SYSTEM AND METHOD FOR OPERATIONAL ACOUSTIC OPTIMIZATION OF A VARIABLE SPEED COMPRESSOR AND REFRIGERATOR

Abstract

The present invention relates to a system and method for operational acoustic optimization of a variable speed compressor (2) comprising a synchronous motor (6), a frequency inverter (3) and a control block (5), such optimization being carried out by modifying the switching frequency of the supply signal (9) of the motor (6) contained in the compressor (2), via a control block (5), only during the aligmnent phase of the motor (6), thus, not impairing the performance of the compressor (2), the thermal management of the inverter (3) and the acoustic performance of the system.

Claims

1.-16. (canceled)

17. System for operational acoustic optimization of a variable speed compressor (2), the system comprising a variable speed compressor (2) that comprises a synchronous motor (6), a frequency inverter (3) and a control block (5); the frequency inverter (3) being electrically connected to the synchronous motor (6) and an electrical network (4); the control block (5) being electrically connected to the frequency inverter (3) and being configured to control the speed of the synchronous motor (6) included in the variable speed compressor (2); characterized in that the control block (5) is further configured to establish a first switching frequency (F1) and a second switching frequency (F2) of the frequency inverter (3) to supply the synchronous motor (6) with a power supply signal (9), whereby the first switching frequency (F1) is located in a region of the frequency spectrum that is barely perceptible by a human ear or in a non-audible region of the frequency spectrum; the control block (5) being configured to further establish a time period (T1) in which the synchronous motor (6) will be fed by the frequency inverter signal (3) with the first switching frequency (F1); wherein the time period (T1) corresponds to at least one alignment operation period of the motor (6); the frequency inverter (3) being configured to start the variable speed compressor (2) by supplying motor (6) with a signal (9) with the first switching frequency (F1) for the duration of the time period (T1); and the frequency inverter (3) being further configured to supply the motor (6) with a signal (9) with the second switching frequency (F2) after the time period (T1).

18. System for operational acoustic optimization of a variable speed compressor (2) according to claim 17, characterized in that the second switching frequency (F2) has a value in the range of 20 Hz to 20 kHz.

19. System for operational acoustic optimization of a variable speed compressor (2) according to claim 18, characterized in that the second switching frequency (F2) has a value of 5 kHz.

20. System for operational acoustic optimization of a variable speed compressor (2) according to claim 17, characterized in that the first switching frequency (F1) has a value greater than 12 kHz.

21. System for operational acoustic optimization of a variable speed compressor (2) according to claim 17, characterized in that the first switching frequency (F1) has a value greater than 20 kHz.

22. System for operational acoustic optimization of a variable speed compressor (2) according to claim 17, characterized in that an alignment phase of the motor (6) comprises at least one alignment operation of the motor (6) with a time period (T1).

23. System for operational acoustic optimization of a variable speed compressor (2) according to claim 22, characterized in that the alignment phase of the motor (6) comprises multiple alignment operations of the motor (6).

24. A method for operational acoustic optimization of a variable speed compressor (2) comprising a synchronous motor (6), the compressor (2) being electrically associated with a frequency inverter (3) and a control block (5); the method comprising: (a) establishing a first switching frequency (F1), whereby the first switching frequency (F1) is located in a region of the frequency spectrum that is barely perceptible by the human ear or in a non-audible region of the frequency spectrum; (b) establishing a second switching frequency (F2); (c) establishing a time period (T1), which corresponds to the duration of at least one aligning operation of the synchronous motor (6); (d) starting the variable speed compressor (2) by supplying the synchronous motor (6) with a signal (9) with the first switching frequency (F1) established in step (a), during the time period (T1) established in step (c); and (e) after the time period (T1) established in step (c), supply the synchronous motor (6) with a signal (9) with the second switching frequency (F2) established in step (b).

25. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the steps (a), (b), and (c) are performed by the control block (5).

26. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the steps (d) and (e) are performed by the frequency inverter (3).

27. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the time period (T1) established in step (c) corresponds to multiple alignment operations of the motor (6).

28. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the second switching frequency (F2) has a value in the range of 20 Hz at 20 kHz.

29. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the second switching frequency (F2) has a value of 5 kHz.

30. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the first switching frequency (F1) has a value greater than 12 kHz.

31. Method for operational acoustic optimization of a system comprising a variable speed compressor (2) according to claim 24, characterized in that the first switching frequency (F1) has a value greater than 20 kHz.

32. Refrigerator, characterized in that it comprises a system as defined in claim 17.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0024] The present invention will be described in more detail below based on an example of execution shown in the drawings. The Figures shows:

[0025] FIG. 1—is a representative graph that illustrates a tonal, in a graph of bandwidth frequencies of ⅓ octave.

[0026] FIG. 2—illustrates a system that comprises a frequency inverter connected to the electrical network, associated with a control block and a variable speed compressor that includes a synchronous motor.

[0027] FIG. 3—illustrates a possible embodiment of the frequency inverter associated with the synchronous motor of the variable speed compressor.

[0028] FIG. 4—illustrates a possible implementation of the power supply signal of the synchronous motor, resulting from the operation of the frequency inverter.

[0029] FIG. 5—is a representative graph, showing the performance curve of a synchronous motor as a function of the frequency of the power supply signal of the motor.

[0030] FIG. 6—is a simplified diagram of the compressor operating steps, illustrating the frequency modification of the power supply signal of the synchronous motor in relation to a time established after the alignment operation of the motor.

[0031] FIG. 7—illustrates a graph representing the hearing thresholds of the human ear, indicating the minimum intensity required in dB for a frequency to be perceived.

DETAILED DESCRIPTION OF THE FIGURES

[0032] The present invention provides means to reduce the acoustic noise generated during the first operational moments of a variable speed compressor 2, that is, during the so-called alignment phase of the motor 6. In such an alignment phase of the motor 6, at least an operation called the alignment operation of the motor 6, in which a supply signal 9, with a specific switching frequency, supplies the synchronous motor 6 for a time period T1, such period T1 is, therefore, an alignment operation period of the motor 6.

[0033] Such an alignment operation period of the motor 6 results in the alignment of the synchronous motor 6 to the magnetic field generated by the supply signal 9, which allows the subsequent operation of the synchronous motor 6 in its normal operation, that is, operation in a closed loop. This occurs because the power supply signal 9 consequently generates a magnetic field, which induces the synchronous motor 6 to align with such field since the rotor of the synchronous motor 6 is made of magnetic materials.

[0034] Therefore, after the alignment phase of the motor 6, it is observed that the synchronous motor 6 is electrically aligned to the magnetic field generated by the power supply signal 9. Consequently, the alignment phase of the motor 6 allows the mechanical position of the motor 6 to be determined as well.

[0035] The determination of the mechanical position of the aforementioned motor 6 is advantageous, for example, in applications related to the use of the motor 6 with compressors, since in such applications, it is desired to determine the mechanical position of a piston that may come to compose a compression system.

[0036] In other words, the alignment phase of the motor 6 results in two desired situations. The first refers to the determination of the electrical alignment of the motor 6, in order to enable the correct power supply of the motor and its operation in a closed loop. The second, on the other hand, refers to the mechanical alignment of the motor 6 and, consequently, the determination of the mechanical position of a piston that can comprise a compression system attached to the motor 6.

[0037] During the alignment phase of the motor 6, the noise generated by the switching frequency of the power supply of the motor 6 stands out for being characterized as a tonal noise 1 since there are no other sources of noise, once the motor is stopped.

[0038] As previously mentioned and illustrated by FIG. 1, the tonal noise is a sound, whose result of its frequency analysis, with a bandwidth of ⅓ octave, presents a frequency with a level of at least 5 dB (A) higher than the level of the adjacent frequency bands.

[0039] Referring to FIG. 2, and in a simplified way, the variable speed compressor 2, which comprises a synchronous motor 6, is electrically associated with a frequency inverter 3, said frequency inverter 3 being connected to the electrical network 4 and a control block 5.

[0040] During the operation of the compressor 2, the frequency inverter 3 is responsible for supplying the motor 6 of the compressor 2, from an intermediate source of direct current 8, with a switched signal 7 with a defined frequency, similarly to an alternating pulse 9, as shown in FIGS. 3 and 4.

[0041] Control block 5 is responsible for controlling the rotation speed of the motor 6 of the compressor 2, acting as a control system as widely used and known from the prior art.

[0042] Usually, a switching frequency of the power supply signal 9 of the motor 6 is defined after the alignment phase of the motor 6, in order to obtain the optimum performance of the compressor 2, as shown in FIG. 5. However, due to this criterion, this switching frequency used to supply the motor 6 ends up being in the human audible frequency range, that is, between 20 Hz and 20 kHz.

[0043] Thus, in order to solve the problem related to the noise generated in the alignment phase of the motor 6 of the compressor 2, the present invention provides a system and a method wherein the switching frequency of the power supply signal 9 of the motor 6 of the compressor 2 is changed only during the alignment phase of the motor.

[0044] In this scenario, and according to a preferential embodiment of the present invention, the control block 5, associated with the frequency inverter 3 and the compressor 2, is also configured to establish at least two switching frequencies (F1, F2), as shown in FIG. 6.

[0045] A first switching frequency F1 established by the control block 5 is the frequency of the power supply signal 9 during the alignment phase of the motor 6.

[0046] A second switching frequency F2 established by the control block 5 will be the frequency of the power supply signal 9 that supplies the motor 6 of the compressor 2 after the alignment phase of the motor 6.

[0047] Additionally, and still referring to FIG. 6, the control block 5 must be configured to establish a time period T1 in which the frequency inverter 3 must send the signal 9 with the first switching frequency F1 established by the control block 5. This time period T1 corresponds to the duration of the alignment phase of the 6, therefore, corresponding to an alignment operation time of the motor 6. Immediately after this time period T1, the control block 5 must indicate the change of frequency to the frequency inverter 3 so that the motor 6 of the compressor 2 is then fed with a signal 9 with the second switching frequency F2, established by the control block 5.

[0048] However, the above description should not be understood as a limitation of the present invention, so that the alignment phase of the motor 6 can comprise several alignment operations of the motor 6. That is, the time period T1 in which the alignment operation of the motor 6 can be repeated multiple times.

[0049] Such repetition may occur due to the mechanical alignment of the motor 6 to the magnetic field generated by the power supply signal 9, as previously mentioned. The determination of the mechanical position of the motor 6 can be achieved both through a single alignment operation, as well as through several alignment operations, as mentioned above since it is desired to achieve both the electrical alignment and the mechanical alignment of the motor 6.

[0050] In other words, the alignment phase of the motor 6 can comprise several alignment operations of the motor 6, in order to make it possible to obtain both the electrical alignment and the mechanical alignment of the motor 6.

[0051] According to a preferential embodiment of the invention, the first switching frequency F1 must be higher than the second switching frequency F2. Preferably, the second switching frequency F2 is defined in order to obtain the optimum operating efficiency of the compressor. In this sense, and only preferentially, the second switching frequency F2 has a value between 20 Hz and 20 kHz, more preferably, it has a value of 5 kHz.

[0052] Referring to FIG. 7, a graph representing the hearing thresholds of the human ear is illustrated, indicating the minimum necessary intensity, in dB, for a frequency to be perceived. Generally speaking, the greatest auditory sensitivity occurs between the frequencies of 2 kHz and 5 kHz, so that there is a significant loss of sensitivity as it progresses in relation to both ends of the audible frequency band. In particular, after the frequency of 12 kHz, the hearing sensitivity of the human ear is significantly reduced.

[0053] As previously mentioned, the first switching frequency F1 must be higher than the second switching frequency F2, so that it is barely perceptible, or totally imperceptible, to the human ears. In this scenario, and still referring to FIG. 6, the first switching frequency F1 can be higher than 20 kHz.

[0054] However, as shown in FIG. 7, and in accordance with the information described above, the sensitivity of the human ear is significantly reduced at frequencies above 12 kHz. Thus, when it is not technically possible to establish a first switching frequency F1 of 20 kHz, establishing the first switching frequency F1 at 12 kHz is sufficient to achieve the objectives of the present invention, that is, to significantly reduce noise generated during the alignment phase of the motor 6.

[0055] Therefore, in a preferential embodiment, the first switching frequency F1 should preferably be higher than 12 kHz. Most preferably, the first switching frequency F1 should be higher than 20 kHz.

[0056] Given the preferential configuration exposed above, it is understood that the first switching frequency F1 is located, preferably, in a non-audible region of the frequency spectrum (ultrasound) or, even more preferably, in the region barely perceptible by the human ear, according to the definition of audibility thresholds illustrated in FIG. 6. Thus, the power supply signal 9 of the motor 2 of the compressor 3, when it has such a first switching frequency F1, will not have a perceptible sound volume or at least will be practically imperceptible to the human ear.

[0057] In this sense, and according to the aforementioned preferential embodiment, the control block 5 is configured to establish the time period T1, in which, immediately after such time period T1, the frequency of the power supply signal 9 of the motor 6 is modified. This moment must be understood as the moment after the end of the alignment phase of the motor 6, that is, when the motor 6 starts to turn, operating in a closed loop.

[0058] In other words, the time period T1 indicates the length of time for which the motor 6 will be fed with a signal 9 with the first switching frequency F1. Therefore, immediately after the time period T1, and therefore, after the alignment phase of the motor 6, it will be fed with a signal 9 with the second switching frequency F2.

[0059] In addition, and in harmony with the preferential red embodiment described, the present invention also relates to a method for operation acoustic optimization a variable speed compressor 2 comprising a synchronous motor 6, the compressor 2 being electrically associated with a frequency inverter 3 and a control block 5, the method being characterized by comprising the following steps:

[0060] (a) establishing a first switching frequency F1;

[0061] (b) establishing a second switching frequency F2;

[0062] (c) establishing a time period T1, which corresponds to the duration of the alignment operation of the synchronous motor 6;

[0063] (d) supplying the synchronous motor (6) with a signal

[0064] (9) with the first switching frequency (F1) established in step (a), during the time period T1 established in step(c); and

[0065] (e) after the time period T1 established in step (c), supply the synchronous motor (6) with a signal (9) with the second switching frequency F2 established in step (b).

[0066] Thus, and in harmony with the information previously described, the control block 5 is configured to perform steps (a), (b) and (c), while steps (d) and (e), referring to a power supply to the motor 6 of the compressor 2 with the set frequency switching F1, F2, is performed by the frequency converter 3.

[0067] In addition, referring to step (a), a first switching frequency F1 is established, such first switching frequency F1 having, preferably, a value higher than 12 kHz. Most preferably, the first switching frequency F1 has a value higher than 20 kHz.

[0068] Referring to step (b), a second switching frequency F2 is established, said second switching frequency F2 having a value in the range of 20 Hz to 20 kHz. Preferably, the second switching frequency F2 has a value of 5 kHz.

[0069] Additionally, referring to step (c), the established time period T1, which corresponds to at least an alignment operation of the motor 6, can correspond to multiple alignment operations of the motor 6.

[0070] Finally, and in harmony with the information previously described, the present invention also relates to a refrigerator that comprises a system for acoustic optimization as previously described.

[0071] Advantageously, the present invention provides means to eliminate the noise generated by a variable speed compressor 2 during the alignment phase of the motor 6, not impairing the performance of compressor 2 or the thermal management of the frequency inverter 3. This is because, during the alignment of the motor 6, a first switching frequency F1 of the motor 6 is established, which has a value in the range of frequencies not audible, or barely perceptible, to humans. After such alignment, a second switching frequency F2 is used, with a value lower than the first switching frequency F1 and established in order to obtain an optimal performance of the compressor 2 and ensure the thermal management of the inverter 3.

[0072] Thus, only during the alignment phase, the compressor 2 will operate with a switching frequency that is not established and directed to obtain an optimal performance and, as it is a transitory phase, it does not have a significant impact on thermal management inverter 3. During the remaining operation of the compressor 2, in which a signal 9 with the second switching frequency F2 powers the motor 6, the performance of compressor 2 and the thermal management of the inverter 3 will be prioritized when establishing this second frequency F2.

[0073] Considering the described example of a preferential embodiment, it should be understood that the scope of the present invention covers other possible variations, being limited only by the scope of the appended claims.