KR102613972B1 - Pipings liquid amount check sight glass structure - Google Patents

Abstract

The purpose of the present invention is to provide a site glass structure for checking the pipe flow rate. The structure of the present invention includes a glass support portion 120 provided on one side of the pipe 110; A side glass 125 mounted on the glass support 120; and a retaining member 130 coupled to the glass support 120 so as to secure the side glass 125 to the glass support 120.

Description

Piping flow rate check sight glass structure {Pipings liquid amount check sight glass structure}

The present invention relates to a site glass structure for checking the pipe flow rate, and more specifically, to a site glass structure for checking the pipe flow rate for checking the flow rate supplied into the pipe.

In general, piping includes plant piping installed in chemical plants, steel mills, etc., piping in manufacturing facilities, tanks, boilers, etc., and fluids such as liquid or gas continuously flow within the piping in a certain amount for a certain period of time. . At this time, the amount of fluid supplied through the inside of the pipe is checked over time and used for process management and various analysis data based on this, so it is used to check and observe the fluid flowing through these various pipes. We need means.

Korean Patent Publication No. 10-2017-0016048 (published on February 13, 2017) Korea Public Utility Model No. 20-2013-0002660 (published on May 3, 2013) Korean Patent No. 10-1720249 (registered on March 21, 2017) Korean Patent No. 10-1497499 (registered on February 24, 2015)

The purpose of the present invention is to provide a pipe flow rate confirmation sight glass structure for checking the flow rate supplied into the pipe from the outside of the pipe.

According to the present invention to solve the above problem, a glass support portion 120 provided on one side of the pipe 110; A side glass 125 mounted on the glass support 120; A site glass structure for checking the pipe flow rate is provided, including a retaining member 130 coupled to the glass support 120 to secure the side glass 125 to the glass support 120.

One side of the pipe 110 is provided with a pipe-side flow rate confirmation hole 112 penetrating through the inner and outer peripheral surfaces, and the pipe-side flow rate confirmation hole of the pipe 110 is provided at the bottom 124 of the glass supporter 120. A through hole 122 for checking the flow rate is provided in communication with (112), and the bottom 124 of the glass support part 120 is provided with a packing coupling support protrusion disposed at an outer position of the through hole 122 for checking the flow rate. (126) is provided, packing 140 is coupled to the outer peripheral surface of the packing coupling support jaw 126, and the retaining member 130 penetrates the retaining side facing the flow rate confirmation through hole 122. It is configured in a ring shape with a hole 132, the bottom of the side glass 125 is in contact with the packing 140, and the upper surface of the side glass 125 is on the bottom of the retaining member 130. It is characterized in that it is configured to maintain a sealed state between the flow rate confirmation hole 112 on the pipe side of the pipe 110 and the side glass 125 by the packing 140.

The inner glass receiving hole of the glass supporter 120 is formed as a circular space when viewed from above the glass supporter 120, and the retaining side thread portion of the outer peripheral surface of the retaining member 130 is the inner peripheral surface of the glass supporter 120. It is coupled to the support side thread formed in, and the bottom of the retaining member 130 presses the side glass 125 so that the side glass 125 is fixed to the inner glass receiving hole of the glass support part 120. In addition, a liquid stagnation prevention hole 114 is further provided on the inner peripheral surface of the pipe 110 to be disposed in the area of the pipe side flow rate confirmation hole 112, and the liquid stagnation prevention hole 114 is located in the pipe 110. It is characterized in that it is arranged in a direction perpendicular to the longitudinal direction of.

The pipe flow rate confirmation site glass structure of the present invention has the effect of quickly and conveniently checking the flow rate supplied into the pipe from the outside of the pipe through the side glass installed on one side of the pipe.

1 is a cross-sectional view of the site glass structure for checking the pipe flow rate according to the present invention;
Figure 2 is a cross-sectional view of a site glass structure for checking the pipe flow rate according to another embodiment of the present invention;
Figure 3 is a photograph showing the disassembled state of the side glass and retaining member, which are the main parts of the pipe flow rate confirmation site glass structure shown in Figure 1, from above;
Figure 4 is a photograph showing the pipe flow rate confirmation site glass structure according to the present invention from above;
Figure 5 is a cross-sectional view schematically showing the process of coupling the reinforced retainer and reinforced side glass, which are the main parts of the pipe flow rate confirmation site glass structure according to another embodiment of the present invention, to the glass support part of the pipe;
Figure 6 is an enlarged view of the main part of Figure 5;
Figure 7 is a cross-sectional view showing a state in which the reinforced retainer and reinforced side glass shown in Figures 5 and 6 are coupled to the glass support part of the pipe;
Figure 8 is an enlarged view of the main part of Figure 7;
Figure 9 is a cross-sectional view showing a state in which the main parts of the present invention, the reinforcing retainer and the reinforcing side glass, are coupled to the glass support part of the pipe and the sealing reinforcing packing is coupled;
Figure 10 is an enlarged view of the main part of Figure 9;
Figure 11 is an enlarged cross-sectional view showing the structure of the release bolt and the release operation stone part, which are other main parts of the present invention;
Figure 12 is an enlarged view of the main part of Figure 11;
Figure 13 is a cross-sectional view showing the reinforcing coupling support piece and the reinforcing coupling hook piece shown in Figures 11 and 12 in an open state;
Figure 14 is an enlarged view of the main part of Figure 13;
Figure 15 is a cross-sectional view showing a state in which a plate with clearance, which is a main part of another embodiment of the present invention, is installed inside the pipe;
Figures 16 and 17 are enlarged views of another modified embodiment of the plate with clearance shown in Figure 15;
Figure 18 is a cross-sectional view showing a state in which the propeller, which is a main part of another embodiment of the present invention, is installed inside the pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The purpose, features, and advantages of the present invention can be more easily understood by referring to the accompanying drawings and the following detailed description. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being "connected," "coupled," or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that elements may be “connected,” “combined,” or “connected.”

In addition, the specific structural and functional descriptions in the present invention are merely illustrative for the purpose of explaining embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms and may be applied in the present specification or application. It should not be construed as limited to the embodiments described in.

Figure 1 is a cross-sectional view of a site glass structure for checking piping flow rate according to the present invention, Figure 2 is a cross-sectional view of a site glass structure for checking piping flow rate according to another embodiment of the present invention, and Figure 3 is a site glass structure for checking piping flow rate shown in Figure 1. A photo showing the disassembled state of the main parts of the side glass and retaining member from above, and Figure 4 is a photo showing the site glass structure for checking the pipe flow rate according to the present invention from above.

Referring to the drawings, the present invention includes a glass support portion 120 provided on one side of a pipe 110; A side glass 125 mounted on the glass support 120; It is a pipe flow rate confirmation site glass structure that includes a retaining member 130 coupled to the glass support 120 so as to secure the side glass 125 to the glass support 120.

The pipe 110 is configured in the shape of a pipe with a circular fluid receiving space therein.

A pipe-side flow rate confirmation hole 112 is provided on one side of the pipe 110. The pipe-side flow rate confirmation hole 112 penetrates the inner and outer peripheral surfaces of the pipe 110. The pipe-side flow rate confirmation hole 112 has a circular hole shape.

The bottom 124 of the glass supporter 120 is provided with a flow rate confirmation through hole 122 that communicates with the pipe side flow rate confirmation hole 112 of the pipe 110. The outer end of the bottom part 124 of the glass support part 120 is integrally connected to the pipe 110, and a circular hole-shaped through hole 122 for confirming the flow rate is provided in the bottom part 124 of the glass support part 120. This is provided. The center of the flow rate confirmation hole 122 formed in the bottom 124 of the glass support portion 120 is disposed on the same line as the center of the pipe side flow rate confirmation hole 112 formed on one side of the pipe 110, From the outside of the pipe 110, the flow rate filled in the fluid receiving space inside the pipe 110 can be confirmed through the flow rate confirmation through hole 122 and the pipe side flow rate confirmation hole 112.

Meanwhile, a packing coupling support protrusion 126 is provided on the upper surface of the bottom portion 124 of the glass support portion 120 to be disposed around the through hole 122 for confirming the flow rate. The packing coupling support jaw 126 is composed of an annular closed-loop shaped jaw. A packing 140 seating groove for seating the packing 140 is formed between the outer peripheral surface of the packing coupling support jaw 126 and the inner surface of the glass support portion 120.

The glass supporter 120 has a rectangular block shape when viewed from above, an upper open hole is provided at the upper end of the glass supporter 120, the bottom part 124 is provided below the upper open hole, and the bottom The part 124 is provided with a through hole 122 for checking the flow rate, and the inner glass receiving hole of the glass support part 120 is configured in the shape of a circular hole communicating with the upper open hole.

The annular packing 140 is seated and coupled to the seating groove of the packing 140, and the packing coupling support jaw 126 supports the inner surface of the packing 140. That is, the bottom portion 124 of the glass support portion 120 is provided with a packing coupling support jaw 126 to be disposed outside the flow rate confirmation through hole 122, and the packing coupling support projection 126 Packing 140 is configured to be coupled to the outer peripheral surface.

The retaining member 130 is configured in a ring shape with a retaining-side through-hole 132 facing the flow rate confirmation through-hole 122.

Retaining-side confirmation holes are provided through the upper and lower surfaces of the retaining member 130. The retaining side confirmation hole has a circular hole shape, and the center of the retaining side confirmation hole is the center of the flow rate confirmation through hole 122 formed in the bottom 124 of the glass support part 120 and one side of the pipe 110. It is disposed on the same line as the center of the pipe-side flow rate confirmation hole 112 formed in , and the retaining-side confirmation hole of the retaining member 130 and the flow rate confirmation through-hole 122 are formed on the outside of the pipe 110. It is possible to check the flow rate filled in the fluid receiving space inside the pipe 110 through the flow rate confirmation hole 112 on the pipe side.

The bottom of the side glass 125 is pressed into contact with the packing 140, and the upper surface of the side glass 125 is pressed into contact with the bottom of the retaining member 130, so that the piping 110 is pressed by the packing 140. ) is configured to maintain a sealed state between the pipe-side flow rate confirmation hole 112 formed in the side glass 125 and the side glass 125.

The inner glass receiving hole of the glass supporter 120 is formed as a circular space when viewed from above the glass supporter 120, and the retaining side thread portion of the outer peripheral surface of the retaining member 130 is the inner peripheral surface of the glass supporter 120. It is coupled to the support side thread formed in , and the bottom of the retaining member 130 presses the side glass 125 to support the side glass 125 to be fixed to the inner glass receiving hole of the glass supporter 120. As described above, the bottom surface of the side glass 125 is pressed into contact with the packing 140, and the upper surface of the side glass 125 is pressed into contact with the bottom surface of the retaining member 130 by the packing 140. A sealed state can be maintained between the pipe-side flow rate confirmation hole 112 formed in the pipe 110 and the side glass 125.

Therefore, the pipe flow rate confirmation site glass structure according to the present invention allows the flow rate supplied into the pipe 110 to be quickly and conveniently measured from the outside of the pipe 110 through the side glass 125 installed on one side of the pipe 110. There is a verifiable effect.

In addition, the retaining-side threaded portion of the outer peripheral surface of the retaining member 130 is coupled to the support-side threaded portion formed on the inner peripheral surface of the glass support portion 120, so that the bottom surface of the retaining member 130 is connected to the side glass 125. Since the side glass 125 is supported to be fixed to the internal glass receiving hole of the glass supporter 120 by applying pressure, the side glass 125 can be easily and quickly attached to the pipe 110.

In addition, when the retaining member 130 is coupled to the glass supporter 120 by rotating the screw, the pipe-side flow rate confirmation hole 112 and the side glass 125 formed in the pipe 110 by the packing 140. Since the sealing state between the pipes 110 and the side glass 125 can be maintained, a sealing support structure between the pipe 110 and the side glass 125 can be implemented simply and easily.

In addition, in the present invention, a liquid stagnation prevention hole 114 is further provided on the inner peripheral surface of the pipe 110 to be disposed in the area of the pipe-side flow rate confirmation hole 112. The liquid stagnation prevention hole 114 is characterized in that it is arranged in a direction perpendicular to the longitudinal direction of the pipe 110.

The liquid stagnation prevention hole 114 is configured to penetrate the pipe 110 in the longitudinal direction.

Since the liquid to be checked is prevented from stagnating by the liquid stagnation prevention hole 114, the flow rate of the liquid can be confirmed and measured more smoothly and accurately.

If liquid accumulates in the pipe-side flow rate confirmation hole 112 formed in the pipe 110, the flow rate of the liquid cannot be properly measured and is excessively measured and confirmed. In the present invention, the liquid to be confirmed is checked by the liquid stagnation prevention hole 114. Since stagnation is prevented in the flow rate confirmation hole 112 on the piping side, the flow rate of liquid can be checked and measured more smoothly and accurately.

Meanwhile, Figure 5 is a cross-sectional view schematically showing the process of coupling the reinforcing retainer and the reinforcing side glass, which are the main parts of the pipe flow rate confirmation site glass structure according to another embodiment of the present invention, to the glass support of the pipe, and Figure 6 is a cross-sectional view of Figure 5. Figure 7 is an enlarged view of the main part, Figure 7 is a cross-sectional view showing a state in which the reinforcing retainer and reinforced side glass shown in Figures 5 and 6 are combined with the glass support part of the pipe, Figure 8 is an enlarged view of the main part of Figure 7, and Figure 9 is a view showing the present invention. A cross-sectional view showing a state in which the main parts of the reinforcement retainer and the reinforcement side glass are combined with the glass support part of the pipe and the sealing reinforcement packing is combined, Figure 10 is an enlarged view of the main part of Figure 9, and Figure 11 is another main part of the present invention. A cross-sectional view showing an enlarged structure of the release bolt and the release operation stone part, Figure 12 is an enlarged view of the main part of Figure 11, and Figure 13 is a state in which the reinforcing coupling support piece and the reinforcing coupling hook piece shown in Figures 11 and 12 are opened. The cross-sectional view shown in FIG. 14 is an enlarged view of the main part of FIG. 13.

The present invention includes a reinforcing coupling step 152 provided on the outer peripheral surface of the glass support portion 120 on one side of the pipe 110; A reinforcement retainer 160 arranged above the glass supporter 120 and configured in a closed loop ring shape with a reinforcement retaining side confirmation hole penetrating from the top and bottom on the inside. A reinforcement retaining side glass coupling groove 162 provided on the inner peripheral surface of the reinforcement retainer 160; A reinforced side glass (170) whose peripheral portion is inserted and coupled to the reinforced retaining side glass coupling groove (162); A reinforcing coupling bridge piece (182) extending in a direction perpendicular to the bottom surface of the reinforcing retainer (160); a reinforcing coupling support ledge (184) connected to the reinforcing coupling bridge piece (182) and extending in a direction parallel to the bottom of the reinforcing retainer (160); Groove reinforcement coupling support piece receiving (186) formed between the upper surface of the reinforcement coupling support ledge (184) and the bottom surface of the reinforcement retainer (160); At least two or more reinforcements that are coupled to the groove reinforcement coupling support piece accommodation 186 and advance toward the center of the reinforcement retaining side confirmation hole of the reinforcement retainer 160 or move backward in a direction away from the center of the reinforcement retaining side confirmation hole. Combined support piece (192); A reinforcing hook piece 194 provided on the reinforcing coupling support piece 192 and hooked to the bottom of the reinforcing coupling step 152; It is characterized in that it further includes a reinforcing coupling support elastic body 202, both ends of which are connected to the outer surface of the groove reinforcing coupling support piece receiving 186 and the reinforcing coupling support piece 192.

When explaining the connection portion between the reinforcement retainer 160 and the reinforcement side glass 170, the reinforcement retainer 160 has a groove on the inner surface, and the reinforcement side glass 170 is inserted into the groove and joined together. There are several methods, such as forming a half-circumferential groove in the half-half reinforcement retainer part and joining two half-half reinforcement retainer parts while inserting the peripheral part of the reinforcement side grease (170) into the half-circumferential groove of the half-half reinforcement retainer part. In this way, the reinforcement retainer 160 and the reinforcement side glass 170 can be combined.

The reinforcing coupling support elastic body 202 may be composed of a spring whose both ends are connected to the inner surface of the groove reinforcing coupling support piece receiving 186 inside the reinforcement retainer 160 and the outer surface of the reinforcing coupling support piece 192. there is.

As shown in FIGS. 5 and 6, the bottom surface of the reinforcing hook pieces 194 provided on at least two of the reinforcing coupling support pieces 192 is a reinforcing coupling step provided on the outer peripheral surface of the glass support portion 120. (152) The reinforcing retainer 160 is placed above the glass supporter 120 so as to contact the upper end, and then when the reinforcing retainer 160 is pressed toward the glass supporter 120, the reinforcing coupling support piece 192 The reinforcing hook piece 194 provided in the glass support part 120 retreats in a direction away from the center of the inner glass receiving hole, and at the same time, the reinforcing coupling support elastic body 202 is compressed, and then two or more of the reinforcing coupling support pieces 192 When the upper surface of the reinforcing hook piece 194 of ) is pressed past the lower end of the reinforcing coupling step 152 of the glass support part 120, the compressed reinforcing coupling support elastic body 202 is again restored by elastic restoring force. As it unfolds, the reinforcing coupling support piece 192 and the reinforcing coupling hook piece 194 advance again toward the center of the inner glass receiving hole of the glass support part 120, so that the upper surface of the reinforcing coupling hook piece 194 becomes the reinforcing coupling step 152. ), the reinforcement retainer 160 and the reinforcement side glass 170 are fixed to the glass supporter 120, so that the reinforcement side glass 170 can be placed above the side glass 125. .

Therefore, in the present invention, the reinforcement retainer 160 and the reinforcement side glass 170 are further coupled to the side glass 125 coupled to the glass support part 120 of the pipe 110, so that the glass support part of the pipe 110 The sealing structure between the side glass 125 coupled to (120) and the flow rate confirmation hole 112 on the pipe side of the pipe 110 can be further strengthened, and the side glass 125 and the reinforcement retainer 160 are reinforced. Since the flow rate confirmation hole 112 on the piping side of the piping 110 can be double protected by the side glass 170, if the side glass 125 coupled to the piping 110 is damaged by an external impact. It has the effect of further increasing safety by preventing .

Meanwhile, the bottom surface of the reinforcing hook piece 194 provided on the reinforcing coupling support piece 192 is provided with an insertion guide tapered surface 195 inclined downward toward the outer surface of the reinforcing retainer 160, so that the insertion guide taper When the reinforcement retainer 160 is pressed toward the glass support unit 120 while the surface 195 is in contact with the upper end of the reinforcement coupling step 152 provided on the outer peripheral surface of the glass support unit 120, the reinforcement coupling support piece ( The insertion guide tape of the reinforcing hook piece 194 provided in 192) retreats more smoothly in a direction away from the center of the inner glass receiving hole of the glass support portion 120, and at the same time, the reinforcing coupling support elastic body 202 is compressed. Therefore, there is an effect in that the reinforcing retainer 160 and the reinforcing side glass 170 can be more easily and smoothly combined with the glass support portion 120 of the pipe 110.

In addition, the present invention is provided with a reinforcement packing coupling groove 163 on the bottom of the reinforcement retainer 160, and the sealing reinforcement packing 164 is inserted into the reinforcement packing coupling groove 163, and the sealing reinforcement packing 164 ) protrudes further downward from the bottom of the reinforcement retainer 160.

Therefore, in a state in which the reinforcement retainer 160 and the reinforcement side glass 170 are coupled to the glass support part 120 of the pipe 110, the bottom surface of the reinforcement retainer 160 and the glass support part ( 120) has the effect of sealing between the upper ends.

At this time, as shown in FIGS. 9 and 10, an internal packing coupling groove 128 is provided at the upper end of the glass support part 120, and the inner packing coupling groove 128 is located at the upper end of the glass support part 120. It is composed of a tapered groove whose inner diameter gradually becomes larger toward the pipe 110, and the reinforcing packing coupling groove 163 is composed of a tapered groove whose inner diameter becomes gradually smaller toward the upper surface from the bottom of the reinforcement retainer 160. In a state where the reinforcement retainer 160 and the reinforcement side glass 170 are coupled to the glass support part 120 of the pipe 110, the sealing reinforcement packing 164 is compressed to form the internal packing coupling groove 128 and the reinforcement packing. Since the coupling groove 163 is tightly filled, the sealing reinforcement packing 164 has the effect of maintaining a more solid seal between the glass support part 120 and the reinforcement retainer 160 of the pipe 110. there is.

In addition, as shown in FIGS. 11 to 14, the present invention includes a release bolt coupling hole 165 formed at a certain depth from the upper surface of the reinforcement retainer 160 toward the bottom surface and having a threaded portion on the inner peripheral surface; A release stone lifting guide hole 166 that continues to the release bolt coupling hole 165 and penetrates the bottom of the reinforcement retainer 160 and has an inner diameter that is relatively larger than the inner diameter of the release bolt coupling hole 165; A release bolt (167) with a release screw portion provided on the outer peripheral surface coupled to the screw portion on the inner peripheral surface of the release bolt coupling hole (165); It is provided at the lower end of the release bolt 167 and relatively slideably coupled to the release stone lifting guide hole 166, and the outer diameter gradually increases from the bottom of the reinforcement retainer 160 to the upper surface of the reinforcement retainer 160. It is made of a tapered protrusion shape and the release operation protrusion piece whose bottom surface is in contact with the upper end of the reinforcing coupling support piece 192 is characterized in that it further includes a.

When the reinforcement retainer 160 and the reinforcement side glass 170 are fixed to the glass supporter 120 and the reinforcement side glass 170 is disposed above the side glass 125, the release bolt 167 is It is raised upward, and the bottom of the release operation stone piece is in contact with the upper end of the reinforcing coupling support piece 192.

In this state, insert a tool such as a driver or wrench into the tool coupling groove such as the wrench groove where the straight driver groove or cross-shaped driver groove provided at the upper end of the release bolt 167 moves the release bolt 167 in one direction (e.g. For example, when rotated clockwise, the release bolt 167 descends toward the pipe 110 and the bottom surface of the release operation stone piece continues to descend while in contact with the upper inner end of the reinforcing coupling support piece 192. The release operation protrusion causes the reinforcing coupling support piece 192 and the reinforcing coupling hook piece 194 to fall outward from the position where they are caught on the lower end of the reinforcing coupling step 152 of the glass support part 120. In this state, the reinforcing retainer 160, the reinforcing side glass 170, the reinforcing coupling support piece 192, and the reinforcing coupling hook piece 194 can be lifted out and separated from the glass support portion 120 of the pipe 110. .

Therefore, the present invention requires the reinforcement retainer 160, the reinforcement side glass 170, the reinforcement coupling support piece 192, and the reinforcement coupling hook piece 194 to be lifted out and separated from the glass support portion 120 of the pipe 110. When there is, the release bolt 167 is rotated in one direction (for example, clockwise), and the reinforcing coupling support piece 192 and the reinforcing coupling hook piece 194 coupled to the reinforcing retainer 160 are Since the glass support portion 120 can be pulled outward from the position where it is caught at the lower end of the reinforcing coupling step 152, the reinforcing retainer 160, the reinforcing side glass 170, the reinforcing coupling support piece 192, and the reinforcement It is expected that the coupling hook piece 194 can be easily and quickly separated from the glass support portion 120 of the pipe 110, and furthermore, maintenance work such as replacement of the side glass 125 coupled to the pipe 110 is also convenient. There is an effect that is achieved.

Meanwhile, Figure 15 is a cross-sectional view showing a state where a plate with clearance, which is the main part of another embodiment of the present invention, is installed inside the pipe, and Figures 16 and 17 are enlarged views of another modified embodiment of the plate with clearance shown in Figure 15. 18 is a cross-sectional view schematically showing a state in which a propeller, which is a main part of another embodiment of the present invention, is installed inside the pipe.

In the present invention, a plate 200 with a gap is further installed above the partition wall 114W of the liquid stagnation prevention hole 114, so that the flow rate and the direction of the flow rate moving left and right according to the direction of the flow rate can be confirmed. The plate 200 is installed inside the pipe 110 and can be moved along the flow direction.

When viewed in cross section, the plate 200 may have various shapes such as a cross-sectional square channel shape, a triangular channel shape, or an oval shape.

In this case, the flow rate confirmation and flow direction confirmation functions can be more reliably guaranteed, and it becomes easier for the operator to confirm the flow direction and flow rate.

Additionally, in the present invention, a waterwheel-shaped propeller 210 can be further installed. The shaft at the center of the propeller 210 is coupled to the pipe 110 so that the propeller 210 can rotate according to the fluid flow inside the pipe 110.

In this case, the effect of being able to easily determine the flow and direction of the fluid without interfering with the fluid flow can be expected.

The present invention is not limited to the above-described embodiments, and those skilled in the art will understand that various modifications and variations can be made without changing the gist of the present invention. .

Therefore, the embodiments described above are provided to fully inform those skilled in the art of the present invention of the scope of the invention, and should be understood as illustrative in all respects and not restrictive. The invention is defined only by the scope of the claims.

110. Piping 112. Flow rate confirmation hole on the piping side
114. Liquid stagnation prevention hole 120. Glass support part
122. Through hole for checking flow rate 124. Bottom part
125. Side glass 126. Packing joint support jaw
128. Internal packing coupling groove 130. Retaining member
132. Retaining side through hole 140. Packing
152. Reinforced joint step 160. Reinforced retainer
162. Reinforced retaining side glass joining groove
164. Reinforced packing coupling groove 165. Release bolt coupling hole
166. Release stone lifting guide hole 167. Release bolt
168. Release operation stone piece 170. Reinforced side glass
182. Reinforced bridge piece 184. Reinforced joint support ledge
186. Receiving groove for reinforced joint support piece 192. Reinforced joint support piece
194. Reinforced hook piece 195. Insertion guide tapered surface
202. Reinforced bonded support elastomer

Claims (3)

A glass support portion 120 provided on one side of the pipe 110;
A side glass 125 mounted on the glass support 120;
A retaining member 130 coupled to the glass support 120 to secure the side glass 125 to the glass support 120,
One side of the pipe 110 is provided with a pipe-side flow rate confirmation hole 112 penetrating through the inner and outer peripheral surfaces, and the pipe-side flow rate confirmation hole of the pipe 110 is provided at the bottom 124 of the glass supporter 120. A through hole 122 for checking the flow rate is provided in communication with (112), and the bottom 124 of the glass support part 120 is provided with a packing coupling support protrusion disposed at an outer position of the through hole 122 for checking the flow rate. (126) is provided, packing 140 is coupled to the outer peripheral surface of the packing coupling support jaw 126, and the retaining member 130 penetrates the retaining side facing the flow rate confirmation through hole 122. It is configured in a ring shape with a hole 132, the bottom of the side glass 125 is in contact with the packing 140, and the upper surface of the side glass 125 is on the bottom of the retaining member 130. It is configured to maintain a sealed state between the flow rate confirmation hole 112 on the pipe side of the pipe 110 and the side glass 125 by the packing 140,
A reinforcing coupling step 152 provided on the outer peripheral surface of the glass support part 120 on one side of the pipe 110; A reinforcement retainer 160 arranged above the glass supporter 120 and configured in a closed loop ring shape with a reinforcement retaining side confirmation hole penetrating from the top and bottom on the inside. A reinforcement retaining side glass coupling groove 162 provided on the inner peripheral surface of the reinforcement retainer 160; A reinforced side glass (170) whose peripheral portion is inserted and coupled to the reinforced retaining side glass coupling groove (162); A reinforcing coupling bridge piece (182) extending in a direction perpendicular to the bottom surface of the reinforcing retainer (160); a reinforcing coupling support ledge (184) connected to the reinforcing coupling bridge piece (182) and extending in a direction parallel to the bottom of the reinforcing retainer (160); Groove reinforcement coupling support piece receiving (186) formed between the upper surface of the reinforcement coupling support ledge (184) and the bottom surface of the reinforcement retainer (160); At least two or more reinforcements that are coupled to the groove reinforcement coupling support piece accommodation 186 and advance toward the center of the reinforcement retaining side confirmation hole of the reinforcement retainer 160 or move backward in a direction away from the center of the reinforcement retaining side confirmation hole. Combined support piece (192); A reinforcing hook piece 194 provided on the reinforcing coupling support piece 192 and hooked to the bottom of the reinforcing coupling step 152; A site glass structure for checking the pipe flow rate, further comprising: a reinforcing coupling support elastic body (202), both ends of which are connected to the outer surface of the groove reinforcing coupling support piece accommodation (186) and the reinforcing coupling support piece (192). delete delete

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