JP2020153322A - Rotary compressor - Google Patents

Abstract

To prevent a refrigerant from flowing back through a communication pipe of an accumulator, to improve a circulation flow rate of the whole rotary compressor.SOLUTION: An accumulator 25 in a rotary compressor has: a vertically placed cylindrical accumulator container 26; and two communication pipes 31T and 31S whose one ends are opened to an upper part inside the accumulator container, and other ends extend from the inside to the outside of the accumulator container and are connected to an upper suction pipe and a lower suction pipe, respectively. Inside the accumulator container, the two communication pipes are provided with a cylindrical tapered part 32 whose inner diameter gradually decreases toward the other end.SELECTED DRAWING: Figure 6A

Description

The present invention relates to a rotary compressor.

As a compressor for air conditioners and refrigerators, a rotating shaft with an eccentric part is rotated by a motor, and a ring-shaped piston fitted in the eccentric part is revolved inside the cylinder to suck the refrigerant into the cylinder. A so-called rotary compressor is known.

As a related technology, in a rotary compressor, a suction pipe for supplying a refrigerant into the cylinder is provided through the compressor housing, and in order to improve the fixing means for fixing the suction pipe to the cylinder, A technique is known in which a bush whose inner diameter is gradually reduced toward the tip is inserted into a suction pipe (Patent Document 1).

In addition, as a related technology, in order to reduce fluctuations in load torque per rotation of the rotating shaft, a rotating shaft having two eccentric portions having 180 ° different phases is provided, and depending on the rotating shaft, two upper and lower cylinders are provided. In a two-cylinder rotary compressor that compresses with a piston and a piston, in order to maximize the circulation flow rate (volumetric efficiency) by effectively utilizing the resonance phenomenon in the suction pipe that communicates the accumulator and the cylinder, the two cylinders A technique for optimizing the length and cross-sectional area of the suction pipe communicating with each of them is known (Patent Document 2).

Japanese Unexamined Patent Publication No. 4-116289 Japanese Unexamined Patent Publication No. 2014-185564

In the cylinder of the rotary compressor, the refrigerant is continuously sucked over one rotation of the rotating shaft, but the suction force fluctuates during one rotation. Since the two-cylinder rotary compressor has two cylinders having a phase difference of 180 [°] in one rotation of the rotating shaft, the suction force of one cylinder is small and the suction force of the other cylinder is large. .. Therefore, a part of the refrigerant sucked into one cylinder flows back through the connecting pipe inside the accumulator and is sucked into the other cylinder, so that the circulation flow rate of the entire rotary compressor is reduced. There's a problem.

The disclosed technique has been made in view of the above, and provides a rotary compressor capable of suppressing the backflow of the refrigerant through the connecting pipe of the accumulator and improving the circulation flow rate of the entire rotary compressor. The purpose.

One aspect of the rotary compressor disclosed in the present application is a vertically placed cylindrical compressor in which a discharge pipe for discharging a refrigerant is provided at an upper portion and an upper suction pipe and a lower suction pipe for sucking the refrigerant are provided on a side surface portion. The housing, the accumulator fixed to the compressor housing and connected to the upper suction pipe and the lower suction pipe, the motor arranged in the compressor housing, and the motor located below the motor in the compressor housing and driven by the motor. It has a compression unit that sucks refrigerant from an accumulator via an upper suction pipe and a lower suction pipe, compresses it, and discharges it from a discharge pipe. The compression unit includes an annular upper cylinder, an annular lower cylinder, and an upper cylinder. On the upper end plate that closes the upper side and the lower end plate that closes the lower side of the lower cylinder, the intermediate partition plate that is placed between the upper cylinder and the lower cylinder and closes the lower side of the upper cylinder and the upper side of the lower cylinder, and the upper end plate. A rotating shaft supported by a main bearing portion provided and an auxiliary bearing portion provided on the lower end plate and rotated by a motor, and an upper eccentric portion and a lower eccentric portion provided with a phase difference between the rotating shafts. The upper piston, which is fitted to the upper eccentric part and revolves along the inner peripheral surface of the upper cylinder to form the upper cylinder chamber in the upper cylinder, and the upper piston, which is fitted to the lower eccentric part and revolves along the inner peripheral surface of the lower cylinder. The lower piston that forms the lower cylinder chamber in the lower cylinder and the upper cylinder chamber that protrudes into the upper cylinder chamber from the upper vane groove provided in the upper cylinder and comes into contact with the upper piston to divide the upper cylinder chamber into an upper suction chamber and an upper compression chamber. The accumulator includes an upper vane and a lower vane that protrudes into the lower cylinder chamber from the lower vane groove provided in the lower cylinder and abuts on the lower piston to divide the lower cylinder chamber into a lower suction chamber and a lower compression chamber. A vertically placed cylindrical accumulator container, and two that have one end open to the upper part inside the accumulator container and the other end extending from the inside to the outside of the accumulator container and connected to each of the upper suction pipe and the lower suction pipe. In a rotary compressor having a connecting pipe, the two connecting pipes inside the accumulator container are provided with a tubular tip that gradually decreases in inner diameter toward the other end side.

According to one aspect of the rotary compressor disclosed in the present application, it is possible to suppress the backflow of the refrigerant through the connecting pipe of the accumulator and improve the circulation flow rate of the entire rotary compressor.

FIG. 1 is a vertical sectional view showing a rotary compressor of an embodiment. FIG. 2 is an exploded perspective view showing a compression portion of the rotary compressor of the embodiment. FIG. 3 is a cross-sectional view for explaining the rotation of the piston in the cylinder, the suction process, and the compression process in the rotary compressor of the embodiment. FIG. 4 is a graph showing the relationship between the rotation angle of the rotation shaft and the volume change rate of the suction chamber in the rotary compressor of the embodiment. FIG. 5 is a vertical sectional view showing an accumulator included in the rotary compressor of the embodiment. FIG. 6A is a vertical sectional view for explaining a main part of the accumulator in the embodiment. FIG. 6B is a vertical sectional view for explaining a main part of the accumulator in the embodiment. FIG. 7 is a graph for explaining the energy consumption efficiency of the rotary compressor of the embodiment. FIG. 8 is a graph for explaining the input energy in the rotary compressor of the embodiment. FIG. 9 is a graph for explaining the heating capacity of the rotary compressor of the embodiment. FIG. 10 is a graph for explaining the heating period efficiency in the rotary compressor of the embodiment. FIG. 11 is a vertical cross-sectional view showing the accumulator in another embodiment. FIG. 12A is a vertical sectional view for explaining a main part of the accumulator in another embodiment. FIG. 12B is a vertical cross-sectional view for explaining a main part of the accumulator in another embodiment.

Hereinafter, examples of the rotary compressor disclosed in the present application will be described in detail with reference to the drawings. The rotary compressor disclosed in the present application is not limited by the following examples.

(Rotary compressor configuration)
FIG. 1 is a vertical sectional view showing a rotary compressor of an embodiment. FIG. 2 is an exploded perspective view showing a compression portion of the rotary compressor of the embodiment.

As shown in FIG. 1, the rotary compressor 1 is arranged in a compression unit 12 arranged at the lower part in a sealed vertical cylindrical compressor housing 10 and at an upper part in the compressor housing 10. A motor 11 for driving the compression unit 12 via a rotating shaft 15 and a vertically placed cylindrical accumulator 25 fixed to the outer peripheral surface of the compressor housing 10 are provided.

The accumulator 25 includes a vertically placed cylindrical accumulator container 26 and a low pressure introduction pipe 27 connected to the upper part of the accumulator container 26. The accumulator container 26 is connected to the upper cylinder chamber 130T (see FIG. 2) of the upper cylinder 121T via the upper suction pipe 105 and the L-shaped low pressure connecting pipe 31T, and is connected to the lower suction pipe 104 and the L-shaped low pressure connecting pipe. It is connected to the lower cylinder chamber 130S (see FIG. 2) of the lower cylinder 121S via 31S. The low pressure introduction pipe 27 is provided so as to penetrate the upper part of the accumulator container 26 and is connected to the low pressure side in the refrigeration cycle. Further, in the accumulator container 26, a filter 29 for catching foreign matter from the refrigerant supplied from the low pressure introduction pipe 27 is provided between the low pressure introduction pipe 27 and the low pressure connecting pipes 31T and 31S. Details of the accumulator 25 in this embodiment will be described later.

The motor 11 includes a stator 111 arranged on the outside and a rotor 112 arranged on the inside. The stator 111 is fixed to the inner peripheral surface of the compressor housing 10 in a shrink-fitted state, and the rotor 112 is fixed to the rotating shaft 15 in a shrink-fitted state.

In the rotating shaft 15, the lower sub-shaft portion 151 of the lower eccentric portion 152S is rotatably supported by the sub-bearing portion 161S provided on the lower end plate 160S, and the upper main shaft portion 153 of the upper eccentric portion 152T is the upper end plate. The upper piston 125T and the lower piston 125S are rotatably supported by the main bearing portion 161T provided on the 160T, and the upper eccentric portion 152T and the lower eccentric portion 152S provided with a phase difference of 180 degrees from each other, respectively. As a result, the upper piston 125T and the lower piston 125S are rotatably supported by the compression portion 12, and the upper piston 125T and the lower piston 125S revolve along the inner peripheral surface 137T of the upper cylinder 121T and the inner peripheral surface 137S of the lower cylinder 121S, respectively. Exercise.

Inside the compressor housing 10, the lubricity of the sliding portions such as the upper piston 125T and the lower piston 125S sliding in the compression portion 12 is ensured, and the upper compression chamber 133T (see FIG. 2) and the lower compression chamber 133S. In order to seal (see FIG. 2), the lubricating oil 18 is sealed in an amount that substantially immerses the compression portion 12. Mounting legs 310 (see FIG. 1) for locking a plurality of elastic support members (not shown) that support the entire rotary compressor 1 are fixed to the lower side of the compressor housing 10.

As shown in FIG. 1, the compressor housing 10 is provided with a discharge pipe 107 for discharging the refrigerant at the upper portion, and an upper suction pipe 105 and a lower suction pipe 104 for sucking the refrigerant are provided at the side surface portion. There is. The compression unit 12 compresses the refrigerant sucked from the upper suction pipe 105 and the lower suction pipe 104, and discharges the refrigerant from the discharge pipe 107. As shown in FIG. 2, the compression portion 12 has an upper end plate cover 170T, an upper end plate 160T, an annular upper cylinder 121T, an intermediate partition plate 140, and an annular shape having a bulging portion in which a hollow space is formed from above. The lower cylinder 121S, the lower end plate 160S, and the flat lower end plate cover 170S are laminated. The entire compression unit 12 is fixed by a plurality of through bolts 174, 175 and auxiliary bolts 176 arranged substantially concentrically from above and below.

As shown in FIG. 2, the upper cylinder 121T is formed with a cylindrical inner peripheral surface 137T. Inside the inner peripheral surface 137T of the upper cylinder, an upper piston 125T having an outer diameter smaller than the inner diameter of the inner peripheral surface 137 of the upper cylinder 121T is arranged, and the inner peripheral surface 137T and the outer peripheral surface 139T of the upper piston 125T are arranged. An upper compression chamber 133T that sucks in the refrigerant, compresses it, and discharges it is formed between the two. The lower cylinder 121S is formed with a cylindrical inner peripheral surface 137S. Inside the inner peripheral surface 137S of the lower cylinder 121S, a lower piston 125S having an outer diameter smaller than the inner diameter of the inner peripheral surface 137S of the lower cylinder 121S is arranged, and the inner peripheral surface 137S and the outer peripheral surface 139S of the lower piston 125S are arranged. A lower compression chamber 133S that sucks in the refrigerant, compresses it, and discharges it is formed between the two.

The upper cylinder 121T has an upper protruding portion 122T protruding in the radial direction of the cylindrical inner peripheral surface 137T from the circular outer peripheral portion. The upper protruding portion 122T is provided with an upper vane groove 128T that extends outward radially from the upper cylinder chamber 130T. The upper vane 127T is slidably arranged in the upper vane groove 128T. The lower cylinder 121S has a downward protruding portion 122S protruding in the radial direction of the cylindrical inner peripheral surface 137S from the circular outer peripheral portion. The lower side protrusion 122S is provided with a lower vane groove 128S that extends outward radially from the lower cylinder chamber 130S. The lower vane 127S is slidably arranged in the lower vane groove 128S.

The upper cylinder 121T is provided with an upper spring hole 124T at a position overlapping the upper vane groove 128T from the outer surface at a depth that does not penetrate the upper cylinder chamber 130T. An upper spring 126T is arranged in the upper spring hole 124T. The lower cylinder 121S is provided with a lower spring hole 124S at a position overlapping the lower vane groove 128S from the outer surface at a depth that does not penetrate the lower cylinder chamber 130S. A lower spring 126S is arranged in the lower spring hole 124S.

Further, in the lower cylinder 121S, the compressed refrigerant in the compressor housing 10 is introduced into the lower vane 127S by communicating the radial outside of the lower vane groove 128S and the inside of the compressor housing 10 at an opening. A lower pressure introduction path 129S that applies back pressure by the pressure of the refrigerant is formed. The compressed refrigerant in the compressor housing 10 is also introduced from the lower spring hole 124S. Further, the compressed refrigerant in the compressor housing 10 is introduced into the upper cylinder 121T by communicating the radial outside of the upper vane groove 128T and the inside of the compressor housing 10 at an opening to be introduced into the upper vane 127T. An upper pressure introduction path 129T that applies back pressure by the pressure of the refrigerant is formed. The compressed refrigerant in the compressor housing 10 is also introduced from the upper spring hole 124T.

The upper protrusion 122T of the upper cylinder 121T is provided with an upper suction hole 135T that fits with the upper suction pipe 105. The lower protrusion 122S of the lower cylinder 121S is provided with a lower suction hole 135S that fits with the lower suction pipe 104.

The upper cylinder chamber 130T is closed at the upper and lower ends by an upper end plate 160T and an intermediate partition plate 140, respectively. The lower cylinder chamber 130S is closed at the top and bottom by an intermediate partition plate 140 and a lower end plate 160S, respectively.

The upper cylinder chamber 130T is provided in the upper suction chamber 131T communicating with the upper suction hole 135T and the upper end plate 160T by the upper vane 127T being pressed by the upper spring 126T and abutting on the outer peripheral surface 139T of the upper piston 125T. It is partitioned into an upper compression chamber 133T that communicates with the upper discharge hole 190T (see FIG. 3). The lower cylinder chamber 130S is provided in the lower suction chamber 131S communicating with the lower suction hole 135S and the lower end plate 160S by the lower vane 127S being pressed by the lower spring 126S and abutting on the outer peripheral surface 139S of the lower piston 125S. It is partitioned into a lower compression chamber 133S communicating with the lower discharge hole 190S (see FIG. 3).

As shown in FIG. 2, the upper end plate 160T is provided with an upper discharge hole 190T that penetrates the upper end plate 160T and communicates with the upper compression chamber 133T of the upper cylinder 121T, and an upper discharge hole 190T is provided on the outlet side of the upper discharge hole 190T. An upper valve seat (not shown) is formed around the discharge hole 190T. The upper end plate 160T is formed with an upper discharge valve accommodating recess 164T extending in a groove shape in the circumferential direction of the upper end plate 160T from the position of the upper discharge hole 190T.

The upper discharge valve accommodating recess 164T includes a lead valve type upper discharge valve 200T and a rear end portion in which the rear end portion is fixed in the upper discharge valve accommodating recess 164T by the upper rivet 202T and the front portion opens and closes the upper discharge hole 190T. The entire upper discharge valve retainer 201T, which is overlapped with the upper discharge valve 200T and is fixed in the upper discharge valve accommodating recess 164T by the upper rivet 202T and the front part is curved (warped) to regulate the opening degree of the upper discharge valve 200T. It is contained.

The lower end plate 160S is provided with a lower discharge hole 190S that penetrates the lower end plate 160S and communicates with the lower compression chamber 133S of the lower cylinder 121S. The lower end plate 160S is formed with a lower discharge valve accommodating recess (not shown) extending in a groove shape in the circumferential direction of the lower end plate 160S from the position of the lower discharge hole 190S.

In the lower discharge valve accommodating recess, the rear end portion is fixed in the lower discharge valve accommodating recess by the lower rivet 202S, and the front portion opens and closes the lower discharge hole 190S. The entire lower discharge valve retainer 201S, which is overlapped with the valve 200S and fixed in the lower discharge valve accommodating recess by the lower rivet 202S and the front portion is curved (warped) to regulate the opening degree of the lower discharge valve 200S, is accommodated. There is.

An upper end plate cover chamber 180T is formed between the upper end plate 160T which is closely fixed to each other and the upper end plate cover 170T having a bulging portion. A lower end plate cover chamber 180S (see FIG. 1) is formed between the lower end plate 160S which is closely fixed to each other and the flat end plate cover 170S. A refrigerant passage hole 136 is provided that penetrates the lower end plate 160S, the lower cylinder 121S, the intermediate partition plate 140, the upper end plate 160T, and the upper cylinder 121T and communicates the lower end plate cover chamber 180S and the upper end plate cover chamber 180T.

The flow of the refrigerant due to the rotation of the rotating shaft 15 will be described below. In the upper cylinder chamber 130T, the upper piston 125T fitted to the upper eccentric portion 152T of the rotating shaft 15 is placed on the inner peripheral surface 137T (outer peripheral surface of the upper cylinder chamber 130T) of the upper cylinder 121T by the rotation of the rotating shaft 15. By revolving along the circumference, the upper suction chamber 131T sucks the refrigerant from the upper suction pipe 105 while expanding the volume, the upper compression chamber 133T compresses the refrigerant while reducing the volume, and the pressure of the compressed refrigerant is discharged upward. When the pressure becomes higher than the pressure of the upper end plate cover chamber 180T on the outer side of the valve 200T, the upper discharge valve 200T opens and the refrigerant is discharged from the upper compression chamber 133T to the upper end plate cover chamber 180T. The refrigerant discharged into the upper end plate cover chamber 180T is discharged into the compressor housing 10 from the upper end plate cover discharge hole 172T (see FIG. 1) provided in the upper end plate cover 170T.

Further, in the lower cylinder chamber 130S, the lower piston 125S fitted to the lower eccentric portion 152S of the rotating shaft 15 due to the rotation of the rotating shaft 15 causes the inner peripheral surface 137S of the lower cylinder 121S (the outer peripheral surface of the lower cylinder chamber 130S). ), The lower suction chamber 131S sucks the refrigerant from the lower suction pipe 104 while expanding the volume, and the lower compression chamber 133S compresses the refrigerant while reducing the volume, and the pressure of the compressed refrigerant is increased. When the pressure becomes higher than the pressure of the lower end plate cover chamber 180S on the outer side of the lower discharge valve 200S, the lower discharge valve 200S opens and the refrigerant is discharged from the lower compression chamber 133S to the lower end plate cover chamber 180S. The refrigerant discharged into the lower end plate cover chamber 180S is discharged into the compressor housing 10 from the upper end plate cover discharge hole 172T provided in the upper end plate cover 170T through the refrigerant passage hole 136 and the upper end plate cover chamber 180T. ..

The refrigerant discharged into the compressor housing 10 is a notch (not shown) provided on the outer periphery of the stator 111 that communicates vertically, a gap in the winding portion of the stator 111 (not shown), or the stator 111. It is guided above the motor 11 through the gap 115 (see FIG. 1) between the rotor 112 and the rotor 112, and is discharged from the discharge pipe 107 as a discharge portion arranged in the upper part of the compressor housing 10.

(Characteristic configuration of rotary compressor)
Next, the characteristic configuration of the rotary compressor 1 of the embodiment will be described. Features of the embodiment include the details 32 described below of the low pressure connecting pipes 31T and 31S of the accumulator 25.

Hereinafter, when simply referred to as a cylinder 121, it refers to both the upper cylinder 121T and the lower cylinder 121S, and when it is simply referred to as a piston 125, it refers to both the upper piston 125T and the lower piston 125S. Similarly, when simply referred to as the suction chamber 131, it refers to both the upper suction chamber 131T and the lower suction chamber 131S, and when simply referred to as the compression chamber 133, it refers to both the upper compression chamber 133T and the lower compression chamber 133S. .. Further, when it is simply referred to as a suction hole 135, it refers to both the upper suction hole 135T and the lower suction hole 135S, and when it is simply referred to as a vane 127, it refers to both the upper vane 127T and the lower vane 127S.

First, it will be described that the circulation flow rate of the entire rotary compressor 1 is reduced due to the influence of the flow of each other's refrigerant gas in each suction step in the two upper cylinders 121T and the lower cylinder 121S.

FIG. 3 is a cross-sectional view for explaining the rotation of the piston 125 in the cylinder 121, the suction process, and the compression process in the rotary compressor 1 of the embodiment. FIG. 3 shows, as an example, how the refrigerant is sucked and compressed as the volume of the upper suction chamber 131T of the upper cylinder 121T increases. Further, FIG. 3 shows a state in which the rotation angle of the upper piston 125T changes in the order of 0 degree, 90 degree, 180 degree, 270 degree, 360 degree (0 degree) in every 90 degree. That is, FIG. 3 shows changes in the sizes of the upper suction chamber 131T and the upper compression chamber 133T in the upper cylinder 121T with the rotation angle of the rotating shaft 15.

As shown in FIG. 3, the rotation angle of the rotating shaft 15 when the piston 125 pushes the vane 127 most into the cylinder 121 is set to 0 [°]. When the rotation angle is 0 [°], it is immediately before the suction chamber 131 shifts to the compression chamber 133, and the compression chamber 133 is reduced to a position where the volume becomes zero. When the rotation angle is 90 [°], the suction chamber 131 at the rotation angle of 0 ° is cut off from the suction hole 135 and becomes the compression chamber 133 as it is to start the compression of the refrigerant, and is newly communicated with the suction hole 135. A suction chamber 131 is formed, and suction of the refrigerant into the suction chamber 131 is started. When the rotation angle is 180 [°] and 270 [°], the suction chamber 131 further expands and the suction of the refrigerant proceeds. When the rotation angle is further rotated by 90 [°] from 270 [°], the rotation angle returns to the state of 0 [°], and the volume of the suction chamber 131 becomes maximum during one rotation of the rotation shaft 15.

FIG. 4 is a graph showing the relationship between the rotation angle of the rotating shaft 15 and the volume change rate of the suction chamber 131 in the rotary compressor 1 of the embodiment. In FIG. 4, the vertical axis shows the volume change rate [mm ³ / deg] of the suction chamber 131, and the rotation angle [°] of the rotation shaft 15. Further, in FIG. 4, the volume change rate of the upper suction chamber 131T of the upper cylinder 121T is shown by a solid line, and the volume change rate of the lower suction chamber 131S of the lower cylinder 121S is shown by a broken line. In FIG. 4, as an example of the two-cylinder rotary compressor 1, the rotation angle of the rotating shaft 15 is 10 [cc] when the maximum volume of the suction chamber 131 of each cylinder 121 during one rotation of the rotating shaft 15 is 10 [cc]. The volume change rate of the suction chamber 131 of each cylinder 121 per 1 [°] is shown. That is, when the volume change rate is large, the volume of the suction chamber 131 changes more rapidly than when the volume change rate is small.

As shown in FIG. 4, when the volume of the suction chamber 131 increases with the rotation of the rotating shaft 15, the rate of change in the volume of the suction chamber 131 with respect to the rotation angle of the rotating shaft 15 is during one rotation of the rotating shaft 15. It fluctuates greatly. The volume change rate is the largest when the rotation angle of the rotation shaft 15 is 180 [°], and the volume change rate becomes zero when the rotation angle is near 0 [°]. Further, as shown in FIG. 4, the volume change rate of the lower suction chamber 131S of the lower cylinder 121S is 180 [°] in one rotation of the rotating shaft 15 with the volume change rate of the upper suction chamber 131T of the upper cylinder 121T described above. ] It will change in a shifted state.

Next, the influence of the change in the volume of the suction chamber 131 during one rotation of the rotating shaft 15 on the inside of the accumulator container 26 and the flow of the refrigerant in the low-pressure connecting pipes 31T and 31S will be described.

Considering the average behavior of the rotating shaft 15 in one rotation, the refrigerant is supplied from the refrigeration cycle to the inside of the accumulator container 26 through the low pressure introduction pipes 31T and 31S, and further communicates with each other from the inside of the accumulator container 26. Refrigerant is supplied to the two suction chambers 131 through the low pressure communication pipes 31T and 31S, the lower suction pipe 104, and the upper suction pipe 105. However, when the rotation angle of the rotating shaft 15 is 0 [°] shown in FIG. 3, since the volume change of the upper suction chamber 131T of the upper cylinder 121T is zero, there is no suction force and the lower cylinder 121S is lower. Since the volume change of the suction chamber 131S is the maximum during one rotation of the rotating shaft 15, the suction force is maximum during one rotation of the rotating shaft 15. Due to the influence of the relationship between the suction force of the upper suction chamber 131T and the suction force of the lower suction chamber 131S, the refrigerant inside the accumulator container 26 when the rotation angle of the rotation shaft 15 shown in FIG. 3 is 0 [°]. Is sucked from the low pressure connecting pipe 31S communicating with the lower suction chamber 131S of the lower cylinder 121S.

In order to replenish the refrigerant sucked from the low pressure connecting pipe 31S communicating with the lower suction chamber 131S of the lower cylinder 121S, the refrigerant is sucked into the inside of the accumulator container 26 from the low pressure introduction pipe 27 through the filter 29, and at the same time. Since there is no suction force of the upper suction chamber 131T of the upper cylinder 121T when the rotation angle of the rotating shaft 15 shown in FIG. 3 is 0 [°], the low pressure connecting pipe 31T communicating with the upper suction chamber 131T of the upper cylinder 121T is passed through. The refrigerant is also sucked from the upper suction chamber 131T of the upper cylinder 121T.

That is, the rotation angle of the rotating shaft 15 becomes 0 [°], and as shown in FIG. 3, immediately before the upper suction chamber 131T of the upper cylinder 121T is cut off from the upper suction hole 135T and becomes an independent upper compression chamber 133T. The refrigerant once sucked into the upper suction chamber 131T of the upper cylinder 121T flows back through the upper suction pipe 105 and the low pressure connecting pipe 31T communicating with the upper cylinder 121T, and is sucked into the lower suction chamber 131S of the lower cylinder 121S. Cylinder. On the other hand, when the rotation angle of the rotating shaft 15 shown in FIG. 3 is 180 [°], the refrigerant in the lower suction chamber 131S of the lower cylinder 121S becomes the lower cylinder 121S, contrary to the backflow in the upper cylinder 121T described above. The lower suction pipe 104 and the low pressure connecting pipe 31S that communicate with each other flow back and are sucked from the inside of the accumulator container 26 into the upper suction chamber 131T of the upper cylinder 121T via the low pressure connecting pipe 31T.

As described above, the backflow phenomenon in the upper suction pipe 105, the lower suction pipe 104, and the low pressure connecting pipes 31T and 31S is immediately before the suction chamber 131 of the cylinder 121 is shut off from the suction hole 135 and is transferred to the compression chamber 133. growing. For this reason, immediately before the transition from the suction chamber 131 to the compression chamber 133, the density of the refrigerant in the suction chamber 131 is lowered, which causes a decrease in the circulation flow rate of the entire rotary compressor 1. In this embodiment, in order to prevent the refrigerant from flowing back through the low pressure connecting pipes 31T and 31S of the accumulator 25, the detailed 32 described later is provided in the low pressure connecting pipes 31T and 31S.

(Low pressure connecting pipe of accumulator)
FIG. 5 is a vertical sectional view showing an accumulator 25 included in the rotary compressor 1 of the embodiment. As shown in FIG. 5, the accumulator 25 has low pressure connecting pipes 31T and 31S as two connecting pipes. The low-pressure connecting pipes 31T and 31S are formed in a circular pipe having a circular cross section. The inner diameter of the low pressure connecting pipe 31T and the inner diameter of the low pressure connecting pipe 31S are equal to each other. The accumulator container 26 of the accumulator 25 is composed of a pair of upper container 26a and lower container 26b in combination, and supports low-pressure connecting pipes 31T and 31S at a connecting portion between the upper container 26a and the lower container 26b. A plate 26c is provided.

The low-pressure connecting pipe 31T has an upper end at one end open to the upper part inside the accumulator container 26, and the lower end at the other end extends from the inside to the outside of the accumulator container 26 and is connected to the upper suction pipe 105. .. Similarly, the low pressure connecting pipe 31S has an upper end at one end open to the upper part inside the accumulator container 26, and the lower end at the other end extends from the inside to the outside of the accumulator container 26 and is connected to the lower suction pipe 104. ing. For example, the low-pressure connecting pipe 31T and the low-pressure connecting pipe 31S may be configured by connecting two upper connecting pipes and a lower connecting pipe at the lower part of the accumulator container 26. Further, the lower end of the low pressure connecting pipe 31T and the lower end of the low pressure connecting pipe 31S may penetrate the lower portion of the accumulator container 26.

Inside the accumulator container 26, inside each of the two low-pressure connecting pipes 31T and 31S, a cylindrical tip 32 whose inner diameter gradually decreases from the upper end side to the lower end side is provided. By providing the tip details 32 inside the low pressure connecting pipes 31T and 31S, the refrigerant passing through the tip of the tip details 32 when the refrigerant flows back through the low pressure connecting pipes 31T and 31S into the accumulator container 26. Since the flow resistance of the refrigerant increases, it is possible to prevent the refrigerant from flowing back through the low-pressure connecting pipes 31T and 31S.

The low-pressure connecting pipe 31T has an L-shaped first connecting pipe 31a which is continuously formed from the upper end to the tip 32 and is connected to the lower part of the accumulator container 26 and to the upper suction pipe 105. It has a second connecting pipe 31b. Similarly, the low pressure connecting pipe 31S is connected to the straight tubular first connecting pipe 31a formed continuously from the upper end to the tip 32, and the lower part of the accumulator container 26 and the lower suction pipe 104. It has a character-shaped second connecting pipe 31b and. The tip detail 32 provided at the lower end of the first connecting pipe 31a is inserted into the upper end of the second connecting pipe 31b to connect the first connecting pipe 31a and the second connecting pipe 31b. There is.

Further, the two low-pressure connecting pipes 31T and 31S have a plurality of liquid return holes 34 that communicate the inside of the respective low-pressure connecting pipes 31T and 31S with the inside of the accumulator container 26. In the accumulator 25, the liquid refrigerant in the accumulator container 26 is connected at low pressure by sucking the liquid refrigerant little by little into the low pressure connecting pipes 31T and 31S through the plurality of liquid return holes 34 of the low pressure connecting pipes 31T and 31S. It increases beyond the position of the opening at the upper end of the pipes 31T and 31S, and prevents a large amount of liquid refrigerant from suddenly flowing into the low pressure connecting pipes 31T and 31S.

The detail 32 of each of the low pressure connecting pipes 31T and 31S is provided below the liquid return hole 34 located at the lowermost position among the plurality of liquid return holes 34. As a result, the function of the liquid return hole 34 is suppressed from being deteriorated, and the low pressure connecting pipes 31T and 31S are divided into the first connecting pipe 31a and the second connecting pipe 31b to form the first connecting pipe 31a and the second connecting pipe 31a. The pipes 31b can be easily formed, respectively, and the workability of the low-pressure connecting pipes 31T and 31S having the tip details 32 is improved. Although not shown, the tip (lower end) of the tip detail 32 may extend to the outside of the lower part of the accumulator container 26.

FIG. 6A is a vertical sectional view for explaining a main part of the accumulator 25 in the embodiment. FIG. 6B is a vertical sectional view for explaining a main part of the accumulator 25 in the embodiment.

As shown in FIG. 6A, the two low pressure connecting pipes 31T and 31S have a flow path cross section of the inner surface of the tip detail 32 at the tip of the tip detail 32 of S1 [mm ² ], and the low pressure communication at the position of the tip of the tip detail 32. Let the flow path cross section of the inner surfaces of the pipes 31T and 31S be S2 [mm ² ].
S2 × 0.4 ≦ S1 ≦ S2 × 0.7 ・ ・ ・ ・ (Equation 1)
Meet. Here, the tip of the tip detail 32 refers to the lower end having the smallest inner diameter of the tip detail 32.

When S2 × 0.4> S1, the flow path cross-sectional area S1 at the tip of the tip 32 becomes too small, so that the flow resistance in the normal flow of the refrigerant from the accumulator container 26 toward the suction chamber 131 of the cylinder 121. Is not preferable because the density of the refrigerant sucked into the cylinder 121 decreases, which causes a decrease in the circulation flow rate of the entire rotary compressor 1. On the other hand, when S1> S2 × 0.7, the cross-sectional area S1 of the flow path at the tip of the tip 32 becomes too large, so that the effect of suppressing the backflow from the suction chamber 131 of the cylinder 121 into the accumulator container 26 is small. It is not preferable because it becomes. Therefore, the size of the flow path cross-section S1 at the tip of the tip 32 has an appropriate range, and the flow path breakage at the tip of the tip 32 with respect to the flow path cross section S2 of the straight pipe portion of the low-pressure connecting pipe 31. Since the area S1 is optimized when the equation 1 is satisfied, it is possible to effectively increase the circulation flow rate of the entire rotary compressor 1.

Further, as shown in FIG. 6B, in the tip detail 32, the inner diameter at the tip of the tip detail 32 is D1 [mm], and the length in the refrigerant flow direction (tube axial direction) in the tip detail 32 is L [mm].
D1 ≤ L ... (Equation 2)
Meet.

When D1> L, the diameter reduction ratio of the tip 32 becomes too large in the direction of the normal refrigerant flow in the low pressure connecting pipes 31T and 31S, so that the normal flow from the inside of the accumulator container 26 toward the suction chamber 131 of the cylinder 121. The flow resistance of the refrigerant increases, the density of the refrigerant sucked into the cylinder 121 decreases, and the circulation flow rate of the entire rotary compressor 1 decreases, which is not preferable. Therefore, when the shape (diameter reduction ratio) of the tip 32 satisfies Equation 2, the flow resistance of the refrigerant flowing through the low pressure connecting pipes 31T and 31S from the inside of the accumulator container 26 toward the cylinder 121 is reduced, and the rotary compressor 1 is used. It is possible to effectively increase the overall circulating flow rate.

The detail 32 of the low pressure connecting pipes 31T and 31S in this embodiment satisfies both of the formulas 1 and 2, but by satisfying only one of the formulas 1 and 2, the refrigerant is the low pressure connecting pipes 31T and 31S. Since the backflow of the rotary compressor 1 is suppressed, the effect of improving the circulation flow rate of the entire rotary compressor 1 can be obtained.

(Comparison between Examples and Comparative Examples)
The low-pressure connecting pipe 31 of the embodiment having the detail 32 (hereinafter, when simply referred to as the low-pressure connecting pipe 31, both the low-pressure connecting pipes 31T and 31S are referred to) and the comparative example having a straight shape which is a straight pipe. The result of comparison with the low pressure connecting pipe will be described. Here, a heating operation in a refrigeration cycle device including the rotary compressor 1 will be described as an example. In FIGS. 7 to 9, examples are shown by solid lines, and comparative examples are shown by broken lines.

FIG. 7 is a graph for explaining the energy consumption efficiency (COP) in the rotary compressor 1 of the embodiment. In FIG. 7, the vertical axis represents the primary COP, and the horizontal axis represents the rotation speed [rps] of the rotary compressor 1. As shown in FIG. 7, the primary COP in the examples is improved as compared with the comparative example.

FIG. 8 is a graph for explaining the input energy in the rotary compressor 1 of the embodiment. In FIG. 8, the vertical axis represents the input energy [W / (cc · rev)], and the horizontal axis represents the rotation speed [rps] of the rotary compressor 1. As shown in FIG. 8, in the embodiment, the input energy [W / (cc · rev)] input for the heating operation is smaller than that in the comparative example.

FIG. 9 is a graph for explaining the heating capacity of the rotary compressor 1 of the embodiment. In FIG. 9, the vertical axis represents the heating capacity [kW], and the horizontal axis represents the rotation speed [rps] of the rotary compressor 1. As shown in FIG. 9, the heating capacity [kW] in the examples is higher than that in the comparative example.

FIG. 10 is a graph for explaining the heating period efficiency in the rotary compressor 1 of the embodiment. As shown in FIG. 10, when the heating period efficiency is set to 100% in the comparative example having the straight-shaped connecting pipe of the comparative example, the example having the tapered low-pressure connecting pipe 31 having the taper 32 is 100. Improves to 0.6%. Although the comparison results during the heating operation are shown in FIGS. 7 to 10, the same effect can be obtained during the cooling operation.

(Effect of Examples)
As described above, the accumulator 25 in the rotary compressor 1 of the embodiment has an inner diameter gradually decreasing from the upper end side to the lower end side inside each of the two low pressure connecting pipes 31T and 31S inside the accumulator container 26. A tubular tip 32 is provided. Therefore, the detail 32 can prevent the refrigerant from flowing back from the suction chamber 131 of the cylinder 121 toward the inside of the accumulator container 26 in the low pressure connecting pipe 31. As a result, it is possible to reduce the loss caused by the interference of the refrigerant gas flows with each other in each suction step of the two cylinders 121, and improve the circulation flow rate of the entire rotary compressor 1.

Further, the two low-pressure connecting pipes 31T and 31S of the accumulator 25 in the rotary compressor 1 of the embodiment have the flow path cross section of the inner surface of the tip detail 32 at the tip of the tip detail 32 at the position of S1 and the tip end of the tip detail 32. S2 × 0.4 ≦ S1 ≦ S2 × 0.7 ... (Equation 1) is satisfied, where S2 is the cross-sectional area of the flow path on the inner surface of the low-pressure connecting pipe 31. As a result, in consideration of the trade-off between the flow resistance in the normal flow rate of the refrigerant from the inside of the accumulator container 26 toward the cylinder 121 and the flow resistance in the backflow of the refrigerant from the cylinder 121 toward the inside of the accumulator container 26, the detail 32 Since the flow path cross-sectional area S1 at the tip is formed to an appropriate size, the circulating flow rate of the entire rotary compressor 1 can be effectively increased.

Further, in the tip detail 32 of the low pressure connecting pipe 31 of the accumulator 25 in the embodiment, D1 ≦ L ... (L), where D1 is the inner diameter at the tip of the tip detail 32 and L is the length in the flow direction of the refrigerant in the tip detail 32. Equation 2) is satisfied. As a result, the flow resistance of the refrigerant flowing through the low-pressure connecting pipes 31T and 31S from the inside of the accumulator container 26 toward the cylinder 121 can be reduced, and the circulating flow rate of the entire rotary compressor 1 can be effectively increased.

Further, each of the two low-pressure communication pipes 31T and 31S of the accumulator 25 in the rotary compressor 1 of the embodiment has a liquid return hole 34 that communicates the inside of the low-pressure communication pipe 31 and the inside of the accumulator container 26. The tip 32 is provided below the accumulator hole 34. As a result, it is possible to suppress the deterioration of the function of the liquid return hole 34 and to easily form the low-pressure connecting pipes 31T and 31S having the tip detail 32 by dividing the tip detail 32 as a boundary. The workability of the low pressure connecting pipes 31T and 31S having the detail 32 can be improved.

Further, each of the two low-pressure connecting pipes 31T and 31S of the accumulator 25 in the rotary compressor 1 of the embodiment is formed on the first connecting pipe 31a continuously formed from one end to the tip 32, and on the lower part of the accumulator container 26. It has a second connecting pipe 31b that is connected and connected to each of the upper suction pipe 105 and the lower suction pipe 104, and the tip detail 32 is inserted into the second connecting pipe 31b to form the first connecting pipe. The 31a and the second connecting pipe 31b are connected. As a result, the low-pressure connecting pipes 31T and 31S can be divided into the first connecting pipe 31a and the second connecting pipe 31b, and the first connecting pipe 31a and the second connecting pipe 31b can be easily formed, respectively. The tip 32 can be easily formed inside the low pressure connecting pipes 31T and 31S.

Hereinafter, other examples will be described with reference to the drawings. In another embodiment, the same components as those in the above-described embodiment are designated by the same reference numerals as those in the above-described embodiment, and the description thereof will be omitted. The other embodiment is different from the embodiment in that the low pressure connecting pipe 31 of the accumulator 25 has a plurality of details.

(Other Examples)
FIG. 11 is a vertical cross-sectional view showing the accumulator 25 in another embodiment. FIG. 12A is a vertical sectional view for explaining a main part of the accumulator 25 in another embodiment. FIG. 12B is a vertical sectional view for explaining a main part of the accumulator 25 in another embodiment.

Each of the low-pressure connecting pipes 31T and 31S of the accumulator 25 in the other embodiment has a second detail 33 provided on the upper end side in addition to the first detail 32 which is the detail 32 in the above-described embodiment. That is, each of the two low-pressure connecting pipes 31T and 31S is provided with a first detail 32 and a second detail 33 as a plurality of details between the upper end and the lower part of the accumulator container 26.

The low-pressure connecting pipe 31T is an L-shape connected to the straight tubular first connecting pipe 31a formed continuously from the upper end to the first detail 32, the lower part of the accumulator container 26, and the upper suction pipe 105. It has a second connecting pipe 31b having a shape, and a straight tubular third connecting pipe 31c formed continuously from the upper end to the second detail 33. Similarly, the low pressure connecting pipe 31S is connected to the straight tubular first connecting pipe 31a formed continuously from the upper end to the first detail 32, the lower part of the accumulator container 26, and the lower suction pipe 104. It has an L-shaped second connecting pipe 31b and a straight tubular third connecting pipe 31c formed continuously from the upper end to the second detail 33.

The first detail 32 provided at the lower end of the first connecting pipe 31a is inserted into the upper end of the second connecting pipe 31b to connect the first connecting pipe 31a and the second connecting pipe 31b. Has been done. The second detail 33 provided at the lower end of the third connecting pipe 31c is inserted into the upper end of the first connecting pipe 31a to connect the third connecting pipe 31c and the first connecting pipe 31a. Has been done.

The first detail 32 in each of the low pressure connecting pipes 31T and 31S satisfies the above equations 1 and 2, respectively. The second detail 33 also satisfies the equations 1 and 2, respectively, as in the case of the first detail 32.

That is, as shown in FIG. 12A, the two low-pressure connecting pipes 31T and 31S have a flow path cross section of the inner surface of the second tip detail 33 at the tip of the second tip detail 33 S1 [mm ² ] and the second tip detail 33. Let the flow path cross section of the inner surfaces of the low pressure connecting pipes 31T and 31S at the position of the tip of 33 be S2 [mm ² ].
S2 × 0.4 ≦ S1 ≦ S2 × 0.7 ・ ・ ・ ・ (Equation 1)
Meet.

Similar to the first detail 32, it is optimized when the flow path cross section S1 at the tip of the second detail 33 satisfies the equation 1 with respect to the flow path cross section S2 of the straight pipe portion of the low pressure connecting pipe 31. Therefore, it is possible to effectively increase the circulation flow rate of the entire rotary compressor 1.

Similarly, as shown in FIG. 12B, the second detail 33 has an inner diameter of D1 [mm] at the tip of the second detail 33 and a length in the flow direction (tube axis direction) of the refrigerant in the second detail 33. Let L [mm] be
D1 ≤ L ... (Equation 2)
Meet.

Similar to the first detail 32, the shape (diameter reduction ratio) of the second detail 33 satisfies the equation 2, so that the flow rate of the refrigerant flowing from the accumulator container 26 toward the cylinder 121 through the low pressure connecting pipes 31T and 31S It is possible to reduce the resistance and effectively increase the circulating flow rate of the entire rotary compressor 1.

The position of the second detail 33 inside the accumulator container 26 is not limited, and may be arranged at the center between the upper end and the lower end of the low pressure connecting pipes 31T and 31S, if necessary. Further, the number of details of the low-pressure connecting pipes 31T and 31S is not limited, and a third detail may be provided, and a plurality of low-pressure connecting pipes 31T and 31S may be provided while suppressing an increase in flow resistance in each detail. The overall flow resistance due to the details may be increased. Further, in this case, since the diameter reduction ratio of each tip detail can be suppressed to be small, the workability of each tip detail can be improved.

In another embodiment, the low pressure connecting pipe 31 includes the first detail 32 and the second detail 33, so that the refrigerant can be prevented from flowing back through the low pressure connecting pipe 31 of the accumulator 25. As a result, it is possible to reduce the loss caused by the interference of the refrigerant gas flows with each other in each suction step of the two cylinders 121, and improve the circulation flow rate of the entire rotary compressor 1.

Further, since the low pressure connecting pipe 31 has a plurality of tips, the desired flow resistance when the refrigerant flows back is ensured by the plurality of tips while avoiding an increase in the diameter reduction ratio of the individual tips. However, it becomes possible to appropriately suppress the backflow of the refrigerant. Further, according to another embodiment, by having the first tip detail 32 and the second tip detail 33 so as to obtain the same effect as the structure having only the first tip detail 32, one tip detail is reduced. It is possible to reduce the diameter ratio and improve the workability of each detail. It should be noted that the plurality of details may have different diameter reduction ratios, if necessary.

1 Rotary compressor 10 Compressor housing 11 Motor 12 Compressor 15 Rotating shaft 25 Accumulator 26 Accumulator container 27 Low-pressure introduction pipe 31T, 31S Low-pressure connecting pipe (connecting pipe)
31a 1st connecting pipe 31b 2nd connecting pipe 32 Tip detail, 1st tip detail 33 2nd tip detail 34 Liquid return hole 105 Upper suction pipe 104 Lower suction pipe 107 Discharge pipe 111 stator 112 Rotor 121T Upper cylinder 121S Lower cylinder 125T Upper Piston 125S Lower piston 127T Upper vane 127S Lower vane 128T Upper vane groove 128S Lower vane groove 130T Upper cylinder chamber 130S Lower cylinder chamber 131T Upper suction chamber 131S Lower suction chamber 133T Upper compression chamber 133S Lower compression chamber 140 Intermediate partition plate 151 Sub-shaft 152T Upper eccentric part 152S Lower eccentric part 153 Main shaft part 160T Upper end plate 160S Lower end plate 161T Main bearing part 161S Sub-bearing part

Claims (6)

A vertically placed cylindrical compressor housing in which a discharge pipe for discharging the refrigerant is provided at the upper part and an upper suction pipe and a lower suction pipe for sucking the refrigerant are provided on the side surface and is fixed to the compressor housing. An accumulator connected to the upper suction pipe and the lower suction pipe, a motor arranged in the compressor housing, and the upper suction pipe and the motor arranged below the motor in the compressor housing and driven by the motor. It has a compression unit that sucks the refrigerant from the accumulator through the lower suction pipe, compresses it, and discharges it from the discharge pipe.
The compression unit is
An annular upper cylinder and an annular lower cylinder,
An upper end plate that closes the upper side of the upper cylinder and a lower end plate that closes the lower side of the lower cylinder,
An intermediate partition plate that is arranged between the upper cylinder and the lower cylinder and closes the lower side of the upper cylinder and the upper side of the lower cylinder.
A rotating shaft supported by a main bearing portion provided on the upper end plate and an auxiliary bearing portion provided on the lower end plate and rotated by the motor.
An upper eccentric portion and a lower eccentric portion provided on the rotating shaft with a phase difference from each other,
An upper piston that is fitted into the upper eccentric portion and revolves along the inner peripheral surface of the upper cylinder to form an upper cylinder chamber in the upper cylinder.
A lower piston that is fitted into the lower eccentric portion and revolves along the inner peripheral surface of the lower cylinder to form a lower cylinder chamber in the lower cylinder.
An upper vane that protrudes into the upper cylinder chamber from the upper vane groove provided in the upper cylinder and abuts on the upper piston to partition the upper cylinder chamber into an upper suction chamber and an upper compression chamber.
It is provided with a lower vane that protrudes into the lower cylinder chamber from the lower vane groove provided in the lower cylinder and abuts on the lower piston to partition the lower cylinder chamber into a lower suction chamber and a lower compression chamber.
The accumulator
Vertically placed cylindrical accumulator container and
One end opens to the upper part inside the accumulator container, and the other end extends from the inside to the outside of the accumulator container and is connected to each of the upper suction pipe and the lower suction pipe. In the rotary compressor that has
A rotary compressor in which the two connecting pipes inside the accumulator container are provided with tubular tips whose inner diameter gradually decreases toward the other end side. In the two connecting pipes, the flow path cross section of the inner surface of the tip at the tip of the tip is S1, and the flow path cross section of the inner surface of the connecting pipe at the position of the tip of the tip is S2.
S2 × 0.4 ≦ S1 ≦ S2 × 0.7
The rotary compressor according to claim 1. In the detail, the inner diameter at the tip of the detail is D1, and the length in the flow direction of the refrigerant in the detail is L.
D1 ≤ L
The rotary compressor according to claim 1 or 2, which satisfies the above conditions. The two connecting pipes have a liquid return hole that communicates the inside of the connecting pipe and the inside of the accumulator container.
The rotary compressor according to any one of claims 1 to 3, wherein the details are provided below the liquid return hole. The two connecting pipes are connected to a first connecting pipe continuously formed from one end to the fine details, to the lower part of the accumulator container, and to each of the upper suction pipe and the lower suction pipe. Any of claims 1 to 4, wherein the second connecting pipe is provided, and the details are inserted into the second connecting pipe to connect the first connecting pipe and the second connecting pipe. The rotary compressor according to item 1. The rotary compressor according to any one of claims 1 to 3, wherein the two connecting pipes are provided with a plurality of the details between the one end and the lower portion of the accumulator container.

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