TWM448662U - Improved gas heating and circulation structure of pipe - Google Patents

Description

Gas heating cycle improvement structure of pipeline

This creation relates to a pipeline structure, in particular to an innovative designer who can heat and heat the pipeline by means of a gas heating cycle.

According to the high-tech or semiconductor industry, it is quite common to set up a vacuum line or a liquid line in the plant to transport the fluid required in the process, because the general fluid in the process is too low due to the temperature outside the line. It is easy to form deposits in the tube, and these deposits not only affect the smoothness of the fluid transport, but also cause the pipeline to block and greatly reduce the speed and quality of the transport; the industry is used to improve this problem. Some methods are to coat a heater outside the pipeline (commonly known as a heating jacket), so that the pipeline maintains a certain temperature range to avoid deposits in the pipeline and ensure smooth flow of fluid in the pipeline.

However, the conventional heater system must rely on the electric energy to operate and generate the heating action. However, the pipelines in the general factory are usually connected by the majority of the pipelines, so the pipelines of each section must be matched with each other. Covering a heater, the power consumed and spent is quite large. For example, if a heater consumes about 140 W (watts), when the pipeline is set to 100 knots, the overall heater consumes The power system is up to 14 KW (kW, 1 kW = 1000 watts), and the more the number of sections set in the pipeline, the more power is consumed, so long-term use will not only lead to a significant increase in power consumption, but also Waste of energy and cost increases, it is no longer in line with the concept of environmental protection and energy conservation that is increasingly valued by modern times. In addition, conventionally all-electric heaters are repeatedly activated to start heating and turn off cooling. There is a common problem that the damage rate is too high, and it is difficult to maintain a uniform and uniform temperature for the heating temperature of each section of the pipeline, resulting in the occurrence of deposits in the pipeline with lower temperature, which in turn affects the fluid flow. The smoothness of these problems is an important issue that the industry must further improve.

Therefore, in view of the problems existing in the above-mentioned practices, how to develop an innovative design that can be more ideal and practical, and the relevant industry should further consider the goal and direction of breakthrough.

In view of this, the inventor has been engaged in the manufacturing development and design experience of related products for many years. After detailed design and careful evaluation, the inventor has finally obtained the practical invention.

The main purpose of this creation is to provide a gas heating cycle improvement structure for pipelines. The problem to be solved is to think about how to develop a more ideal and practical purpose, and to think about innovative breakthroughs; The technical feature is mainly that the gas heating cycle improvement structure of the pipeline comprises at least two pipe members in a hollow pipe body shape which are connected to each other; the coated hollow capsule body is wrapped around the outer pipe member and is in a ring shape. Forming an outer annular surface, an inner annular surface, and an accommodating space formed in a closed state between the inner and outer annular surfaces, wherein the inner annular surface abuts against the outer side of the tubular member, And at least one gas circulation port is disposed at a predetermined position of the outer surface of the hollow capsule, wherein at least one of the hollow capsules is further provided with a gas inlet; a gas heating device is disposed at the gas inlet of the hollow capsule a corresponding position of the mouth, whereby a predetermined gas can be heated; a gas delivery device, disposed at a corresponding position outside the tube, can deliver gas to the gas heating device, and Heated gas from the gas inlet into the accommodating space of the hollow balloon; at least one communication tube a gas circulation port disposed in the hollow tube body and disposed in the two hollow capsules, wherein the gas located in the accommodating space can pass through the communication tube member into the other hollow capsule body, and the gas is in the hollow capsule body. The formed accommodating space is in a flowable circulation state; at least one connecting member is disposed at a position where the pipe fittings are connected, thereby enabling each pipe member to obtain a stable limit; thereby innovating and uniquely designing, thereby innovating and uniquely designing Compared with the conventional pipelines, it is necessary to cope with the problem that the power consumption of the heater is too large and the energy is wasted. The creation is to use the heated gas in the housing space of each hollow capsule. The structure of the flow cycle can keep the pipe fittings in a certain temperature range, so that the fluid contained in the pipe can keep the flow smooth and prevent the sediment from being generated. Therefore, it is only necessary to use the gas heating device and the gas conveying device to implement The heating effect of all the pipeline components can minimize the power consumption, and can achieve environmental protection, energy saving, energy consumption reduction and cost reduction. Progressive.

Please refer to Figures 1 to 3 for a preferred embodiment of the gas heating cycle improvement structure of the present pipeline, but these embodiments are for illustrative purposes only and are not limited by this structure in the patent application: The gas heating cycle improved structure of the pipeline includes:

At least two tubular members 10 are in a hollow tubular body shape that are connected to each other; and a coated hollow capsule 20 is wrapped around the outside of each tubular member 10 and is formed in an annular shape to define an outer annular surface 21 and an inner ring. The surface 22 and the accommodating space 23 formed in a closed state between the inner and outer annular surfaces 21 and 22, wherein the inner annular surface 21 abuts against the outer side of the tubular member 10, and the hollow capsule 20 The outer ring surface 22 is provided with at least one gas circulation port 24 at a predetermined position, wherein at least one of the hollow cells 20 is further provided with a gas introduction port 25; the hollow capsule 20 of the present invention can be woven with a heat-resistant type. Cloth or plastic material, but not limited to this; in addition, the pipe fittings disclosed in this creation are based on three groups. The hollow capsules 20 are arranged in three groups to be respectively wrapped around the outer tubes 10, and wherein the gas capsules 24 are disposed at predetermined positions in front of and behind the hollow capsules 20 in the middle section. Similarly, when the hollow capsule 2010 is four groups, five groups, or even more groups, the hollow capsule 20 of the middle portion refers to the hollow capsule 20 except for the first segment and the last segment of the hollow capsule 20. All of them belong to the middle section; a gas heating device 30 is disposed at a corresponding position of the gas inlet port 25 of the hollow capsule 20, so that a predetermined gas A (such as air, nitrogen, etc.) can be heated, and the gas heating device 30 In the implementation, the heating temperature range can be preset, and when the temperature is lowered, the gas heating device 30 can automatically perform a heating operation to maintain the gas A at a certain temperature; a gas delivery device 40 is disposed outside the tube 10 At the position, the gas A can be sent to the gas heating device 30, and the heated gas A is introduced into the accommodating space 23 of the hollow capsule 20 from the gas inlet 25; Can be set for nitrogen , A blower, a vacuum pump, air compressor, is not limited to this section.

The at least one connecting tube member 50 is connected to the gas circulation port 24 of the second hollow capsule 20 in a hollow tubular body shape, so that the gas A located in the accommodating space 23 can pass through the communicating tube member 50 into another hollow sac. The body 20 is arranged in a flowable circulation state in the accommodating space 23 formed by the hollow capsule 20; at least one connecting member 60 is disposed at the joint position of each of the tubes 10, so that the tubes 10 can be obtained. The above-mentioned gas conveying device 60 can be an air compressor, so that the gas A can be blown to the gas heating device 30 and the gas A is blown. The generated wind pressure allows the gas A to enter the accommodating space 13 of the hollow capsule 20, so that the heated gas A can be flow-circulated in the accommodating space 13 of each hollow capsule 20. The structure can maintain the temperature of each pipe member 10 in a certain temperature range, so that the fluid B contained in the pipe member 10 can keep the flow smooth and prevent The deposit is produced, and at the same time has the advantages of energy saving and energy cost reduction; as shown in FIG. 2, the connecting member 60 is embodied in a ring-shaped frame and can pass through the pipe member 10, and the connecting member 60 is provided. The utility model is composed of a plurality of stoppers 61 and a connecting rod 62 connected between the stoppers 61, and is passed through a second stopper 61 located above by a screw member 63, thereby making the connecting member 60 is in a lockable and relaxed state, that is, after the tubular member 10 is passed through the connecting member 60, the stopper 61 can be pressed to tighten the tubular member 12 or the relaxed state by rotating the screw member 63.

As shown in FIG. 4, in the present implementation, a pressure relief device 28 can be disposed at the end of the hollow capsule 20 so that the gas A in the accommodating space 23 can be vented by the pressure relief device 28. To the outside, the circulation effect of the gas A in the accommodating space 23 can be increased, but this portion is not limited.

As shown in FIG. 5, it is another embodiment of the present invention, wherein the gas delivery device 40 is an existing nitrogen device, and wherein it is different from at least one hollow capsule provided with the gas introduction port 25. Further, a gas outlet port 26 is provided, so that the gas A accommodated in the accommodating space 23 can be led out from the gas outlet port 26, and the gas outlet port 26 is provided with a pressure relief device 28B. Controlling the pressure at which the gas A is led, and the pressure relief device 28B is referred to as a pressure relief valve type; and wherein the gas outlet 26 is in communication with a circulating line 27 existing in the plant, such that the gas The A system can be led out by the gas outlet 26, and the gas A is blown to the other place via the gas delivery device 40 to other places for other purposes; likewise, when the heated gas A enters the accommodation space of each hollow capsule 20 After 23, the system can maintain the flow circulation state, thereby enabling the pipe member 10 to maintain a certain temperature range, so that the internal fluid B can maintain a smooth flow, and compared with the conventional method of using a power-consuming heater to heat the pipeline. This creation uses gas A flow The circulation mode can maintain uniform and uniform temperature of each pipe member 10, can effectively prevent the occurrence of deposits, and is not easily damaged by using the internal structure for a long time, and can further reduce energy consumption; and wherein the gas outlet is further A check valve 70 is disposed between the gas delivery device 26 and the gas delivery device 40 to prevent the The gas A enters the accommodating space 23 directly from the gas outlet 26; the actuating structure of the check valve 70 is generally known in the art, and therefore will not be described herein.

Efficacy description:

The facts that enhance the effectiveness of this creation are as follows:

The "Gas Heating Cycle Improvement Structure of the Pipeline" disclosed in this work mainly consists of an innovative structure in which a pipe member, a coated hollow capsule, a gas heating device, a gas conveying device, a connecting pipe member, and a connecting member are co-constructed. In the case of the conventional pipelines, it is necessary to cooperate with a heater to generate excessive power and waste energy. The creation uses a heated gas to flow in the housing space of each hollow capsule. The structure of the circulation can keep the pipe fittings in a certain temperature range, so that the fluid contained in the pipe can keep the flow smooth, prevent the sediment from being generated, minimize the use of electricity, and achieve environmental protection, energy saving and power consumption reduction. Reduce practical costs such as cost and expenditure.

The disclosures of the above embodiments are used to specifically explain the present creation, and although the descriptions are made through specific terms, the scope of patents of the novel creation cannot be limited thereby; those skilled in the art can understand the spirit of the creation. Changes and modifications are made to the equivalent purpose, and such changes and modifications are to be included in the scope defined by the scope of the patent application as described later.

10‧‧‧ Pipe fittings

20‧‧‧ hollow capsule

21‧‧‧ outer annulus

22‧‧‧ Inner torus

23‧‧‧ accommodating space

24‧‧‧ gas circulation port

25‧‧‧ gas inlet

26‧‧‧ gas outlet

27‧‧‧Circulation line

28, 28B‧‧‧ Pressure relief device

30‧‧‧Gas heating unit

40‧‧‧ gas delivery device

50‧‧‧Connected fittings

60‧‧‧Connecting members

61‧‧‧stop block

62‧‧‧ Connecting rod

63‧‧‧ Screw locks

70‧‧‧ check valve

A‧‧‧ gas

B‧‧‧ fluid

Figure 1: An exploded perspective view of the structure of the creation.

Fig. 2 is a combination diagram of the assembled structure of the present invention and the hollow outer tube assembly type.

Figure 3: A cross-sectional view of the configuration of the creation structure.

Figure 4: A cross-sectional view of the implementation of this creation.

Figure 5: A cross-sectional view of another embodiment of the present invention.

10‧‧‧ Pipe fittings

20‧‧‧ hollow capsule

21‧‧‧ outer annulus

22‧‧‧ Inner torus

24‧‧‧ gas circulation port

50‧‧‧Connected fittings

60‧‧‧Connecting members

61‧‧‧stop block

62‧‧‧ Connecting rod

63‧‧‧ Screw locks

Claims (6)

The invention relates to a gas heating cycle improvement structure of a pipeline, comprising: at least two pipe fittings, which are in a hollow tubular body shape which are connected to each other; and a coated hollow capsule body, which is wrapped around the outer tubular members and is formed in an annular shape. An outer annular surface, an inner annular surface, and an accommodating space formed in a closed state between the inner and outer annular surfaces, wherein the inner annular surface abuts against the outer side of the tubular member, and the hollow balloon body At least one gas circulation port is disposed at a predetermined position of the outer annular surface, wherein at least one of the hollow capsules is further provided with a gas inlet; a gas heating device is disposed at a corresponding position of the gas inlet of the hollow capsule The gas can be heated by a predetermined gas; a gas conveying device is disposed at a corresponding position outside the pipe member to deliver the gas to the gas heating device, and the heated gas is introduced into the hollow capsule from the gas inlet port. The at least one connecting pipe member is connected to the gas circulation port of the second hollow capsule in a hollow tubular body shape, so that the gas located in the accommodating space can pass through the connecting pipe member to enter another a hollow capsule, and the gas is in a flowable circulation state in the accommodating space formed by the hollow capsule; at least one connecting member is disposed at the joint position of each of the tubes, so that each tube can obtain a stable limit; Therefore, the enthalpy can use the heated gas to flow in the accommodating space provided in each of the hollow capsules, so that each tube can maintain a certain temperature range, so that the fluid contained in the tube can maintain a smooth flow. Prevent the formation of sediments, and achieve the purpose of environmental protection and energy saving, reducing power consumption and reducing costs. The gas heating cycle improving structure of the pipeline according to the first aspect of the patent application, wherein the hollow capsule system is formed of a heat-resistant type of woven fabric or plastic material. The gas heating cycle improving structure of the pipeline according to claim 1, wherein the gas conveying device is one of a nitrogen gas device, a blower, a vacuum pump, and the like, and an air compressor. The gas heating cycle improving structure of the pipeline according to claim 1, wherein the gas conveying device is an existing nitrogen gas device, and wherein the gas conveying device is different from at least one hollow balloon body provided with a gas inlet port Further, a gas outlet is provided to enable gas to be led out through the gas outlet; wherein a check valve is disposed between the gas outlet and the gas delivery device to prevent the gas from directly entering the gas outlet Included in the space. The gas heating cycle improving structure of the pipeline according to any one of claims 1 to 4, wherein the connecting member is in a ring frame shape to provide passage of the pipe member, and the connecting member comprises A plurality of stoppers and a pivoting rod are connected to the connecting rods between the stopping blocks, and are passed through a second stopping block located above by a screw locking member, so that the connecting member is locked and relaxed. status. The gas heating cycle improvement structure of the pipeline according to any one of claims 1 to 4, wherein the pipe is set to at least three sets of configurations, so that the hollow capsule system is matched to at least three The group is respectively wrapped around the outside of each pipe member, and wherein two gas circulation ports are arranged at predetermined positions in front of and behind the hollow body of the intermediate section.