JP5642648B2 - Ice machine - Google Patents

Description

  The present invention relates to an ice making machine including a refrigeration mechanism that uses a flammable refrigerant and a refrigerant detection means that can detect refrigerant leaked from the refrigeration mechanism.

  The refrigeration mechanism in an ice making machine circulates a refrigerant in a circuit configured by connecting a compressor, a condenser, an expansion valve, and an evaporator by piping. The refrigeration mechanism uses a compressor to convert the refrigerant to a high-pressure gas, the condenser to cool the refrigerant to a high-temperature liquid, the expansion means to adiabatically expand the liquid, and the evaporator to vaporize the refrigerant. The evaporator is cooled by heat. As the refrigerant, a hydrocarbon (HC) refrigerant having no ability to destroy the ozone layer and having a low global warming potential is employed.

  Hydrocarbon refrigerants are flammable. For this reason, a refrigerant detection sensor is provided in a machine room in which a compressor and a condenser constituting the refrigeration mechanism are provided, and an ice making part room in which an evaporator is provided to detect refrigerant leaking from the refrigeration mechanism. Yes. In addition, the refrigerator provided with the refrigerant | coolant detection sensor is disclosed by patent document 1. FIG.

Japanese Patent Laid-Open No. 10-111061

  The sensor is desired to detect the refrigerant with high sensitivity in order to ensure safety. Therefore, a highly sensitive sensor that improves the performance of the sensor itself is used. However, high-sensitivity sensors are expensive, which increases manufacturing costs. Also, the hydrocarbon refrigerant having a specific gravity greater than that of air flows downward when leaking from the refrigeration mechanism. For this reason, when the leakage location of the refrigerant is away from the sensor, it cannot be detected by the sensor, and there is a problem that the leakage of the refrigerant can be detected only when the leakage of the refrigerant occurs directly above the sensor.

  Accordingly, the present invention has been proposed to solve these problems in view of the above-mentioned problems inherent in the prior art, and provides an ice making machine that can accurately detect leakage of refrigerant without incurring costs. The purpose is to do.

In order to overcome the above-mentioned problems and achieve the intended purpose, an ice making machine according to claim 1 of the present application includes:
Defined in an upper portion of the housing, the evaporator is provided to configure the machine room compressor and the condenser is arranged to constitute a refrigeration mechanism for circulating a flammable refrigerant, a portion of the refrigeration mechanism An ice making mechanism, and an ice making part chamber defined below the machine room inside the housing, and accepts water discharged from the ice making mechanism and tilts downward toward a drain outlet. In the ice making machine in which a drain tray having an inner bottom surface is disposed below the ice making mechanism in the ice making section chamber ,
The drain port of the drain tray is formed at a position biased laterally in the ice making room,
The casing is formed with a space portion that spatially communicates the machine room and the ice making section chamber on an inner surface located on a side where the drain port is formed,
Refrigerant detecting means for detecting the flammable refrigerant that has leaked from the refrigeration mechanism, the subject matter that is disposed in proximity to the right above the front Sharing, ABS Mizuguchi.

According to the invention which concerns on Claim 1, the refrigerant | coolant which leaked from the freezing mechanism and flowed down on the drain tray arrange | positioned under the ice making mechanism flows down toward the drain outlet of a drain tray. And since the leaked refrigerant | coolant collected by this drain outlet and the density | concentration increased is detected with the refrigerant | coolant detection means arrange | positioned above the drain outlet, a leaked refrigerant | coolant can be detected accurately. Therefore, it is possible to accurately detect the leakage of the refrigerant without increasing the performance of the refrigerant detection means itself. Moreover, since it is set as the structure which collects a leakage refrigerant | coolant with the existing drain tray, and it is not necessary to use a highly sensitive refrigerant | coolant detection means, the manufacturing cost of an ice making machine can be held down. Further, the leaked refrigerant can be collected at the drain outlet by the inclination of the inner bottom surface of the drain pan and can be accurately detected by the refrigerant detection means. In addition, since the refrigerant leaked in the machine room defined above the ice making room moves to the ice making room through the space, it leaks not only from the freezing mechanism into the ice making room but also from the freezing mechanism to the machine room. The collected refrigerant can also be collected on a drain pan disposed below the ice making mechanism and detected by a single coolant detection means disposed above the drain outlet. That is, since it is not necessary to dispose the refrigerant detecting means in the ice making room and the machine room, the number of parts is reduced, the number of assembling steps is reduced, and the manufacturing cost of the ice making machine can be suppressed. Further, since the space portion is provided on the side where the drainage port is formed, the leakage refrigerant flowing from the machine room to the ice making unit chamber is efficiently guided to the drainage port and can be accurately detected by the refrigerant detection means.

According to a second aspect of the present invention, the housing is configured by assembling a panel to a frame, and the machine room and the ice making chamber are vertically divided by a partition plate attached to the frame, and the attachment position of the partition plate The outer surface of the frame corresponding to is provided with a ridge extending in the vertical direction,
The gist is that the space is formed between the frame and the panel by the protrusions .

  According to the ice making machine of the present invention, it is possible to accurately detect the leaked refrigerant without increasing the cost.

It is a front view which shows roughly the structure of the ice making machine of an Example in the state which removed the front panel. It is a schematic block diagram of the ice making mechanism and freezing mechanism in the ice making machine of an Example. It is the left view which represented roughly the structure of the ice making machine of an Example. FIG. 4 is a partial cross-sectional view taken along line XX in FIG. 3. FIG. 4 is a partial cross-sectional view taken along line YY in FIG. 3. It is explanatory drawing which shows the relationship between the drain tray of an Example, and a refrigerant | coolant detection sensor, Comprising: (a) is a vertical front view, (b) is a top view.

  Next, a preferred embodiment of the ice making machine according to the present invention will be described below with reference to the accompanying drawings. In the following description, “upper”, “lower”, “left”, “right”, “front”, and “rear” are designated with reference to a state where the ice making machine 10 is viewed from the front as shown in FIG.

  As shown in FIG. 1, the ice making machine 10 according to the embodiment is a stack-on type that is placed on an ice storage 70 that defines an ice storage chamber 72 and has an ice making mechanism 40 and a refrigeration mechanism 30. Further, in the embodiment, a description will be given by taking as an example an injection type ice making machine 10 that generates block-shaped ice blocks I. The ice making machine 10 has a casing 12 that is configured in a substantially box shape by assembling panels 16 on the front, rear, left, right, and top surfaces of the frame 14 forming the exoskeleton. The inside of the housing 12 is divided into a machine room 22 defined above by a partition plate 20 attached to the frame 14 and an ice making part room 24 having a heat insulation structure defined below the machine room 22. It is divided. In the machine room 22, a compressor CM and a condenser CD that constitute the refrigeration mechanism 30, an electrical box CB that controls the ice making machine 10, and other various components are disposed. In the ice making chamber 24, an expansion valve EV, an evaporator EP, and the like constituting the ice making mechanism 40 and the refrigeration mechanism 30 are disposed in the upper part of the ice making unit 24, and a drain pan 54 that receives the waste water from the ice making mechanism 40 below the ice making mechanism 40. Is arranged.

  The machine room 22 can release heat generated from the compressor CM or the like through a large number of air holes 18 provided in the panel 16. The vent hole 18 is provided in a portion of the panel 16 corresponding to the upper side in the machine chamber 22 and is not formed in a portion of the panel 16 corresponding to the lower side in the machine chamber 22. As shown in FIGS. 3 to 5, a machine room is formed between the frame 14 and the panel 16 on the left surface of the housing 12 by a protrusion 26 provided on the outer surface of the frame 14 and extending in the vertical direction. A communication space (space part) 28 is formed to communicate the upper part 22 and the ice making part chamber 24 in the vertical direction. A plurality of ridges 26 are provided in the middle frame portion 14 a corresponding to the arrangement position of the partition plate 20 in the frame 14 so as to be separated in the front-rear direction. The communication space 28 does not impair the heat insulating property of the ice making section chamber 24 because the protruding dimension of the protrusion 26 is very small.

  As shown in FIGS. 1 and 2, the ice making mechanism 40 includes an ice making chamber 42 that defines a large number of ice making chambers 42A that open downward, and is disposed below the ice making chamber 42 so that each ice making chamber 42A has a structure. A water tray 44 provided with a corresponding fountain hole (not shown) for ice making water and a water supply valve WV disposed at the lower portion of the water tray 44 and opened upward and connected to an external water source. An ice-making water tank 46 for storing ice-making water, and a pump provided below the ice-making water tank 46, which sprays ice-making water stored in the ice-making water tank 46 from a water tray 44 and circulates it into each ice making chamber 42A. The motor 48 includes an opening / closing mechanism 50 that tilts the water tray 44 and the ice making water tank 46 integrally. The ice making mechanism 40 is attached to an attachment member 52 installed on the upper part of the ice making section chamber 24. The ice making chamber 42 is fixed to the mounting member 52 in a horizontal state with the opening of each ice making chamber 42A facing downward. In the water tray 44, the left end of the water tray 44 is tiltably supported by the mounting member 52, and the right end of the water tray 44 is connected to an opening / closing mechanism 50 disposed on the mounting member 52. The water tray 44 and the ice making water tank 46 fixed to the water tray 44 are tilted so as to approach and separate from the ice making chamber 42 by operating the opening / closing mechanism 50. The water tray 44 and the ice making water tank 46 are closed so that the water tray 44 is raised so as to close the ice making chamber 42A (shown by a solid line in FIG. 2), and the water tray 44 is lowered so as to open the ice making chamber 42A. The posture is shifted to the released posture (indicated by a two-dot chain line in FIG. 2). The ice making water tank 46 is a bucket-shaped member that opens upward, and in the closed posture, the ice making water tank 46 stores therein a predetermined amount of ice making water supplied from an external water source by opening the supply water valve WV. In the open posture, the stored ice making water is discharged.

  As shown in FIG. 1, below the ice making water tank 46 in the ice making part chamber 24, a drain tray 54 for receiving ice making water discharged from the ice making water tank 46 is provided biased to the left side. As shown in FIG. 6, the drainage tray 54 is configured such that a wall portion 58 having a required height is erected on the end edge of a substantially rectangular bottom plate portion 56, and the drainage plate 54 is drained at a position biased to the left rear side of the bottom plate portion 56. A mouth 60 is formed. The drain tray 54 is formed such that the inner bottom surface 56a that is the upper surface of the bottom plate portion 56 is inclined downward toward the drain port 60, and the drain port 60 is provided at the lowest position on the inner bottom surface 56a. For this reason, the ice making water discharged from the ice making water tank 46 to the drain tray 54 flows down on the inner bottom surface 56 a and is smoothly guided to the drain port 60. The drainage tray 54 is arranged so that the front and rear wall portions 58 and the left wall portion 58 are in contact with the inner wall surface of the housing 12, and between the right wall portion 58 and the inner wall surface of the housing 12, as shown in FIG. An ice passage 62 that communicates the ice storage chamber 72 of the ice storage 70 disposed below the ice making machine 10 with the ice making section chamber 24 is formed. Then, the ice block I generated by the ice making mechanism 40 falls into the ice storage chamber 72 through the ice passage 62.

  As shown in FIGS. 1 and 2, the refrigeration mechanism 30 includes a compressor CM disposed in the machine room 22, a water-cooled condenser CD disposed in the machine room 22, and cooled by cooling water. The expansion valve EV disposed in the upper part of the ice making chamber 24 and the evaporator EP disposed in a meandering manner on the upper surface of the ice making chamber 42 constituting the ice making mechanism 40 disposed in the ice making chamber 24 are piped. The circuit connected by P is filled with a combustible refrigerant. The refrigeration mechanism 30 converts the refrigerant into a high-temperature and high-pressure gas using the compressor CM, cools the refrigerant using the condenser CD to form a high-pressure liquid, adiabatically expands the refrigerant using the expansion valve EV, and uses the evaporator EP to create the ice making chamber 42. The ice making chamber 40 is cooled by exchanging heat with the ice making mechanism 42 to perform the ice making operation. In addition, the refrigeration mechanism 30 is provided with a hot gas valve HV in a pipe P connecting the outlet side of the compressor CM and the inlet side of the evaporator EP, and the hot gas valve HV is opened to open a high temperature from the compressor CM. The ice making mechanism 40 is deiced by supplying a refrigerant (hot gas) to the evaporator EP and exchanging heat with the ice making chamber 42 to heat the ice making chamber 42. Yes.

  The refrigerant is a hydrocarbon refrigerant and has a specific gravity greater than air and is flammable. In the embodiment, a mixed gas such as propane or isobutane is used as the refrigerant, but other flammable refrigerants may be used. When this refrigerant leaks from the compressor CM, the condenser CD, the expansion valve EV, the evaporator EP, and the pipe P connecting them with each other, the leaked refrigerant flows down in the ice making machine 10. To do. When the refrigerant leaks in the ice making chamber 24, the leaked refrigerant that has moved downward in the ice making chamber 24 flows down onto the drain tray 54 and is collected at the drain outlet 60 along the inclination of the inner bottom surface 56a of the drain tray 54 (FIG. The movement of the leaking refrigerant is indicated by an arrow at 6). Even if the refrigerant leaks in the machine room 22, the leaked refrigerant that has moved downward in the machine room 22 is made from the machine room 22 through the communication space 28 formed on the left surface of the housing 12. It can flow down to the chamber 24 (the movement of the leaked refrigerant is indicated by an arrow in FIG. 5). For this reason, not only the refrigerant leaked in the ice making chamber 24 but also the refrigerant leaked in the machine chamber 22 can flow down onto the drain tray 54.

  As shown in FIGS. 1 and 6, a refrigerant detection sensor S as a refrigerant detection means capable of detecting refrigerant leaked from the refrigeration mechanism 30 is attached to the inner wall surface of the housing 12. The refrigerant detection sensor S is a tin oxide semiconductor type, and can appropriately detect a refrigerant made of propane, isobutane, or the like. The refrigerant detection sensor S is electrically connected to the electrical box CB disposed in the machine room 22 and transmits a detection signal to the electrical box CB when the refrigerant is detected. The refrigerant detection sensor S transmits a detection signal when the refrigerant exceeds a predetermined concentration. The refrigerant detection sensor S is provided at a position biased to the left back side in the ice making section chamber 24 and is close to the drain outlet 60 formed in the drain tray 54. As shown in FIG. 6B, “directly above the drain port 60” refers to a state in which the detection unit SD in the refrigerant detection sensor S disposed above the drain port 60 overlaps the drain port 60 vertically. Further, being close to the upper side of the drainage port 60 means that the detection unit SD of the refrigerant detection sensor S is in the flow path of the leaked refrigerant whose concentration is increased by being collected at the drainage port 60 along the inner bottom surface 56a of the drainage tray 54. Say to be located. In the embodiment, as shown in FIG. 6A, the vertical dimension (H) from the drain port 60 to the lower end of the detection unit SD in the refrigerant detection sensor S is from the drain port 60 to the protruding end of the wall 58. It is smaller than twice (2h) the vertical dimension (h).

  Next, the operation of the ice making machine 10 according to the embodiment will be described. In the ice making machine 10, the leaked refrigerant that leaks from the refrigeration mechanism 30, moves downward in the ice making machine 10, and flows down to the drain tray 54, along the inner bottom surface 56 a of the drain tray 54 that is inclined downward toward the drain outlet 60. And collected in the drain 60 (see FIG. 6). In the ice making machine 10, the refrigerant detected at the drain outlet 60 is detected by the refrigerant detection sensor S disposed close to the upper side of the drain outlet 60, so that the refrigerant leaks right above the refrigerant detection sensor S. In addition, the refrigerant that has flowed down to the drain tray 54 can be detected. Further, in the ice making machine 10, since the concentration of the leaked refrigerant is increased by being collected at the drain port 60, the refrigerant can be accurately detected by the refrigerant detection sensor S without increasing the performance of the refrigerant detection sensor S itself. The ice making machine 10 is configured to collect the leaked refrigerant in the existing drain pan 54 that receives the ice making water discharged from the ice making water tank 46, and it is not necessary to use the highly sensitive refrigerant detection sensor S. Can be suppressed.

  The refrigerant leaked in the machine room 22 can move to the ice making part room 24 through the communication space 28 provided in the housing 12 (see FIG. 5). For this reason, not only the refrigerant leaked into the ice making chamber 24 but also the refrigerant leaked into the machine chamber 22 can be detected by one refrigerant detection sensor S provided in the ice making chamber 24. That is, the ice making machine 10 does not need to be provided with the refrigerant detection sensor S in each of the ice making room 24 and the machine room 22, so that the number of parts is reduced and the number of assembling steps is reduced, and the manufacturing cost can be reduced. .

  In the ice making machine 10, the drain outlet 60 of the drain tray 54 is formed at a position biased to the left side in the ice making section chamber 24, and the communication space 28 is formed on the left surface of the housing 12. That is, in the ice making machine 10, since the drain port 60 of the drain tray 54 and the communication space 28 are both formed to be biased to the left side, the leaked refrigerant that has flowed down from the machine room 22 to the ice making part chamber 24 via the communication space 28. Can be efficiently detected by the refrigerant detection sensor S.

  Since the ice making machine 10 employs a water-cooled condenser CD as the condenser CD constituting the refrigeration mechanism 30, there is no need to provide a fan in the machine room 22, and the refrigerant leaked into the machine room 22 is caused by its own weight. It is easy to flow down to the ice making section chamber 24 below 22. Further, since the ice making machine 10 has a configuration in which the vent hole 18 is provided only in a portion of the panel 16 corresponding to the upper side of the machine room 22, the refrigerant leaking into the machine room 22 is difficult to move from the vent hole 18 to the outside. Tends to flow down from the machine room 22 to the ice making room 24. Therefore, when the refrigerant leaks, the leaked refrigerant gathers in the drain tray 54 without being diffused, and the occurrence of the refrigerant leak can be detected at an early stage.

(Example of change)
The present invention is not limited to the above-described embodiments, and can be modified as follows.
(1) In the embodiment, a stack-on type injection type ice making machine having an injection type ice making mechanism and placed on the upper part of the ice storage has been described as an example, but an ice making machine having an ice storage chamber is described. Alternatively, an ice making machine having a flow-down type ice making mechanism may be used.
(2) In the embodiment, the configuration in which the protrusions are provided in the middle frame portion of the frame as the communication space that communicates the machine room and the ice making room is not limited to this, but the machine room and the ice making room are provided in the frame. A communication space may be formed by forming a hole or a groove communicating with each other, or by attaching a heat insulating material to the frame.
(3) In the embodiment, an ice making machine including a water-cooled condenser has been described as an example, but an air-cooled condenser may be used. Further, in the embodiment, an ice making machine in which a machine room and an ice making room are defined in a vertical relationship is adopted inside the housing, but the relationship between the machine room and the ice making room is defined. May be.
(4) In the embodiment, the ice making machine in which the drain outlet and the refrigerant detection sensor are arranged on the left back side in the ice making unit chamber is described as an example, but the refrigerant detection sensor is arranged close to the upper side of the drain outlet. What is necessary is just to be done, and the arrangement | positioning position of a drain outlet or a refrigerant | coolant detection sensor is not limited to the left back side.
(5) In the embodiment, the ice making machine in which the communication space is provided on the left side of the housing has been described as an example. However, the communication space may be provided corresponding to the position where the drainage port is formed.

10 ice making machines, 12 housings, 14 frames, 16 panels, 20 partition plates, 22 machine rooms, 24 ice making room rooms, 26 ridges, 28 communication spaces (space parts), 30 refrigeration mechanisms,
40 ice making mechanism, 54 drainage tray, 56a inner bottom surface, 60 drainage port, CD condenser,
CM compressor, EP evaporator, S refrigerant detection sensor (refrigerant detection means)

Claims (2)

A machine room (22) defined in an upper part of the housing (12) and provided with a compressor (CM) and a condenser (CD) constituting a refrigeration mechanism (30) for circulating a combustible refrigerant; , evaporator which constitutes a part of the refrigeration mechanism (30) ice making mechanism (EP) is provided (40) is disposed, below the machine room (22) in the interior of the housing (12) And a drainage tray (54 ) having an inner bottom surface (56a) inclined toward the drainage port (60) and receiving water discharged from the icemaking mechanism (40). In an ice making machine disposed below the ice making mechanism (40) in the ice making room (24) ,
The drainage port (60) of the drainage tray (54) is formed at a position biased laterally in the ice making section chamber (24),
The casing (12) has a space (28) spatially communicating with the machine room (22) and the ice making room (24) on the inner surface located on the side where the drain port (60) is formed. Formed,
The refrigerant detecting means for detecting the leaked flammable refrigerant from the refrigeration system (30) (S) is a characterized by proximity that <br/> disposed directly above the front Sharing, ABS Mizuguchi (60) Ice machine. The housing (12) is configured by assembling a panel (16) to a frame (14), and the machine room (22) and the ice making room (24) by a partition plate (20) attached to the frame (14). ) Is vertically divided, and on the outer surface of the frame (14) corresponding to the attachment position of the partition plate (20), a protrusion (26) extending in the vertical direction is provided,
The ice making machine according to claim 1, wherein the space portion (28) is formed between the frame (14) and the panel (16) by the protrusion (26) .

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