JP5712775B2 - accumulator - Google Patents

Description

  The present invention relates to an accumulator disposed between an evaporator and a compressor of a refrigeration cycle.

  In the vapor compression (heat pump type) refrigeration cycle, an accumulator is disposed in the refrigerant flow path between the evaporator and the compressor. The accumulator basically has a function of supplying a gas refrigerant to the compressor in order to prevent liquid compression of the compressor, and a function of returning oil circulating through the refrigeration cycle together with the refrigerant to the compressor. One conventional example of an accumulator having such a function is shown in FIG. 4 (see Patent Document 1).

  In FIG. 4, the accumulator 50 includes a case 52 having a liquid storage chamber 51, a refrigerant inlet 53 for supplying a refrigerant to the liquid storage chamber 51, a double outlet pipe 54 disposed in the center of the liquid storage chamber 51, Between the rectifying member 60 disposed above the liquid chamber 51, the two resistance plates 61 and 62 disposed at an interval below the liquid storage chamber 51, and the two resistance plates 61 and 62. And a desiccant (not shown) contained in the space. Each of the resistance plates 61 and 62 is formed with a refrigerant communication hole (not shown). Thereby, the refrigerant can freely flow in and out between the upper and lower spaces of the two resistance plates 61 and 62.

  The double outlet pipe 54 has an inner pipe 55, an outer pipe 56 and a pipe holder 57. An upper end opening surrounded by the inner pipe 55 and the outer pipe 56 is formed as a refrigerant outlet 58. The refrigerant outlet 58 protrudes into the internal space of the rectifying member 60. The pipe holder 57 is disposed at the lowest end position of the liquid storage chamber 51. An oil return hole 59 is formed in the pipe holder 57. The oil return hole 59 communicates with the liquid storage chamber 51 via a filter 65 and the like.

  In the above configuration, the refrigerant supplied from the refrigerant inlet 53 flows down along the rectifying member 60. The gas refrigerant having a light specific gravity among the refrigerants flowing down along the flow regulating member 60 is located above the liquid storage chamber 51, but the liquid refrigerant having a high specific gravity flows down and accumulates below the liquid storage chamber 51. Since the refrigerant outlet 58 is located above the liquid storage chamber 51, the refrigerant outlet sucks in the gas refrigerant, and the gas refrigerant is sent to a compressor (not shown). The liquid refrigerant that accumulates in the lower portion of the liquid storage chamber 51 is agitated by dropping from the rectifying member 60 or the like, and the liquid refrigerant and oil are mixed by this agitation. The liquid refrigerant mixed with oil is returned from the oil return hole 59 to the compressor (not shown).

  The refrigerant supplied to the liquid storage chamber 51 absorbs moisture by a desiccant (not shown) between the two resistance plates 61 and 62.

JP 2008-32269 A

  However, in the conventional accumulator 50, a desiccant (not shown) is accommodated at a position below the rectifying member 60. The lower position of the rectifying member 60 is a space for separating the refrigerant from gas and liquid. If there is a desiccant in the space, the liquid storage chamber 51 is enlarged by the amount of the space for accommodating the desiccant.

  The refrigerant outlet 58 and the resistance plate 61 have poor gas-liquid separation properties unless they are arranged with a certain distance. If the refrigerant outlet 58 and the resistance plate 61 are installed at a large distance and a storage space for a desiccant is further provided below the resistance plate 61, the liquid storage chamber 51 is further increased in size. The increase in the size of the liquid storage chamber 51 is directly linked to the increase in the size of the accumulator 50.

  Therefore, the present invention has been made to solve the above-described problems, and an object of the present invention is to provide an accumulator that can be miniaturized without reducing the gas-liquid separation property of the refrigerant.

The present invention includes a liquid storage chamber capable of storing a refrigerant, a refrigerant inlet that supplies the refrigerant to the liquid storage chamber, a refrigerant outlet that opens to an upper portion of the liquid storage chamber and discharges the refrigerant in the liquid storage chamber, A rectifying member disposed below the refrigerant inlet of the liquid storage chamber, the refrigerant supplied from the refrigerant inlet flowing on the outer surface side to form a predetermined refrigerant flow, and housed in an internal space of the rectifying member A desiccant, and an upper surface of the flow regulating member is provided with an attachment portion to the upper surface wall of the liquid storage chamber and a groove for guiding a refrigerant to a side peripheral surface of the liquid storage chamber. Is located at the upper end of the groove and fixed in contact with the upper wall of the liquid storage chamber .

The groove preferably includes a turning groove for flowing the refrigerant supplied from the refrigerant inlet in the turning direction.

  The side circumferential surface of the liquid storage chamber is preferably a circumferential surface.

  The liquid storage chamber is preferably provided with an agitation promoting portion.

  According to the present invention, the internal space of the rectifying member is a dead space that does not contribute to the gas-liquid separation of the refrigerant. Since the desiccant is accommodated in this space, the size can be reduced without reducing the gas-liquid separation of the refrigerant. .

1 is a perspective view of an accumulator according to a first embodiment of the present invention. 1 shows a first embodiment of the present invention and is a cross-sectional view of an accumulator. FIG. FIG. 2 is a plan view of a turning deflection unit according to the first embodiment of the present invention. It is sectional drawing of the accumulator of a prior art example.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 to 3 show an embodiment of the present invention. 1 and 2, the accumulator 1 includes a case 3 having a liquid storage chamber 2, a refrigerant supply pipe 4 that supplies a refrigerant to the liquid storage chamber 2, and a refrigerant discharge pipe that discharges the refrigerant in the liquid storage chamber 2. 5, a rectifying member 10 that generates a swirling flow that is a predetermined flow in the refrigerant supplied from the refrigerant supply pipe 4, a closing member 20 that closes the lower surface of the case 3, and the closing member 20 are provided integrally. An interference projecting wall 21 which is an agitation promoting part for agitating the swirling refrigerant generated in the rectifying member 10 in the vertical direction, and a desiccant 30 for absorbing moisture from the refrigerant are provided.

  The case 3 has a cylindrical shape whose upper surface is closed. The inner peripheral surface of the liquid storage chamber 2 is a circumferential surface 2a.

  The refrigerant supply pipe 4 opens into the liquid storage chamber 2 from the upper surface of the case 3. A front end opening of the refrigerant supply pipe 4 is a refrigerant inlet 4a. The refrigerant inlet 4 a opens at the center of the upper surface of the liquid storage chamber 2. The other end side of the refrigerant supply pipe 4 is connected to a refrigerant outlet of an evaporator (not shown).

  The refrigerant discharge pipe 5 passes through the center of the closing member 20 and is inserted into the liquid storage chamber 2 from the lower surface. The inserted refrigerant discharge pipe 5 is arranged in a vertical state at the central position of the liquid storage chamber 2. A front end opening of the refrigerant discharge pipe 5 is a refrigerant outlet 5a. The refrigerant outlet 5 a is open above the liquid storage chamber 2 and at a position slightly entering the internal space of the rectifying member 10. An oil return hole 6 is provided in the refrigerant discharge pipe 5. The oil return hole 6 opens at a position below the liquid storage chamber 2 and near the upper surface height of the interference projection wall 21. The other end of the refrigerant discharge pipe 5 is connected to a refrigerant inlet of a compressor (not shown).

  The rectifying member 10 is screwed to the upper surface wall of the case 3 as shown in FIGS. The flow regulating member 10 includes an upper surface wall portion 11 and a cylindrical side wall portion 12. The upper surface wall portion 11 is provided with a refrigerant receiving groove 11a at the center position. The refrigerant receiving groove 11a faces the refrigerant inlet 4a. The upper surface wall 11 is provided with three swirling grooves 11b that are communicated with the refrigerant receiving groove 11a and extend in a spiral shape in a generally radial direction at equal intervals. The outer diameter of the cylindrical side wall portion 12 is set to be slightly smaller than the inner surface of the case 3, that is, the circumferential surface 2 a of the liquid storage chamber 2. Thus, a gap d through which the refrigerant can flow is formed over the entire circumference between the cylindrical side wall portion 12 and the inner surface of the case 3.

  The closing member 20 is a substantially disk-shaped member. The closing member 20 is press-fitted into the lower surface side of the case 3.

  The interference protruding wall 21 is provided on the upper surface of the closing member 20. That is, the interference protruding wall 21 is disposed in the liquid storage chamber 2. The interference protruding wall 21 is a protruding wall having a trapezoidal cross section extending along the radial direction of the liquid storage chamber 2.

  The desiccant 30 is accommodated in the internal space 11 c of the rectifying member 10. A refrigerant outlet 5 a is opened at a position immediately below the desiccant 30.

  In the above configuration, the refrigerant that has passed through the evaporator (not shown) is supplied to the liquid storage chamber 2 from the refrigerant inlet 4 a through the refrigerant supply pipe 4. The refrigerant supplied from the refrigerant inlet 4 a flows on the outer surface side of the rectifying member 10. Specifically, it falls into the refrigerant receiving groove 11a and flows along the three turning grooves 11b by its own flow force and its own weight. The refrigerant flowing in each swirl groove 11b flows in the swirl direction and falls into the liquid storage chamber 2. Accordingly, the refrigerant falling from each swirl groove 11b flows into the liquid storage chamber 2 as a swirl flow along the circumferential surface 2a of the liquid storage chamber 2 by the resultant force of the flow force in the swirl direction and the weight of the refrigerant. A swirling flow of the refrigerant is generated in the lower part of the liquid storage chamber 2.

  The swirling flow of the refrigerant hits the inclined surface 21 a on one side of the interference protruding wall 21. Then, the refrigerant flow rises along the inclined surface 21 a, passes through the upper surface of the interference protruding wall 21, and descends along the inclined surface 21 a on the other side of the interference protruding wall 21 after passing through the upper surface of the interference protruding wall 21. Due to the fluctuating flow of the refrigerant in the vertical direction, the refrigerant is forcibly stirred in the vertical direction. By such agitation, the oil was separated and collected below the liquid storage chamber 2 or floated above the refrigerant so that the return amount from the oil return hole 6 did not change greatly, and the oil was mixed in. The liquid refrigerant is returned from the oil return hole 6. The gas refrigerant is returned to the compressor (not shown) from the refrigerant outlet 5a.

  In addition, excess moisture is absorbed by the desiccant 30 in the refrigerant supplied to the liquid storage chamber 2.

  As described above, the desiccant 30 is accommodated in the internal space 11 c of the rectifying member 10. The internal space 11c of the rectifying member 10 is a dead space that does not contribute to the gas-liquid separation of the refrigerant. Since the desiccant 30 is accommodated in this space, the accumulator 1 can be reduced in size without reducing the gas-liquid separation of the refrigerant. I can plan.

  Generally, as the desiccant 30, a porous granular material is often used. The desiccant made of such a granular material is placed in the desiccant-containing space (between the two resistance plates 61 and 62) in the region where the refrigerant flows in the liquid storage chamber 51 as in the conventional example (see FIG. 4). When placed in a bag such as a nonwoven fabric and placed in the liquid storage chamber, the desiccant interferes with the swirling flow in the liquid storage chamber 2. However, since the desiccant 30 accommodated in the internal space of the flow regulating member 10 does not interfere with the swirling flow in the liquid storage chamber 2, the refrigerant is effectively swirled in the liquid storage chamber 2 and the oil is stirred. The Then, in such a state that the rotation of the refrigerant is maintained, the refrigerant flows down to the lower side of the liquid storage chamber 2, and the stirring is further efficiently performed by the interference projection wall 21 of the liquid storage chamber 2. Stir.

  The rectifying member 10 has a turning groove 11b that allows the refrigerant supplied from the refrigerant inlet 4a to flow in the turning direction. Therefore, a swirl flow can be formed with a simple structure. The liquid refrigerant and oil are sufficiently mixed by the swirling flow, and an appropriate amount of oil can be returned to the compressor.

  A side circumferential surface of the liquid storage chamber 2 is a circumferential surface 2a. Therefore, the swirl flow can be smoothly formed by the cooperation with the flow regulating member 10.

(Other)
In the above embodiment, the stirring promoting portion is formed by the interference protruding wall 21 protruding from the upper surface of the closing member 20, but is not limited to this, and means that can stir the refrigerant in the vertical direction. I just need it. The stirring promoting part may be provided on the circumferential surface 2a of the liquid storage chamber 2, for example. The stirring promoting part may be provided integrally with the closing member 20, the case 3, or the like, or may be provided separately.

DESCRIPTION OF SYMBOLS 1 Accumulator 2 Liquid storage chamber 2a Circumferential surface 4a Refrigerant inlet 5a Refrigerant outlet 10 Rectification member 10b Swivel groove 11c Internal space 21 Interference protrusion wall (stirring promotion part)
30 Desiccant

Claims (4)

A liquid storage chamber (2) capable of storing a refrigerant, a refrigerant inlet (4a) for supplying the refrigerant to the liquid storage chamber (2), and an opening at an upper portion of the liquid storage chamber (2). The refrigerant outlet (5a) for discharging the refrigerant of (2) and the refrigerant inlet (4a) of the liquid storage chamber (2) are arranged below the refrigerant inlet (4a), and the refrigerant supplied from the refrigerant inlet (4a) has an outer surface side. A rectifying member (10) that flows to form a predetermined refrigerant flow; and a desiccant (30) accommodated in an internal space (11c) of the rectifying member (10), and is provided on an upper surface of the rectifying member (10). includes a mounting portion of the top surface wall of the liquid reservoir chamber (2), the refrigerant the liquid reservoir chamber (2) of the side peripheral surface to guide rather groove (11a, 11b) and is provided, wherein the mounting portion It is pre-positioned at the upper end of Kimizo (11a, 11b), and is fixed in contact with the upper wall of the liquid reservoir chamber (2) An accumulator (1) characterized by being. An accumulator (1) according to claim 1,
It said groove (11a, 11b) is an accumulator characterized in that it comprises a turning groove for flowing the refrigerant supplied to the turning direction (11b) from said refrigerant inlet (4a) (1). An accumulator (1) according to claim 2,
The accumulator (1), wherein a side circumferential surface of the liquid storage chamber (2) is a circumferential surface (2a). An accumulator (1) according to claim 2 or claim 3,
The accumulator (1), wherein the liquid storage chamber (2) is provided with an agitation promoting portion (21).

Images