Air compression device for application of dry air to interior exhaust trap
By installing an internal dry air discharge collection unit within the air compression system, the problems of noise and condensate in the compressed air system are solved, achieving internal recycling of compressed air and maximizing energy efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- TURBOWIN
- Filing Date
- 2021-08-27
- Publication Date
- 2026-06-23
Smart Images

Figure CN115707869B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to an air compression device that utilizes an internal discharge trap for dry air, and more specifically, to an air compression device that utilizes an internal discharge trap for dry air, thereby solving various problems caused by discharge by guiding the discharge occurring within the compressed air system into the compressed air system, without guiding it to the outside (atmosphere). At the same time, it can improve the on-site environment where compressed air is used and maximize energy efficiency and achieve a virtuous cycle of energy by recycling the discharged compressed air. Background Technology
[0002] Currently, in industrial sites that utilize compressed air, in addition to the compressed air required on-site, the system achieves stable operation by discharging compressed air from the system to the outside.
[0003] This is called "discharge," which refers to the release of air or gas from a compressed air system into the atmosphere when the internal pressure is too high.
[0004] The air vent is a device that automatically discharges air flowing through the piping. If the air vent is not discharged from the compressed air system, excessive noise will be generated because the air will fill the piping. Furthermore, the moisture contained in the compressed air will cause corrosion or increased maintenance costs. It can also cause air malfunctions that interfere with the operation of devices such as water injection or pumps, which can seriously affect the accuracy of sensors used to measure the air flow in the piping and the operation of control valves. In severe cases, it can cause the entire equipment to malfunction.
[0005] However, as mentioned above, the discharge method in industrial sites involves releasing air into the atmosphere, which causes another problem on site, namely, noise and condensation.
[0006] Therefore, the present invention provides an air compression unit that can improve the working environment by enabling discharge within a compressed air system.
[0007] In this regard, such as Figure 7aAs shown, prior art related to air compression devices that utilize dry air internal discharge collection units includes Korean Patent Publication No. 10-1868915, entitled "Collection Device for Vacuum Pump Moisture Removal System" (hereinafter referred to as "Prior Art 1"). The collection device for the vacuum pump moisture removal system includes: a housing having multiple compartments formed vertically inside; an inflow pipe inserted from the upper part of the housing into the interior of the housing for conveying air flowing in from a vacuum object to the compartment located at the lowermost end of the housing among the multiple compartments; an oil trap built into two or more compartments, including the compartment located at the lowermost end of the housing; and a filter unit inserted into the multiple compartments. A compartment removes at least one of moisture, oil, and foreign matter from the air passing through the oil catcher. Multiple compartments are connected by a connecting port, which is formed alternately at the upper and lower parts of the compartments. Air passing through the oil catcher, which is built into two or more compartments including the lowermost compartment of the outer shell, moves left and right along the alternately formed connecting port and rises. The air is transferred through the inflow pipe to the lowermost compartment of the outer shell and moves upward through the oil catcher to the upper part of the outer shell. The uppermost compartment of the outer shell is connected to a vacuum pump so that the air is drawn in by the vacuum pump, thereby effectively removing moisture.
[0008] like Figure 7b As shown, another prior art is the "Vacuum Pump Moisture Removal System" (hereinafter referred to as "Prior Art 2") in Korean Patent Publication No. 10-1868914. The vacuum pump moisture removal system includes: a vacuum pump that creates a negative pressure inside the vacuum object by drawing air from the vacuum object; and an auxiliary vacuum pump for drawing in the internal air of the vacuum pump. Moisture contained in the air drawn from the vacuum object is drawn in by the vacuum pump and condenses inside the vacuum pump. When the internal pressure of the vacuum pump decreases due to the auxiliary vacuum pump, the condensate generated inside the vacuum pump is vaporized and discharged to the outside of the vacuum pump through the auxiliary vacuum pump, thereby effectively removing the moisture contained in the air drawn from the vacuum object and flowing into the vacuum pump.
[0009] As described above, the technical fields of the prior art 1 and prior art 2 are similar to those of the present invention. They share similar or identical technical concepts in terms of the inventive objective of removing moisture contained in the incoming air through an air-inhaling device. However, they differ in terms of the technical problem, the effect, and the technical solution of the invention.
[0010] That is, the specific technical solutions of an invention used to achieve its technical objectives and effects differ in their technical features.
[0011] Therefore, unlike existing technologies for removing moisture from the air, including the aforementioned prior art 1 and prior art 2, the present invention will achieve its technical features based on the specific technical problem, technical solution, and effects of the invention.
[0012] Existing technical documents
[0013] Patent documents
[0014] Document 01: Korean Patent Publication No. 10-1868915 (granted on June 12, 2018)
[0015] Document 02: Korean Patent Publication No. 10-1868914 (granted on June 12, 2018) Summary of the Invention
[0016] Technical issues
[0017] In order to solve the existing problems as described above, the object of the present invention is to provide an air compression unit that improves the on-site environment by preventing problems caused by discharge, namely by preventing noise and condensation from being generated on-site.
[0018] Another object of the present invention is to maximize energy efficiency and achieve a virtuous cycle of energy by processing (removing moisture) the compressed air that is discharged and then recycled within the air compression device system.
[0019] Technical solution
[0020] This invention aims to achieve the above-mentioned objectives. The air compression device of this invention, utilizing an internal dry air discharge trap, is characterized by comprising: an air compression system housing unit for internally performing air intake, compression, and discharge; an air compression unit, coupled to one side of the air compression system housing unit, generating compressed air by intake and compression of air flowing in from the outside; and a compressed air internal / external discharge unit, coupled to one side of the air compression system housing unit and connected to one side of the air compression unit, for discharging the compressed air generated by the air compression unit to the outside, wherein the compressed air internal / external discharge unit includes: a compressed air discharge section for discharging to the outside... The compressed air compressed by the air compression unit is discharged; and the dry air internal discharge collection unit is connected to one side of the compressed air discharge unit to decompose the compressed air and guide a portion of the decomposed compressed air to flow along a separate specific path to discharge the flowing compressed air into the air compression system housing unit. This prevents air backflow during the process of the compressed air generated from the air compression unit being discharged by the compressed air discharge unit. By making the air compression system housing unit discharge only the compressed air required on site, it achieves that no compressed air is discharged to the outside except for the compressed air required on site, thereby preventing noise and condensation caused by the compressed air discharged to the outside.
[0021] In this case, the present invention is characterized in that the internal discharge trapping unit for dry air includes: an internal discharge compressed air flow piping module connected to the lower side of the compressed air discharge unit, wherein compressed air supplied to the compressed air discharge unit and compressed by the air compression unit is decomposed, causing the decomposed compressed air to flow along a separate specific path; and an internal discharge compressed air dewatering trapping module connected to the end of the internal discharge compressed air flow piping module, wherein moisture is removed from the compressed air flowing through the internal discharge compressed air flow piping module so that the dewatered compressed air is discharged as dry air into the interior of the air compression system housing unit, preventing air backflow during the discharge of compressed air generated from the air compression unit by the compressed air discharge unit, and simultaneously removing moisture from the decomposed and discharged compressed air by the internal discharge compressed air dewatering trapping module, thereby allowing the dry air to flow back into the air compression unit, thereby maximizing energy efficiency and achieving a virtuous cycle of energy.
[0022] On the other hand, the terms or words used in the scope of protection of the invention in this specification should not be interpreted in the usual understanding or dictionary meaning. Based on the principle that the inventor can appropriately define the terms and concepts in order to explain his own invention in the best way, they should be interpreted in the meaning and concept that conforms to the technical idea of the invention.
[0023] Therefore, the embodiments and structures shown in the accompanying drawings described in this specification are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, it should be understood that various equivalent technical solutions and modifications that can replace them may exist at the time of application of the present invention.
[0024] The effects of the invention
[0025] The present invention, having the above-described structure and function, has the following effects.
[0026] First, it can improve the working environment by addressing various problems caused by drainage in the past, namely by preventing various safety accidents caused by noise and condensate generation.
[0027] Secondly, the amount of compressed air emitted to the outside (atmosphere) can be significantly reduced by discharging it within the air compression unit system. This maximizes energy efficiency and achieves a virtuous cycle of energy.
[0028] Third, the problems caused by the exhaust within the air compression unit system can be addressed in advance. Specifically, the condensation and internal noise generated within the air compression unit system can be resolved beforehand to achieve exhaust within the air compression unit system. Attached Figure Description
[0029] Figure 1 This is a structural diagram illustrating the air compression device of the present invention, which is used to collect and discharge dry air internally.
[0030] Figure 2 This is a conceptual diagram illustrating the air compression device of the present invention, which is used to collect and discharge dry air internally.
[0031] Figure 3 The diagram illustrates an embodiment of the air compression device of the present invention, which utilizes the internal discharge and collection section for dry air.
[0032] Figure 4 The figure shows a portion of actual photographs of an embodiment of an air compression device for an internal dry air discharge trapping section according to the present invention.
[0033] Figure 5 This is a simplified diagram illustrating an embodiment of the compressed air internal and external discharge unit, a structural element of the air compression device of the present invention, which utilizes an internal discharge and collection section for dry air.
[0034] Figure 6 A flowchart is provided to briefly illustrate the mechanism of the compressed air internal and external discharge unit in the air compression device of the present invention, which utilizes the internal discharge and collection section of dry air.
[0035] Figure 7aThis is a representative diagram of prior art 1 related to the air compression device of the dry air internal discharge collection section of the present invention.
[0036] Figure 7b This is a representative diagram of prior art 2 related to the air compression device of the application dry air internal discharge collection section of the present invention.
[0037] Explanation of reference numerals in the attached figures
[0038] 1: An air compression device that discharges dry air from the internal collection section.
[0039] 100: Air compression system housing unit; 110: Air compression system housing section
[0040] 120: External air inlet section; 121: External air inlet filter module
[0041] 130: Compressed air exhaust section
[0042] 140: Heat exchanger fluid supply unit; 150: Air compression system control unit
[0043] 200: Air compression unit; 210: Air compression section
[0044] 220: Air intake filter section; 230: Plate heat exchanger section
[0045] 240: Heat transfer fluid flow pipeline section; 250: Compressed air movement pipeline section
[0046] 300: Compressed air internal and external discharge unit; 310: Compressed air discharge section
[0047] 311: Compressed air discharge piping module; 312: Compressed air discharge check valve module
[0048] 313: Externally discharged compressed air dewatering and collection module
[0049] 313-1: First water-collecting shell element
[0050] 313-2: First water-collecting water droplet element
[0051] 313-3: First moisture discharge pipeline element; 314: Water discharge pipeline module
[0052] 320: Dry air is discharged from the internal collection section.
[0053] 321: Internal exhaust compressed air flow piping module
[0054] 321-1: First internal exhaust compressed air flow piping element
[0055] 321-2: Second internal exhaust compressed air flow piping element
[0056] 321-3: Third internal exhaust compressed air flow piping element
[0057] 321-4: Elements of the first compressed air pressure regulating windproof valve
[0058] 321-5: Elements of the second compressed air pressure regulating windproof valve
[0059] 321-6: Elements of the third compressed air pressure regulating windproof valve
[0060] 322: Internal compressed air discharge water collection module
[0061] 322-1: Second water-collecting shell element
[0062] 322-2: Second water-collecting water droplet element
[0063] 322-3: Noise reduction element of internal compressed air exhaust
[0064] 322-4: Internal exhaust dry air filtration element
[0065] 322-5: Second water-collecting shell fixing bracket element
[0066] 322-6: Second moisture discharge pipeline element Detailed Implementation
[0067] Hereinafter, with reference to the accompanying drawings, the function, structure and operation of the air compression device 1 of the application dry air internal discharge and collection section of the present invention will be described in detail.
[0068] Figure 1 This is a structural diagram illustrating the air compression device of the present invention, which utilizes the internal discharge and collection section for dry air. Figure 2 This is a conceptual diagram illustrating the air compression device of the present invention, which utilizes the internal discharge and collection section for dry air. Figure 3 The figures are provided to briefly illustrate an embodiment of the air compression device of the present invention, which utilizes an internal dry air discharge and collection unit. Figure 4 The figures shown are partial photographs of an embodiment of an air compression device for applying the internal exhaust trapping section of the present invention. Figure 5 This is a simplified diagram illustrating an embodiment of the compressed air internal and external discharge unit in the air compression device of the present invention, which utilizes an internal dry air discharge and collection section. Figure 6 A flowchart is provided to briefly illustrate the mechanism of the compressed air internal and external discharge unit in the air compression device of the present invention, which utilizes the internal discharge and collection section of dry air.
[0069] like Figures 1 to 6 As shown, the air compression device 1 of the present invention, which utilizes an internal dry air discharge and collection section, is characterized by comprising: an air compression system housing unit 100 for internally realizing air intake, compression, and discharge; an air compression unit 200, coupled to one side of the air compression system housing unit 100, generating compressed air by intake and compression of air flowing in from the outside; and a compressed air internal / external discharge unit 300, coupled to one side of the air compression system housing unit 100 and connected to one side of the air compression unit 200, for discharging the compressed air generated by the air compression unit 200 to the outside, wherein the compressed air internal / external discharge unit 300 includes: a compressed air discharge section 310 for discharging to the outside... The compressed air compressed by the air compression unit 200 is discharged; and the dry air internal discharge trap 320 is connected to one side of the compressed air discharge unit 310 to decompose the compressed air and guide a portion of the decomposed compressed air to flow along a separate specific path to discharge the flowing compressed air into the air compression system housing unit 100, so as to prevent air backflow during the process of the compressed air generated from the air compression unit 200 being discharged by the compressed air discharge unit 310. By making the air compression system housing unit 100 discharge only the compressed air required on site, it achieves that no compressed air is discharged to the outside except for the compressed air required on site, thereby preventing noise and condensation caused by the compressed air discharged to the outside.
[0070] That is, the present invention relates to an air compression device that guides compressed air that would otherwise be discharged to the outside (atmosphere) into the air compression system, except for compressed air supplied to where it is needed, and does not discharge it into the outside (atmosphere), thereby preventing noise and condensation caused by discharging compressed air into the outside (atmosphere). Furthermore, as the compressed air is discharged into the air compression system, it will flow back into the air compression unit 200, be drawn in and compressed again, thereby improving energy efficiency and a virtuous cycle of energy. Problems (condensation) caused by the discharged compressed air can be prevented in advance by removing moisture from the discharged compressed air, thereby creating an optimal environment inside and outside the air compression system.
[0071] The following will provide further details.
[0072] The air compression system housing unit 100 includes: an air compression system housing portion 110, which has a defined space inside for housing the air compression unit 200 and the compressed air internal and external discharge unit 300; an external air inlet portion 120, which is formed through one side of the air compression system housing portion 110 in a specific shape, for allowing air to flow from the outside into the interior of the air compression system housing portion 110, and is combined with an external air inlet filter module 121; a compressed air outlet portion 130, which is formed through one side of the air compression system housing portion 110, for allowing compressed air compressed by the air compression unit 200 to be discharged to the outside through the compressed air internal and external discharge unit 300; and a heat exchanger fluid supply portion 140, which is formed through the upper... One side of the air compression system housing 110 is used to supply fluid (antifreeze) to the plate heat exchanger section 230, which cools the heat of the compressed air rising during the process of the compressed air compressed by the air compression unit 200 being discharged to the outside through the compressed air internal and external discharge unit 300; the air compression unit 200 is formed on one side of the air compression system housing 110 and is located inside the air compression system housing 110; and the air compression system control unit 150 controls the operation of the compressed air internal and external discharge unit 300 based on information obtained from various sensors, thereby controlling the discharge pressure and flow rate of the compressed air, so that the compressed air device is formed into a system device.
[0073] The air compression unit 200 includes: an air compression section 210 for drawing in and compressing air flowing in from the outside; an air intake filter section 220 for filtering the air drawn in through the air compression section 210; a plate heat exchanger section 230 for transferring heat generated in the compressed air during the process of discharging the compressed air compressed by the air compression section 210 to the outside; a heat transfer fluid flow line section 240, one end of which is connected to the heat exchanger fluid supply section 140 and the other end of which is connected to the plate heat exchanger section 230, so that fluid (antifreeze) flows and circulates to the plate heat exchanger section 230 in such a way that heat generated by the compressed air is transferred; and a compressed air movement line section 250, one end of which is connected to one side of the compressed air internal and external discharge unit 300 and the other end of which is connected to the air compression section 210, for discharging the compressed air compressed by the air compression section 210 to the outside, thereby smoothly realizing the air intake and compression processes.
[0074] The present invention is characterized in that the compressed air internal and external discharge unit 300 includes: a compressed air discharge section 310 for discharging compressed air compressed by the air compression unit 200 to the outside; and a dry air internal discharge and collection section 320, which is connected to one side of the compressed air discharge section 310, decomposes the compressed air and guides a portion of the decomposed compressed air to flow along a separate specific path to discharge the flowing compressed air into the air compression system housing unit 100, so as to prevent air backflow during the process of the compressed air generated from the air compression unit 200 being discharged by the compressed air discharge section 310. By making the air compression system housing unit 100 discharge only the compressed air required on site, it is achieved that no compressed air other than the compressed air required on site is discharged to the outside, thereby preventing noise and condensation caused by the compressed air discharged to the outside.
[0075] In this case, the compressed air discharge unit 310 includes: a compressed air discharge piping module 311, which allows compressed air compressed by the air compression unit 200 to flow in and discharge to the outside; a compressed air discharge check valve module 312, which allows the compressed air discharged from the compressed air discharge piping module 311 to flow in only one direction and discharge; an externally discharged compressed air dewatering and trapping module 313, formed in the lower part of the compressed air discharge piping module 311, which removes moisture from the compressed air flowing into the compressed air discharge piping module 311 to discharge high-quality compressed air to the outside through the compressed air discharge piping module 311; and a dewatering and moisture discharge pipeline module 314, which discharges the compressed air through the compressed air discharge piping module 311 to the outside. The compressed air is discharged externally via a water-removing module 313 to filter out moisture from the compressed air. This allows the compressed air, compressed by the air compression unit 200, to be processed (moisture-removing) before being discharged externally. The externally discharged compressed air water-removing module 313 includes: a first water-removing housing element 313-1, with a conical lower portion, allowing moisture separated from the compressed air flowing into the compressed air discharge piping module 311 to fall downwards; and a first water-removing water-falling plate element 313-2, which forms a downwardly inclined predetermined angle inside the first water-removing housing element 313-1 and is arranged in a specific pattern, interacting with the compressed air flowing into the compressed air discharge piping module 311. Moisture is removed by contact and friction, causing the removed moisture to fall in the direction of gravity; and a first moisture discharge pipeline element 313-3, which is combined with the lower end of the first water-collecting housing element 313-1, is used to discharge the falling moisture to the outside, thereby removing moisture from the compressed air flowing in the compressed air discharge piping module 311, while the dry air internal discharge collection unit 320 includes: an internal discharge compressed air flow piping module 321, which is connected to the lower side of the compressed air discharge unit 310, and as the compressed air supplied to the compressed air discharge unit 310 is compressed by the air compression unit 200, the compressed air is decomposed, causing the decomposed compressed air to flow along a separate specific path; and an internal discharge The compressed air dewatering and trapping module 322 is connected to the end of the internally discharged compressed air flow piping module 321. It removes moisture from the compressed air flowing through the internally discharged compressed air flow piping module 321, so that the dewatered compressed air is discharged as dry air into the air compression system housing unit 100. This prevents air backflow during the process of compressed air generated from the air compression unit 200 being discharged by the compressed air discharge section 310. At the same time, the internally discharged compressed air dewatering and trapping module 322 removes moisture from the decomposed and discharged compressed air, so that it flows back into the air compression unit 200 as dry air, thereby maximizing energy efficiency and achieving a virtuous cycle of energy.
[0076] In this case, the internal compressed air flow piping module 321 includes: a first internal compressed air flow piping element 321-1, which temporarily reduces the pressure of the compressed air by decomposing a portion of the compressed air flowing to be discharged to the outside through the compressed air discharge section 310, thereby preventing backflow of the compressed air and adjusting the pressure of the discharged compressed air to an appropriate pressure; a second internal compressed air flow piping element 321-2, which is formed parallel to the lower part of the first internal compressed air flow piping element 321-1 and performs the same function as the first internal compressed air flow piping element 321-1; a third internal compressed air flow piping element 321-3, which is formed parallel to the lower part of the second internal compressed air flow piping element 321-2 and performs the same function as the first internal compressed air flow piping element 321-1; and a first compressed air pressure regulating windproof valve element 321-4, which is formed parallel to the first internal compressed air flow piping element 321-2 and performs the same function as the first internal compressed air flow piping element 321-1; and a first compressed air pressure regulating windproof valve element 321-4, which is formed parallel to the first internal compressed air flow piping element 321-1. The first compressed air pressure regulating damper element 321-4, the second compressed air pressure regulating damper element 321-5, and the third compressed air pressure regulating damper element 321-6 are combined with one side of the second internal discharge compressed air flow piping element 321-2 to control the flow of compressed air smoothly. This allows for the appropriate opening and closing of the first compressed air pressure regulating damper element 321-4, the second compressed air pressure regulating damper element 321-5, and the third compressed air pressure regulating damper element 321-6 based on the pressure and quantity of the compressed air flowing into the compressed air discharge section 310 and the load or unload status of the air compression unit 200. This not only ensures a stable system for compressing and discharging air but also facilitates smooth pressure control of the discharged compressed air.
[0077] Furthermore, the internal compressed air dewatering and capturing module 322 includes: a second dewatering and capturing housing element 322-1, the lower part of which is conical, so that water separated from the compressed air flowing into the internal compressed air flow piping module 321 falls downwards; a second dewatering and capturing water drop plate element 322-2, which is formed inside the second dewatering and capturing housing element 322-1 and arranged in a specific manner, removes water by contacting and rubbing against the compressed air flowing into the internal compressed air flow piping module 321, and causes the removed water to fall in the direction of gravity; and an internal compressed air noise reduction element 322-3, which is combined with the upper part of the second dewatering and capturing housing element 322-1 to reduce the noise caused by the discharged compressed air; The dry air filter element 322-4, which is connected to the upper part of the internal compressed air noise reduction element 322-3, performs a final filtration of moisture and foreign matter in the discharged compressed air, and discharges the moisture-removed compressed air into the air compression system housing 110; the second water-collecting housing fixing bracket element 322-5 is used to fix the second water-collecting housing element 322-1 on the inner side of the air compression system housing 110; and the second water discharge pipeline element 322-6, which is connected to the lower end of the second water-collecting housing element 322-1, is used to discharge the falling water to the outside, thereby removing moisture from the compressed air flowing in the internal compressed air flow piping module 311 and discharging it into the air compression system housing 110 as dry air.
[0078] on the other hand, Figure 6 To briefly illustrate the mechanism of the compressed air internal and external discharge unit in the air compression device of the present invention, which utilizes the internal discharge and capture section for dry air, a flowchart will be provided below for further explanation. First, air located outside the air compression system housing unit 100 flows into the interior of the air compression system housing unit 100. The air flowing into the interior of the air compression system housing unit 100 is drawn in and compressed by the air compression unit 200. The compressed air compressed by the air compression unit 200 is discharged to the exterior of the air compression system housing unit 100 (to discharge the compressed air required at the site) through the compressed air internal and external discharge unit 300. At the same time, it is discharged into the interior of the air compression system housing unit 100 (to process the discharged compressed air and discharge it as dry air). This solves the problems of noise and condensation caused by discharging compressed air to the exterior of the air compression system housing unit 100 in the past. Moreover, by allowing the dehydrated compressed air discharged into the interior of the air compression system housing unit 100 to flow back into the air compression unit 200 and be compressed again, the working environment at the site is improved and energy efficiency is maximized and a virtuous cycle of energy is achieved.
[0079] That is, as air located outside the air compression system housing 110 flows into the interior of the air compression system housing 110 through the external air inlet 120, the air flowing into the interior of the air compression system housing 110 will be drawn in and compressed by the air compression unit 210 after passing through the air intake filter unit 220. The compressed air compressed by the air compression unit 210 flows through the compressed air moving pipeline unit 250 and flows to the outside of the air compression system housing 110 through the compressed air discharge piping module 311 and the internal discharge compressed air flow piping module 321, respectively. The compressed air flowing through the compressed air discharge piping module 311 is discharged internally, and the compressed air is discharged to the outside of the air compression system housing 110 after the moisture is removed by the external compressed air dewatering capture module 313. Since the moisture is removed from the discharged compressed air flowing through the internal compressed air discharge piping module 321 by the internal compressed air dewatering capture module 322, the prior art problem (preventing noise and condensation) can be solved by discharging moisture-removed compressed air into the air compression system housing 110.
[0080] As described above, the present invention is not limited to the above embodiments. It is obvious that those skilled in the art can make various modifications and variations without departing from the spirit and scope of the present invention.
[0081] Therefore, since the present invention can be implemented through various methods without departing from the technical concept or main features, the embodiments of the present invention are merely simple illustrations at all levels and should not be interpreted in a limiting way; various modifications can be implemented.
[0082] Industrial availability
[0083] This invention relates to an air compression device that utilizes an internal dry air discharge collection unit, which can be used to promote the development of various industrial sectors, such as manufacturing and sales industries, and in particular, to promote environmental improvement and energy efficiency in industrial sites that require compressed air, and to achieve a virtuous cycle of energy in environmentally friendly energy industries.
Claims
1. An air compression device (1) that utilizes an internal dry air discharge collection section, characterized in that, include: An air compression system housing unit (100) is used to internally realize the intake, compression and exhaust of air; An air compression unit (200), located inside the aforementioned air compression system housing unit (100), generates compressed air by drawing in and compressing air flowing in from the outside; and The compressed air internal and external discharge unit (300) is located inside the air compression system housing unit (100) and connected to one side of the air compression unit (200) for discharging compressed air generated by the air compression unit (200) to the outside. The compressed air internal and external discharge unit (300) includes: Compressed air discharge section (310) for discharging the compressed air required on site from the compressed air compressed by the air compression unit (200); and The dry air internal discharge collection unit (320) is connected to one side of the aforementioned compressed air discharge unit (310). It decomposes the compressed air and guides a portion of the decomposed compressed air to flow along a separate, specific path to discharge the flowing compressed air into the interior of the air compression system housing unit (100). This prevents air backflow during the discharge of compressed air generated from the air compression unit (200) by the compressed air discharge unit (310). Compressed air compressed by the air compression unit (200) is discharged to the outside of the air compression system housing unit (100) as the compressed air required for the site through the compressed air internal and external discharge unit (300). At the same time, it is discharged into the air compression system housing unit (100) as the discharged compressed air. By ensuring that the air compression system housing unit (100) only discharges the compressed air required for the site, no compressed air other than the compressed air required for the site is discharged to the outside, thereby preventing noise and condensation caused by the compressed air discharged to the outside. The dry air internal discharge collection unit (320) includes: An internal compressed air flow piping module (321) is connected to the lower side of the compressed air discharge section (310). As the compressed air supplied to the compressed air discharge section (310) through the air compression unit (200) is decomposed, the decomposed compressed air flows along a separate, specific path; and The internally discharged compressed air dehumidification and collection module (322) is connected to the end of the aforementioned internally discharged compressed air flow piping module (321) to remove moisture from the compressed air flowing through the internally discharged compressed air flow piping module (321) so that the moisture-removed compressed air is discharged as dry air into the interior of the air compression system housing unit (100). To prevent air backflow during the discharge of compressed air generated from the air compression unit (200) through the compressed air discharge unit (310), and to remove moisture from the discharged compressed air through the internal compressed air dewatering module (322), the compressed air is then dried and flows back into the air compression unit (200), thereby maximizing energy efficiency and achieving a virtuous cycle of energy. The aforementioned internal exhaust compressed air flow piping module (321) includes: First internal exhaust compressed air flow piping element (321-1) ) By decomposing a portion of the compressed air flowing to be discharged to the outside through the compressed air discharge section (310), the pressure of the compressed air is temporarily reduced, the backflow of the compressed air is prevented, and the pressure of the discharged compressed air is adjusted to an appropriate pressure. The second internal exhaust compressed air flow piping element (321-2) is formed in parallel below the first internal exhaust compressed air flow piping element (321-1) and has the same function as the first internal exhaust compressed air flow piping element (321-1). The third internal exhaust compressed air flow piping element (321-3) is formed in parallel below the second internal exhaust compressed air flow piping element (321-2) and has the same function as the first internal exhaust compressed air flow piping element (321-1). The first compressed air pressure regulating windproof valve element (321-4) is combined with one side of the aforementioned first internal discharge compressed air flow piping element (321-1) to control the flow of compressed air to become smooth. The second compressed air pressure regulating windproof valve element (321-5), combined with one side of the aforementioned second internal discharge compressed air flow piping element (321-2), controls the flow of compressed air to become smooth; and The third compressed air pressure regulating windproof valve element (321-6), combined with one side of the aforementioned third internal discharge compressed air flow piping element (321-3), controls the flow of compressed air to become smooth.