KR100947667B1 - Impeller Shaft supporting Structure Of Vertical Waltman Type Flowmeter - Google Patents

Abstract

According to the present invention, a bushing for supporting the rotating shaft by inserting the rotating shaft through the through-hole formed in the center portion to support the rotating shaft, a bearing provided to support the rotating shaft in contact with the end and one side of the rotating shaft, the bushing and the bearing in the insertion groove formed in the center portion Is formed by the bearing housing and the inner support to the rotating shaft is formed to support the rotating shaft and the bearing housing is installed in the fastening groove is fixed to the inner body of the water meter including a rotating shaft support that is installed to be fixed to the inner housing, bearing housing And at least one foreign matter discharge passage is provided at one side of the rotary shaft support, and the foreign matter contained in the water flowing into the bearing housing flows out of the rotary shaft support through the foreign substance discharge passage in the bearing housing. Provides a support structure for the rotor shaft of the Waltmann water meter.

According to the disclosed rotor wheel support structure of the vertical Waltmann type water meter, since the frictional force due to the deposition of foreign matter contained in the water flowing into the water shaft during the rotation drive of the water meter does not increase, so as to the water meter during the initial rotation of the rotating shaft. Even when the flow rate is small, the vane is rotated to measure the fine flow rate.

Water meter, rotating shaft, support structure, bushing, outflow hole, bearing, foreign substance

Description

Impeller Shaft supporting Structure Of Vertical Waltman Type Flowmeter

The present invention relates to a rotor wheel support structure of the vertical Waltmann type water meter, and more specifically, by forming a foreign material outflow path in the bearing housing and the shaft support supporting the rotating shaft rotating inside the water meter. In addition, the foreign matter contained in the water flowing into the bearing housing relates to the rotor shaft support structure of the water meter, characterized in that the outflow to the outside of the rotary shaft support through the foreign substance outflow passage.

In general, the water meter is to accurately measure the amount of water used in each household or other places of use, which is installed at a predetermined position of the water pipe to measure the quantity according to the flow rate of water passing through the water pipe and display it as a number. Meters are widely known and widely used according to their structure.

Among the various water meters, the structure of the vertical Waltmann type water meter according to the present invention will be described as follows.

Figure 1 is an exploded perspective view showing the overall configuration of a general vertical Waltman water meter, Figure 2 is a cross-sectional view showing the blade shaft support structure of a conventional vertical Waltman water meter.

1 and 2, the main body 10 is mounted through a flange of both sides at a predetermined position of the water pipe, the inner body 13 and the inner body of the water meter inserted into the main body 10 ( The upper cover 11 is fastened to the upper portion of the 13 to fix the inner body 13 to the main body 10.

The inside of the inner body 13 is provided with a vane 14 which is rotated by the water pressure of the incoming water in the transverse direction, is inserted into the insertion hole formed in the center of the vane 14 is fastened to the blade (14) One end is supported by the support 18 fixed to the inner body 13 and the other end is supported by the gear cover 16 and the rotary shaft support 20 so that the rotary drive can be rotated together as it rotates. ) Is mounted.

Inside the rotating shaft support 20, the rotating shaft 15 is inserted through a through hole formed in a central portion thereof so that the bushing 21 supporting the rotating shaft 15 and one end of one side of the rotating shaft 15 come into contact with the rotating shaft ( A bearing 22 is provided which is adapted to support 15.

In addition, the gear cover 16 is internally installed to support the worm 17a, the worm gear 17b, and the pinion 17c, and a through hole is formed in the center thereof so that the rotation shaft 15 is inserted therethrough.

The rotational force of the rotary shaft 15 is decelerated through the worm 17a, the worm gear 17b and the pinion 17c, and is transmitted to the measurement unit 19 located above the inner body 13, and the measurement unit receives the rotational force. 19, an integrated display unit 12 is provided to rotate the indicator hand so that the display can be displayed numerically.

Therefore, as the user uses the tap water, the water passing through the water pipe passes through the inner body 13 in the main body 10 and drives the vane 14 and the rotation shaft 15 to rotate, and the rotational force is the worm 17a. ) And decelerated through power transmission devices such as worm gear 17b and pinion 17c, and transmitted to the upper measuring unit 19. The transmitted rotational force rotates the indicator needle in the measuring unit 19 to a number. The amount of water used is measured by being displayed on the integration display unit 12.

The water meter is configured to rotate the blade wheel 14 and the rotation shaft 15 at high speed by the flow of water flowing therein, so as to minimize the rotational interference of the rotation shaft 15, the center portion of the bushing 21 is provided. It is inevitable that the diameter of the rotating shaft 15 is smaller than the diameter of the formed through hole.

Accordingly, water containing fine foreign matter is introduced into the gap generated by the size difference between the diameter of the rotating shaft 15 and the diameter of the through hole formed in the center of the bushing 21, and the introduced foreign matter is introduced into the water flow of the introduced water. Due to the water flow, it does not flow out in the bearing support 20 and accumulates in devices such as the rotating shaft 15, the bushing 21, and the bearing 22.

The foreign matter thus deposited increases resistance when the rotary shaft 15 rotates in contact with the bearing 22 and the bushing 21, and the blade wheels such as the rotary shaft 15, the bearing 22, the bushing 21, and the like. Accelerates abrasion due to friction of the accessories associated with the rotation of (14), whereby the diameter of the bearing 22 and bushing 21 and the diameter of the rotating shaft 15 to fix and support the shaking of the rotating shaft 15 The difference in size is gradually separated.

In addition, due to the size difference of the spaced apart as described above, the unstable vibration occurs in the rotating shaft 15 to cause a reduction in the rotational speed of the blade wheel 14, the measurement performance of the water meter is lowered, so that the train for flow measurement ( Difference between the actual flow rate and the measured flow rate), and the bushing 21, bearing 22, worm 17a, worm gear 17b, and pinion 17c, etc., which are mechanically connected to the rotary shaft 15; The unstable vibration is also transmitted to the accessories of the to facilitate the wear of the accessories to shorten the life of the water meter.

In addition, when the water meter is not used for a certain period of time, a ringing phenomenon occurs in which the metal and the smooth surface of the metal adhere to each other due to the accumulated foreign matter upon reuse, thereby causing the rotating shaft 14 and the bushing 21 and The bearings 22 stick to each other, and the frictional force due to the foreign matter increases, so that they do not operate at the minute flow rate during the initial rotation of the rotating shaft 14 and at a flow rate exceeding the standard value of the maximum allowable error of the minimum flow rate of the water meter. There is a problem that the initial rotation of the rotary shaft 14 is possible.

Here, the minimum flow rate means the lowest flow rate at which the rotation axis of the water meter can be operated without exceeding the maximum allowable error, and the maximum allowable error means an extreme value of the water meter indicating error allowed by the water meter calibration standard.

The present invention was created in order to solve the above-described problems, the foreign material contained in the water flowing into the bearing housing by forming a foreign matter discharge passage on one side of the bearing housing and the rotary shaft support provided to support the rotating shaft is the bearing By allowing the foreign substance to flow out of the rotary shaft support through the foreign substance outflow passage, foreign matter is accumulated and accumulated in the bushing and the bearing including the rotary shaft, so that it is possible to measure even the micro flow rate flowing into the water meter. It aims to improve the measurement performance by minimizing the train when measuring the flow rate and to extend the life of the water meter.

The rotor blade support structure of the vertical Waltmann type water meter of the present invention for achieving the above object is a bushing through which the rotary shaft is inserted through the through-hole formed in the center to support the rotary shaft, and one end and one side of the rotary shaft The bearing housing is provided to support the rotating shaft and the bushing and the bearing are internally fixed to the insertion groove formed in the center portion, and the bearing housing is provided to support the rotating shaft, and a fastening groove is formed on the inner surface thereof so that the bearing housing is fastened. It is installed in the groove is fixed and includes a rotating shaft support installed to be fixed to the inner body of the water meter.

In addition, one side of the bearing housing and the rotating shaft support is provided with at least one foreign material outflow passage, the foreign matter contained in the water flowing into the bearing housing in the bearing housing through the foreign material outflow passage of the rotary shaft support body Characterized in that the outflow to the outside.

Here, a predetermined space is formed inside the bearing housing, and the water pressure of the bearing housing internal space is higher than that of the water meter body, which is the bearing housing external space, due to the water flow flowing into the bearing housing. This can be characterized as occurring.

In addition, it is preferable that the diameter of the insertion groove positioned between the bushings and the bearings which are inherently fixed to both insertion grooves of the bearing housing is larger than the diameter of the through hole formed at the center of the bushing.

In addition, the diameter of the foreign matter outflow hole can be characterized in that it is formed smaller than the diameter of the through hole formed in the central portion of the bushing.

In addition, the foreign matter outflow passage is preferably provided so that the foreign matter outflow groove formed in one end of the bearing housing and the foreign matter outflow hole formed in the insertion groove of the rotary shaft support.

According to the inventors of the rotor shaft support structure of the vertical Waltmann water meter,

First, when the rotating shaft and the bushing and the bearing are in contact with each other, the frictional force due to the foreign matter does not increase, and the rotating shaft and the bushing and the bearing are not bonded to each other due to the ringing phenomenon even when the water meter is not used for a certain period of time. The rotor blades are rotatable even at a minute flow rate at the time of rotation, so that a fine flow rate measurement is possible.

Second, since foreign matters are not deposited on the bushing and the bearing including the rotating shaft, the vibration and rotational interference caused by the rotating shaft can be minimized.

Third, it extends the life of water meter by minimizing the friction caused by friction of power transmission devices such as worm, worm gear and pinion which are mechanically connected to the rotating shaft, including rotary shaft, bushing, bearing, etc. You can.

Fourth, since the vibration and rotation interference of the rotating shaft is minimized and the rotation speed due to the foreign matter does not occur, the measurement performance can be improved by minimizing the train for the flow rate.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

First, the configuration and operation of the present invention by the accompanying drawings in detail as follows.

3 is a cross-sectional view showing a rotor wheel shaft support structure of the present invention, Figure 4 is an exploded perspective view showing the configuration of the rotary shaft support member of the present invention.

As shown in FIG. 3, the inner body 33 is inserted into the main body of the Waltman type water meter of the present invention, and the vane 34 is rotated by the water pressure of the water flowing into the inner body 33. Direction is provided.

One end is supported by a support (not shown) fixed to the inner body 33 so as to be rotatably driven together with the insertion hole formed at the center portion of the vane 34 so that the vane 34 rotates. The other end is supported by the gear cover 36 and the rotary shaft support 40 to mount the rotary shaft 35.

Here, the gear cover 36 is provided with an insertion hole into which the rotary shaft 35 of the vane 34 is fastened at the center thereof, and both ends thereof are fastened by fastening bolts to the inner body 33 and fixed. On one side of the gear cover 36, the rotating shaft support body 40 for supporting the rotating shaft 35 is fastened by the fastening bolt 45. In addition, power transmission devices such as a worm, a worm gear, and a pinion are supported in the gear cover 36 to be rotatable.

The configuration of the rotary shaft support 40 according to the present invention is shown in more detail in FIG.

Referring to FIG. 4, the bearing housing 50 has a central portion through which a through hole is formed, and a bearing 52 provided at both ends of the through hole in contact with one end and one side of the rotating shaft 35 to support the rotating shaft 35. The bushing insertion groove 54 is fixedly inserted into the bushing insertion groove 54 and the bushing 51 is inserted into the rotating shaft 35 through the through-hole formed in the center portion is fixed to the bushing 51 for supporting the rotating shaft 35 ( 53) is formed.

Here, the bearing 52 and the bushing 51 is made of a material such as sapphire, ceramic, rubber sintered hard and smooth surface, the bearing 52 and the bushing 51 is a high speed It is possible to minimize the rotational interference caused by being installed in contact with the rotating shaft 35 to rotate, it is desirable to reduce the wear of each component due to friction.

 In addition, the one end of the bearing housing 50 is formed with a foreign substance outflow groove 55 for the foreign matter contained in the water flowing into the inside, the rotary shaft support (55) corresponding to the position of the foreign substance outflow groove (55) The foreign substance outlet hole 46 is formed in the fastening groove 41 of the 40.

The foreign substance discharge groove 55 and the foreign substance discharge hole 46 are connected to each other by inserting and fastening the bearing housing 50 and the rotary shaft support 40 to each other to form one foreign substance discharge passage.

FIG. 5 is a view illustrating a configuration in which water containing foreign matters escapes from the inside of the bearing housing 50 to the outside through a foreign substance outlet passage formed by connecting the foreign substance outlet hole 46 and the foreign substance outlet hole 46. to be.

As shown in FIG. 5, in order to minimize rotational interference generated when the rotary shaft 35, the bushing 51, and the gear cover 36 rotate in contact with each other, the diameter of the rotary shaft 35 is equal to the diameter of the bushing 51. Inevitably smaller than the diameter of the inside and the diameter of the through-hole formed in the gear cover 36.

Therefore, as shown in FIG. 5, the water penetrating the inside of the water meter between the gap generated due to the size difference between the diameter of the rotating shaft 35 and the internal diameter of the through hole formed in the bushing 51 and the gear cover 36. Water enters.

The introduced water passes through the through hole in the bushing 51 through the through hole in the gearbox 36 due to the flow of water in the direction of the arrow, and the foreign matter outflow passage reaches the bearing housing 50. Through it is to exit to the outside of the rotary shaft support 40.

Thus, foreign matter contained in the water flowing into the bearing housing 50 remains on the surface of the bushing 51 including the rotating shaft 35 and the bearing 52 and bearing housing 50 due to the water flow. It will not flow out with the water flowing into the bearing housing 50 outside.

Here, the diameter of the predetermined inner space 44 located between the bushing 51 and the bearing 52 which are inherently fixed to both insertion grooves 53 and 54 of the bearing housing 50, It is preferable to form larger than the diameter of the through hole formed in the central portion of the bushing (51).

This is because the water pressure of the bearing housing 50, the inner space 44 of the bearing body 50 is the outer space of the bearing housing 50 due to the water flow containing the foreign matter flowing into the bearing housing 50. High water pressure is maintained as compared to the water pressure in the inner space, due to the difference between the water pressure in the bearing housing 50 and the water pressure of the inner space of the inner body 33, the other water flow in the bearing housing 50 (the The flow of water flowing out to the outside through the foreign matter outflow groove in the bearing housing 50, the foreign matter inside the bearing housing 50 along the water flow of the foreign matter outflow groove 55 and the foreign matter outflow hole ( 46 is to exit to the inner space of the water meter body that is the outer space of the bearing housing 50.

In addition, it is preferable that the diameter of the foreign matter outlet hole 46 is smaller than the diameter of the inside of the bushing 51.

As described above, the internal water pressure of the bearing housing 50 must maintain a high water pressure compared to the external water pressure of the bearing housing 50, whereas the other water flows occur due to the pressure difference, When the diameter is larger than the diameter of the inside of the bushing 51, the hydraulic pressure difference between the inside and outside the bearing housing 50 is reduced or equal, so that the foreign matter flows out of the bearing housing 50 smoothly.

In addition, the bearing housing 50 and the rotary shaft support 40, the condition that the pressure inside the bearing housing 50 is maintained to be greater than the external pressure and the durability of the bearing housing 50 and the rotary shaft support 40 In consideration of the foreign matter discharge groove 55 and the foreign matter discharge hole 46 may be provided with two or more foreign matter discharge passage is formed.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1 is an exploded perspective view showing the overall configuration of a general vertical Waltmann water meter,

Figure 2 is a cross-sectional view of the support structure of the rotor blade axis of the conventional vertical Waltmann water meter,

3 is a cross-sectional view of the rotor blade support structure of the present invention,

Figure 4 is an exploded perspective view showing the configuration of the rotary shaft support of the present invention,

5 is a cross-sectional view showing a configuration in which foreign matter flows out from the bearing housing of the present invention to the outside.

<Explanation of symbols for the main parts of the drawings>

34 ... wing 35 ... rotation shaft

40.Rotary shaft support 46

50 ... Bass housing 51 ... Bushing

52.Receive 55

Claims (5)

Is inserted into the insertion hole formed in the center portion of the rotor blades that rotate inside the vertical Waltmann type water meter is installed to enable the rotary drive together as the rotor blades rotate, the rotational force is transmitted to the measuring unit through the worm and worm gear In the supporting structure for supporting, A bushing through which the rotating shaft is inserted through the through-hole formed in the center to support the rotating shaft; A shaft bearing provided to support the rotary shaft by contacting one end of the rotary shaft and one side thereof; and A bearing housing provided with the bushing and the bearing supported in the insertion groove formed at the center thereof, and configured to support the rotating shaft; And Forming a fastening groove on the inner side and the bearing housing is installed in the fastening groove is fixed, and includes a rotating shaft support that is installed to be fixed to the inner body of the water meter, One side of the bearing housing and the rotary shaft support is provided with at least one foreign matter outflow passage, foreign matter contained in the water flowing into the bearing housing to the outside of the rotary shaft support through the foreign matter outflow passage in the bearing housing. Rotor axis support structure of vertical Waltmann water meter characterized in that the flow The method of claim 1, Since a predetermined space is formed inside the bearing housing, the water pressure flowing into the bearing housing causes the water pressure of the bearing housing inner space to be higher than that of the water meter body which is the bearing housing outer space. Rotor axis support structure of vertical Waltmann water meter, characterized in that The method of claim 2, Vertical Waltmann type water, characterized in that the diameter of the insertion groove which is located between the bushing and the bearing is installed in each of the two grooves of the bearing housing is formed larger than the diameter of the through hole formed in the central portion of the bushing Metric rotor shaft support structure The method of claim 3, wherein The foreign material flow passage supporting the rotor shaft support structure of the vertical Waltmann-type water meter, characterized in that the foreign matter discharge groove formed in one end of the bearing housing and the foreign matter discharge hole formed in the coupling groove of the rotary shaft support is connected to each other. The method of claim 4, wherein The foreign material outflow hole diameter, the rotor shaft support structure of the vertical Waltmann-type water meter is formed smaller than the diameter of the through hole formed in the central portion of the bushing

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