JP2002188581A - Refrigerant pump system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To securely and sufficiently damp pressure fluctuation caused by pulsation of refrigerant under the conditions of large flow and a large differential pressure and under the conditions that refrigerant temperature is greatly fluctuated. SOLUTION: A refrigerant pump system 1 has an electric motor 4 and a pump mechanism 5 incorporated into a sealed vessel 3 to suck refrigerant through a suction pipe 14 and discharge it from a discharge pipe 15. A plurality of pulsation reducing vessels 18a, 18b provided with sheath heaters 19 as heating means, respectively, are connected with the discharge pipe 15 among the suction pipe 14 and the discharge pipe 15.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigerant pump system, and more particularly to a refrigerant pump system suitable for use in an air conditioner or the like.

[0002]

2. Description of the Related Art Conventionally, as a technique in such a field, a technique disclosed in Japanese Patent Application Laid-Open No. Hei 6-299974 is known. The conventional refrigerant pump system described in this publication is incorporated in an air conditioner or the like and is used to transfer a liquid refrigerant. This refrigerant pump system includes an electric motor and a pump mechanism (positive displacement pump mechanism) housed in a closed container. The pump mechanism is connected with a suction pipe for sucking the refrigerant and a discharge pipe for discharging the refrigerant. Also, of the suction pipe and the discharge pipe,
A container having a predetermined volume is connected to the discharge pipe via a riser pipe. A heating means such as a sheath heater is provided on the outer periphery of the container.

[0003] In the refrigerant pump system configured as described above, when the pump mechanism is driven by the electric motor, the rolling piston constituting the pump mechanism performs eccentric rotational motion in the cylinder chamber, whereby the liquid refrigerant flows through the suction pipe, The liquid refrigerant, which has flowed into the compression chamber via the suction port and the suction chamber and has been pressurized, is discharged from the compression chamber via the discharge port and the discharge pipe. At this time, the liquid refrigerant is discharged to the discharge pipe every time the rolling piston makes one rotation, so that pulsation occurs in the liquid refrigerant flowing through the discharge pipe, causing pressure fluctuation.

On the other hand, in this refrigerant pump system, a part of the liquid refrigerant flowing through the discharge pipe flows into the container via the riser pipe. The liquid refrigerant flowing into the container from the discharge pipe evaporates inside the container heated by the heating means. Accordingly, the inside of the container is filled with the gas refrigerant, and the pressure fluctuation caused by the pulsation of the liquid refrigerant flowing through the discharge pipe is reduced by the gas refrigerant. As a result, according to the refrigerant pump system, it is possible to reduce vibration and noise generated in the discharge pipe (or the suction pipe).

[0005]

On the other hand, in recent years, as the performance of a cooling device or the like to which the refrigerant pump system is applied has been improved, it has been required to further improve the performance of the refrigerant pump system as described above. ing. In addition, application of the above-described refrigerant pump system to an air conditioner that performs both a cooling operation and a heating operation has been studied. In these cases, the refrigerant pump system must be
It is necessary to operate under conditions of high differential pressure or under conditions where the refrigerant temperature fluctuates greatly. However,
The above-described conventional refrigerant pump system cannot sufficiently cope with these operating conditions, and it is difficult to sufficiently reduce pressure fluctuation caused by pulsation of the liquid refrigerant flowing through the discharge pipe and the like.

[0006] Therefore, the present invention can reliably and sufficiently suppress the pressure fluctuation caused by the pulsation of the refrigerant even under the condition of a large flow rate, a high differential pressure, or a condition in which the refrigerant temperature fluctuates greatly. It is an object of the present invention to provide a refrigerant pump system that can be moderated.

[0007]

According to a first aspect of the present invention, there is provided a refrigerant pump system having an electric motor and a pump mechanism incorporated in a closed container, which sucks refrigerant through a suction pipe and discharges the refrigerant. In a refrigerant pump system that discharges from a pipe, a plurality of pulsation mitigating containers each having a heating unit are connected to at least one of the suction pipe and the discharge pipe.

This refrigerant pump system is applied to, for example, an air conditioner and is used to transfer refrigerant. The refrigerant pump system uses a pump mechanism driven by an electric motor to suck the refrigerant through a suction pipe. The refrigerant discharged from the discharge pipe is discharged. A plurality of pulsation mitigation containers are connected to at least one of the suction pipe and the discharge pipe. Each pulsation alleviating container has a closed space with a predetermined volume inside and is provided with a heating means at an outer peripheral portion or the like, and at least one of a suction pipe and a discharge pipe via a short communication pipe having a small diameter. Connected to one side. Thus, during operation of the refrigerant pump system, part of the refrigerant flowing through at least one of the suction pipe and the discharge pipe flows into the pulsation mitigation container. The refrigerant flowing into the pulsation mitigation container evaporates inside the pulsation mitigation container being heated by the heating means.

Here, the configuration in which each pulsation alleviating container is connected to at least one of the suction pipe and the discharge pipe by a communication pipe is the same as the one that models the so-called Helmholtz resonance principle. In this case, the resonance frequency can be determined from the volume of the pulsation mitigating container, the cross-sectional area of the flow path of the communication pipe, and the flow path length. Therefore, by changing the resonance frequency of each pulsation mitigation container in advance according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition, and the like in the refrigerant pump system, the operating condition of the refrigerant pump system changes. Even so, at least one of the pulsation mitigating containers can absorb the pulsation generated in the suction pipe and the discharge pipe. As a result, according to the refrigerant pump system, even when the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like is widened, the vibration and noise generated in the discharge pipe and the suction pipe are favorably reduced. be able to.

Preferably, each pulsation alleviating container is connected to at least one of a suction pipe and a discharge pipe via a communication pipe provided with an on-off valve in the middle.

With such a configuration, it is possible to appropriately select a pulsation mitigation vessel through which the refrigerant flows by opening and closing the respective on-off valves according to the operating conditions of the refrigerant pump system. Thus, for a certain operating condition, the inflow of the refrigerant into the pulsation mitigation container in which the pulsation absorption effect based on the preset resonance frequency is small is stopped, and the heat absorption of the refrigerant in the pulsation mitigation container is effectively reduced. It can be reduced.

Further, at least one of the suction pipe and the discharge pipe has a switching valve in the middle, and is branched into a plurality of branches downstream of the switching valve. Preferably, it is connected to a branch.

Even if such a configuration is adopted, it is possible to appropriately select a pulsation mitigation vessel through which the refrigerant flows by operating the switching valve according to the operating conditions of the refrigerant pump system. Thus, for a certain operating condition, the inflow of the refrigerant into the pulsation mitigation container in which the pulsation absorption effect based on the preset resonance frequency is small is stopped, and the heat absorption of the refrigerant in the pulsation mitigation container is effectively reduced. It can be reduced. In addition, by arranging the pulsation mitigation containers in parallel in this manner, it is possible to shorten the length of the suction pipe and the discharge pipe, thereby increasing the pressure loss due to the long pipe length. Can be suppressed.

According to a fourth aspect of the present invention, there is provided a refrigerant pump system having an electric motor and a pump mechanism built in a closed container, wherein the refrigerant pump sucks refrigerant through a suction pipe and discharges the refrigerant from a discharge pipe. In the system, at least one of the suction pipe and the discharge pipe is connected to a pulsation mitigating container provided with a heating means via a plurality of communication pipes, and is connected to at least one of the plurality of communication pipes. Is characterized in that an on-off valve is provided.

This refrigerant pump system is also applied to, for example, an air conditioner, and is used for transferring refrigerant. The refrigerant pump system uses a pump mechanism driven by an electric motor to suck the refrigerant through a suction pipe. The refrigerant discharged from the discharge pipe is discharged. A pulsation mitigating container is connected to at least one of the suction pipe and the discharge pipe via a plurality of communication pipes. The pulsation alleviating container has a closed space with a predetermined volume inside and a heating means at an outer peripheral portion or the like. Also,
At least one of the communication pipes is provided with an on-off valve. By operating the on-off valve appropriately during the operation of the refrigerant pump system, a part of the refrigerant is reduced in pulsation through one or more or all of the plurality of communication pipes. It will flow into the container. The refrigerant flowing into the pulsation mitigation container evaporates inside the pulsation mitigation container being heated by the heating means.

Here, the configuration in which the pulsation mitigating container is connected to at least one of the suction pipe and the discharge pipe by a plurality of communication pipes is also the same as the one that models the so-called Helmholtz resonance principle. Then, in this refrigerant pump system, the resonance frequency is different for each case in which the pulsation mitigation container and the discharge pipe or the like are communicated via any one, a plurality, or all of the plurality of communication pipes. Can be made. Thereby, according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition, and the like in the refrigerant pump system, the communication pipe that communicates the pulsation mitigation container and the discharge pipe or the like is appropriately selected and combined, so that the refrigerant pump system can be used. It is possible to obtain a pulsation absorbing effect corresponding to the change in the operating conditions. As a result, according to the refrigerant pump system, even when the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like is widened, the vibration and noise generated in the discharge pipe and the suction pipe are favorably reduced. be able to.

In this case, it is preferable that at least one of the plurality of communication pipes has a flow path length different from that of the other communication pipes.

As described above, at least one of the plurality of communication pipes is bent so that the length of the flow path is different from that of the other communication pipes. The degree of freedom in setting different resonance frequencies can be further increased for each case in which the pulsation mitigation container and the discharge pipe or the like are communicated via one or more or all of them.

According to a sixth aspect of the present invention, there is provided a refrigerant pump system having an electric motor and a pump mechanism incorporated in a closed container, wherein the refrigerant is sucked through a suction pipe and discharged from a discharge pipe. In the system, at least one of the suction pipe and the discharge pipe is connected via a first communication pipe to a pulsation mitigation vessel provided with a heating means, and in the middle of the first communication pipe, A switching valve connected to the pulsation mitigating container via the second communication pipe is provided.

This refrigerant pump system is also applied to, for example, an air conditioner, and is used to transfer refrigerant. The refrigerant pump system uses a pump mechanism driven by an electric motor to suck the refrigerant through a suction pipe. The refrigerant discharged from the discharge pipe is discharged. A pulsation mitigation container is connected to at least one of the suction pipe and the discharge pipe via a first communication pipe. The pulsation alleviating container has a closed space with a predetermined volume inside and a heating means at an outer peripheral portion or the like.

A switching valve is provided in the middle of the first communication pipe. This switching valve (outlet port) is connected to the pulsation mitigating container via the second communication pipe. Accordingly, if the switching valve is appropriately operated during the operation of the refrigerant pump system, a part of the refrigerant flows into the pulsation mitigation container via one of the first communication pipe and the second communication pipe. Will be. The refrigerant flowing into the pulsation mitigation container evaporates inside the pulsation mitigation container being heated by the heating means.

Here, the structure in which the pulsation mitigation container is connected to at least one of the suction pipe and the discharge pipe by the first communication pipe and the second communication pipe as described above also uses the so-called Helmholtz resonance principle. This is the same configuration as modeled. Then, in this case, by making the flow path length, the flow path cross-sectional area, and the like of the first communication pipe and the second communication pipe different, one of the first and second communication pipes is used. A different resonance frequency can be set for each case in which the pulsation mitigation container communicates with the discharge pipe or the like. This allows
Depending on the flow rate condition of the refrigerant in the refrigerant pump system, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like, by appropriately selecting a communication pipe for communicating the pulsation mitigation container with the discharge pipe, the operating condition of the refrigerant pump system is A pulsation absorption effect corresponding to the change can be obtained. As a result, according to the refrigerant pump system, even when the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like is widened, the vibration and noise generated in the discharge pipe and the suction pipe are favorably reduced. be able to.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a refrigerant pump system according to the present invention will be described below in detail with reference to the drawings.

[First Embodiment] FIG. 1 is a sectional view showing a refrigerant pump system according to the present invention. The refrigerant pump system 1 shown in FIG. 1 is suitably applied to an air conditioner (not shown) that enables both a cooling operation and a heating operation, and is used to transfer a liquid refrigerant. The refrigerant pump system 1 includes a hermetic pump unit 2 as shown in FIG. The hermetic pump unit 2 includes a closed container 3 including a main body 3a, a top cover 3b, and a bottom cover 3c.
The motor 4 and the pump mechanism 5 are built in. The electric motor 4 has a stator 4a fixed to the main body 3a, and a rotor 4b connected to the crankshaft 6, and receives electric power from the outside via an electrode terminal 7 attached to the upper lid 3b.

The pump mechanism 5 is configured as a so-called positive displacement pump mechanism, and is connected to the electric motor 4 via a crankshaft 6. The pump mechanism 5 has a cylinder block 11 in which a suction chamber (not shown), a compression chamber 8, a suction port 9, a discharge port 10, and the like are formed. Inside the cylinder block 11, the crankshaft 6
A rolling piston 12 fixed to the end of the housing is accommodated. The suction port 9 is connected to a suction pipe 14 penetrating the closed container 3, and the discharge port 10 is connected to a discharge pipe 15 penetrating the closed container 3. Thereby, when the electric motor 4 is operated, the electric motor 4 is operated via the suction pipe 14 and the suction port 9.
The liquid refrigerant is sucked into the suction chamber of the pump mechanism 5, and the liquid refrigerant pressurized in the compression chamber 8 is discharged from the discharge pipe 15 through the discharge port 10.

On the other hand, the discharge pipe 15 connected to the hermetic pump unit 2 has enlarged diameter portions 16a and 16b at two places in the middle as shown in FIG. And each enlarged diameter part 1
Pulsation mitigation containers 18a and 16b are connected to communication pipes (rising pipes) 17a and 17b extending substantially vertically in the vertical direction.
a and 18b are connected one by one. Each of the pulsation alleviating containers 18a and 18b is configured as a closed container having a predetermined capacity, and a sheath heater (heating means) 19 is provided on the outer periphery of each container. Each of the communication pipes 17a and 17b is made of a short and small-diameter tube material having a predetermined flow path cross-sectional area (inner diameter) and a flow path length.

In the refrigerant pump system 1 configured as described above, during operation, a part of the refrigerant flowing through the discharge pipe 15 is relieved of pulsation through the enlarged diameter portions 16a and 16b and the communication pipes 17a and 17b. It flows into both containers 18a and 18b. The refrigerant flowing into the pulsation mitigation containers 18a and 18b evaporates inside the pulsation mitigation containers 18a and 18b heated by the sheath heater 19.
Here, each of the pulsation mitigating containers 18a and 18b is connected to the communication pipe 17.
a, 17b, the enlarged diameter portions 16a, 16b of the discharge pipe 15
Is a configuration similar to that obtained by modeling the so-called Helmholtz resonance principle.

That is, each pulsation alleviating container 18a, 18b
The volume V _a, V _b, the communicating tube 17a, the flow path cross-sectional area of S _a of 17b, S _b, the communicating tube 17a, the flow path length of 17b l _a, if l _b, each pulse relaxation containers 18a, each 18b, Helmholtz resonance frequency f _a, the _{f b, f a = (c} / 2π) · √ (Co a / V) ... (1) f b = (c / 2π) · √ (Co _b / V) (2) Where Co _a = S _a / l _a , Co _b
= A S _b / l _b.

Therefore, according to the refrigerant flow conditions, the differential pressure conditions, the refrigerant temperature fluctuation conditions, etc., in the refrigerant pump system 1, the volume V
_a , _Vb , the cross-sectional area S _{a of} each communication pipe 17a, 17b,
S _b, and the channel length l _a, by previously made different appropriately and l _b set appropriately to resonance and the resonance frequency f _a frequency f _b, the operating conditions the coolant pump system 1 greatly changes Also, the pulsation generated in the discharge pipe 15 can be reliably absorbed by at least one of the pulsation mitigation containers 18a and 18b.

For example, when the refrigerant pump system 1 is applied to an air conditioner capable of operating in a cooling / heating operation, the pulsation mitigation vessel 18 is used.
The resonant frequency f _a of a, and sets on the basis of the standard coolant temperature during cooling operation, the resonance frequency f _b of the pulsation relaxation container 18b, and set on the basis of the standard coolant temperature during the heating operation deep. Accordingly, even when the refrigerant temperature greatly fluctuates due to switching of the cooling / heating operation or the like and the physical property value such as the sound speed changes, the discharge pipe 15 is surely generated by one of the pulsation mitigation containers 18a and 18b. Pulsation can be absorbed. As described above, according to the refrigerant pump system 1, even if the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like are widened, the vibration and the noise generated in the discharge pipe 15 can be favorably reduced. Can be.

By setting the cross-sectional area (inner diameter) of the flow path of the enlarged diameter portions 16a, 16b to be sufficiently larger than the cross-sectional area (inner diameter) of the flow path of the discharge pipe 15, each of the pulsation reducing containers 18a,
The pulsation absorption effect in 18b can be further improved. The pulsation absorbing effect of each of the pulsation mitigating containers 18a and 18b acts additively. Even if the refrigerant flowing through the discharge pipe 15 flows into all the pulsation mitigating containers 18a and 18b, the pulsation absorbing effect is reduced. It does not lower. Further, the above-described refrigerant pump system 1 includes:
Of the suction pipe 14 and the discharge pipe 15, the discharge pipe 15 has been described as being provided with a plurality of pulsation mitigating containers 18a and 18b, but the present invention is not limited to this. That is,
The plurality of pulsation mitigation containers 18a and 18b may be provided for the suction pipe 14, or may be provided for both the suction pipe 14 and the discharge pipe 15.

FIG. 2 is a schematic configuration diagram showing another embodiment of the first embodiment of the refrigerant pump system according to the present invention. The refrigerant pump system 1A shown in FIG. 2 includes a communication pipe 17 provided in the refrigerant pump system 1 shown in FIG.
On-off valves Va and Vb are provided in the middle of a and 17b, respectively. Thus, each pulsation mitigation container 18
Communication pipe 1 provided with on-off valves Va, Vb halfway through a, 18b
If it is connected to the discharge pipe 15 via 7a, 17b, one or both of the on-off valves Va, Vb are opened in accordance with the operating conditions of the refrigerant pump system 1, thereby pulsating the refrigerant to flow. The relaxation containers 18a and 18b can be appropriately selected.

Thus, for a certain operating condition, the flow of the refrigerant into the pulsation mitigation vessel 18a or 18b in which the pulsation absorption effect based on the preset resonance frequencies f _a and f _b is small is stopped, and Pulsation mitigation container 18a
Alternatively, the heat absorption of the refrigerant in 18b can be effectively reduced. In this case, also in this case, the plurality of pulsation mitigation containers 18 are used.
a, 18 b may be provided for the suction pipe 14, or may be provided for both the suction pipe 14 and the discharge pipe 15.

FIG. 3 is a schematic diagram showing still another aspect of the first embodiment of the refrigerant pump system according to the present invention. The refrigerant pump system 1B shown in FIG. 3 differs from the refrigerant pump system 1 shown in FIG. 1 in that the pulsation mitigation containers 18a and 18b are provided in parallel with the discharge pipe 15. That is, as shown in FIG. 3, the discharge pipe 15 has a switching valve Vc in the middle, and is branched into a plurality of branch portions 15a and 15b downstream of the switching valve Vc. Each of the branch portions 15a, 15b is provided with an enlarged diameter portion 16a, 1
6b, and merges again downstream of the enlarged diameter portions 16a, 16b. And the pulsation mitigation containers 18a, 18
b is connected to the enlarged diameter portions 16a and 16b provided in the branch portions 15a and 15b, respectively, via communication pipes 17a and 17b.

By operating the switching valve Vc in accordance with the operating conditions of the refrigerant pump system 1B having the above-described structure, the pulsation mitigation vessel 18 through which the refrigerant flows can be provided.
a or 18b can be appropriately selected. Thus, relative to operating conditions, to stop the flow of refrigerant for advance have been set resonance frequency f _a, pulsating relaxation vessel 18a or 18b so that pulsation absorbing effect based on f _b is small, the pulsation relaxation container The heat absorption of the refrigerant in 18a or 18b can be effectively reduced. Also, by disposing the pulsation mitigation containers 18a and 18b in parallel in this manner, the length of the discharge pipe 15 (suction pipe 14) can be shortened. Pressure loss can be suppressed from increasing. In this case as well, the plurality of pulsation mitigating containers 18a and 18b are connected to the suction pipe 1
4 may be provided, or both the suction pipe 14 and the discharge pipe 15 may be provided.

[Second Embodiment] Hereinafter, a second embodiment of the refrigerant pump system according to the present invention will be described in detail with reference to FIG. Note that the same reference numerals are given to the same elements as those described in regard to the above-described first embodiment, and redundant description will be omitted.

FIG. 4 shows a refrigerant pump system 1C according to the first embodiment.
Similarly to the above, a closed pump unit (both not shown) having an electric motor and a pump mechanism built in a closed container, which sucks a refrigerant through a suction pipe (not shown) and discharges the refrigerant from a discharge pipe 15 It is. The discharge pipe 15 has an enlarged diameter portion 1 having a flow path cross-sectional area sufficiently larger than its flow path cross-sectional area.
6 is provided in one place on the way. Further, in the refrigerant pump system 1C, a plurality of (two in the present embodiment) communication pipes 17a and a plurality of pulsation mitigation containers 18 each having a sheath heater 19 as a heating means are provided in the enlarged diameter portion 16 of the discharge pipe 15. 17b
Connected through. And each communication pipe 17a, 1
7b, the communication pipe 17a is provided with an on-off valve Va.

In the refrigerant pump system 1C configured as described above, during the operation, the refrigerant flow condition, the differential pressure condition,
By appropriately opening and closing the on-off valve Va according to the temperature fluctuation condition of the refrigerant, etc., a part of the refrigerant flowing through the discharge pipe 15
The fluid flows into the pulsation mitigation vessel 18 only through the communication pipe 17b or through both the communication pipes 17a and 17b. Then, the refrigerant flowing into the pulsation alleviating container 18 is:
It evaporates inside the pulsation alleviating container 18 heated by the sheath heater 19.

Here, as in the present embodiment, the pulsation mitigation container 18 is connected to the discharge pipe 15 by a plurality of communication pipes 17a and 17b.
Also has the same configuration as that of modeling the so-called Helmholtz resonance principle. In this case, the resonance frequency can be made different between the case where the discharge pipe 15 and the pulsation mitigating container 18 are communicated only by the communication pipe 17b and the case where they are communicated by both the communication pipes 17a and 17b. That is, the resonance frequency f _b when the discharge tube 15 and the pulsation relaxation container 18 made to communicate only by communicating pipe 17b is as shown in the above (2), communicating the discharge pipe 15 and the pulsation relaxation vessel 18 Tubes 17a, 17b
Resonant frequency f _r when the communicated by both may be defined as _{f r = (c / 2π)} · √ (ΣCo / V) ... (3). Here, ΣCo is given by ΣCo = れ ば Co, where S _i is the flow path cross-sectional area of the communication pipe and l _i is the flow path length of the communication pipe.
_{Σ (S i / l i)} = a _{S a / l a + S b} / l b.

Thus, in the refrigerant pump system 1C, the pulsation mitigation vessel 18 and the discharge pipe 1 are controlled in accordance with the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition and the like during operation.
By appropriately selecting and combining the communication pipes 17a and 17b that communicate with the valve 5, it is possible to obtain a pulsation absorption effect corresponding to a change in operating conditions. As a result, according to the refrigerant pump system 1C, it is possible to satisfactorily reduce the vibration and noise generated in the discharge pipe 15 even when the range of the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition, and the like is increased. it can.

FIG. 5 is a sectional view showing another aspect of the second embodiment of the refrigerant pump system according to the present invention.
The refrigerant pump system 1D shown in FIG. 4 includes communication pipes 17a and 17b included in the refrigerant pump system 1C shown in FIG.
Correspond to those provided with on-off valves Va and Vb. In the refrigerant pump system 1D configured as described above, during operation, the on-off valve Va and the on-off valve Vb are appropriately opened and closed according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition, and the like. Some of the refrigerant flowing through the discharge pipe 15 is
Only the communication pipe 17a, only the communication pipe 17b, or the communication pipe 1
It flows into the pulsation mitigation container 18 via both 7a and 17b.

In this case, the discharge pipe 15 and the pulsation reducing container 18
Are communicated only by the communication pipe 17a, when the communication is performed only by the communication pipe 17b, and when the communication pipe 17b is
The resonance frequency can be made different from the case where the communication is made by both of a and 17b. That is, the discharge pipe 15
The resonance frequency f _a when the pulsation mitigation container 18 and the pulsation mitigation container 18 are communicated only by the communication pipe 17a is as shown in the above equation (1), and the resonance frequency f _b when the communication is performed only by the communication pipe 17b is: As shown in the above equation (2), the discharge pipe 15 and the pulsation mitigating container 18 are connected with the communication pipes 17a and 17b.
Resonant frequency f _r when the communicated by both is as shown in equation (3) of the.

Thus, in the refrigerant pump system 1D, the pulsation mitigation vessel 18 and the discharge pipe 1 are changed according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition and the like during operation.
By appropriately selecting and combining the communication pipes 17a and 17b that communicate with the valve 5, it is possible to obtain a pulsation absorption effect that is finely adapted to changes in operating conditions. As a result, according to the refrigerant pump system 1D, even if the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like is widened, the vibration and noise generated in the discharge pipe 15 can be reduced extremely favorably. be able to.

FIG. 6 is a sectional view showing still another aspect of the second embodiment of the refrigerant pump system according to the present invention. The refrigerant pump system 1E shown in FIG. 5 includes communication pipes 17a, 17a included in the refrigerant pump system 1D shown in FIG.
7b, the flow path length of one communication pipe 17b is set to be longer than the flow path length of the other communication pipe 17a. As described above, at least one of the plurality of communication pipes 17a and 17b is bent so that the length of the flow path is different from that of the other communication pipes.
The degree of freedom in setting a different resonance frequency for each case in which the pulsation mitigation container 18 and the discharge pipe 15 are communicated via any one or all of a and 17b is increased. Becomes possible.

It should be noted that also in the above-described second embodiment of the refrigerant pump system according to the present invention, the pulsation buffer 18
May be provided for the suction pipe 14 or for both the suction pipe 14 and the discharge pipe 15. Also, the above-described refrigerant pump systems 1C to 1E connect the discharge pipe 15 and the pulsation mitigating container 18 to each of the two communication pipes 17a and 17b.
However, the present invention is not limited to this. That is, the discharge pipe 15 and the pulsation mitigating container 18 may be connected via three or more communication pipes. In this case, the on-off valve may be provided in at least one of the communication pipes. In addition, in order to make the resonance frequency different, the flow passage cross-sectional areas of the plurality of communication pipes may be set to be different from each other.

[Third Embodiment] Hereinafter, a third embodiment of the refrigerant pump system according to the present invention will be described in detail with reference to FIG. Note that the same reference numerals are given to the same elements as those described in regard to the above-described first embodiment and the like, and redundant description will be omitted.

The refrigerant pump system 1F shown in FIG. 7 also has a hermetic pump unit (both not shown) having a motor and a pump mechanism built in a hermetic container, similarly to the above-described refrigerant pump systems 1 to 1E. Then, the refrigerant is sucked through a suction pipe (not shown) and discharged from the discharge pipe 15. The discharge pipe 15 includes an enlarged diameter portion 16 having a flow path cross-sectional area sufficiently larger than the flow path cross-sectional area at one position. In the refrigerant pump system 1F, the discharge pipe 1
5 is provided with a sheath heater 19 as a heating means.
Is connected via a first communication pipe 17a. A switching valve Vc is provided in the middle of the first communication pipe 17a. This switching valve Vc
The (outlet port) is connected to the pulsation mitigation vessel 18 via the second communication pipe 17b. The second communication pipe 17b is configured as shown in FIG.
As shown in the figure, the first communication pipe 17a is bent.
It has a longer flow path length.

Thus, in the refrigerant pump system 1F, if the switching valve Vc is appropriately operated according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition and the like during operation,
Part of the refrigerant is supplied to the pulsation mitigation container 18 via the first communication pipe 17a or to the second communication pipe 17b (and the first communication pipe 17a
) Flows into the pulsation mitigation container 18 through the Then, the refrigerant flowing into the pulsation alleviating container 18 is:
It evaporates inside the pulsation alleviating container 18 heated by the sheath heater 19.

Here, as in the present embodiment, the configuration in which the pulsation mitigation container is connected to the discharge pipe 15 by the first communication pipe 17a and the second communication pipe 17b is the same as the one that models the so-called Helmholtz resonance principle. Configuration. And
In this case, by making the flow path length, the flow path cross-sectional area, and the like of the first communication pipe 17a and the second communication pipe 17b different, one of the first communication pipe 17a and the second communication pipe 17b is interposed. A different resonance frequency can be set for each case where the pulsation alleviating container 18 and the discharge pipe 15 are communicated.

Accordingly, the communication pipes 17a and 17b for communicating the pulsation mitigation vessel 18 and the discharge pipe 15 are appropriately selected according to the refrigerant flow condition, the differential pressure condition, the refrigerant temperature fluctuation condition and the like in the refrigerant pump system 1F. By doing so, it is possible to obtain a pulsation absorbing effect corresponding to a change in operating conditions. As a result, according to the refrigerant pump system 1F, even if the range of the flow rate condition of the refrigerant, the differential pressure condition, the temperature fluctuation condition of the refrigerant, and the like is increased, the vibration and noise generated in the discharge pipe 15 and the suction pipe 14 can be reduced satisfactorily. Can be reduced. In addition,
Also in this case, a plurality of pulsation mitigation containers 18a and 18b may be provided for the suction pipe 14, or may be provided for both the suction pipe 14 and the discharge pipe 15.

[0051]

Since the refrigerant pump system according to the present invention is configured as described above, the following effects can be obtained. That is, in the refrigerant pump system according to the present invention, first, at least one of the suction pipe and the discharge pipe is connected to a plurality of pulsation mitigating containers each having a heating unit. Secondly, in the refrigerant pump system according to the present invention, at least one of the suction pipe and the discharge pipe is connected to the pulsation mitigation vessel provided with the heating means via the plurality of communication pipes. At least one of the communication pipes is provided with an on-off valve. And
Third, in the refrigerant pump system according to the present invention, at least one of the suction pipe and the discharge pipe is connected to the pulsation mitigation vessel provided with the heating means via the first communication pipe, and A switching valve connected to the pulsation mitigation vessel via the second communication pipe is provided in the middle of the communication pipe.
As a result, even under a condition of a large flow rate and a high differential pressure, or under a condition in which the refrigerant temperature fluctuates greatly, the pressure fluctuation caused by the pulsation of the refrigerant can be reliably and sufficiently mitigated.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a first embodiment of a refrigerant pump system according to the present invention.

FIG. 2 is a schematic configuration diagram showing another aspect of the first embodiment of the refrigerant pump system according to the present invention.

FIG. 3 is a schematic configuration diagram showing still another aspect of the first embodiment of the refrigerant pump system according to the present invention.

FIG. 4 is a sectional view showing a second embodiment of the refrigerant pump system according to the present invention.

FIG. 5 is a sectional view showing another aspect of the second embodiment of the refrigerant pump system according to the present invention.

FIG. 6 is a sectional view showing still another aspect of the second embodiment of the refrigerant pump system according to the present invention.

FIG. 7 is a sectional view showing a third embodiment of the refrigerant pump system according to the present invention.

[Explanation of symbols]

1, 1A, 1B, 1C, 1D, 1E, 1F: refrigerant pump system, 2: sealed pump unit, 3: sealed container,
4 ... Electric motor, 5 ... Pump mechanism, 14 ... Suction pipe, 15 ... Discharge pipe, 15a, 15b ... Branch section, 16, 16a, 16b
... Expansion part, 17a, 17b ... Communication pipe, 18, 18a, 1
8b: pulsation mitigating container, 19: sheath heater (heating means), Va, Vb: open / close valve, Vc: switching valve.

Claims (6)

[Claims] 1. A refrigerant pump system having an electric motor and a pump mechanism incorporated in a closed container, wherein refrigerant is sucked through a suction pipe and discharged from a discharge pipe. , At least one of which is connected to a plurality of pulsation mitigating containers each provided with a heating means. 2. The pulsation mitigation container is connected to at least one of the suction pipe and the discharge pipe via a communication pipe provided with an on-off valve in the middle. 2. The refrigerant pump system according to 1. 3. The pulsation mitigation container, wherein at least one of the suction pipe and the discharge pipe has a switching valve in the middle and is branched into a plurality of branch portions downstream of the switching valve. The refrigerant pump system according to claim 1, wherein the refrigerant pump is connected to each of the branch portions. 4. A refrigerant pump system having an electric motor and a pump mechanism built in a closed container, wherein the refrigerant is sucked through a suction pipe and discharged from a discharge pipe. A pulsation mitigating vessel provided with a heating means is connected to at least one of the plurality of communication pipes through a plurality of communication pipes, and at least one of the plurality of communication pipes is provided with an on-off valve. A refrigerant pump system characterized by the above-mentioned. 5. The refrigerant pump system according to claim 4, wherein at least one of the plurality of communication pipes has a flow path length different from that of the other communication pipes. . 6. A refrigerant pump system having an electric motor and a pump mechanism built in a closed container, wherein the refrigerant is sucked through a suction pipe and discharged from a discharge pipe. A pulsation mitigating vessel provided with a heating means is connected to at least one of the pulsation mitigation vessels via a first communication pipe, and the pulsation mitigation vessel is provided with a second communication pipe in the middle of the first communication pipe. A refrigerant pump system comprising a switching valve connected to a pulsation alleviating container.