JP7028461B2 - High-performance protective cap for insulation pipe - Google Patents

Description

Technology for high-performance protective caps for insulation pipes

The present invention relates to a protective cap for a heat insulating pipe that covers the surface of the heat insulating pipe and serves to prevent the heat insulating pipe from shrinking between joints of the heat insulating pipe connected together.

Insulated pipes cover main pipes, including gas pipes used in industrial applications and cooling systems. The main pipe consists of a heat insulating pipe characterized by a connecting piece of a pipe network that covers the main pipe in the longitudinal direction.

Therefore, direct or bent joints may be provided between some of the insulation pipes. There is concern that these joints will lead to gas leaks, causing heat exchange between the gas and liquid in the pipe, and the atmosphere will accelerate the combustion process. Also, the joints can separate from each other and contract, causing gas leaks.

To protect and increase efficiency of insulation pipes, insulation caps for insulation pipes are usually made of steel or stainless steel to prevent heat exchange between the gas and liquid in the pipe and the atmosphere to accelerate the combustion process. Not only does it prevent the bending joint from separating and shrinking.

Protective caps for this type of insulation pipe may be subject to compliance with the regulations of some countries such as Japan.

According to the requested patent number JP4015-113869A, this patent reveals a protective cap for insulation tubes with several teeth on one side of the first belt. These teeth engage the locking groove on the other side of the second belt. This mechanism allows the protective cap to be fitted to the insulation tube in the same way that the belt is tightened. Nevertheless, it has the disadvantage that it is difficult to reposition the joint because it is difficult to lower and advance just a few teeth into the locking groove of the other belt and hook them. Further, in order to perform the engagement firmly and easily, it is inconvenient because the axes of the first belt and the second belt must be aligned. Moreover, it will be difficult to separate the protective cap and the insulation tube from each other after connection. Although this structure is strong, it is not easy to rearrange and tighten the joints.

The protective cap for a high-performance heat insulating tube of the present invention allows a second unit having a first set of serrated bars, which are through holes, to be inserted into a locking groove located in a second panel of the third unit. be able to. The second set of teeth consists of a metal plate placed perpendicular to the second panel in the third unit and engages with the first set of serrated bars of the second unit. It forms a locking mechanism similar to the tightening of a belt. The additional second set of teeth consists of a metal plate placed perpendicular to the second panel in the third unit, from the short edge of the second unit through the through hole of the second unit. Engage with a first set of serrated bars. The joint is further tightened in the same way as the belt is tightened. As a result, when the insulation pipe is placed in a difficult place to install, such as outside a building or in a small area, the slide allows for strong and easy installation and adjustment of the tightening level.

The protective cap for a heat insulating tube has the following features.

The first unit is a set of flats that are formed along the outer edge, in particular the outer edge of a particular metal sheet, especially the rectangular portion, and are joined together using a folding method to form a continuous structure of the first unit. It features a metal sheet. At least one piece of metal sheet is joined together. Specifically, five sheets are supplied.

Several metal sheets are joined together along a first longitudinal edge to form a C-shaped curve that covers the insulation tube. The first unit forms a curved shape to support the insulation tube covering in the curved joint region.

The metal sheets may be similar or different in size.

The second unit is a set formed along the outer edge, in particular the portion where the length from the first longitudinal edge of the second unit to the first minor edge of the second unit is reduced. It features a flat metal sheet. The first longitudinal edge of the second unit is connected on the other side to the first minor edge of the first unit by a folding method similar to the can folding procedure. In particular, the second unit is available as a single sheet.

The third unit is a set of flats formed along the outer edge, in particular the portion where the length is reduced from the first longitudinal edge of the third unit to the first minor edge of the third unit. It features a metal sheet. The first longitudinal edge of the third unit is connected to the second minor edge of the first unit on the second side by a folding method similar to the can folding procedure. In particular, the third unit is available as a single sheet.

The second unit and the third unit may be similar or different in size. Also, the second unit and the third unit are in opposite positions.

The second unit and the third unit form a C-shaped curve covering the heat insulating tube by connecting the first longitudinal edge of the second unit and the first longitudinal edge of the third unit. .. Engagement forms a curved shape that supports the connection between the first short edge of the first unit and the second edge of the first unit.

A set of serrated bars, which are tooth-shaped through holes, are provided at the position of the second unit, particularly adjacent to the first short edge of the second unit. The tips of the first set of serrated bars face upwards directly opposite the second unit. The first set of serrated bars is formed on the surface of the second unit on the outside of the first panel.

The first set of serrated bars form a linear axis extending from the first short edge of the second unit to the first longitudinal edge of the second unit. The first set of serrated bars is a straight line parallel to the first short edge of the second unit.

A locking groove for engaging with the first set of serrated bars of the second unit is provided at the position of the third unit, particularly adjacent to the first short edge of the third unit. Be done.

The locking groove is formed by a metal portion folded into a C-shaped locking groove on one side and a metal portion folded into a C-shaped locking groove on the other side, and is formed in the third unit. By being located on the second panel of the metal, a second unit with a first set of serrated bars can be properly inserted into the locking groove to form a strong engagement.

The locking groove is a metal portion folded into a C-shaped locking groove on one side and a C-shaped locking groove on the other side at a lower position connecting to the second panel located in the third unit. Formed by a metal part folded in a shape, it is perpendicular to the second panel in the third unit between the C-shaped locking groove on the first side and the C-shaped locking groove on the second side. It has a second set of teeth, which is a metal plate installed in. The tip of the serrated bar faces upward in direct opposition to the third unit. The second set of teeth is hooked and engaged with the first set of serrated bars of the second unit.

A second set of teeth in at least one row is provided from the first short edge of the third unit. The second set of teeth is formed parallel to the first short edge of the third unit.

Protective caps are used to cover the insulation tube around the joint area. These direct or bent joints between some insulating pipes can lead to gas leaks, causing heat exchange between gas and liquid in the pipes, and the atmosphere can accelerate the combustion process. Also, the joints can separate from each other and contract, causing gas leaks. To avoid these problems, protective caps for insulation tubes are used.

The first unit, the second unit and the third unit are inserted into the heat insulating pipe. The second unit has a first set of serrated bars that are through holes and is inserted into the locking groove of the third unit located in the second panel within the third unit.

The second set of teeth consists of a metal plate installed perpendicular to the second panel in the third unit and engages with the first set of serrated bars, which are through holes in the second unit. Together, it forms a locking mechanism similar to the tightening of the belt.

The second set of teeth consists of a metal plate installed perpendicular to the second panel in the third unit and engages with the first set of serrated bars, which are through holes in the second unit. It fits.

The closer the second set of teeth is to the first unit, the tighter the engagement, similar to the tightening of the belt. As a result, when the insulation pipe is placed in a difficult place to install, such as outside a building or in a small area, the slide allows for strong and easy installation and adjustment of the tightening level.

It is an object of the present invention to provide a high performance protective cap for insulation pipes that improves fitting as well as belt tightening and provides strong and easy installation and adjustment of tightening level by sliding. The second set of teeth can be engaged with the first set of serrated bars by inserting them into the locking groove by sliding. This is convenient when the insulation pipe is placed in a difficult place to install, such as outside a building or in a small area.

FIG. 1 shows a component of a high performance protective cap for a heat insulating tube consisting of:

The first unit (10) features a set of flat metal sheets formed according to an outer edge, in particular a rectangular portion. The first longitudinal edges (11A) of a set of metal sheets are joined together by a folding method similar to the can folding procedure to form a continuous structure of the first unit (10). At least one piece of metal sheet is connected together, specifically five sheets are supplied.

FIG. 2 is coupled together along a first longitudinal edge (11A) to form a C-shaped curve on the first side (AA) to cover and protect the insulation tube (40) (FIGS. 7-). 8) Shows some metal sheets. The first unit (10) forms a curved shape to support the covering of the insulation tube (40) at the curved joint region.

The metal sheets may be similar or different in size.

The second unit (20) has a length from the outer edge, in particular the first longitudinal edge (11B) of the second unit (20) to the first minor edge (21A) of the second unit (20). It features a set of flat metal sheets that are formed along the portion where is reduced. The first longitudinal edge (11B) of the second unit (20) is the first short edge of the first unit (10) on the first side (B1) by a folding method similar to the can folding procedure. It is connected with (21). In particular, the second unit (20) is available as a single sheet.

FIG. 3 shows a portion where the length is reduced from the outer edge, particularly the first longitudinal edge (11C) of the third unit (30) to the first minor edge (21B) of the third unit (30). 3 shows a third unit (30) characterized by a set of flat metal sheets molded along. The first longitudinal edge (11C) of the third unit (30) is the second short edge of the first unit (10) on the second side (B2) by a folding method similar to the can folding procedure. It is connected with (22). In particular, the third unit (30) is available as a single sheet.

FIG. 4 (see FIGS. 2-3) shows a second unit (20) and a third unit (30) that are similar or different in size. Further, the second unit (20) and the third unit (30) are in opposite positions.

The second unit (20) and the third unit (30) are the first longitudinal edge (11B) of the second unit (20) and the first longitudinal edge (11C) of the third unit (30). By connecting and, a C-shaped curve (B) is formed (see FIGS. 2 to 3), which covers the heat insulating pipe (40) (see FIGS. 7 to 8). The engagement forms a curved shape to support the connection between the first short edge (21) of the first unit (10) and the second edge (22) of the first unit (10).

As shown in FIGS. 5 and 6, the tooth shape penetrates at the position of the second unit (20), particularly at the position adjacent to the first short edge (21A) of the second unit (20). A first set of serrated bars (31), which are holes, is provided. The tip of the serrated bar of the first set faces upward directly facing the second unit (20). The first set of serrated bars (31) is formed on the surface of the second unit (20) outside the first panel (41).

The first set of serrated bars (31) is a straight line extending from the first short edge (21A) of the second unit (20) to the first longitudinal edge (11B) of the second unit (20). Form a shaft. The first set of serrated bars (31) is a straight line parallel to the first short edge (21A) of the second unit (20).

The position of the third unit (30), particularly the position adjacent to the first short edge (21B) of the third unit (30), is the sawtooth of the first set of the second unit (20). A locking groove (50) that engages with the shaped bar (31) is provided.

The locking groove (50) includes a metal portion folded into a C-shaped locking groove on the first side (51) and a metal portion folded into a C-shaped locking groove on the second side (52). The second unit (20), which is formed by and is located in the second panel (42) within the third unit (30) and has a first set of serrated bars (31), is rigid. It can be inserted into a locking groove (50) suitable for forming an engagement.

The locking groove (50) was folded into a C-shaped locking groove on the first side (51) at a lower position connecting to the second panel (42) located in the third unit (30). Formed by a metal portion and a metal portion folded into a C-shaped locking groove on the second side (52), the C-shaped locking groove on the first side (51) and the second side (52). Between the C-shaped locking grooves, there is a second set of teeth (32), which is a metal plate installed perpendicular to the second panel (42) in the third unit (30). The tip of the serrated bar faces upward directly facing the third unit (30). The second set of teeth (32) is hooked and engaged with the first set of serrated bars (31) of the second unit (20).

A second set of teeth (32) in at least one row is provided from the first short edge (21B) of the third unit (30). The second set of teeth (32) is formed parallel to the first short edge (21B) of the third unit (30).

7 and 8 show protective caps used to cover the insulation tube (40) around the joint area. These direct or bent joints between some insulated can pipes (40) can lead to gas leaks, causing heat exchange between gas and liquid in the pipe, and the atmosphere can accelerate the combustion process. .. Also, the joints can separate from each other and contract, causing gas leaks. To protect the insulation tube (40), a protective cap for the insulation tube (60) is used.

The first unit (10), the second unit (20), and the third unit (30) are inserted into the heat insulating tube (40). A second unit (20) having a first set of serrated bars (31) that are through holes is located in a second panel (42) within the third unit (30). It is inserted into the locking groove (50) of 30).

(See FIGS. 6 and 7) The second set of teeth (32) consists of a metal plate installed perpendicular to the second panel (42) in the third unit (30). It engages with a first set of serrated bars (31), which are through holes of the unit (20) of 2, to form a locking mechanism similar to belt tightening.

The closer the second set of teeth (32) is to the first unit (10), the tighter the engagement, similar to the tightening of the belt. As a result, when the insulation pipe (40) is placed in a place where installation is difficult, such as outside a building or in a narrow area, the slide enables strong and easy installation and adjustment of the tightening level.

It is a figure which shows the component of the high-performance protective cap for a heat insulating tube by this invention. It is a figure which shows the component of the high-performance protective cap for a heat insulating tube by this invention (top view). It is a figure which shows the component of the high-performance protective cap for a heat insulating tube by this invention (bottom view). It is a figure which shows the component of the high-performance protective cap for a heat insulating tube by this invention (rear view). It is a figure which shows the component of the high-performance protective cap for a heat insulating tube by this invention (side view). It is a figure which shows the component of the high-performance protective cap for a heat insulating tube similar to FIG. 4 by this invention (rear view). It is a figure which shows the function of the high-performance protective cap for a heat insulating tube by this invention (top view). It is a figure which shows the function of the high-performance protective cap for a heat insulating tube by this invention (bottom view). Best Method of Invention Described in the above [Mode for Carrying Out the Invention].

Claims (8)

A high-performance protective cap for heat insulating tubes with the following features:
The first unit (10) features a set of flat metal sheets formed according to an outer edge, in particular a rectangular portion. The first longitudinal edges (11A) of a set of metal sheets are joined together by a folding method similar to the can folding procedure to form a continuous structure of the first unit (10). At least one piece of metal sheet is connected together, specifically five sheets are supplied.
Several metal sheets are joined together along the first longitudinal edge (11A) to form a C-shaped curve on the first side (AA) to cover and protect the insulation tube (40). (See FIGS. 7-8). The first unit (10) forms a curved shape to cover and protect the insulation tube (40) at the curved joint region.
The second unit (20) has an outer edge, particularly from the first longitudinal edge (11B) of the second unit (20) to the first short edge (21A) of the second unit (20). It features a flat metal sheet formed along a portion where the length is reduced. The first longitudinal edge (11B) of the second unit (20) is the first unit (10) on the side (B1) of the second unit (20) by a folding method similar to the can folding procedure. ) Is connected to the first short edge (21).
The second unit (20) is available as a single sheet.
The third unit (30) has an outer edge, particularly from the first longitudinal edge (11C) of the third unit (30) to the first short edge (21B) of the third unit (30). It features a flat metal sheet formed along a portion where the length is reduced. The first longitudinal edge (11C) of the third unit (30) is on the side (B2) of the third unit (30) by a folding method similar to a can folding procedure. ) Is connected to the second short edge (22), and in particular, the third unit (30) is available as one sheet.
Further , the second unit (20) and the third unit (30) are located at opposite positions.
The second unit (20) and the third unit (30) are the first longitudinal edge (11B) of the second unit (20) and the first of the third unit (30). By connecting with the longitudinal edge (11C) of the above, a C-shaped curve covering the heat insulating pipe (40) is formed on the second side (BB). A curved shape is formed by engagement with the first short edge (21) of the first unit (10) and the second short edge (22) of the first unit (10). Support the connection.
As a special feature,
A first set of tooth-shaped through holes at the position of the second unit (20), in particular at a position adjacent to the first short edge (21A) of the second unit (20). A serrated bar (31) is provided. The tips of the first set of serrated bars face upward directly with the second unit (20). The first set of serrated bars (31) is formed on the surface of the second unit (20) outside the first panel (41).
A locking groove (20) into which the second unit (20) is inserted is located at the position of the third unit (30), particularly at a position adjacent to the first short edge (21B) of the third unit (30). 50) is provided.
The first unit (10), the second unit (20), and the third unit (30) are inserted into the heat insulating tube (40). The second unit having the first set of serrated bars (31) which is a through hole is located in the second panel (42) in the third unit (30). It is inserted into the locking groove (50) of (30). The second set of teeth (32) is made of a metal plate installed perpendicular to the second panel (42) in the third unit (30), and is of the second unit (20). Engage with the first set of serrated bars (31), which are through holes, to form a locking mechanism similar to belt tightening. By a folding method similar to the can folding procedure, the first longitudinal edge (11B) of the second unit (20) is on the side (B1) of the second unit (20). Connected to the first short edge (21) of (10),
At the first longitudinal edge (11A) of some metal sheets, the first unit (10) is interconnected by a folding method similar to a can folding procedure.
The high-performance protective cap for a heat insulating tube according to claim 1. The first longitudinal edge (11C) of the third unit (30) is on the side (B2) of the third unit (30) by a folding method similar to the can folding procedure. The high-performance protective cap for a heat insulating tube according to claim 1 or 2, which is connected to the second short edge (22) of (10). Any one of claims 1 to 3 , wherein the first set of serrated bars (31) is a straight line parallel to the first short edge (21A) of the second unit (20). High-performance protective cap for insulation pipes as described in. The locking groove (50) has a metal portion folded into a C-shaped locking groove on the first side (51) and a metal portion folded into a C-shaped locking groove on the second side (52). The high performance protective cap for a heat insulating tube according to any one of claims 1 to 4 , which is formed by the third unit (30) and is located in the second panel (42). The locking groove (50) is of suitable size so that the second unit (20) with the first set of serrated bars (31) can be suitably inserted into the locking groove (50). The high-performance protective cap for a heat insulating tube according to any one of claims 1 to 5 , which has the above and forms a strong engagement. A metal folded into a C-shaped locking groove on the first side (51) at a lower position where the locking groove connects to the second panel (42) located in the third unit (30). 1 High-performance protective cap for heat insulating pipe according to any one of 6 to 6 . The second set of teeth (32) is located between the C-shaped locking groove in which the first side (51) is folded and the C-shaped locking groove in which the second side (52) is folded. It is a metal plate installed perpendicularly to the second panel (42) in the unit (30), and the tip of the serrated bar directly faces the third unit (30). 1 to 7 , wherein the second set of teeth (32) is formed in parallel with the first short edge (21B) of the third unit (30). High-performance protective cap for heat insulating pipe as described in item 1.

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