measured by the first temperature measuring sensor 100 When the temperature of 21 is higher than the temperature of the liquid measured by the second temperature measuring sensor 110, the control valve 120 is opened to the There is provided a metering pump, characterized in that the high-pressure air is supplied to the inside of the large diameter portion 62 through the inlet port (63).

Metering pump according to the invention is provided with a waterproof housing 60 on the outside of the drive shaft 21 for connecting the head 10 and the drive motor 20, the waterproof housing (60) on the inner end of the waterproof housing ( A bushing 70 is provided to seal a gap between the drive shaft 21 and the drive shaft 21 to prevent liquid from flowing into the waterproof housing 60. A heat dissipation fin 80 is provided at a circumference of the drive shaft 21. It is provided.

Therefore, even if the tube 30 is damaged and the liquid flows out, the liquid may flow into the driving motor 20 to prevent the driving motor 20 from being damaged or a fire may be generated, and the heat of the driving shaft 21 may be prevented. By radiating heat, there is an advantage that the heat generated while the driving motor 20 is driven can be prevented from being transferred to the liquid passing through the tube 30 through the head 10.

1 is a front view showing a typical metering pump,
Figure 2 is a side cross-sectional view showing a typical metering pump,
Figure 3 is a side cross-sectional view showing a metering pump according to the present invention,
Figure 4 is a side cross-sectional view showing a second embodiment of the metering pump according to the present invention,
Figure 5 is a circuit diagram showing a second embodiment of the metering pump according to the present invention.

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

4 shows a metering pump according to the present invention, a head 10 having a plurality of rollers 11 arranged on a circumferential surface in a circular shape, and a head connected to the head 10 through a driving shaft 21. Drive motor 20 for rotating the 10, the tube 30 disposed so as to pass through the outer peripheral portion of the head 10, and the tube 30 is disposed so as to surround the outside of the tube 30 It is the same as the conventional one including the support block 40 for supporting the outer surface of the roller 11 in close contact with the head (10).

At this time, the head 10, the drive motor 20 and the support block 40 is provided on the inside or front of the case (50).

In addition, according to the present invention, the driving shaft 21 is coupled to the waterproof housing 60 formed so that the through holes 61 and 62 to which the driving shaft 21 is coupled penetrate the front and rear surfaces.

The waterproof housing 60 is made of a metal material having high strength and high thermal conductivity, and a rear end thereof is fixedly coupled to the front surface of the driving motor 20.

At this time, the through holes (61, 62) is composed of a small diameter portion 61 in the front and a large diameter portion 62 in the rear.

The drive shaft 21 is provided with a bushing 70 and a heat dissipation fin 80.

The bushing 70 is configured to have a cylindrical shape of a neuron teflon material and is coupled to the inside of the small diameter portion 61 to seal a gap between the waterproof housing 60 and the drive shaft 21 so as to seal the gap between the waterproof housing 60. Prevents liquid from entering the interior.

The heat dissipation fin 80 is configured in the form of a screw wound spirally around the circumference of the drive shaft 21 so as to be located inside the large diameter portion 62, and radiates heat of the drive shaft 21 and At the same time, when the drive shaft 21 is rotated, it is rotated together with the drive shaft 21 so that the air inside the large diameter portion 62 is discharged from the front to the rear along the drive shaft 21.

In this case, an inlet port 63 and an exhaust port 64 connected to the large diameter part 62 are formed on a circumferential surface of the waterproof housing 60.

Therefore, when the drive shaft 21 is rotated, the air introduced into the intake port 63 is in contact with the heat dissipation fin 80 to cool the heat dissipation fin 80 and then is discharged to the exhaust port 64.

Reference numeral 65, which is not described, illustrates a bearing provided in the small diameter portion 61 of the waterproof housing 60 to support the drive shaft 21.

The metering pump configured as described above is provided with a waterproof housing 60 on the outside of the drive shaft 21 connecting the head 10 and the driving motor 20, and the waterproof housing 60 is provided at an inner end of the waterproof housing 60. ) And a bushing 70 for sealing a gap between the driving shaft 21 and preventing the liquid from flowing into the waterproof housing 60, and a heat dissipation fin 80 provided at a circumference of the driving shaft 21. do.

Therefore, even if the tube 30 is damaged and the liquid inside the tube 30 is leaked, the liquid may flow into the driving motor 20 to prevent the driving motor 20 from being damaged or a fire may be generated. The heat generated by the heat dissipation of the drive shaft 21 may be prevented from being transferred to the liquid passing through the tube 30 through the head 10 while the drive motor 20 is driven.

In addition, an inlet port 63 and an exhaust port 64 connected to the large diameter part 62 are formed on a circumferential surface of the waterproof housing 60, and the heat dissipation fin 80 has a thin metal plate around the drive shaft 21. Consists of a screw wound in a spiral direction, when the heat radiation fin 80 is rotated together with the drive shaft 21, the outside air flows into the large diameter portion 62 through the inlet (63) and then the exhaust port ( By discharging to the drive shaft 21 and the heat dissipation fin 80 while being discharged to 64, by circulating the outside air to the inside of the large diameter portion 62, there is an advantage that can further improve the cooling effect.

4 and 5 illustrate another embodiment according to the present invention, which is connected to the inlet port 63 through an air supply pipe 91 to supply high-pressure air to the inside of the large diameter part 62. 90, a first temperature sensor 100 connected to the drive shaft 21 to measure the temperature of the drive shaft 21, and a temperature of the liquid connected to the tube 30 and passing through the tube 30. The second temperature measuring sensor 110 for measuring the control valve 120 is connected to the air supply pipe 91 to control the flow of air supplied through the air supply pipe 91, and the first temperature measuring sensor A control unit 130 is further provided to control the operation of the control valve 120 by receiving a signal from the 100 and the second temperature measuring sensor 110.

At this time, the inlet port 63 is configured to have a very small diameter compared to the exhaust port (64).

The air supply means 90 uses a general air compressor, and supplies high-pressure air into the large diameter part 62 through the inlet port 63, thereby entering the large diameter part 62 through the inlet port 63. At the same time as the supplied high-pressure air is introduced into the large diameter portion 62, it expands to lower the ambient temperature.

As described above, the principle of lowering the ambient temperature while expanding the high pressure air is generally used in a general cooling device, and thus detailed description thereof will be omitted.

The first temperature measuring sensor 100 and the second temperature measuring sensor 110 use a general temperature sensor.

The control valve 120 uses a solenoid valve connected to the middle portion of the air supply pipe (91).

The control unit 130 is the control valve when the temperature of the drive shaft 21 measured by the first temperature measuring sensor 100 is higher than the temperature of the liquid measured by the second temperature measuring sensor 110 Open the 120 to supply high pressure air to the inside of the large diameter portion 62 through the inlet port 63, and when the temperature of the drive shaft 21 is lower than the temperature of the liquid, the control valve 120 is opened. Closed so that air is not supplied to the inside of the large diameter portion 62.

The metering pump configured as described above measures the temperature of the liquid passing through the tube 30 and the temperature of the driving shaft 21, and the temperature of the driving shaft 21 is higher than that of the liquid by the heat generated from the driving motor 20. When raised, the large diameter portion 62 is supplied with air to forcibly cool the drive shaft 21, and the liquid passing through the tube 30 is heated by heat transmitted to the tube 30 through the drive shaft 21. You can prevent it.

On the contrary, when the temperature of the drive shaft 21 is lower than the temperature of the liquid, air is not supplied to the large-diameter portion 62, so that the temperature of the drive shaft 21 is excessively lowered to allow the liquid to pass through the tube 30. The temperature can be prevented from falling.

Therefore, compared to the above-described first embodiment in which the drive shaft 21 is simply cooled by using the heat dissipation fins 80, the drive shaft 21 can be cooled more effectively, and the drive shaft 21 is excessively cooled to allow the tube to cool. By preventing the temperature of the liquid passing through the 30 from being lowered, there is an advantage that the temperature of the liquid passing through the tube 30 can be more effectively prevented from being changed by external influences.

In addition, since the high-pressure air is supplied to the inside of the large diameter part 62 through the inlet port 63 and expanded, the temperature is reduced, and thus the structure is very simple and the operation reliability is very high, and the device is very compact. There is an advantage that can be configured.

In the present embodiment, the diameter of the inlet port 63 is made very small, so that the high-pressure air supplied through the inlet port 63 is expanded in the large diameter part 62 to reduce the temperature, but the inlet port 63 ) Or a separate expansion valve is further provided in the air supply pipe 91, so that the high-pressure air supplied through the air supply pipe 91 may be more effectively expanded inside the large diameter part 62.

10. Head 20. Drive motor
30.Tube 40.Support Block
50. Case 60. Waterproof housing
70. Bushing 80. Heat sink fin
90. Air supply means 100. First temperature measuring sensor
110. Second temperature measuring sensor 120. Control valve
130. Control Unit

Claims (3)

The head 10 is arranged to form a plurality of rollers 11 in the circumferential surface,
A drive motor 20 connected to the head 10 through a drive shaft 21 to rotate the head 10;
A tube 30 disposed to pass through an outer circumference of the head 10,
In the fixed amount pump including a support block 40 disposed to surround the outer side of the tube 30 to support the tube 30 to be in close contact with the outer surface of the roller 11 of the head 10,
Through holes 61 and 62 to which the drive shaft 21 is coupled are formed to penetrate the front and rear surfaces, and the waterproof housing 60 coupled to the outside of the drive shaft 21;
Bushing 70 provided in the through-holes (61, 62) to seal the gap between the waterproof housing 60 and the drive shaft 21 to prevent liquid from flowing into the waterproof housing (60); ,
It further comprises a heat dissipation fin (80) coupled to the circumference of the drive shaft 21 so as to be located inside the through holes (61, 62) to release the heat of the drive shaft (21),
The through holes 61 and 62 include a small diameter portion 61 to which the bushing 70 is coupled, and a large diameter portion 62 at which the heat dissipation fin 80 is located.
On the circumferential surface of the waterproof housing 60 is formed an inlet port 63 and an exhaust port 64 connected to the large diameter portion 62,
The heat dissipation fin 80 is configured in the form of a screw wound in a spiral direction on the circumference of the drive shaft 21, a thin metal plate,
When the heat dissipation fin 80 is rotated together with the drive shaft 21, the outside air flows into the large diameter portion 62 through the inlet port 63, and then is discharged to the exhaust port 64 while the drive shaft 21 and the heat dissipation fin ( 80),
An air supply means 90 connected to the inlet port 63 through an air supply pipe 91 to supply high pressure air to the inside of the large diameter part 62;
A first temperature measuring sensor 100 connected to the drive shaft 21 and measuring a temperature of the drive shaft 21;
A second temperature measuring sensor 110 connected to the tube 30 to measure the temperature of the liquid passing through the tube 30;
A control valve 120 connected to the air supply pipe 91 and controlling a flow of air supplied through the air supply pipe 91;
Further comprising a control unit 130 for receiving the signals of the first temperature measuring sensor 100 and the second temperature measuring sensor 110 to control the operation of the control valve 120,
The control unit 130 is the control valve when the temperature of the drive shaft 21 measured by the first temperature measuring sensor 100 is higher than the temperature of the liquid measured by the second temperature measuring sensor 110. Metering pump, characterized in that for opening the 120 to supply the high-pressure air into the large diameter portion 62 through the inlet (63). delete delete

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