TR2021020661A2 - A COMPRESSOR WITH VIBRATION DAMPING ELEMENT - Google Patents

Abstract

This invention consists of a housing (2), a body (3) located within the housing (2), a rotor located on the body (3) and a stator (4) located around the rotor, concentrically with the rotor. It relates to a compressor (1) containing at least one connection part (5) located on (4) and allowing the stator (4) to be placed in the housing (2) and at least one spring (7) placed on the connection part (5).

Description

DESCRIPTION A COMPRESSOR CONTAINING A VIBRATION DAMPING ELEMENT This invention relates to a hermetic compressor whose vibration damping is improved in order to reduce transient and steady state vibrations, especially at low speeds, when the spring has high vibrations. In hermetic type compressors, the electric motor consisting of the stator and rotor used to drive the crankshaft mechanism, the cylinder-piston mechanism and other mechanisms are located on a body in a leak-proof casing. In hermetic compressors used in coolers, the movement of the piston that compresses the refrigerant is provided by an electric motor. The rotor of the electric motor is connected to the crankshaft, and the crankshaft transmits the movement to the pistons through a connecting rod. The compression chamber into which the pistons move back and forth is located on a cylinder block. The cylinder block is also fixed on the stator of the electric motor. When the compressor starts, the electric motor is energized and the rotor starts to rotate. A vibration occurs on the stator caused by the magnetic field. Additionally, a vibration occurs due to the movement of the rotor and depends on the rotation speed of the rotor. The back and forth movement of the pistons creates a similar vibration. The vibration resulting from both the electric motor and the movement of the pistons is transmitted to the compressor body and creates a noise that can be heard from outside. Since hermetic compressors are used especially in home appliances such as refrigerators, vibration is an undesirable situation. The inevitable noise caused by vibration must be minimized for user satisfaction. Vibration and sound resulting from the operation of the electric motor, mechanical forces and refrigerant gas force are tried to be reduced by keeping the electric motor on a plane with multiple springs, one end of which is fixed to the electric inotor (lamination parts of the stator) and the other end to the housing. During the compressor's operating cycle, a powerful start trigger is used in the starting phase to overcome engine shaking and dry friction conditions. Therefore, these initial harmful vibrations are inevitable because compressors have to pass through low frequencies that coincide with the resonant frequencies of the system until they reach stable operation at high frequencies. Therefore, despite low speed (revolutions per minute) operation, initially high displacements are observed, while in steady state the vibrations decrease at high frequencies away from the resonance frequency of the system. When the compressor operates at high speeds, the displacement movement caused by the oscillation of the spring due to the oscillatory effect on the body caused by vibration is low. Since the operating speed of the compressor is high and the vibration intervals of the spring are very frequent, the displacement caused by the spring swinging left and right is less. However, on the contrary, since the spring vibration intervals are less frequent at low speeds, the displacement caused by the spring skidding movements caused by vibration is high. For this reason, it is possible to control the vibration occurring in the compressor more effectively by restricting the spring drift that occurs especially at low speeds. The document describes a compressor that uses magnetic particles to adjust the stiffness of the transmission elements, reducing vibrations. In its application, the compressor is mentioned, which includes a vibration damping mechanism in which one large spring is used instead of four small springs. In the document, a compressor is mentioned, which includes a vibration damping element located under the spring and on the lower leg connected to the housing. The aim of the invention is to realize a compressor in which the displacements of the cocompressor due to temporary start-up, temporary shutdown and steady-state spring shaking are reduced during operation. The compressor of the invention includes a housing, a body placed inside the housing and carrying the parts of the compressor such as the cylinder, piston, engine and cylinder head, a rotor forming the engine, and a stator around the rotor, concentric with the rotor. The stator is placed in the housing with at least one connection piece from its lower surface. In order to overcome the vibration problem, at least one spring is placed on at least one connection part. Spring, pin on the housing, etc. The stator is connected to the housing by passing it to a second connection piece. The compressor of the invention contains a vibration damping element on the spring, which is used to dampen the vibrations that occur in the body during the operation of the compressor, and is produced from a flexible material to prevent the high shaking movement of the spring, especially at low speeds. The vibration damping element is in the form of a sleeve that is mounted on the spring in a way that almost surrounds the spring. There is a gap at least in one area between the vibration damping element and the spring. The gap in question may be equal in every region surrounding the spring, or it may be of different sizes, narrowing and/or expanding structures. In an embodiment of the invention, the gap between the spring and the vibration damping element is between 0.1 mm and 1 mm, preferably between 0.1 mm and 0.5 mm. By producing the vibration damping element from any flexible material such as thermoplastic elastomer, extra noise and undesirable situations are prevented when the spring and vibration damping element come into contact. The vibration damping element, produced from a rigid material, creates more noise and vibration effects as it comes into contact with the spring. In an embodiment of the invention, the vibration damping element is a cylindrical pipe suitable for placing a spring inside. In this form, when the vibration damping element surrounds the spring, the inner wall of the spring and the vibration damping element are close to each other, but there is a gap between them in at least one area. In this way, the shaking and displacement movements of the spring are restricted by the vibration damping element, preventing noise and dampening the vibration. In an embodiment of the invention, the vibration damping element surrounds the spring almost completely, in a way that it almost comes into contact with the spring in the region of the connection element in the housing to which the spring is connected, and in a way that leaves a gap between it and the spring in the region of the connection part that connects the spring to the stator. In this application, the inner wall that forms the cylindrical body of the vibration damping element has a segmented structure. At least a two-piece wall with at least one intermediate stage can be placed to surround the arc with spaces of different sizes. In this way, some parts of the arc are surrounded by a wider gap, while other parts are surrounded by a narrower gap. This enables vibration damping to occur more effectively in cases where the vibration of the spring is not the same in all regions. It can be achieved by surrounding the spring with different gaps in different parts, by having different wall thicknesses between the inner and outer walls of the vibration damping element, or by having gradual transitions between the inner wall and the outer wall. In one embodiment of the invention, the vibration damping element contains an S-shaped inner wall with an irregular waveform. In this way, irregular gaps are created between the spring and the vibration damping element. Thanks to the invention, a compressor is produced that dampens the vibrations and noise caused by the operation of the electric motor and moving parts and increases user satisfaction. Sample applications of the co-compressor realized to achieve the purpose of this invention are shown in the attached figures, and these figures; Figure 1- is the perspective view of the compressor that is the subject of the invention in an application. Figure 2- is an application view of the compressor subject to the invention, showing its internal parts such as body, cylinder head and stator. Figure 3- is the view of an application showing the spring, vibration damping element and stator connection in the co-compressor of the invention. Figure 4- is the view of an application in which the gap between the vibration damping element and the spring in the compressor of the invention extends equally on both sides of the spring. Figure 5- is the view of an application in which the gap between the vibration damping element and the spring in the co-compressor of the invention is in a conical form. Figure 6- is the view of an application in which the gap between the vibration damping element and the spring in the compressor of the invention has a two-stage, changing structure. Figure 7- is the view of an application in which the gap between the vibration damping element and the spring in the compressor of the invention has a structure of more than two stages. Figure 8- is the view of an application in which the gap between the vibration damping element and the spring in the compressor of the invention is in an irregular form. The equivalents of the references mentioned in the figures are given below. 1. Compressor Housing Connection part Vibration damping element Cylindrical body SDPOTJQMJÄPJN Inner wall. Space 1 1 . First wall 12. Second wall 13. Stage Compressor (1), a casing (2), a body (3) located within the casing (2), a rotor located on the body (3) and around the rotor, concentric with the rotor. It contains a stator (4) located on the stator (4), at least one connection piece (5) located on the stator (4) that allows the stator (4) to be placed in the housing (2), and at least one spring (7) placed on the connection piece (5). . The compressor (1) of the present invention is a vibration damping element produced from an elastic material, mounted on the spring (7) in a way that leaves a gap (10) between it and the spring (7) in at least one part of it, and almost completely surrounds the spring (7). It contains (6). The vibration damping element (6) in the compressor (1) of the present invention is mounted on the spring (7) in a way that almost completely surrounds the spring (7) placed between the stator (4) and the housing (2). In this way, the vibration damping element (6) serves as a limitation for the spring (7) in high vibrations occurring on the spring (7), especially at low operating speeds, and vibration and noise are reduced thanks to the gap (10) between the spring (7) and the spring (7). . The vibration damping element (6) is produced from a flexible material. In this way, the formation of extra vibration and noise is prevented when the spring (7) comes into contact with the vibration damping element (6) while oscillating within the gap (10) during the shaking. In an embodiment of the invention, the compressor (1) contains an inner wall (8) and a vibration damping element (6) containing a cylindrical body (8) with a hollow structure, suitable for placing the spring (7) inside. In an embodiment of the invention, the compressor (1) contains a gap (10) between 0.1 mm and 1 mm, which is located equally in all regions between the inner wall (8) of the vibration damping element (6) and the spring (7). In this way, the displacement due to oscillation occurring in every region of the spring (7) is damped equally. In an embodiment of the invention, the compressor (1) is connected to at least one first wall (1 1) surrounding at least a part of the spring (7), at least one stage (13) connected to the first wall (1 1), and to the first wall through the stage (13). At least one second wall (12) that is connected to (l 1) and surrounds another part of the spring (7) in a way that leaves a gap (10) between them to a different extent than the gap (10) between the first wall (l 1) and the spring (7). It contains a vibration damping element (6) containing an inner wall (9). In this application, a cavity (10) structure with at least one step in the form of a staircase is formed between the inner wall (9) and the spring (7). This structure ensures the damping of oscillatory movements of different frequencies occurring in different parts of the spring (7). In an embodiment of the invention, the compressor (]) expands from the lower part of the spring (7) placed in the housing (2) towards the connection piece (5), in order to create a gap (10) in conical form between the spring (7) and the vibration damper element (6), It contains a vibration damping element (6) containing a conical inner wall (9). In an embodiment of the invention, the compressor (1) contains a vibration damping element (6) with an inner wall (9) in a wavy structure (S form) to create a wavy-shaped gap (10) between the spring (7) and the vibration damping element (6). . In one embodiment of the invention, the compressor (1) contains the vibration damping element (6) produced from any flexible material such as thermoplastic polyurethane (TPU), thermoplastic elastomer (TPE), elastic PVC and/or polyolefin plastomer. The therinoplastic material in question can be chosen from any material with a stiffness value between 0.2 and 2 N/mm, resistant to refrigerant oil and temperature. The stiffness value of the material can be measured by any force testing device that works by using the method that includes the following steps: - Force is applied to the sample material by means of a linear trigger, - The applied force is measured with a dynamometer from under the sample, - Meanwhile, the movement of the linear trigger is detected by a laser sensor ( It is measured with the help of a different displacement sensor), - According to the measured data, a graph of force (N) against displacement (mm) is obtained, - A linear verification curve with the equation y = mx + b is applied to the graph and "calculated according to the data obtained" The "m" value gives a value in "N/nini", which is the stiffness value. A cooling device, for example a household refrigerator, contains a compressor (l) according to the invention. Thanks to the invention, a compressor (1) with improved vibration damping and a cooling device containing the said compressor (1) are realized. TR TR

Claims (8)

STEMS 1. A housing (2), a body (3) located within the housing (2), a rotor located on the body (3) and a stator (4) located around the rotor, concentric with the rotor. ) and containing at least one connection piece (5) located on the stator (4) that enables the stator (4) to be placed in the housing (2) and at least one spring (7) placed on the connection piece (5); It is a vibration damping element (6) produced from an elastic material, mounted on the spring (7) in such a way that there is a gap (10) between it and the spring (7) in at least one part of it and that it almost completely surrounds the spring (7). compressor (1). 2. A compressor (1) as in claim 1, characterized by an inner wall (8) and a vibration damping element (6) containing a cylindrical body (8) with a hollow structure, suitable for placing the spring (7) inside. 3. A system as in claim 1 or 2, characterized by a gap (10) between 0.1 inrn and 1 mm, located equally in all regions between the inner wall (8) of the vibration damping element (6) and the spring (7). compressor (l). 4. At least one first wall (1 1) surrounding at least a part of the spring (7), at least one stage (13) connected to the first wall (1 1), connected to the first wall (11) through the stage (13) and the spring Vibration comprising an inner wall (9) having at least one second wall (12) surrounding another part of (7) in a way that leaves a gap (10) of a different size between the first wall (11) and the spring (7). A compressor (1) as in claim 1 or ?, characterized by a damping element (6). 5. In order to create a conical-shaped gap (10) between the spring (7) and the vibration damping element (6), an internal conical shape will be created, expanding from the lower part of the spring (7) placed in the housing (2) towards the connection piece (5). A compressor (1) as in any one of claims 1 to 3, characterized by a vibration damping element (6) containing a wall (9) 6. Claims 1 to 3, characterized by the vibration damping element (6) having an inner wall (9) in a wavy structure (S form) to form a wavy-shaped gap (10) between the spring (7) and the vibration damping element (6). a compressor (l) as in any of ” 7. A compressor (1) as in any one of claims 1 to 6, characterized by a vibration damping element (6) produced from any flexible material such as thermoplastic polyurethane (TPU), thermoplastic elastomer (TPE), elastic PVC and/or polyolefin plastomer. 8. A cooling device containing a compressor (1) as in any one of claims 1 to 7.