JP2018178742A - Pumping unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pump unit that can properly support a frozen crack due to handling fluid.SOLUTION: A pump unit 100 includes: a pump device 1 provided with a plurality of entry/exit ports for water; and a closing device 60 closing at least a discharge port 9 of the entry/exit ports and including a deformation part 61 with stiffness that is lower than a liquid contact part in the pump device 1.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a pump unit.

  Conventionally, as a pump unit, for example, a cascade pump (also referred to as an eddy current pump or a Wesco pump) as described in Patent Document 1 is known. The cascade pump is a pump device including a pump for pumping water, an electric motor provided on the back side of the pump and driving the pump, and an inverter device for supplying electric power to the electric motor. The pump, the electric motor, and the inverter The device is fixed to the unit base.

JP, 2015-218658, A

  By the way, in such a pump device, when left in the winter period, for example, when the handling liquid remaining in the inside can not be discharged, the handling liquid is frozen and a stress due to volume expansion occurs. . And the liquid contact part (pump casing, piping, etc.) in a pump apparatus has a possibility that a stress crack may be carried out, when it can not endure the said stress. In this case, it is general to reinforce the stress-cracked damaged portion, but when the damaged portion is reinforced, the next weak portion is broken, and there is no limit. Further, if all the damaged parts are reinforced, there is a problem that the shape of the liquid contact part is far from the original shape and the weight is also increased.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a pump unit capable of appropriately coping with freeze fracture due to a handling liquid.

(1) A pump unit according to one aspect of the present invention closes a pump device provided with a plurality of liquid inlets and outlets, and at least one of the plurality of inlets and outlets, and is more than a liquid contact portion in the pump device. And a closing device provided with a low-rigidity deformation portion.
According to this configuration, since the closing device for closing at least one of the liquid inlet and outlet of the pump device includes the deformed portion having a rigidity lower than the liquid contact portion in the pump device, the liquid is frozen in the pump device Then, the deformation portion of the closing device is deformed first, so that the generation of stress in the liquid contact portion in the pump device can be alleviated. In addition, even if the deformation portion can not withstand the stress due to volumetric expansion of the liquid and is broken, the deformation portion is provided in the closing device for closing the liquid inlet and outlet, so replacement is easy, and the overall part It is possible to cope with freeze cracking economically without leading to replacement.

(2) In the pump unit described in the above (1), at least a part of the liquid contact portion connected to the closing device of the pump device is formed of a synthetic resin, and The thickness may be thinner than the thickness of the liquid contact portion formed of the synthetic resin.
In this case, the rigidity of the deformed portion can be managed by the difference between the thickness of the deformed portion and the thickness of the liquid contact portion formed of the synthetic resin. Adjustment is easy.

(3) In the pump unit described in the above (1) or (2), a cut groove may be formed in the deformed portion.
In this case, since the deformed portion freezes and cracks from the cut groove, it is possible to reliably prevent the freeze crack in the liquid contact portion in the pump device.

(4) It is a pump unit described in said (3), Comprising: The said cut groove may be formed in the back side of the said deformation part at least.
In this case, when the volume of the liquid expands due to freezing and the deformation portion is deformed so as to expand, a tensile stress acts on the back side of the deformation portion, so that a cut groove is formed on the back side. It is possible to make the part easy to freeze and crack.

(5) In the pump unit described in the above (1) to (4), the closing device has a closing member detachably attached to the port, and the deformation portion is integral with the closing member. It may be formed of
In this case, by replacing the closing member, the frozen and cracked deformed portion can be replaced together, and the replacement operation becomes easy. In addition, when the closing member is newly attached, the deformation portion can also be attached together, so that it is possible to prevent the installation failure of the deformation portion.

(6) In the pump unit described in (5), a screw hole may be formed on the back side of the deformed portion formed in the closing member.
In this case, by forming a screw hole on the back side of the deformation portion, even if the deformation portion is broken, the tear of the deformation portion can be closed by a plug or the like as an emergency measure. You can quickly restore the pump.

(7) In the pump unit described in the above (1) to (4), the closing device has a closing member detachably attached to the port, and the deformation portion is different from the closing member It may be provided by the body.
In this case, for example, it is possible to cope with freeze cracking by adding a deformation portion separately to the existing closing member, and only when the deformation portion is freeze cracked, only the deformation portion needs to be replaced. It is economical.

(8) It is a pump unit described in said (1)-(7), Comprising: The said deformation | transformation part may be a diaphragm.
In this case, the occurrence of stress in the liquid contact portion in the pump device can be alleviated without damaging the deformed portion due to the large elastic deformation of the diaphragm.

(9) The pump unit according to any one of (1) to (8), wherein the plurality of outlets include a plurality of outlets for discharging the liquid, and the closing device includes the plurality of outlets. It may be attached to at least one.
In this case, since the discharge port is more likely to collect liquid than the suction port which assembles the liquid in place, the freeze cracking can be effectively prevented by attaching a closing device having a deformed portion to the discharge port. it can.

(10) The pump unit described in the above (1) to (9), wherein the pump device has a pump for discharging the liquid, and a unit base made of synthetic resin for supporting the pump, The unit base may have, as the liquid contact portion, a pipe portion communicating with the internal flow path of the pump, and the deformation portion may have lower rigidity than the pipe portion.
In this case, a piping portion is formed as a liquid contact portion, and a unit base made of a synthetic resin which is very likely to cause a freeze crack can be effectively protected. The unit base is a basic member which is a base of the pump unit, and therefore, it is not necessary to perform a troublesome replacement operation such as removing a component device supported by the unit base.

  According to the above aspect of the present invention, it is possible to appropriately cope with freeze cracking due to the handling liquid.

It is a front view showing pump unit 100 concerning one embodiment. It is a longitudinal cross-sectional view which shows the internal structure of the pump casing 30 shown in FIG. It is an appearance perspective view showing pump unit 100 concerning one embodiment. It is a bottom view showing pump unit 100 concerning one embodiment. It is a cross-sectional schematic diagram corresponding to the arrow AA cross section of FIG. It is a cross-sectional schematic diagram which shows the mode near the closing apparatus 60 when water freezes in the pump unit 100 which concerns on one Embodiment. It is a cross-sectional schematic diagram which shows 60 A of closing devices which concern on the modification of the closing device 60 of one Embodiment. It is a cross-sectional schematic diagram which shows the closure apparatus 60B which concerns on the modification of the closure apparatus 60 of one Embodiment. It is a cross-sectional schematic diagram which shows 60 C of closure devices which concern on the modification of the closure device 60 of one Embodiment. It is a cross-sectional schematic diagram which shows closing apparatus 60D which concerns on the modification of the closing apparatus 60 of one Embodiment. It is a cross-sectional schematic diagram which shows the closing apparatus 60E which concerns on the modification of the closing apparatus 60 of one Embodiment. It is a perspective view showing closure member 62E of closure device 60E concerning a modification of closure device 60 of one embodiment.

Hereinafter, a pump unit 100 according to an embodiment will be described with reference to the drawings.
FIG. 1 is a front view showing a pump unit 100 according to one embodiment. FIG. 2 is a longitudinal sectional view showing an internal structure of the pump casing 30 shown in FIG.
The pump unit 100 includes the pump device 1 and a closing device 60 (see FIG. 5 described later).

  As shown in FIG. 1, the pump device 1 includes a pump 2 for pumping water, a motor (not shown) provided on the back side of the pump 2 to drive the pump 2, and an inverter device 4 for supplying electric power to the motor. These units include a pump 2, a motor, and a unit base 5 made of synthetic resin for supporting the inverter device 4. The pump 2, the motor, and the inverter device 4 are substantially entirely covered with a unit cover 6 made of synthetic resin.

  The pump 2 is a cascade pump also referred to as a friction pump, and includes an impeller 20 and a pump casing 30 forming a pump chamber 31 for housing the impeller 20 as shown in FIG. 2. As shown in FIG. 1, a pump casing cover 50 is attached to the front side of the pump casing 30, and the impeller 20 can be accessed when the pump casing cover 50 is removed. As shown in FIG. 2, the impeller 20 is formed in a disk shape having a large number of grooves 21 cut in its peripheral portion, and the peripheral portion makes the water present in the pump chamber 31 approximately one turn. While boosting.

Although this pump 2 is small in size, a single impeller 20 can obtain a head comparable to several stages of centrifugal pumps, and is suitable for the purpose of small volume high head. In addition, since the cascade pump has self-priming property, it is suitable for pumping up water and well water stored in a water receiving tank installed at a position lower than the pump 2.
The motor drives the pump 2 by rotating the impeller 20. The drive of the motor is controlled by the inverter device 4 and variable operation of the pump 2 is enabled. Here, when it is not necessary to perform variable speed operation in the inverter device 4, the inverter device 4 may not have variable speed means.

  As shown in FIG. 1, a suction port 7 exposed from the unit cover 6 and a discharge port 8 are provided on the front of the pump device 1. The suction port 7 communicates with one end 32 a of the internal flow path 32 formed inside the pump casing 30 shown in FIG. 2, and the discharge port 8 communicates with the other end 32 b of the internal flow path 32. . A pump chamber 31 and a steam-water separation chamber 33 are formed in the internal flow passage 32.

  A flow check valve 35 is provided in the suction flow passage 34 from the one end 32 a to the pump chamber 31 in the internal flow passage 32. The flow check valve 35 is provided at a position higher than the pump chamber 31 and fills the inside of the pump chamber 31 to secure a water level necessary for self-priming prior to driving of the pump 2 and at the time of stopping the pump 2 It serves to prevent backflow of water and to always fill the pump chamber 31 with water. That is, the flow check valve 35 closes the suction flow passage 34 by its own weight when the pump 2 is stopped, and is pushed up by water (including air at the start time) rising up the suction flow passage 34 when the pump 2 is driven. And the suction flow path 34 is opened.

  An air-water separation chamber 33 is disposed downstream of the pump chamber 31. In the connection flow path 36 between the pump chamber 31 and the air-water separation chamber 33 in the internal flow path 32, a baffle 37 with which the liquid discharged from the pump chamber 31 collides is disposed. A hole 33 a communicating with the pump chamber 31 is formed at the bottom of the air-water separation chamber 33. The hole 33a is for returning the water separated from the air in the air-water separation chamber 33 back to the pump chamber 31 at the time of self-priming operation at the start of the pump 2, thereby generating a negative pressure in the pump chamber 31. , Remove the air in the suction flow path 34 and suck up the water.

  Above the air-water separation chamber 33, a priming port 38 is formed. The priming port 38 is closed by a priming faucet 39. The priming faucet 39 is opened in a state where water is not filled in the pump casing 30 at the time of installation of the pump 2 and the like, and is opened before the pump 2 is started. The separation chamber 33 is full of water up to the priming water level 40. The self-priming operation is performed by driving the pump 2 described above, the air in the suction flow path 34 is exhausted, and when the water rises, the self-priming operation is finished, and the air-water separation chamber 33 and the air-water separation chamber 33 After the downstream side is filled with water, the pumping operation is performed by driving the pump 2.

  A pressure sensor 42 is provided in the discharge flow path 41 from the air-water separation chamber 33 to the other end 32 b in the internal flow path 32. The pressure sensor 42 is disposed above the priming water level 40, completes the self-priming operation, and detects the pressure of the discharge flow channel 41 filled with water. The detection result of the pressure sensor 42 is output to the inverter device 4, and the inverter device 4 controls the drive of the motor based on the target pressure and the detection result of the known discharge pressure constant control and estimated terminal pressure constant control. .

  In addition, the discharge flow path 41 is provided with a pressure tank (not shown). In the pressure tank, a rubber bladder is built in a pressure resistant container, and when the discharge pressure of the pump 2 rises, air outside the bladder is compressed and water is stored in a pressurized state. Also, for example, as the pressure in the discharge flow channel 41 decreases with the use of water, the compressed air expands and pushes out the stored water into the discharge flow channel 41. In this manner, even after the pump 2 is started up, water can be supplied from the pressure tank to the discharge flow path 41 for a while even if the rotational speed is not increased to the level sufficient for water supply.

FIG. 3 is an external perspective view showing the pump unit 100 according to one embodiment. FIG. 4 is a bottom view showing the pump unit 100 according to one embodiment. FIG. 5 is a schematic cross-sectional view corresponding to the cross section taken along line AA of FIG.
As shown in FIG. 3, the pump apparatus 1 is provided with discharge ports 9 and 10 in addition to the discharge port 8. The discharge ports 9 and 10 communicate with each other through a piping portion 11 integrally formed with the unit base 5 made of synthetic resin. The pipe portion 11 is a branch pipe branched in two directions, and a connection flange 11 a is provided on the upstream side thereof.

  The piping part 11 is connected with the bottom part of the discharge port 8 via the connection pipe 12, as shown in FIG. The bottom of the discharge port 8 is also provided with a connection flange similar to the connection flange 13 provided in the bottom of the suction port 7 (in practice, it is closed by a closing flange not shown). The one end 12a of the connection pipe 12 is connected via a bolt. Further, the other end 12 b of the connection pipe 12 is connected to the connection flange 11 a of the pipe portion 11 via a bolt.

  The connecting pipe 12 is made of the same copper alloy as the impeller 20, the pump casing 30 and the pump casing cover 50. The connecting tube 12 made of a copper alloy is higher in rigidity than the piping portion 11 made of a synthetic resin formed on the unit base 5. Further, as shown in FIG. 4, the connection pipe 12 is substantially U-shaped to connect between the bottom of the discharge port 8 and the bottom of the piping portion 11, and water is easily accumulated.

  As shown in FIG. 3, the pump device 1 is for household use, and suction piping fluidly connected to a water tank, a well, a water pipe, etc., which is a supply source of handling liquid, and supply destinations (faucet etc inside and outside the house In addition to the discharge port 8, the discharge ports 9 and 10 are provided in order to give freedom in the connection position with the discharge pipe connected thereto. Also, a plurality of suction ports 7 may be provided for the same reason.

  The discharge ports 9 and 10 are used as discharge destinations of the processing liquid of the pump 2 when the discharge port 8 is used (when the discharge pipe leading to the supply destination of the handling liquid is connected to the discharge port 8) Since it is not used, it is necessary to close it to prevent the handling fluid from leaking. In the present embodiment, a closure device 60 as shown in FIG. 5 is attached to the discharge port 9 among the discharge ports 9 and 10. On the other hand, a metal closing flange (not shown) is attached to the discharge port 10. A closing device 60 described below may be attached to the discharge port 10 as well.

  As shown in FIG. 5, the closing device 60 is connected to the piping portion 11 and includes a deformed portion 61 whose rigidity is lower than that of the synthetic resin piping portion 11 which is a liquid contact portion in the pump device 1. Here, the liquid contact portion in the pump device 1 means a portion in contact with the handling liquid inside the device of the pump device 1, and for example, as shown in FIG. As shown in FIG. 4, the pump casing 30 and the pump casing cover 50 forming the separation chamber 33 etc., between the pipe portion 11 of the unit base 5 communicating with the internal flow path 32, the internal flow path 32 and the piping portion 11 It includes a connecting pipe 12 to be connected, a flow check valve 35 provided along the internal flow path 32, a flush water valve 39, a pressure sensor 42 and the like as shown in FIG. In general, a pump that transports liquid may generate air lock or the like if it sucks air, and may malfunction. Therefore, after the self-priming operation described above is completed, the water in the pump device 1 is intentionally used. As long as it does not withdraw, the flow path in the pump device 1 is filled with the handling liquid.

  In the present embodiment, among the liquid contact portions in the pump device 1, the piping portion 11 made of synthetic resin formed on the unit base 5 has the lowest rigidity, and the deformation portion 61 has a lower rigidity than the piping portion 11. The rigidity is low. In the present embodiment, the deformation portion 61 is formed of the same material as the piping portion 11 (unit base 5), and when the thickness (thickness) of the piping portion 11 is t1, t2 is thinner than t1. It has a thickness. As an example, when t1 is 3.0 to 5.0 mm, t2 is about 0.5 to 2.0 mm.

  In particular, since the pump unit 100 is installed outdoors, there is a possibility that the handling liquid in the connection pipe 12 may freeze due to the cold air from the installation surface. In the present embodiment, the pipe portion 11 is in fluid communication with the copper alloy connection pipe 12, and the transport liquid in the connection pipe 12 freezes and expands, and the shock transmitted to the pipe portion 11 is eventually connected. There is a possibility that the piping portion 11 which is less rigid than the pipe 12 may be damaged. Therefore, in order to prevent freeze fracture of the piping portion 11, it is more effective to connect the closing device 60 to any one of the discharge ports 8, 9 and 10 which are the liquid inlet and outlet close to the connection pipe 12.

  Further, in the deformation portion 61, a cut groove 63 is formed. The cut groove 63 is a groove formed in a slit shape with a V-shaped cross-sectional view with respect to the back surface 61 b of the deformation portion 61, and the thickness of the deformation portion 61 is locally reduced. Note that the cut grooves 63 may be formed in a cross shape such as a cross, or a plurality of grooves may be provided in any direction. In addition, the cut groove 63 may be formed on the front surface 61 a side of the deformation portion 61 (a side facing the discharge port 9). Furthermore, the cut grooves 63 formed on the front surface 61a side and the back surface 61b side may be formed to match back to back or may not be matched.

  The deformation portion 61 is integrally formed with the closing member 62. The closing member 62 is a component of the closing device 60, and has a flange portion 62a detachably attachable to the connection flange 11b around the discharge port 9 via a bolt (not shown). A screw hole 64 is formed in the closing member 62. The screw hole 64 is formed on the back surface 61 b side of the deformation portion 61 formed in the closing member 62. The screw hole 64 of the present embodiment is formed in the vertical direction with respect to the back surface 61 b of the deformation portion 61, but if the back surface 61 b can be accessed, for example, in the diagonal direction with respect to the back surface 61 b of the deformation portion 61 It may be formed.

  Moreover, the connection method of the discharge port 9 and the closing apparatus 60 is not restricted to the connection by the connection flange 11b mentioned above and the flange part 62a. For example, it may be connected by screwing. Specifically, instead of the flange 11b and the flange portion 62a, a screw groove in which the discharge port 9 and the closing member 62 can be screwed is formed, and the male screw formed in the closing member 62 is screwed into the female screw formed in the discharge port 9. Alternatively, the discharge port 9 and the closing member 62 may be connected. Also, any fastener may be used to connect the discharge port 9 and the closing member 62.

  Subsequently, the operation of the closing device 60 configured as described above will be described.

FIG. 6 is a schematic cross-sectional view showing the vicinity of the closing device 60 when water is frozen in the pump unit 100 according to one embodiment.
If the water remains in the inside of the pump device 1, for example, if it is left during the winter season, the water freezes as shown in FIG. 6 (a). Specifically, as shown in FIG. 4, the water remaining in the connecting pipe 12 piped in a U-shape at the bottom of the unit base 5 is gradually frozen due to the bottom cooling, and the freezing is caused by the piping It travels up to 11 and reaches a closing device 60 which closes the discharge port 9.

  Here, the closing device 60 is connected to the piping portion 11 which is a liquid contact portion, and includes a deformation portion 61 whose rigidity is lower than that of the liquid contact portion in the pump device 1. As described above, in the present embodiment, since the closing device 60 for closing the discharge port 9 of the pump device 1 includes the deformation portion 61 whose rigidity is lower than the liquid contact portion in the pump device 1, the inside of the pump device 1 When the water is frozen at first, the deformation portion 61 of the closing device 60 is deformed as shown in FIG. 6 (a). When the deformation portion 61 is deformed, the volume (space) in the liquid contact portion in the pump device 1 is increased, and therefore, the generation of stress in the liquid contact portion in the pump device 1 can be alleviated.

  Further, as shown in FIG. 6B, even if the deforming portion 61 can not withstand stress due to volumetric expansion of water and is broken, the deforming portion 61 is provided in the closing device 60 for closing the discharge port 9. Therefore, replacement is easy, and it is possible to cope with freeze fracture economically without leading to overall replacement of parts. Therefore, according to the aspect of the present embodiment, it is possible to appropriately cope with freeze fracture due to the handling liquid.

  Further, the deformation portion 61 is lower in rigidity than the piping portion 11 formed on the unit base 5 made of synthetic resin. Therefore, the piping portion 11 is formed, and the liquid contact portion made of a synthetic resin which is very likely to cause a freeze crack can be effectively protected. For example, since the unit base 5 is a basic member which is a base of the pump unit 100 as shown in FIG. 1, when the unit base 5 is broken, the component devices (pump 2, motor, It is necessary to carry out troublesome replacement work such as removing the inverter device 4 etc.). Since it is not necessary to perform such work, the time when water can not be supplied can be shortened, and the time for water supply to the supply destination can be shortened.

  Further, as shown in FIG. 5, the thickness t2 of the deformed portion 61 is thinner than the thickness t1 of the piping portion 11. According to this configuration, the rigidity of the deformable portion 61 can be managed by the difference between the thickness t2 of the deformable portion 61 and the thickness t1 of the piping portion 11. Therefore, adjustment of the degree of deformation of the deformable portion 61 and the timing of breakage Etc. becomes easy. In this case, it is preferable to assume that the piping portion 11 and the deformation portion 61 are formed of the same material. The stiffness can be managed by comparison.

  Furthermore, a slit groove 63 is formed in the deformed portion 61 of the present embodiment, and as shown in FIG. 6B, since the deformed portion 61 is easily frozen and broken starting from the slit groove 63, the pump device Freezing cracking in the wetted portion in 1 can be reliably prevented. Further, as shown in FIG. 6A, when the volume of water expands due to freezing and the deformation portion 61 is deformed to expand, a tensile stress acts on the back surface 61b side of the deformation portion 61, so this embodiment By forming the cut groove 63 on the back surface 61 b side of the deformation portion 61 as described above, the deformation portion 61 can be more easily frozen and cracked, and the liquid contact portion can be protected.

  Further, since the deformation portion 61 of the present embodiment is integrally formed with the closing member 62 which is detachably attached to the discharge port 9, by replacing the closing member 62, the freeze fractured deformation portion 61 is also exchanged together. And its replacement work is easier. Further, when the closing member 62 is newly attached, the deformation portion 61 can also be attached together, so that there is an advantage that the installation failure of the deformation portion 61 can be prevented.

  In addition, in the present embodiment, since the screw hole 64 is formed on the back surface 61b side of the deformation portion 61 formed in the closing member 62, as shown in FIG. 6B, the deformation portion 61 is broken. Even if this is the case, since the plug 70 can close the break of the deformed portion 61 as an emergency measure, the pump 2 can be restored immediately on site.

  Further, in the present embodiment, the closing device 60 is attached to the discharge port 9 among the plurality of discharge ports 8, 9 and 10 for discharging water. In the present embodiment, since it is assumed that the handling liquid pressurized by the pump 2 is transported to the water supply destination using the discharge port 8, the closing device 60 can not be attached to the discharge port 8, but it is temporarily When the discharge port 8 is not used, the closing device 60 may be attached to the discharge port 8. For example, even if the closing device 60 is attached to the discharge port 8, since the discharge ports 8, 9, 10 communicate with each other through the pipe portion 11 and the connecting pipe 12, the same action as the above-described action can be obtained. . Further, since the discharge ports 8, 9, 10 are more likely to collect water than the suction port 7 connected to the supply source of the handling liquid, the closing device 60 having the deformation portion 61 in these discharge ports 8, 9, 10 is used. By connecting them, it is possible to effectively prevent the freeze cracking.

  As described above, according to the above-described embodiment, at least one of the pump device 1 provided with a plurality of water inlets and outlets (including the suction inlet 7 and the discharge outlets 8, 9 and 10) and the plurality of outlets. By adopting a configuration of closing the (discharge port 9) and including the closing device 60 provided with the deformed portion 61 whose rigidity is lower than the liquid contact portion in the pump device 1, freezing fracture due to the handling liquid is adopted. The pump unit 100 can be appropriately adapted to

  While the preferred embodiments of the invention have been described and described, it is to be understood that these are illustrative of the invention and are not to be considered as limiting. Additions, omissions, substitutions, and other modifications can be made without departing from the scope of the present invention. Accordingly, the present invention should not be considered limited by the foregoing description, but is only limited by the scope of the claims.

  For example, the following modifications may be employed as one aspect of the embodiment of the present invention. In the following description, the same or equivalent components as or to those of the embodiment described above are designated by the same reference numerals, any explanation of which will be simplified or omitted.

FIG. 7 is a schematic cross-sectional view showing a closure device 60A according to a modification of the closure device 60 of one embodiment.
The closing device 60A shown in FIG. 7 has a deformation portion 61A and a closing member 62A provided separately from the deformation portion 61A. The deformation portion 61A is a diaphragm formed of an elastic body such as rubber, and has a top cylindrical body portion 61A1 and a flange portion 61A2 provided at the opening edge of the body portion 61A1. A groove 62b for disposing (sandwiching) the flange portion 61A2 is formed on the facing surface of the closing member 62A facing the end face of the piping portion 11.

  According to such a configuration, since the deformable portion 61A is formed of a diaphragm, the deformable region is large, and it is possible to sufficiently absorb volumetric expansion due to freezing of water. For this reason, it is possible to alleviate the occurrence of stress in the liquid contact portion in the pump device 1 without damaging the deformation portion 61A. Further, since the deformation portion 61A is provided separately from the closing member 62A, for example, adding the deformation portion 61A to the existing closing member 62A can cope with the freeze crack, and the deformation portion 61A is temporarily provided. Even in the case of breakage, it is economical because only the deformation portion 61A needs to be replaced. Further, since the diaphragm of the deformation portion 61A is an elastic body such as rubber, it can be said that the rigidity is lower than that of the synthetic resin of the liquid contact portion.

FIG. 8 is a schematic cross-sectional view showing a closure device 60B according to a modification of the closure device 60 of one embodiment.
In the closing device 60B shown in FIG. 8, the closing member 62B is detachably attached to the piping portion 11 via the attachment member 67. The attachment member 67 has a flange 67a connected to the piping portion 11 via a bolt, a screw 67b with which the closing member 62B is screwed, and a groove 67c for arranging the O-ring 65 on the opposite surface facing the end surface of the piping portion 11. And. In the closing device 60B, although the deformation portion 61B is separate from the closing member 62B, the deformation portion 61B is integrally incorporated into the closing member 62B. The deformation portion 61B is a diaphragm, and has a top cylindrical body portion 61B1 and a flange portion 61B2 provided at the opening edge of the body portion 61B1. A screw 67b is formed on the inner wall surface of the attachment member 67, and a hollow cylindrical screw shaft 62d of the closing member 62B is screwed. A groove 62b with which the flange portion 61B2 engages is formed on the inner wall surface of the screw shaft 62d.

  Further, a groove 67 c in which the O-ring 65 is disposed is formed on the opposite surface of the attachment member 67 facing the end surface of the piping portion 11. Furthermore, in the closing member 62B, a screwdriver portion 66 such as a hexagonal head for turning the screw shaft 62d is formed. According to such a configuration, the closing member 62B can be integrally attached to the piping portion 11 via the attachment member 67 by turning the screw portion 66. Further, since the deformation portion 61B is integrally incorporated in the closing member 62B, it is possible to prevent the assembly portion 61B from being forgotten.

FIG. 9 is a schematic cross-sectional view showing a closure device 60C according to a modification of the closure device 60 of one embodiment.
In the closing device 60C shown in FIG. 9, the closing member 62C is detachably attached to the piping portion 11 via the attachment member 67. The closing member 62C is a drainage cap in which the deformation portion 61C is integrally formed, and has a screw hole 62C1 and a drainage hole 62C2 communicating the inside and the outside of the cap. The attachment member 67 has a flange 67a connected to the piping portion 11 via a bolt, a screw 67b with which the closing member 62C is screwed, and a groove 67c for arranging the O-ring 65 on the opposite surface facing the end surface of the piping portion 11. And.

  According to this configuration, by screwing the closing member 62C into the attachment member 67, the distal end of the screw 67b can be abutted against the deformation portion 61C to close the drainage hole 62C2, and conversely, the closing member 62C By releasing the screwing of the screw 67b, the tip of the screw 67b can be separated from the deformation portion 61C to open the water draining hole 62C2. Further, in such a configuration, even when water is frozen in a state where the water drain hole 62C2 is closed, the closing member 62C includes the deformation portion 61C, so freezing in the liquid contact portion in the pump device 1 Cracks can be prevented.

FIG. 10 is a schematic cross-sectional view showing a closure device 60D according to a modification of the closure device 60 of one embodiment.
A closing device 60D shown in FIG. 10 includes a plurality of deforming portions 61D. The attachment member 67 preferably has a step-like step groove 67d for arranging a plurality of deformation parts 61D. The stepped groove 67 d is formed such that the diameter thereof gradually decreases toward the piping portion 11. The deformed portion 61D is an apical cylindrical resin component intended to be broken, and is arranged with a small diameter on the side of the pipe portion 11 and a large diameter on the back side. In addition, the deformation portion 61D may be provided with one or more cut grooves (not shown). The closing member 62D has a screw shaft 62D1 screwed with a screw 67b formed inside the stepped groove 67d of the attachment member 67. According to such a configuration, even if the first-stage deformed portion 61D is frozen and cracked, if the second-stage deformed portion 61D is not frozen and cracked, use of the pump device 1 without replacement work is required. There is a merit that can be continued. The deformable portion 61D may include a plurality of diaphragms using an elastic member such as rubber.

FIG. 11 is a schematic cross-sectional view showing a closure device 60E according to a modification of the closure device 60 of one embodiment. FIG. 12 is a perspective view showing a closing member 62E of a closing device 60E according to a modification of the closing device 60 of one embodiment.
In the closing device 60E shown in FIG. 11, a closing member 62E having a configuration similar to that of the flush valve 39 shown in FIG. 2 is attached via the attachment member 67. The closing member 62E has a screw shaft 62E1 screwed to the screw 67b of the attachment member 67, and an engaging portion 62E2 engaged with a tool for screwing the screw shaft 62E1. As shown in FIG. 12, the engaging portion 62E2 is formed of a plurality of L-shaped ribs in plan view. And while a deformation | transformation part 61E is formed in the trough of the cross of a rib and a rib, a tool engages with the said trough. Even with such a configuration, by making the rib and the valley of the rib deeper, the deformation portion 61E can be integrally formed while maintaining the mechanism for screwing.

  The connection method between the above-described piping unit 11 and the closing device 60 and the above-described modified examples (closing devices 60A, 60B, 60C, 60D, 60E) is not limited to the above-described connection method. For example, the attachment member 67 may be omitted. Specifically, a thread groove in which the pipe portion 11 and the closing device 60 can be screwed is formed, and an external thread formed in the closing device 60 is screwed into a female screw formed in the pipe portion 11. The closing device 60 may be connected. Also, any fastener may be used to connect the piping unit 11 and the closing device 60.

  As described above, application places of the closing device 60 and the above-described modified examples (closing devices 60A, 60B, 60C, 60D, 60E) are not limited to the suction port 7 or the discharge ports 8, 9, 10, for example, FIG. It may be a cap for water draining holes for closing the water draining holes 62C2 shown in FIG. The pump unit 100 mentioned above has one suction port 7 connected to the supply source of the handling liquid, but if it is a water supply apparatus in which a plurality of suction ports 7 are provided, the closing apparatus 60 may be closed to any of the plurality of suction ports 7 May be connected.

  Further, as a further example of the application portion of the closing device 60 and the above-described modified example (closing devices 60A, 60B, 60C, 60D, 60E), even the priming faucet 39 for closing the priming port 38 shown in FIG. Good. The pump device 1 is a water supply device for household use, and since weight reduction is required, the whole or a part of the pump casing 30 which is a liquid contact portion may be formed of a synthetic resin. As an example, when the portion of the pump casing 30 corresponding to the steam / water separation chamber 33 is formed of a synthetic resin, if the steam / water separation chamber 33 is frozen in a state of being filled with the handling liquid, there is a risk of causing freeze cracking. There is. Therefore, the closing device 60 is connected to the pump casing 30 by applying the closing device 60 to the priming faucet 39 which is a liquid inlet / outlet close to the air-water separation chamber 33. Therefore, the deformation portion 61 can absorb expansion of the transport liquid due to freezing in the air-water separation chamber 33, and the freeze cracking of the pump casing 30 can be prevented. In this case, the rigidity of the deformed portion 61 may be lower than the rigidity of the synthetic resin portion of the pump casing 30.

  Further, for example, in the above embodiment, the rigidity of the deformation portion 61 is made lower than the rigidity of the piping portion 11 of the unit base 5 in order to prevent freeze fracture of the piping portion 11 of the unit base 5 made of synthetic resin. Since, as described above, the flow path in the pump device 1 is filled with the handling liquid, the case where the piping portion 11 which is the liquid contact portion is not formed of synthetic resin in the unit base 5 or the pump device 1 When there is another portion in the inner liquid-contact portion having a rigidity lower than that of the piping portion 11, it is preferable to set the rigidity of the deformation portion 61 based on the other portion having a low rigidity. Further, the connecting pipe 12 may be formed integrally with the unit base 5 with synthetic resin as in the case of the pipe portion 11. Even in such a case, by making the rigidity of the deformation portion 61 lower than that of the pipe portion 11 and the connecting pipe 12 connected to the closing device 60, it is possible to prevent freeze fracture of the pipe portion 11 and the connecting pipe 12.

  Further, for example, the direction of the motor is not limited to the horizontal direction. For example, even in a pump apparatus in which the motor is installed in a substantially vertical direction (vertical direction), the main shaft of the pump 2 is disposed in a substantially horizontal direction. The present invention can also be applied to a pump device of such a horizontal axis pump.

  Further, for example, in the above embodiment, a cascade pump has been exemplified as the pump device 1, but the present invention can be applied to non-volume pumps (such as centrifugal pumps and axial flow pumps).

  DESCRIPTION OF SYMBOLS 1 ... Pump apparatus, 2 ... Pump, 5 ... Unit base, 7 ... Suction port (outlet port), 8 ... Discharge port (outlet port), 9 ... Discharge port (outlet port), 10 ... Discharge port (port / outlet) 11 ... Piping part (Wetted portion), 12: connection pipe (wetted portion), 30: pump casing (wetted portion), 32: internal flow path, 35: flow check valve (wetted portion), 38: water outlet (outlet) , 39: priming faucet (wetted portion), 42: pressure sensor (wetted portion), 60, 60A, 60B, 60C, 60D, 60E, closing device, 61, 61A, 61B, 61C, 61D, 61E, deformed portion 61b: back surface 62, 62A, 62B, 62C, 62D, 62E: closing member, 62C2: water draining hole (outlet), 63: notching groove, 64: screw hole, 70: plug, 100: pump unit

Claims (10)

A pump device provided with a plurality of liquid inlets and outlets;
And at least one of the plurality of inlets and outlets, and a closing device including a deformation portion having a rigidity lower than that of the liquid contact portion in the pump device. At least a part of the liquid contact portion connected to the closing device of the pump device is formed of a synthetic resin,
The pump unit according to claim 1, wherein a thickness of the deformed portion is thinner than a thickness of a liquid contact portion formed of the synthetic resin.   The pump unit according to claim 1 or 2, wherein a cut groove is formed in the deformed portion.   The pump unit according to claim 3, wherein the cut groove is formed at least on the back side of the deformation portion. The closing device has a closing member removably attached to the port.
The pump unit according to any one of claims 1 to 4, wherein the deformation portion is integrally formed with the closing member.   The pump unit according to claim 5, characterized in that a screw hole is formed on the back side of the deformation portion formed in the closing member. The closing device has a closing member removably attached to the port.
The pump unit according to any one of claims 1 to 4, wherein the deformation portion is provided separately from the closing member.   The pump unit according to any one of claims 1 to 7, wherein the deformation portion is a diaphragm. The plurality of inlets and outlets include a plurality of outlets for discharging the liquid,
The pump unit according to any one of claims 1 to 8, wherein the closing device is attached to at least one of the plurality of discharge ports. The pump device
A pump for discharging the liquid;
A unit base made of synthetic resin for supporting the pump;
The unit base is formed with a piping portion communicating with the internal flow path of the pump as the liquid contact portion,
The pump unit according to any one of claims 1 to 9, wherein the deformation portion is lower in rigidity than the piping portion.

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