KR101414930B1 - Index devices and index way of a centrifugal generation of heat banner that used an atmospheric pressure - Google Patents

Abstract

The present invention relates to an exponential device and an exponent method of a centrifugal heat radiator using air pressure, and more particularly, to an exponent device and an exponent method of a centrifugal heat radiator using air pressure, The present invention relates to an indexing device for a centrifugal heat exchanger using an air pressure using an exponential device for injecting an air pressure of the same pressure as the supply water pressure inside the housing. The exponent device is constituted between the housing and the shaft, And an exponent method and an exponent method of a centrifugal heat radiator using air pressure to inject the air through the exponent so that supply water inside the housing is not leaked to the outside by injecting air pressure equal to the pressure of the supply water. With a focus on the technical As it came up finish.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an index device and an index method for a centrifugal heat generator using air pressure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a centrifugal heat generator using air pressure to prevent water from leaking from the inside of a housing, and more particularly, to a centrifugal heat generator using a centrifugal heat generator to prevent water from leaking into a space between the housing and a shaft To an exponential device and an exponent method of a centrifugal heat generator using an air pressure using an exponent device for injecting an air pressure of the same pressure as the supply water pressure inside the housing.

Generally, centrifugal pumps are widely used in industries such as ship water supply, water supply and sewage, mining, and chemical industry. The centrifugal pump is a pump which forms a high-pressure fluid by using a pressure difference caused by a centrifugal force generated by an impeller rotated by a rotation of a driving motor.

Generally, there are three types of pumps used for boilers. The first is to circulate a part of the pump circulating water to the can inside the motor to cool the inside of the motor, and the water flowing between the carbon bearings is lubricated The impeller shaft of the pump unit is separated from the impeller shaft of the pump unit by attaching a permanent magnet plate having a different pole to each shaft. The third is to extend the motor shaft to make one shaft to the end of the pump section. In order to prevent leakage between the motor section and the pump section, a mechanical seal using a mechanical seal is used. Structure.

Among them, the can structure system has no noise, but its structure is complicated, the output of the motor is low and the performance of the pump can not be utilized to the maximum, and the manufacturing cost is high. In the magnetic structure system, It is difficult to lower the manufacturing cost due to the disadvantage of using permanent magnets of < RTI ID = 0.0 >

On the other hand, the circulating pump of the mechanical seal structure has an advantage that the manufacturing cost can be lowered at the lowest cost because of the simple structure except for the risk of leakage of the mechanical seal and the noise generated in the ball bearing.

As described above, the present invention relates to a hot water circulation pump for a boiler in such a mechanical seal structure type.

The circulating pump of the mechanical seal structure has the above-mentioned advantages, but the problem of shortening the life of the pump due to the disconnection of the circuit due to the decrease of the output of the motor and overheating due to the high heat generated in the motor winding during the continuous driving of the pump In addition, there is a problem in that leakage water leaks from the mechanical seal due to any reason causes leakage of water to the inside of the motor due to capillary phenomenon, which rapidly corrodes the ball bearing and shortens the life of the bearing there was.

In order to solve such a problem,

Open No. 20-1995-0006919 relates to a heat-insulating device of a hot-water circulation pump for a boiler, in which a motor shaft extending in one direction is rotated by the power of electric energy, and the outer surface of the motor shaft is enclosed A pump unit for forcibly discharging the warm water drawn through the inlet hole drilled in the case by rotation of the motor unit and the impeller fixed to the motor shaft, and a pump unit positioned between the motor unit and the pump unit, And a cooling chamber in which a space chamber is provided between a vertical wall and a support plate integrally formed with the outer peripheral wall so as to maintain the airtightness in the pump portion, wherein the cooling chamber is positioned inside the space series of the cooling portion, And a heat shield plate of a metal material fixed to the motor shaft by the fixing means is installed so as to block the conduction to the motor portion.

However, not only the cost of the metal end plate is increased but also the gap between the motor shaft and the metallic end plate is inevitably present because a certain portion of the end plate is screwed to the motor shaft with the set screw. There is a problem that the water leaking from the motor shaft can not be prevented from flowing into the motor along the motor shaft.

No. 20-0224136 discloses a water leakage prevention and air cooling device for a hot water circulation pump for a boiler, comprising: a motor unit having a motor shaft extending in one axis; And a support portion for interconnecting and supporting the motor portion and the pump portion. The hot water circulation pump for a boiler includes a plurality of blades formed on the bottom of the pump, And the opening portion is formed on the sidewall of the support portion and the side wall or the bottom surface of the motor portion so that the re-cooling fan can be tightly fitted to the motor shaft in the support portion and the motor portion can be cooled by the rotation of the air- .

However, since the hot water circulation pump equipped with the leakage-blocking and air-cooling device is provided with an air-cooling fan for blocking water leakage, it is unnecessary to increase the cost. Further, due to the additional configuration of the air-cooling fan, there was.

Registration No. 10-0727582 relates to a centrifugal pump having a water leakage tank, comprising: a housing having an inlet through which a fluid to be pumped flows and a discharge port through which a fluid is discharged; A driving motor formed on the housing to rotate the mounted shaft; A mechanical seal coupled to the shaft to prevent leakage of fluid between the shaft and the housing; An impeller connected to the shaft to pump the fluid toward the discharge port by raising the pressure of the fluid flowing into the housing through the inlet; And a water leakage tank formed on the housing through which the shaft penetrates to store the leaked fluid.

The centrifugal pump having the water leakage tank has an additional unnecessary cost rise due to the additional construction of a water leakage tank for containing the water leakage generated in the housing, and the water leakage tank has the constitution of the water leakage tank, There is a problem that it is not possible to prevent the wear of the mechanical seal and prevent the leakage caused by the wear of the mechanical seal.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art described above and provides an index device between a housing and a shaft shaft, And an exponent method and an exponent method of a centrifugal heat radiator using air pressure to inject air pressure equal to the pressure of the supply water so that the supply water does not leak outside, so that the supply water is not leaked.

According to an aspect of the present invention, there is provided an apparatus for supplying water to a vehicle, the apparatus comprising: a housing having an inlet for receiving supply water from the outside and a discharge opening for discharging the supply water to the outside, A centrifugal heat radiator comprising a shaft shaft rotated by the operation of the bearing portion, an indexing device provided between the housing and the shaft shaft for preventing supply of water in the housing from leaking, and a cell disk connected to a shaft shaft in the housing Wherein the exponent unit is formed between the housing and the shaft shaft and has an inlet through which the air can be injected through the housing and the exponent unit.

A shaft shaft connected to the housing and rotated by operation of a drive unit and a bearing unit, and a shaft shaft connected to the housing through rotation of the drive unit and the bearing unit, 1. An exponential method for exponentially indexing water in a centrifugal heat exchanger constituted by a cell disk constituted by a cell disk connected to a shaft axis inside a housing and constituted by an index device between the housing and a shaft axis, The water in the housing is prevented from escaping to the outside by continuously injecting air having a pressure equal to or higher than a pressure generated in the housing through the injection port formed through the exponent unit.

According to the exponential device and the exponent method of the centrifugal heat radiator using the air pressure according to the present invention, the exponential device capable of injecting the air pressure to prevent leakage of the supply water generated in the housing of the centrifugal heat radiator is constituted, The use of the mechanical seal does not require the use of a kernal seal, which leads to many differences in cost, and in the use of the mechanical seal there is an additional cost for replacement of the members due to wear. However, , It is possible to use it semi-permanently, and it can be environmentally friendly by using air.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-
2 is a sectional view showing in detail the exponential device in the configuration of the present invention
3 is a side sectional view showing a cross section taken along line A - A and B - B in Fig. 2
4 is a cross-sectional view illustrating the operation of the housing of the present invention
5 is an enlarged view showing an enlargement of Fig. 4A and another embodiment of a; Fig.
6 is a cross-sectional view showing another preferred embodiment to which the present invention is applied
7 is an operational state diagram showing another preferred embodiment to which the present invention is applied

Generally, the centrifugal heat generators are driven by the rotation of a shaft shaft connected to a driving device and supplied to the interior of the housing, thereby rotating the cell disk in the shaft axis of the housing. And is discharged to the discharge port of the housing.

There is a problem that when the supply water is heated due to the rotation of the shaft shaft, a strong pressure is generated inside the housing, and the supply water leaks between the housing and the shaft shaft due to the shaft shaft configured to pass through the housing.

In order to prevent the above-described problems, an index device is usually provided between the housing and the shaft shaft to prevent leakage of water supplied to the inside of the housing.

However, in the above-mentioned index device, a stator fixed to the housing and a rotor fixed to the shaft are used, respectively, and leakage is prevented due to the adhesion to the stator and rotor. However, the rotor is rotated by the rotation of the shaft shaft, thereby causing wear to occur with the stator which is in close contact with the rotor, thereby causing the centrifugal heat generator to be replaced after a certain period of use, There has been a problem in that it occurs.

Further, in order to minimize the occurrence of abrasion in the index device, various materials have been used, but even when such materials are used, they are not environmentally friendly.

In view of the above problems, the present invention is directed to a centrifugal heat generator having an eco-friendly and semi-permanent index device.

Hereinafter, the configuration of the present invention will be described in more detail with reference to the accompanying drawings 1 to 7.

1 and 2, a housing 200 is provided with an inlet 210 for supplying the supply water from the outside and a discharge opening 220 for discharging the supply water to the outside, A shaft shaft 500 connected to the housing 200 and rotated by the operation of the driving device 300 and the bearing unit 400 and a shaft shaft 500 formed between the housing 200 and the shaft shaft 500, The centrifugal heat exchanger (100) comprises an index device (700) for preventing supply of water from being leaked to the shaft (500) inside the housing (200) The indexing device 700 should be formed between the housing 200 and the shaft shaft 500 and have an inlet 710 through which the air is injected through the housing 200 and the indexing device 700 do.

The inlet port 710 of the exponent unit 700 is formed to penetrate through the housing 200 and to the outside. The air pressure injected into the inlet port 710 is usually used for commercialization. Not.

A space h must be formed between the index device 700 and the shaft shaft 500. This is due to the characteristics of the mechanical device, which is generated finely when the shaft shaft 500 is driven.

A storage groove 711 is formed at an end of the injection port 710 in a portion of the index device 700 where the shaft shaft 500 of the injection port 710 is located. This is because the air pressure injected through the injection port 710 is stored in the storage groove 711 and the air pressure stored in the storage groove 711 is pushed by the air pressure injected through the injection port 710.

The distance of the index device 700 from the storage groove 711 to the inside of the housing 200 should be shorter than the distance to the outside.

This is because the distance of the air pressure pushed in the storage groove 711 to the inside of the housing 200 is short so that the pressure for pushing the supply water is increased.

Referring to FIGS. 2, 3 and 4, an outlet 720 is formed in the exponent unit 700 so that water can be discharged through the space h.

A discharge groove 721 is formed at one side of the index device 700 which is in contact with the shaft shaft 500 at a portion where the discharge port 720 is formed.

In addition, the discharge space h 'is formed outside the exponent unit, and an external discharge port 730 and a cap 731, which can selectively discharge water to the outside of the space, should be formed.

Although the space portion h can prevent leakage of the supply water due to the air pressure injected through the injection port 710 of the index device 700, the air pressure prevents the supply of the supply water in advance Water generated finely by the characteristics of the mechanical device is generated.

The water flowing through the space h passes through the discharge port 720 through the discharge groove 721 formed in the exponent 700.

The water passing through the outlet 720 is located in the discharge space h 'and when the water in the discharge space h' becomes a certain amount, the water is discharged through the external discharge port 730 by removing the cap 731 .

The discharge groove 721 guides the water flowing into the discharge port 720 into the discharge port 720. Since the storage groove 711 and the discharge groove 721 are in accordance with the present invention, The present invention is not limited thereto.

Describing the exponent method of the exponential device based on the above configuration,

A housing (200) having an inlet (210) for receiving supply water from the outside and a discharge opening (220) for discharging the supply water to the outside and moving the supply water; A centrifugal heat radiator 100 composed of a shaft shaft 500 rotated by the operation of the bearing unit 300 and the bearing unit 400 and a cell disk 600 connected to the shaft shaft 500 inside the housing 200 The exponent device (700) is constructed between the housing (200) and the shaft shaft (500) to exponentially index water therein. The exponent device (700) The water in the housing 200 is prevented from escaping to the outside by continuously injecting air having a pressure equal to or higher than the pressure generated in the housing 200 through the injection port 710 passing through the housing 200.

The position of the injection port 710 formed through the exponent unit 700 is formed on the side close to the inside of the housing to induce the introduced air to move toward the inside of the housing having a relatively small resistance.

5, the air pressure injected into the injection port 710 should be equal to or greater than the pressure generated in the housing 200.

This is because the pressure of the air pressure injected into the injection port 710 is equal to the pressure generated inside the housing 200 to flow into the space h between the housing 200 and the shaft shaft 500 .

When the pressure of the air pressure is smaller than the pressure of the inside of the housing 200, the supply water in the housing 200 flows into the space portion h to prevent the leakage of water. It should be equal to or greater than the pressure.

Referring to FIG. 6, another embodiment of the pneumatic exponent 700 of the present invention will be described.

A housing 200 having an inlet 210 for supplying the supply water from the outside and a discharge port 220 for discharging the supply water to the outside and for moving the supply water; The first cell shaft 610 having the first shaft shaft 510 rotated by the operation of the first driving device 310 and the first shaft shaft 510 rotating due to the rotation of the first shaft shaft 510 connected to the cell disc 610 And a second shaft shaft 520 connected to the second cell disc 620 is rotated on the other side of the housing 200. The second shaft device 520 is rotated by the operation of the second driving device 320, The second cell disc 620 is rotated in a direction opposite to the rotating direction of the first cell disc 610 and the first and second shaft shafts 510 And 520, and prevents the supply water in the housing 200 from leaking Wherein the index device 700 is constructed between the housing 200 and the first and second shaft shafts 510 and 520. The index device 700 includes an index And an injection port 710 through which air can be injected through the device 700 is formed.

The description of the exponent device 700 is the same as the description of the first configuration, and thus will not be described.

This is because the pneumatic exponential device 700 according to the present invention can also be mounted on the centrifugal heaters 100 having the drive unit 300, the bearing unit 400, the shaft shaft 500, and the cell disc 600, The centrifugal heaters 100 may be configured to face the above-described configuration of driving the centrifugal heaters 100 and may be applied to the centrifugal heaters 100 in which the first cell disc 610 and the second cell disc 620 reciprocally rotate .

Referring to FIGS. 1 to 7, the operation of the centrifugal heat generator using the pneumatic device according to the present invention will be described in detail.

As shown in FIGS. 1 to 5, the centrifugal heat generator 100 supplies heating water and hot water using the generated thermal energy by generating a rotating force in the supplied water after introducing the supplied water into the interior of the housing 200 The supply water flows into the housing 200 through the inlet 210 formed at one side of the housing 200 and the supply water flowing into the housing 200 flows through the shaft shaft 500 And the rotation of the shaft shaft 500 causes the cell disk 600 connected to the shaft shaft 500 inside the housing 200 to rotate. At this time, the bearing part 400 serves to assist the rotation of the shaft shaft 500.

In the centrifugal heat generator 100, the supply water flowing into the housing 200 is heated by the rotation of the shaft shaft 500, and when the supply water becomes hot water, the water is discharged through the discharge opening 220.

In order to prevent this, in the indexing device 700 of the present invention, air pressure is injected from the outside of the housing 200 to the shaft 200, So that the supply water leaking from the inside of the housing 200 can be prevented from being leaked by the air pressure injected through the injection port 710 of the indexing device 700.

At this time, the air pressure injected into the injection port 710 should be equal to the pressure inside the housing 200. This is to prevent the leakage of water due to the pressure of the supply water when the pressure of the air pressure is made lower than the pressure inside the housing 200.

The air pressure is discharged through the storage groove 711 formed at the end of the injection port 710 and is discharged from the space portion h between the indexing device 700 and the shaft shaft 500, So as to minimize the leakage by allowing the supply water to push each other as opposed to the other.

The air pressure is preferentially stored in the storage groove 711, and the air pressure in the storage groove 711 is pushed by the air pressure injected from the outside to be injected into the space h. At this time, when the air pressure is injected into the space part h, the distance of the exponential device 700 is shorter toward the inside of the housing 200 and the distance to the outside is longer.

At this time, the pressure of the air pressure should be equal to or higher than the pressure of the supply water in the housing (200). When the pressure of the air pressure is made smaller than the supply water pressure, the supply water is pumped by the pressure of the supply water, and the supply water is introduced into the space, and leakage occurs.

The outlet device 720 is formed on the outer side of the injection port 710 so that fine water generated due to the rotation of the shaft shaft 500 And can be discharged through the discharge port 720 when the injection port 710 can not prevent it.

The discharge groove 721 formed in the discharge port 720 allows the water to flow into the discharge port 720 through the discharge groove 721 and then places the water in the discharge space h '. When the amount of water located in the discharge space h 'becomes a proper amount, water is discharged to the outside through the external discharge port 730 by disengaging the cap 731.

6 and 7, the index device 700 of the present invention includes one drive unit 300, a bearing unit 400, a shaft shaft 500, and a structure of a cell disk 600 The first cell disc 610 and the second cell disc 620 which face each other in the single housing 200 may be used in the centrifugal heaters 100 driven by the reciprocating or counter- A first shaft unit 510, and a first cell disc 610. The first driving unit 310, the first bearing unit 410, the first shaft shaft 510, and the first cell disc 610, Each of the first and second cell disks 610 and 620 constituted by the second driving unit 320, the second bearing unit 420, the first shaft shaft 520 and the second cell disc 620, So that the centrifugal heaters 100 can be connected to the rotating centrifugal heaters 100.

100: Centrifugal heater
200: housing 210: inlet 220: outlet
300: driving device 310: first driving device 320: second driving device
400: bearing part 410: first bearing part 420: second bearing part
500: shaft shaft 510: first shaft shaft 520: second shaft shaft
600: cell disc 610: first cell disc 620: second cell disc
700: Indexing device 710: Inlet port 711: Storage groove
720: outlet 721: outlet groove
730: Outside outlet 731: Plug
h: space section h: discharge space

Claims (14)

A housing (200) having an inlet (210) for receiving supply water from the outside and a discharge opening (220) for discharging the supply water to the outside and moving the supply water; A shaft shaft 500 that is rotated by the operation of the bearing 300 and the bearing unit 400 and the water supply unit 400 which is formed between the housing 200 and the shaft shaft 500 and prevents the water in the housing 200 from leaking An exponent unit 700 having an outlet 720 formed therein for discharging water moving through the space h and a discharge space formed outside the exponent unit for selectively discharging water to the outside of the space A centrifugal heat exchanger (100) comprising an outer outlet, a cap, and a cell disk (600) connected to a shaft shaft (500) inside the housing (200)
An inlet 710 is formed through the housing 200 and the exponent unit 700 so as to inject air between the shaft shaft 500 and the exponent unit 700,
A storage groove 711 is formed at an end of the injection port 710 and a discharge groove 721 is formed at one side of an index device 700 which is in contact with the shaft shaft 500,
Wherein the air pressure injected into the injection port (710) is injected at a rate equal to or greater than a pressure generated inside the housing (200).
delete delete delete delete delete A housing 200 having an inlet 210 for supplying the supply water from the outside and a discharge port 220 for discharging the supply water to the outside and for moving the supply water; The first cell shaft 610 having the first shaft shaft 510 rotated by the operation of the first driving device 310 and the first shaft shaft 510 rotating due to the rotation of the first shaft shaft 510 connected to the cell disc 610 And a second shaft shaft 520 connected to the second cell disc 620 is rotated on the other side of the housing 200. The second shaft device 520 is rotated by the operation of the second driving device 320, The second cell disc 620 is rotated in a direction opposite to the rotating direction of the first cell disc 610 and the first and second shaft shafts 510 And 520, and prevents the supply water in the housing 200 from leaking And an outlet port 720 formed at the outlet port 720 so as to discharge the water flowing through the space h, and a discharge space formed outside the expelling device to selectively discharge water out of the space A centrifugal heat generator (100) having an outer discharge port and a stopper,
An inlet 710 is formed through the housing 200 and the respective index devices 700 so as to inject air between the first and second shaft shafts 510 and 520 and the respective index devices 700,
A storage groove 711 is formed at the end of each of the injection holes 710 and a discharge groove 721 is formed in one side of the index device 700 which is in contact with the shaft shaft 500,
Wherein the air pressure injected into each of the injection ports (710) is injected at a rate equal to or greater than a pressure generated in the housing (200)
delete delete delete delete delete A housing (200) having an inlet (210) for receiving supply water from the outside and a discharge opening (220) for discharging the supply water to the outside and moving the supply water; A centrifugal heat radiator 100 composed of a shaft shaft 500 rotated by the operation of the bearing unit 300 and the bearing unit 400 and a cell disk 600 connected to the shaft shaft 500 inside the housing 200 In an exponent method in which water is expended by constructing an index device (700) between the housing (200) and a shaft shaft (500)
The inlet port 710 is formed by passing through the index device 700 that is grounded to the shaft shaft from the outside of the housing 200 and the inlet port 710 between the index device 700 and the shaft shaft is inserted And a discharge groove 721 is formed on one side of the index device 700 which is in contact with the shaft shaft 500 and is connected to the shaft shaft 500 by a pressure equal to a pressure generated inside the housing 200, Or high pressure air is continuously administered to prevent the water inside the housing 200 from escaping outward,
Wherein a position of the injection port (710) passing through the exponent unit (700) is located near the inside of the housing to guide the introduced air to move toward the inside of the housing having a relatively low resistance. Exponential exponent method


delete

Images