KR102699972B1 - Portable copper pipe lock ring compression hydraulic tool - Google Patents

Abstract

A portable hydraulic tool for crimping a copper pipe lock ring is disclosed. The portable hydraulic tool for crimping a copper pipe lock ring comprises: a cylinder including a piston movement section on one side thereof and a hydraulic oil inlet/outlet penetrating the piston movement section; a crimping piston installed in the cylinder so as to be movable along the longitudinal direction of the piston movement section; a tool connection member including a tool connection part having a hydraulic oil inlet/outlet therein and coupled to the cylinder such that the hydraulic oil inlet/outlet is communicated with the hydraulic oil inlet/outlet; a first crimping joint coupled to one end of the cylinder and having a first ring seating groove (410) at an upper end; and a second crimping joint coupled to the other end of the cylinder and connected to the crimping piston so as to move along the crimping piston and having a second ring seating groove at an upper end, characterized in that a hydraulic tool operable to discharge and recover hydraulic oil is connected to the tool connection part, so that hydraulic oil discharged from the hydraulic tool is injected into the piston movement section through the hydraulic oil inlet/outlet and the hydraulic oil inlet/outlet, thereby causing the crimping piston to move backward.

Description

Portable copper pipe lock ring compression hydraulic tool

The present invention relates to a portable hydraulic tool for crimping a copper pipe lock ring, and more particularly, to a portable hydraulic tool for crimping a copper pipe lock ring used for connecting (fitting) pipe to pipe.

Welding is the common method for connecting pipes to pipes. However, when connecting pipes to pipes by welding, problems such as water or oil leakage at the welded joints of the pipes frequently occur.

As a means of resolving this, a socket is connected between pipes and a rock ring is pressed and connected on the socket to prevent water or oil leakage.

For example, the compressor compresses the refrigerant inside the refrigerator, absorbs heat, and sends the compressed refrigerant inside to cool it. If the compressor breaks down, the compressor needs to be replaced, and at this time, the pipes connected to the compressor and the pipes for refrigerant circulation need to be connected.

In such cases, when connecting pipes to pipes by welding, refrigerant gas may leak, and to prevent this, the pipes are connected using the socket and lock ring.

Tools used when connecting pipes using the above sockets and lock rings are disclosed in U.S. Patent Nos. 4,189,817 (“Hydraulic assembly tool for pipe joints”); 5,305,510 (“Hydraulic assembly tool having improved load bearing arrangement for pipe joints”); 5,694,670 (“Safe swaging tool”); 6,434,808 (“Compact installation tool”); and 6,618,919 (“Remote operation of installation tool pump”).

However, the limited mobility of the above tools due to the necessity of connecting the hydraulic supply unit and the hose and the relative immobility of the hydraulic supply unit are some of the disadvantages of this type of installation tools. Furthermore, conventional installation tools are sometimes bulky or heavy, making them difficult to use remotely or in confined spaces.

Therefore, the problem to be solved by the present invention is to provide a portable hydraulic tool for crimping a copper pipe lock ring, which can easily crimp a lock ring, is easy to connect to a hydraulic tool, and is manufactured in a compact cylinder shape so that it can be carried around and used immediately on site.

According to one embodiment of the present invention, a portable hydraulic compression tool for a pipe lock ring comprises: a cylinder including a piston movement section on one side thereof and a hydraulic oil inlet/outlet penetrating the piston movement section; a compression piston installed in the cylinder so as to be movable along the longitudinal direction of the piston movement section; a tool connection member including a tool connection part having a hydraulic oil inlet/outlet therein and coupled to the cylinder such that the hydraulic oil inlet/outlet is in communication with the hydraulic oil inlet/outlet; a first compression joint coupled to one end of the cylinder and having a first ring seating groove (410) at an upper end; and a second compression joint coupled to the other end of the cylinder and connected to the compression piston so as to move along the compression piston and having a second ring seating groove at an upper end, characterized in that a hydraulic tool operable to discharge and recover hydraulic oil is connected to the tool connection part, so that hydraulic oil discharged from the hydraulic tool is injected into the piston movement section through the hydraulic oil inlet/outlet and the hydraulic oil inlet/outlet, thereby causing the compression piston to move backward.

In one embodiment, the compression piston may be configured to automatically return when hydraulic fluid introduced into the piston travel section is returned to the hydraulic tool.

In one embodiment, the cylinder further includes a piston engaging hole extending coaxially with the piston moving section in front of the piston moving section and having a diameter smaller than the piston moving section, the compression piston includes a body portion having a columnar shape with a diameter corresponding to the piston engaging hole and inserted into the piston engaging hole; and a valve portion formed at the rear end of the body portion with a diameter corresponding to the diameter of the piston moving section and accommodated in the piston moving section, and the hydraulic oil inlet/outlet can penetrate toward the boundary between the piston engaging hole and the piston moving section.

In one embodiment, the cylinder further includes a pin guide hole extending a predetermined length along the length of the cylinder and penetrating from an outer surface of the cylinder toward the center of the cylinder so as to be positioned opposite the piston travel range, the piston engaging hole communicates with the pin guide hole, and a body portion of a compression piston inserted into the piston engaging hole is exposed to the pin guide hole, and a second compression joint can be engaged with the compression piston by a joint connecting pin inserted into the pin guide hole and penetrating an end of the body portion.

In one embodiment, the tool connecting member includes a coupling ring portion coupled to the cylinder so as to surround an outer surface of the cylinder, the tool connecting member is formed to protrude cylindrically from the coupling ring portion, and the hydraulic oil injection port can penetrate from the inner center of the tool connecting member into the inner surface of the coupling ring portion.

In one embodiment, the compression piston may further include a spring receiving hole extending from the center of the valve portion toward the distal end of the body portion; and a return spring inserted into the spring receiving hole and supported by a spring holder that seals the piston movement section to return the compression piston.

In one embodiment, the first ring mounting groove and the second ring mounting groove may include a ring mounting portion and a pipe mounting portion having a smaller diameter than the ring mounting portion.

In one embodiment, the cylinder further includes a flange portion that is formed in a ring shape protruding on the outer surface of the cylinder so as to be positioned at the rear of the pin guide hole; and an annular groove formed spaced apart from the flange portion at a distance corresponding to the axial length of the coupling ring portion, and the coupling ring portion may further include a fixing ring that is fitted into the cylinder so as to be in close contact with the flange portion and is coupled to the annular groove to fix the coupling ring portion.

In one embodiment, the retaining ring can be either a C-ring or an E-ring.

In one embodiment, the first compression joint can be secured to the outer surface of the cylinder via a bolt connection.

According to a portable hydraulic tool for crimping a pipe lock ring according to one embodiment of the present invention, a lock ring used when crimping and connecting pipes that need to be joined to each other can be easily crimped, the hydraulic tool can be easily connected, and since it is manufactured in a compact cylinder shape, it has the advantage of being portable and ready for immediate use on site.

FIGS. 1 and 2 are cross-sectional views illustrating the configuration of a portable hydraulic pipe lock ring pressing tool according to one embodiment of the present invention.
FIG. 3 is a side view of a portable hydraulic pipe lock ring crimping tool according to one embodiment of the present invention.
Fig. 4 is a drawing showing a hydraulic tool connected to the tool connecting member illustrated in Fig. 1.
Figure 5 is a cross-sectional view showing a socket and a pair of lock rings used for connecting a pipe to a pipe.
FIGS. 6 to 9 are drawings for explaining a process of pressing and joining a pair of lock rings using a portable hydraulic lock ring pressing tool according to one embodiment of the present invention.

Hereinafter, a portable hydraulic tool for crimping a copper pipe lock ring according to an embodiment of the present invention will be described in detail with reference to the attached drawings. The present invention may have various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, but should be understood to include all modifications, equivalents, and substitutes included in the spirit and technical scope of the present invention. In describing each drawing, similar reference numerals are used for similar components. In the attached drawings, the dimensions of structures are illustrated larger than actual dimensions in order to ensure clarity of the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component.

The terminology used in this application is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly indicates otherwise. In this application, it should be understood that the terms "comprises" or "has" and the like are intended to specify the presence of a feature, number, step, operation, component, part, or combination thereof described in the specification, but do not exclude in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms defined in commonly used dictionaries, such as those defined in common dictionaries, should be interpreted as having a meaning consistent with the meaning they have in the context of the relevant art, and shall not be interpreted in an idealized or overly formal sense, unless expressly defined in this application.

FIG. 1 and FIG. 2 are cross-sectional views illustrating the configuration of a portable hydraulic tool for crimping a copper pipe lock ring according to one embodiment of the present invention, FIG. 3 is a side view of a portable hydraulic tool for crimping a copper pipe lock ring according to one embodiment of the present invention, and FIG. 4 is a drawing showing a state in which a hydraulic tool is connected to a tool connecting member illustrated in FIG. 1.

Referring to FIGS. 1 to 3, a portable hydraulic compression tool for a pipe lock ring according to one embodiment of the present invention may include a cylinder (100), a compression piston (200), a tool connecting member (300), a first compression joint (400), and a second compression joint (500).

The cylinder (100) may include a piston movement section (110), a piston coupling hole (120), a pin guide hole (130), and a hydraulic oil inlet/outlet (140). For example, the cylinder (100) may have a cylindrical structure.

The piston movement section (110) may be formed on one side of the inside of the cylinder (100). That is, the piston movement section (110) may be formed in a hollow shape coaxially with the center of the cylinder (100) and may be formed on one side of the cylinder (100) by extending along the longitudinal direction of the cylinder (100).

The piston coupling hole (120) extends coaxially with the piston movement section (110) and communicates with it in front of the piston movement section (110), and can be formed to have a smaller diameter than the piston movement section (110).

The pin guide hole (130) may be formed from the outer surface of the cylinder (100) toward the center of the cylinder (100) so as to be located on the opposite side of the piston movement section (110), and may extend a certain length along the longitudinal direction of the cylinder (100). At this time, the length of the pin guide hole (130) may be formed shorter than the length of the piston coupling hole (120), and may be communicated with the piston coupling hole (120).

The hydraulic oil inlet/outlet (140) may be passed through the piston movement section (110). Specifically, the hydraulic oil inlet/outlet (140) may be passed through toward the boundary between the piston coupling hole (120) and the piston movement section (110).

The compression piston (200) may be installed in the cylinder (100) so as to be movable along the longitudinal direction of the piston travel section (110). In one embodiment, the compression piston (200) may include a body portion (210) and a valve portion (220).

The body part (210) has a columnar shape with a diameter corresponding to the piston coupling hole (120) and can be inserted into the piston coupling hole (120). At this time, the body part (210) can be exposed to the pin guide hole (130).

The valve part (220) is formed at the rear end of the body part (210) with a diameter corresponding to the diameter of the piston movement section (110), and can be accommodated in the piston movement section (110) when the body part (210) is inserted into the piston coupling hole (120).

Additionally, the compression piston (200) may further include a spring receiving hole (230) and a return spring (240).

The spring receiving hole (230) may extend a certain length from the center of the valve portion (220) toward the end of the body portion (210). At this time, the spring receiving hole (230) may extend to a length that does not penetrate the end of the valve portion (220).

The return spring (240) is inserted into the spring receiving hole (230) and is supported by a spring holder (250) that seals the piston movement section (110), and when the compression piston (200) is moved backward by the pressure of pressing the valve part (220) by hydraulic fluid and the pressure is released, the compression piston (200) can be returned.

The tool connecting member (300) may include a tool connecting portion (310) having a hydraulic oil inlet (311) therein and a coupling ring portion (320), and may be connected to a cylinder (100) so that the hydraulic oil inlet (311) communicates with a hydraulic oil inlet (140).

The coupling ring part (320) may be formed in a circular ring structure and may be coupled to the cylinder (100) to surround the outer surface of the cylinder (100), and the tool connection part (310) may be formed to protrude cylindrically from the coupling ring part (320). When the coupling ring part (320) is coupled to the cylinder (100), the hydraulic oil inlet (311) may be coupled so as to communicate with the hydraulic oil inlet (140).

A hydraulic tool (10) that operates to discharge and recover hydraulic oil can be connected to the tool connection part (310). Here, there is no special limitation on the hydraulic tool (10) as long as it is a tool capable of automatically discharging and recovering hydraulic oil, and there is no special limitation as long as it is in a form in which a hydraulic oil discharge tip (11) that can be connected to the tool connection part (310) is combined.

The hydraulic oil injection port (311) can penetrate from the inner center of the tool connecting portion (310) to the inner surface of the coupling ring portion (320).

The tool connecting member (300) can be fixed to the outer surface of the cylinder (100). To this end, the cylinder (100) may further include a flange portion (150) and an annular groove (160), and the hydraulic tool may further include a fixing ring (600).

The flange portion (150) may be formed in a ring shape to protrude from the outer surface of the cylinder (100) so as to be positioned at the rear of the pin guide hole (130).

The annular groove (160) can be formed spaced apart from the flange portion (150) at an interval corresponding to the axial length of the coupling ring portion (320).

The fixed ring (600) can be coupled to the annular groove (160) to fix the coupling ring part (320). That is, the coupling ring part (320) can be coupled to the annular groove (160) to fix the coupling ring part (320) while being fitted into the cylinder (100) so as to be in close contact with the flange part (150). For example, the fixed ring (600) can be either a C ring or an E ring.

The first compression joint (400) is fixedly connected to one end of the cylinder (100), and a first ring mounting groove (410) may be provided at the top. For example, the first compression joint (400) may be fixed to the outer surface of the cylinder (100) through a bolt connection.

The second compression joint (500) is coupled to the other end of the cylinder (100), is connected to the compression piston (200) so as to move along the compression piston (200), and may have a second ring mounting groove (510) provided at the top.

In order for the second compression joint (500) to be connected to the compression piston (200), the second compression joint (500) can be connected to the compression piston (200) by a joint connecting pin (700) that is inserted into the pin guide hole (130) and penetrates the end of the body part (210).

Here, the first ring mounting groove (410) and the second ring mounting groove (510) of each of the first compression joint (400) and the second compression joint (500) may include a ring mounting portion (411, 511) and a pipe mounting portion (412, 512) having a smaller diameter than the ring mounting portions (411, 511). A lock ring that is coupled to surround the outer surface of the pipe may be mounted in the ring mounting portion (411, 511), and a pipe to which a lock ring is coupled may be mounted in the pipe mounting portion (412, 512).

According to one embodiment of the present invention, a portable hydraulic compression tool for a copper pipe lock ring is used to press-fix a lock ring at a joint portion of a copper pipe. That is, when joining a copper pipe to a copper pipe, a pipe-to-copper pipe joint can be achieved by using a pipe-shaped socket (20) having pipe insertion holes (21) on both sides as shown in FIG. 5 and a pair of lock rings (30) for pressing and fixing to the outer surface of the socket (20), and the pair of lock rings (30) can be pressed and fixed by the portable hydraulic compression tool for a copper pipe lock ring according to one embodiment of the present invention. FIG. 5 is a cross-sectional view showing a socket and a pair of lock rings used for connecting a copper pipe to a copper pipe.

Hereinafter, a process for connecting a copper pipe to a copper pipe by pressing and fixing a pair of lock rings (30) using a portable copper pipe lock ring pressing hydraulic tool according to one embodiment of the present invention will be described with reference to FIGS. 6 to 9. FIGS. 6 to 9 are drawings for explaining a process for pressing and connecting a pair of lock rings using a portable copper pipe lock ring pressing hydraulic tool according to one embodiment of the present invention.

First, insert the ends of the first copper pipe (41) and the second copper pipe (42) into the pipe insertion holes (21) on both sides of the socket (20). At this time, as shown in Fig. 6, one of the pair of lock rings (30) is arranged to surround the outer surface of the first copper pipe (41), and the other is arranged to surround the outer surface of the second copper pipe (42). For example, the first copper pipe (41) may be a pipe for a compressor of a refrigerator, and the second copper pipe (42) may be a pipe for circulating refrigerant.

Next, a pair of lock rings (30) are respectively seated in the first ring seating groove (410) of the first compression joint (400) and the second ring seating groove (510) of the second compression joint (500) as shown in Fig. 6. At this time, the lock ring (30) is seated in the ring seating portions (411, 511), and the first copper pipe (41) and the second copper pipe (42) are seated in the pipe seating portions (412, 512).

Next, the hydraulic tool (10) is connected to the tool connecting member (300) and the hydraulic tool (10) is operated to discharge hydraulic oil. The discharged hydraulic oil is injected into the piston movement section (110) through the hydraulic oil inlet (311) and the hydraulic oil inlet (140) of the tool connecting member (310) as shown in Fig. 7. At this time, the hydraulic oil is injected toward the boundary of the piston coupling hole (120) and the piston movement section (110) and supplied to the front of the valve section (220) of the compression piston (200).

Next, the hydraulic oil supplied to the piston movement section (110) fills the piston movement section (110) in front of the valve section (220), thereby applying pressure to the valve section (220), and accordingly, as shown in FIG. 8, the compression piston (200) is retracted away from the piston coupling hole (120), and the return spring (240) is contracted. In addition, the second compression joint (500) moves along the retracted compression piston (200), and the second compression joint (500) gradually gets closer to the first compression joint (400).

In this process, the second compression joint (500) pushes the lock ring (30) and socket (20) that are installed therein toward the first compression joint (400), and accordingly, as shown in FIG. 8, a pair of lock rings (30) pressurize the outer surface of the socket (20) while compressing the outer surface of the socket (20) to be fitted onto the socket (20), and the first copper pipe (41) and the second copper pipe (42) inserted into the pipe insertion holes (21) on both sides of the socket (20) are also compressed by the lock ring (30).

When a pair of lock rings (30) are fitted onto the socket (20) by compressing the socket (20), the first copper pipe (41) and the second copper pipe (42), and then the hydraulic tool (10) is operated to recover the hydraulic oil injected into the piston travel section (110), the pressure applied to the compression piston (200) is released as the hydraulic oil is recovered from the piston travel section (110) to the hydraulic tool (10), and at this time, as shown in FIG. 9, the return spring (240) is restored to allow the compression piston (200) to return to its initial position, so that the first compression joint (400) and the second compression joint (500) can be separated from the pair of lock rings (30).

According to one embodiment of the present invention, a portable hydraulic tool for crimping a lock ring used when crimping pipes that need to be joined together can easily crimp a lock ring (30), and since the hydraulic tool (10) is manufactured in a compact cylinder shape, it has the advantage of being portable and ready for immediate use on site.

Meanwhile, a corrosion-inhibiting layer on the metal surface may be formed on the surface of the body (210) and valve (220) of the compression piston (200) of the portable pipe lock ring compression hydraulic tool according to one embodiment of the present invention.

The coating material of this corrosion-inhibiting layer is composed of 26 wt% of propanolamine, 28 wt% of cholesterol, 12 wt% of hafnium, 11 wt% of organic acid magnesium, 8 wt% of titanium oxide (TiO ₂ ), 9 wt% of aluminum oxide (AIO ₂ ), and 6 wt% of a solvent, and the coating thickness can be formed at 7 μm.

Propanolamine and cholesterol play a role in corrosion inhibition, weather resistance, and discoloration prevention, and hafnium is a transition metal element with wear resistance and weather resistance, and plays a role in providing excellent waterproofing and corrosion resistance.

Organic magnesium acid plays a role in providing alkali resistance and wettability to the surface of the coating film, and titanium oxide and aluminum oxide are added for the purpose of fire resistance and chemical stability.

The reason why the ratio of the above components and the coating thickness are numerically limited as above is that the inventor analyzed the test results through repeated failures and found that the above ratio showed the optimal effect of improving weather resistance and wear resistance.

Meanwhile, a clean layer may be applied to the inner and outer surfaces of the cylinder (100) of the portable pipe lock ring compression hydraulic tool according to one embodiment of the present invention to prevent and remove contaminants from adhering thereto.

The composition of the above clean layer contains cocoamphocarboxy propionic acid and sodium oleate in a molar ratio of 1:0.01 to 1:2, and the total content of cocoamphocarboxy propionic acid and sodium oleate is 1 to 12 wt% with respect to the entire aqueous solution.

The molar ratio of the above cocoamphocarboxy propionic acid and sodium oleate is preferably 1:0.01 to 1:2. If the molar ratio is outside the above range, there is a problem that the coating property on the inner and outer surfaces of the cylinder (100) is reduced or the moisture absorption on the surface increases after coating, resulting in the removal of the coating film.

The above cocoamphocarboxy propionic acid and sodium oleate are preferably present in an amount of 1 to 12 wt% of the total aqueous composition. If the amount is less than 1 wt%, there is a problem that the coating properties on the inner and outer surfaces of the cylinder (100) are reduced, and if the amount exceeds 12 wt%, crystal precipitation is likely to occur due to an increase in the thickness of the coating film.

Meanwhile, as a method of applying the composition of the clean layer onto the inner and outer surfaces of the cylinder (100), it is preferable to apply it by a spray method. In addition, the final coating film thickness on the inner and outer surfaces of the cylinder (100) is preferably 700 to 2000 Å. If the thickness of the coating film is less than 700 Å, there is a problem of deterioration in the case of high-temperature heat treatment, and if it exceeds 2000 Å, there is a disadvantage of easy occurrence of crystal precipitation on the coating surface.

Additionally, the composition of the clean layer can be prepared by adding 0.1 mol of cocoamphocarboxy propionic acid and 0.05 mol of sodium oleate to 1000 ml of distilled water and then stirring.

The reason why the ratio of the above components and the thickness of the coating film are numerically limited as above is that the inventor of the present invention analyzed the test results through repeated failures and showed the optimal corrosion inhibition effect at the above ratio.

And, a packing is provided between the cylinder (100) and the compression piston (200) to maintain airtightness. The raw material content ratio of this packing is a mixture of 63 wt% of rubber, 12 wt% of tetramethylthiuram disulfide, 8 wt% of barium stearate, 9 wt% of carbon black, and 8 wt% of 3C (N-PHENYL-N'-ISOPROPYL- P-PHENYLENEDIAMINE).

Tetramethylthiuram disulfide is added to improve vulcanization acceleration, barium stearate is added as a softener, carbon black is added to increase or improve wear resistance, thermal conductivity, etc., and 3C (N-PHENYL-N'-ISOPROPYL- P-PHENYLENEDIAMINE) is added as an antioxidant.

Accordingly, the elasticity, toughness, rigidity, etc. of the packing are increased, so durability, weather resistance, etc. are improved, and accordingly, the lifespan of the packing is increased.

The rubber material is formed with a hardness (Shore A) of 63, a tensile strength of 150 kg/cm2, and an elongation of 640%.

The reason for limiting the rubber material composition and components and limiting the numerical mixing ratio, etc. is that the inventor analyzed the test results through repeated failures and found that the optimal effect was achieved at the limited ratio of the components and numerical values.

The description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the invention is not intended to be limited to the disclosed embodiments, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

100 : Cylinder 200 : Compression Piston
300: Tool connecting member 400: First compression joint
500 : 2nd compression joint

Claims (10)

A cylinder (100) including a piston movement section (110) on one side thereof and a hydraulic oil inlet/outlet (140) penetrating the piston movement section (110);
A compression piston (200) installed in a cylinder (100) so as to be movable along the longitudinal direction of the piston movement section (110);
A tool connecting member (300) including a tool connecting member (310) having a hydraulic oil inlet (311) therein and coupled to a cylinder (100) such that the hydraulic oil inlet (311) communicates with the hydraulic oil inlet (140);
A first compression joint (400) coupled to one end of a cylinder (100) and having a first ring mounting groove (410) at the top; and
It is connected to the other end of the cylinder (100), is connected to the compression piston (200) so as to move along the compression piston (200), and includes a second compression joint (500) having a second ring mounting groove (510) at the top.
A hydraulic tool (10) that operates to discharge and recover hydraulic oil is connected to a tool connection part (310), and hydraulic oil discharged from the hydraulic tool (10) is injected into the piston movement section (110) through the hydraulic oil inlet (311) and the hydraulic oil inlet (140), so that the compression piston (200) moves backward;
The cylinder (100) further includes a pin guide hole (130) that extends a certain length along the length of the cylinder (100) and penetrates from the outer surface of the cylinder (100) toward the center of the cylinder (100) so as to be located opposite the piston movement section (110).
The cylinder (100) further includes a piston engaging hole (120) that extends coaxially with the piston moving section (110) in front of the piston moving section (110) and has a diameter smaller than that of the piston moving section (110).
The piston coupling hole (120) communicates with the pin guide hole (130), and the body part (210) of the compression piston (200) inserted into the piston coupling hole (120) is exposed to the pin guide hole (130).
The second compression joint (500) is connected to the compression piston (200) by a joint connecting pin (700) that is inserted into the pin guide hole (130) and penetrates the end of the body (210) of the compression piston (200).
Portable hydraulic plumbing lock ring crimping tool.
In the first paragraph,
The compression piston (200) is configured to automatically return when the hydraulic oil flowing into the piston movement section (110) is recovered to the hydraulic tool (10).
Portable hydraulic plumbing lock ring crimping tool. In the second paragraph,
The compression piston (200) is
A body part (210) having a columnar shape with a diameter corresponding to the piston coupling hole (120) and inserted into the piston coupling hole (120); and
It is formed at the rear end of the body part (210) with a diameter corresponding to the diameter of the piston movement section (110) and includes a valve part (220) accommodated in the piston movement section (110).
The hydraulic oil inlet (140) penetrates toward the boundary of the piston coupling hole (120) and the piston movement section (110).
Portable hydraulic plumbing lock ring crimping tool. delete In the first paragraph,
The tool connecting member (300) includes a connecting ring portion (320) that is connected to the cylinder (100) to surround the outer surface of the cylinder (100).
The tool connection part (310) is formed to protrude in a cylindrical shape from the coupling ring part (320).
The hydraulic oil injection port (311) penetrates from the inner center of the tool connection part (310) to the inner surface of the coupling ring part (320).
Portable hydraulic plumbing lock ring crimping tool. In paragraph 5,
The compression piston (200) is
A spring receiving hole (230) extending from the center of the valve part (220) toward the end of the body part (210); and
It further includes a return spring (240) that is inserted into the spring receiving hole (230) and supported by a spring holder (250) that seals the piston movement section (110) to return the compression piston (200).
Portable hydraulic plumbing lock ring crimping tool. In Article 6,
The first ring mounting groove (410) and the second ring mounting groove (510) include a ring mounting portion (411, 511) and a pipe mounting portion (412, 512) having a smaller diameter than the ring mounting portions (411, 511).
Portable hydraulic plumbing lock ring crimping tool. In Article 7,
The cylinder (100) is
A flange portion (150) formed in a ring shape protruding on the outer surface of the cylinder (100) to be positioned at the rear of the pin guide hole (130); and
It further includes an annular groove (160) formed spaced apart from the flange portion (150) at an interval corresponding to the axial length of the coupling portion (320).
The coupling ring part (320) is fitted into the cylinder (100) so as to be in close contact with the flange part (150),
It further includes a fixing ring (600) that is coupled to the annular groove (160) and fixes the coupling ring part (320).
Portable hydraulic plumbing lock ring crimping tool. In Article 8,
The fixed ring (600) is either a C ring or an E ring.
Portable hydraulic plumbing lock ring crimping tool. In Article 9,
The first compression joint (400) is fixed to the outer surface of the cylinder (100) through a bolt connection.
Portable hydraulic plumbing lock ring crimping tool.