RU169837U1 - FITTING DESIGN FOR GAS SUPPLY - Google Patents

Abstract

A fitting design for gas supply is proposed, made with the possibility of connecting between an air supply pipe made in the form of a hose or a plastic pipe, and an air compressor air outlet and containing a fitting and a heat-insulating pipe. The fitting comprises a first connecting hole configured to connect to an air exhaust opening of the air compressor, and a second connecting hole configured to connect to the air supply pipe. The heat-insulating tube has a first end portion fixed inside the second connecting hole of the fitting and a second end portion protruding outward from the second connecting hole, so that the heat-insulating tube portion protruding outward from the second connecting hole is adapted to be placed in the inner part of the air supply pipe. The high temperature air from the air compressor is passed through a heat-insulating tube into the air supply pipe without directly affecting the fitting.

Description

FIELD OF TECHNOLOGY

This utility model relates generally to a fitting instruction for supplying gas and, more particularly, to a fitting design that is used with a hose or a plastic pipe of an air compressor for supplying air, in which the fitting connected to an air outlet of the air compressor is further equipped with an attached a heat-insulating tube to it, so that the increased length and heat resistance of the heat-insulating tube allow you to direct the air (high-temperature gas) produced and supplied an air compressor directly through the heat insulation pipe to the interior of the air supply tube.

BACKGROUND

The main function of the air compressor is based on the operation of the electric motor, which drives the compressor in such a way that the internal crankshaft is rotationally driven to drive a connecting rod, which causes the piston to reciprocate up and down, thereby causing a change in the internal volume of the cylinder and compressing it way, air.

As shown in FIG. 1, a traditional air compressor described in Taiwan Utility Model No. M458495 is provided with an air supply pipe, which is usually a hose or plastic pipe connected to an air compressor air outlet through a fitting A installed therebetween. Fitting A has an end forming a first connecting tip A1, made with the possibility of connection with the air outlet of the air compressor. The fitting A has an opposite end, forming a second connecting tip A2, configured to be connected to the air supply pipe B, so that the air supplied from the air compressor passes through the air supply pipe B to an external device or machine. However, the traditional fitting A of the air compressor is designed so that its second connecting tip A2 directly fits into the air supply pipe B and thus is connected to it, so that when exposed to high-temperature air generated and supplied by the air compressor, the second connecting tip A2 is exposed prolonged exposure to high temperature air and undergoes multiple temperature expansions and contraction, which ultimately leads to undesirable expansion and, accordingly etstvenno, air leakage and loosening of the joint, so that the stability of the connection between the fitting and the tube A in air deteriorates. In addition, the fitting connection between the air supply pipe B and the second connecting tip A2 can undergo accelerated aging due to prolonged exposure to high temperature, and ultimately harden (become brittle), thereby affecting the operational life of the air supply pipe B.

DISCLOSURE OF A USEFUL MODEL

The fitting design for supplying gas in accordance with this utility model includes a fitting and a heat insulation tube. The fitting has an end forming a first connecting hole for connecting to an air compressor air outlet. The fitting has an opposite end forming a second connecting hole for connection to an air supply pipe. The heat-insulating tube is made of heat-resistant material and has a length exceeding the length of the fitting. The first end portion of the heat-insulating tube is fixed inside the second connecting hole of the fitting. The second end portion of the heat-insulating tube protrudes outward and exits from the second connecting hole, so that a portion of the heat-insulating tube protruding outward from the second connecting hole can be placed in the inside of the air supply pipe.

The effectiveness of this utility model is that the insulating properties and the increased length of the heat-insulating tube helps to conduct the high-temperature air generated and supplied by the air compressor through the heat-insulating tube to the inside of the air supply pipe, so that the heat-insulating pipe can significantly reduce the temperature of high-temperature air and It also helps prevent direct exposure to high temperature on the joint between the fitin. gom and air supply pipe, thereby eliminating the problems associated with thermal expansion and contraction, rapid aging and leakage fitting.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic representation of a conventional fitting for venting the air of an air compressor in operational condition.

FIG. 2 is a perspective view showing a fitting instruction according to the present utility model.

FIG. 3 is a sectional view of a first example of a fitting structure according to the present utility model.

FIG. 4 is a sectional view of a second example of a fitting structure according to the present utility model.

FIG. 5 is a sectional view showing the use of a fitting structure according to the present utility model.

IMPLEMENTATION OF A USEFUL MODEL

In FIG. 2, 3, 5, there is presented a fitting design for supplying gas, proposed in accordance with the present utility model, and in particular, a fitting design mounted on an air outlet for discharging air of an air compressor to perform a connection function between the air compressor and the air supply tube 3. The air supply tube 3 is made in the form of a hose or a plastic pipe. The fitting design comprises a fitting 1 and a heat insulation tube 2.

The fitting 1 has an end forming the first connecting hole 11 and an opposite end forming the second connecting hole 12. The first connecting hole And is configured to connect to the air outlet of the air compressor, and the second connecting hole 12 is configured to connect to the supply pipe 3 air.

The heat-insulating tube 2 is installed in the fitting 1. The heat-insulating tube 2 is made of a heat-resistant material (such as a Teflon pipe) and has a length exceeding the length of the fitting 1. The heat-insulating tube 2 has an end forming the first end part 21 and an opposite end forming the second end part 22. The first end part 21 is fixed inside the second connecting hole 12 of the fitting 1, and the second end part 22 protrudes outward and extends beyond the second connecting hole 12. The heat-insulating section bki 2 projecting outwardly from the second communication hole 12 is located in the interior of the tube 3 air.

In FIG. 3 shows an example of the present utility model in which the first end portion 21 of the heat-insulating tube 2 is fixed inside the second connecting hole 12 of the fitting 1 by, for example, adhesives or a snug fit.

In FIG. 4 shows another example of the present utility model in which the end hole of the first end portion 21 of the heat-insulating tube 2 is designed so that it expands (turns) outward and forms an expanded portion, so that the diameter of the first end part 21 of the heat-insulating tube 2 exceeds the diameter of the second connecting hole 12 of fitting 1. When heat insulation tube 2 is inserted through fitting 1 and thus connected to it, an external reamer or extension of the first end portion 21 of heat insulation tube 2 bespechivaet rigid connection fitting 1 inside.

The fitting 1 is connected through the first connecting hole 11 to the air outlet for air of the air compressor and through the second connecting hole 12 to the air supply pipe 3. A portion of the heat-insulating tube 2 protruding outward from the second connecting hole 12 is located on the inside of the air supply tube 3. Essentially, the heat-insulating tube 2, made of heat-resistant material and having a relatively large length, allows the passage of high-temperature air generated and supplied by the air compressor through the heat-insulating tube 2 into the air supply tube 3.

Since the air supply pipe 3 is a pipe having a certain length, when high temperature air is directed through the heat-insulating pipe into the air supply pipe 3, the high air temperature can be distributed and scattered through the air supply pipe and, thus, is reduced, thereby protecting the connecting portion between fitting 1 and tube 3 of the air supply from direct exposure to high temperature and prevent its thermal expansion and aging. Accordingly, the stability of the connection between the fitting 1 and the air supply pipe 3 can be improved, and the service life can be increased.

Claims (9)

1. Fitting design for gas supply, made with the possibility of installing on the hole for the release of air of an air compressor to perform the function of the connection between the air compressor and the air supply pipe, comprising a fitting having an end forming a first connecting hole and an opposite end forming a second connecting hole, wherein the first connecting hole is configured to connect to an air compressor air outlet, and the second connecting hole is configured to connect to an air supply tube; and a heat insulation tube installed in the fitting and having an end forming a first end part and an opposite end forming a second end part, the first end part being fixed inside the second connecting hole of the fitting and the second end part protruding outward from the second connecting hole, so that the heat-insulating portion a tube protruding outward from the second connecting hole is configured to be placed in the interior of the air supply tube; moreover, the passage of air discharged from the air compressor through the heat-insulating tube to the inside of the air supply tube is ensured. 2. The fitting design of claim 1, wherein the heat-insulating tube is made of heat-resistant material and has a length exceeding the length of the fitting. 3. The fitting design of claim 1, wherein the first end portion of the heat insulation tube is secured within the second connecting hole of the fitting by adhesive. 4. The fitting design of claim 1, wherein the first end portion of the heat insulation tube is secured within the second connecting hole of the fitting by means of a snug fit. 5. The fitting design of claim 1, wherein the first end portion of the heat-insulating tube has an end hole that is deployed and forms an expanded portion, so that the diameter of the first end part of the heat-insulating tube exceeds the diameter of the second connecting hole of the fitting. 6. The fitting design of claim 5, wherein the unfolded end of the first end portion of the heat-insulating tube is securely fixed inside the fitting.

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