JP5370116B2 - refrigerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly reliable refrigerator suppressing tracking, ignition and flame spread of a thermostat by a thermo-cover and eliminating a waste space. <P>SOLUTION: The refrigerator includes: a thermocapillary 13 sensing the temperature of a plate-shaped cooler; the thermostat 12 provided to expose between an ice-making compartment and an inner wall of a refrigerator body and performing supply of electricity and blocking with respect to a compressor based on the temperature sensed by the thermocapillary 13; and the thermo-cover fitted to the bottom of the thermostat 12 and covering connection terminals 12e, 12f of the thermostat 12. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a temperature controller for a refrigerator.

  In a thermostat that adjusts the temperature in the refrigerator compartment of a direct-cooling refrigerator, frost is also formed and accumulated on the back of the plate cooler that cools the refrigerator compartment and ice making chamber, and the thermostat is heated when the thermostat is covered with frost. This may affect the thermocapillary detecting the malfunction, or may cause malfunction, or the tracking terminal may be connected to the power supply or the compressor and energized to cause smoke and fire. As a countermeasure, the entire thermostat is covered with a thermo cover to prevent the thermostat from being covered with frost, or a heater is attached to the thermostat to melt the surrounding frost to prevent condensation of the thermostat. (Described in Patent Document 1)

JP 2009-14316 A (page 5-7, FIGS. 1-3, 9-13)

  In a conventional direct-cooling refrigerator, a thermostat is exposed in the vicinity of the plate cooler, and the thermostat is covered with frost, misdetecting the temperature, or connected to a power supply or compressor to be energized Tracking occurred, and the thermostat smoked and ignited, and the surrounding members were ignited and spread.

As a countermeasure, the entire thermostat was covered with the thermo cover. However, air containing water around the thermostat entered the thermo cover from the gaps in the mounting area and the holes for taking out the thermocapillaries and electrical wiring to the outside of the thermo cover. There was a problem that the thermostat caused condensation and tracking, and smoke, fire, and surrounding members ignited and spread.
In addition, the thermo cover covering the entire thermostat has a problem that the material is expensive and expensive.

  In addition, there is an example in which a heater is attached to the thermostat in the thermo cover, but the thermo cover is large and requires a large space for mounting the thermo cover and the thermostat. Food storage for thermostat installation in the refrigerator body There was a problem that a space that could not be widely required.

  In addition, if water adhering to the thermo cover enters and accumulates from the gap of the thermo cover mounting part, the hole for taking out the thermocapillary or electrical wiring to the outside of the thermo cover, etc., the thermostat is used as a countermeasure when the heater is installed. There was a problem that smoked, ignited, and ignited and ignited peripheral members.

  The present invention has been made to solve the above-described problems, and suppresses tracking, ignition, and fire spread of the thermostat with the thermo cover, and also provides a large thermo cover that covers the entire thermostat and a wide mounting space for mounting it. The object is to obtain a highly reliable refrigerator that eliminates the need for space without requiring it.

The present invention provides a thermostat mounting portion between a plate cooler and a thermostat in an ice making chamber, and the thermostat mounting portion is disposed at a position not in contact with the plate cooler to prevent dew or frost from adhering to the thermostat. It is a thing.

The present invention provides a thermostat mounting portion between a plate cooler and a thermostat in an ice making chamber, and the thermostat mounting portion is disposed at a position not in contact with the plate cooler to prevent dew or frost from adhering to the thermostat. As a result, the area covered by the thermo cover is reduced, the thermo cover is reduced in size, and the thermo cover can be attached to the thermostat, the space for installing the thermostat is reduced, and a highly reliable refrigerator that eliminates waste of space is obtained. Can do.

It is a front view which shows the direct cooling type refrigerator in Embodiment 1 of this invention. It is side surface sectional drawing which shows the direct-cooling type refrigerator in Embodiment 1 of this invention. It is sectional drawing of the ice making chamber in Embodiment 1 of this invention. It is a perspective view of the frame of the ice making chamber in Embodiment 1 of this invention. It is explanatory drawing of the thermostat and thermo cover in Embodiment 1 of this invention. It is a perspective view of the thermocover in Embodiment 1 of this invention. It is a wiring diagram of the thermostat in Embodiment 1 of this invention. It is a front view which shows the direct cooling type refrigerator in Embodiment 2 of this invention. It is sectional drawing of the ice making chamber in Embodiment 2 of this invention. It is sectional drawing of the thermocover in Embodiment 2 of this invention. It is a front view which shows the direct-cooling type refrigerator in Embodiment 3 of this invention. It is sectional drawing of the ice making chamber in Embodiment 3 of this invention. It is sectional drawing of the thermocover in Embodiment 3 of this invention. It is a front view which shows the direct cooling type refrigerator in Embodiment 4 of this invention. It is sectional drawing of the ice making chamber in Embodiment 4 of this invention. It is sectional drawing of the thermocover in Embodiment 4 of this invention. It is a front view which shows the direct-cooling type refrigerator in Embodiment 5 of this invention. It is sectional drawing of the ice making chamber in Embodiment 5 of this invention. It is sectional drawing of the thermocover in Embodiment 5 of this invention.

Embodiment 1 FIG.
1 is a front view of a direct cooling refrigerator according to Embodiment 1 of the present invention without a front door, FIG. 2 is a cross-sectional side view taken along the line AA of the direct cooling refrigerator, and FIG. FIG. 4 is a perspective view of a thermostat and a frame, FIG. 5 is an explanatory diagram of a thermostat and a thermo cover, FIG. 6 is an explanatory diagram of the thermo cover, FIG. 7 is a compressor, a thermostat, and a power source for supplying power to them. FIG.

  1 and 2, the refrigerator 1 includes a refrigerator body 2 having a heat insulating structure with a front opening and a front door 6 having a heat insulating structure provided at the front opening. The front door 6 can be opened and closed in the right direction by a hinge device provided on the refrigerator body 2 side. Moreover, between the refrigerator main body 2 and the front door 6 is kept airtight by the packing 7 arrange | positioned at the back side peripheral part of the front door 6. FIG.

In the refrigerator body 2, the upper and lower surfaces and the left and right side surfaces are surrounded by the upper plate cooler 5, and the front surface is opened, and on the opposite rear surface, an ice making chamber 4 formed by the inner wall of the refrigerator body 2 is formed. Has been. The rear side of the ice making chamber 4 and the space between the inner wall of the refrigerator body 2 and the plate cooler 5 are integrated with the inner wall extending from the inner wall of the refrigerator body 2 as shown in 2a in FIGS. The left and right side surfaces protrude, and this surface and the plate-like cooler 5 come into contact with each other to form a wall in which the upper and lower surfaces, the left and right surfaces, and the rear surface are connected to form a space. A synthetic resin frame 8 is attached to the peripheral edge of the front opening of the ice making chamber 4, and a door 9 that can be opened and closed in the right direction is attached to the frame 8. That is, the ice making chamber 4 is a space in which food is taken in and out, which is surrounded by the door 9 on the front, the plate cooler 5 on the left and right sides, and the inner wall of the refrigerator body 2 on the rear.
The refrigerating room 3 below the ice making room 4 is a space in which food is taken in and out, which is surrounded by the inner wall of the refrigerator body 2 at its bottom and left and right sides and whose front is sealed by an openable front door 6. The ice making chamber 4 and the refrigerator compartment 3 are separated by a plate cooler 5.
Note that the side surface of the ice making chamber 4 is not in contact with the inner wall of the refrigerator body 2, and a space surrounded by the side surface of the ice making chamber 4 and the inner wall of the refrigerator body 2 is formed. Although it is not, it is a space connected to the lower refrigerator compartment 3.
Further, the ice making chamber 4 and the lower refrigerator compartment 3 are cooled to a predetermined temperature range by a plate cooler 5.

  A compressor 11 for compressing the refrigerant is installed in the lower part of the refrigerator main body 2, and the compressed refrigerant flows into a condenser 10 attached to the back of the refrigerator main body 2 and is condensed, and a capillary tube having a pressure reducing function. , And is decompressed, then flows into the plate cooler 5 to evaporate and constitutes a refrigeration cycle that returns to the compressor 11 again.

  FIG. 3 is a cross-sectional view of the ice making chamber 4 as viewed from above. A thermostat mounting portion 16 for attaching the thermostat 12 is provided on the side of the ice making chamber 4, on the front right side of the frame 8, and on the back side. A thermostat 12 for controlling the temperature with the chamber 4 is attached. The thermostat mounting portion 16 is composed of a front surface and a rear surface that are the frame body 8, a left side surface on which the ice making chamber 4 is disposed, and a lower surface on which the refrigerator compartment 3 is disposed, and is a synthetic resin integrated with the frame body 8. When the thermostat 12 is attached, each surface is surrounded and covered. Further, the left side surface of the thermostat mounting portion 16 is in a position away from the plate cooler 5 that forms the ice making chamber 4, and the left side surface of the thermostat mounting portion 16 faces the plate cooler 5. A heat insulating material tape 19 is affixed to the thermostat mounting portion 16 for heat insulation. In addition, although the thermostat attaching part 16 has taken as an example what was integrally molded with the frame 8, you may assemble a separate molded component. Further, the position where the heat insulating tape 19 is affixed may be on the thermostat 12 side of the thermostat mounting portion 16 or on the plate-like cooler 5 only by changing the heat insulating effect and the assembling property. A space 17 formed between the ice making chamber 4 and the inner wall of the refrigerator body 2 is a space connected to the lower refrigerator compartment 3.

FIG. 4 is a perspective view of the frame body 8 and is a view for explaining the attachment of the thermostat 12 to the thermostat mounting portion 16.
The thermostat 12 is fitted and fixed while being sandwiched between the front surface of the thermostat 12 and the front surface portion 16a of the thermostat mounting portion 16, and the rear surface of the thermostat 12 and the rear surface portion 16b of the thermostat mounting portion 16. First, the front surface of the thermostat 12 is fixed by fitting the thermostat mounting bracket A12b and the mounting bracket B12c on the front surface of the thermostat 12 with the not-shown claw on the thermostat 12 mounting side of the front surface portion 16a of the thermostat mounting portion 16. ing. The thermostat mounting bracket A12b and the mounting bracket B12c are disposed above and below the dial shaft 12d of the thermostat 12, and the claw to be fixed on the front surface portion 16a is also disposed above and below the hole 8a formed in the frame body 8. In other words, the thermostat 12 is fixed at a fitting position located above and below the main body of the thermostat 12. The thermostat mounting bracket A12b and the mounting bracket B12c have the same width as the lateral width of the thermostat 12. Further, the rear surface of the thermostat 12 is fixed by fitting with the claws on the rear portion of the main body 12 a of the thermostat 12 and the rear surface portion 16 b of the thermostat mounting portion 16. As described above, the thermostat 12 is fixed at the position A in FIG. 4 while being sandwiched between the front surface portion 16a and the rear surface portion 16b of the thermostat mounting portion 16. However, the position of (a) in FIG. 4 is a position away from the left side surface portion 16c of the thermostat mounting portion 16, that is, there is a gap between the thermostat 12 and the left side surface portion 16c. The right side is open to the space. At this time, the dial shaft 12d of the thermostat 12 is passed through the hole 8a formed in the frame body 8, and the tip end of the dial shaft 12d is fitted into the front surface of the frame body 8, and is fitted into the tip end of the dial shaft 12d. The dial knob 15 is mounted to form a thermostat dial.
The electrical wiring 12g attached to the thermostat 12 is connected to the connection terminal A12e and the connection terminal B12f at the bottom of the thermostat 12. Although not shown in FIG. 4, a thermo cover 18 is attached to the bottom of the thermostat 12, and the connection terminals 12e and 12f are accommodated in the thermo cover 18, and in this state, the thermostat 12 is fixed to the position of "a". The
In this example, an example in which the thermostat mounting portion 16 and the thermostat 12 are mounted on the left side of the ice making chamber 4 has been described. However, this may be at any position as long as the space is connected to the refrigerator compartment 3 around the ice making chamber 4. For example, the right side of the ice making chamber 4 may be used.

FIG. 5 is a left side view of the thermostat 12 with the thermo cover 18 attached thereto. That is, the thermostat 12 shown in FIG. 4 is viewed from the left, and a thermo cover 18 is attached to the thermostat 12. However, only the inside of the thermo cover 18 is a cross-sectional view for explanation. There are connection terminals 12e and 12f at the bottom of the thermostat 12, and although not shown in FIG. 5, an electrical wiring 12g is connected to the compressor 11 and a power source. A thermo cover 18 is mounted so as to cover the bottom and cover the connection terminals 12e and 12f, and the electric wiring 12g is taken out from a wiring hole provided in the thermo cover 18.
The connection terminals 12e and 12f at the bottom of the thermostat 12 are tab terminals on a flat plate, the plate surface of the flat plate, that is, the longitudinal direction faces the side surface of the thermostat 12, and the thickness direction of the flat plate is the front and rear surface, that is, the axis of the dial shaft 12d. Facing the direction. The tab terminals on the flat plate are not aligned on a straight line.
Note that the bottoms of the thermo cover 18 and the thermostat 12 having at least the connection terminals 12e and 12f are made of a flame retardant material. Furthermore, the electrical contact that the thermostat 12 has is located on the bottom side of the thermostat 12 and is housed in a container-shaped housing portion surrounded by the flame retardant material and the six surfaces together with the bottom portion made of the flame retardant material. Only the connection terminals 12e and 12f that are connected to the contacts and connected to the electrical wiring 12g and are energized are led out from the bottom of the storage portion, which is the bottom of the thermostat 12, and are exposed so as to be easily connected to the electrical wiring 12g.
The thermo cover 18 includes a bottom surface provided with wiring holes and four side surfaces, and an upper surface attached to the thermostat 12 is open. A container-shaped storage portion made of a flame-retardant material at the bottom of the thermostat 12 is inserted and fitted in the opened upper portion of the thermo cover 18. That is, the side surface of the bottom storage portion of the thermostat 12, that is, the outer wall 4 surface of the lower side surface of the thermostat 12 and the inner wall surface 4 of the upper side surface of the thermo cover 18 are fitted closely together, and the thermo cover 18 is fitted to the bottom of the thermostat 12. It is fixed. Since the wall surfaces are closely attached to each other, the thermo cover 18 is detached from the thermostat 12 when an external force, that is, a person pulls downward. The thermo cover 18 and the thermostat 12 may be fixed to each other by providing a structure that allows the thermo cover 18 and the thermostat 12 to be fixed so as not to be detached by an external force. However, even in this case, if the fitting part is removed and a person pulls downward, the structure is removed.
Thus, the thermo cover 18 is accommodated in a semi-sealed space formed by the thermo cover 12 with the upper surface being the bottom surface and the side surfaces and the lower surface so as to cover the connection terminals 12e and 12f at the bottom of the thermostat 12.

  6A is a perspective view of the thermo cover 18, FIG. 6B is a plan view, and FIG. 6C is a cross-sectional view taken along the line CC of FIG. 6B. As shown in the plan view of FIG. 6B and the cross-sectional view of FIG. 6C, the bottom surface of the thermo cover 18 is provided with a wiring hole 18a for taking out the electric wiring 12g. It is taken out. Although the wiring hole 18a has been described as being provided on the bottom surface of the thermo cover 18, the wiring hole 18a may be provided below the side surface of the thermo cover 18 as long as there is no problem with the wiring. The wiring hole 18a is a minimum hole for drawing out the wiring. The thermo cover 18 is fitted into the bottom of the thermostat 12, and the bottom of the thermostat 12 serves as the top surface, forming a semi-enclosed space composed of the side and bottom surfaces of the thermo cover 18, and the connection terminal 12e at the bottom of the thermostat 12 is formed in this space. , 12f is stored in a covered state.

  The thermostat 12 incorporates a thermocapillary 13 that functions as a thermal sensor, in which a gas is sealed. The tip of the thermocapillary 13 that performs the heat-sensitive function is the surface of the plate cooler 5, which is attached to the outer lower surface of the ice making chamber 4, that is, the surface of the plate cooler 5 facing the refrigerating chamber 3. This temperature change changes the gas pressure in the thermocapillary 13 and operates the electrical contacts inside the thermostat 12. That is, when the temperature of the plate cooler 5 rises, the internal pressure of the thermocapillary 13 rises, the output of the bellows in the thermostat 12 increases, and the output becomes stronger than the spring force in the thermostat 12 maintaining the equilibrium. The electrical contacts in the thermostat 12 are closed and energized. Conversely, when the temperature of the plate cooler 5 decreases, the internal pressure of the thermocapillary 13 decreases, the output of the bellows in the thermostat 12 decreases, and the force of the spring in the thermostat 12 that is balanced with the output is strong. Then, the electrical contact in the thermostat 12 is opened and shut off. The spring strength can be adjusted by the dial of the thermostat 12 formed by the dial knob 15 and the dial shaft 12d. That is, the temperature at which the thermocapillary 13 detects and the electrical contacts of the thermostat 12 are opened and closed can be changed by the dial of the thermostat 12. Further, the electrical contacts are housed in a container-like housing portion made of a flame retardant on the bottom side inside the thermostat 12, and the connection terminals connected to the electrical contacts are exposed to the outside. In addition, although the front-end | tip which performs the thermosensitive of the thermocapillary 13 was attached to the surface of the plate-shaped cooler 5 which faced the refrigerator compartment 3, the external side surface of the plate-shaped cooler 5 may be sufficient.

FIG. 7 is an electrical wiring diagram showing connections between the compressor 11, the thermostat 12, and the power supply 20. The electrical contact 12h of the thermostat 12 opens and closes due to a change in the internal pressure of the thermocapillary 13. When the electrical contact 12h is closed, the power supply 20 is energized to the compressor 11, and when the electrical contact 12h is opened, the power supply 20 to the compressor 11 is opened. Is turned off. That is, when the temperature of the plate cooler 5 rises, the electrical contact 12h of the thermostat 12 is closed and the compressor 11 is energized, and the refrigerant is compressed and circulated. When the temperature of the plate cooler 5 is lowered, the electrical contact 12h of the thermostat 12 is opened, the power supply to the compressor 11 is interrupted, and the circulation of the refrigerant is stopped. The temperature of the plate cooler 5 for operating or stopping the compressor 11 can be changed by the dial of the thermostat 12.
By controlling the operation of the compressor 11 according to the temperature of the plate cooler 5 with such a configuration, the temperature of the refrigerator compartment 3 and the ice making chamber 4 is controlled to be constant.

  On the other hand, the plate-shaped cooler 5 cools the ice making chamber 4 and the food in the ice making chamber 4, but also cools the air containing moisture that has entered the ice making chamber 4 and adheres to the inner wall surface of the ice making chamber 4 as dew and frost. (Condensation or frosting). Air containing moisture also enters the outside of the ice making chamber 4, that is, the space 17 between the ice making chamber 4 and the inner wall of the refrigerator body 2, and the air convects around the space 17 and the thermostat 12. There is a possibility of condensation or frost formation due to cooling by the plate cooler 5. And, if moisture that has condensed or melted after frosting comes into contact with the connection terminals 12e and 12f of the thermostat 12 to which the power supply or compressor is connected, there is a possibility that the circuit is short-circuited, tracking occurs between the connection terminals, and ignition occurs. is there.

  However, even if dew condensation or frost is generated in the plate cooler 5 or the space 17, the thermostat mounting portion 16 attaches the thermostat 12 to the side surface of the thermostat mounting portion 16, and the generated dew condensation or frost adheres to the thermostat 12. To prevent that.

  The plate cooler 5 and the thermostat mounting portion 16 are separated from each other by the left side surface portion 16c of the thermostat mounting portion 16, and the plate shape cooler 5 and the left side surface portion 16c are not in direct contact with each other. 5, the periphery of the thermostat mounting portion 16 where the thermostat 12 is mounted is not directly cooled. Further, the thermostat 12 is the same, and is not directly in contact with the left side surface portion 16c, and therefore is not directly cooled by the plate cooler 5 or the left side surface portion 16c. Moreover, the heat insulating material tape 19 is affixed on the plate-like cooler 5 side of the left side surface portion 16c, and the plate-like cooler 5 is prevented from cooling the thermostat mounting portion 16. Therefore, it heat-insulates with the thermostat attachment part 16 and the heat insulating material tape 19 stuck on the side surface, and it suppresses that the thermostat attachment part 16 and the thermostat 12 are cooled directly.

  Even if the cooling of the thermostat mounting part 16 proceeds and air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and condensation or frost formation occurs on the thermostat mounting part 16 and the thermostat 12, the dew condensation or frosting occurs. The frosted water drops downward. On the other hand, as shown in FIG. 4 or 5, the connection terminals 12e and 12f of the thermostat 12 connected to the thermostat 12 and the compressor 11 or the power source 20 are at the bottom of the thermostat 12, and the main body 12a of the thermostat 12 is connected to the connection terminal 12e. , 12f becomes like an umbrella and prevents water dripping from the top from adhering to the bottom.

  Further, even if moisture that cannot be dripped from the thermostat 12 and is transmitted below the thermostat 12 is generated, the connection terminals 12e and 12f of the thermostat 12 are covered with the thermo cover 18 as shown in FIG. , 12f is prevented from contacting moisture directly.

However, since the thermo cover 18 and the thermostat 12 are mounted and fixed in a state where the inner wall and the outer wall are in close contact with each other, there is a possibility that a gap is generated without being completely in close contact due to the roughness of the wall surface contact. Further, since the thermo cover 18 has a hole like the wiring hole 18a, the thermo cover 18 can be ventilated to the outside, and air containing moisture may enter. Further, when the thermo cover 18 is fitted into the thermostat 12, there is a possibility that a gap may be generated due to an operation mistake that does not fit into the complete position where the thermo cover 12 should be fitted.
Therefore, condensation in the thermo cover 18 or moisture condensed on the thermostat 12 enters into the thermo cover 18 through a gap between the thermo cover 18 and the thermostat 12, moisture accumulates in the thermo cover 18, and the thermostat 12 Tracking occurs when the connection terminals 12e and 12f come into direct contact with the accumulated water. However, even if tracking occurs and the fire is ignited, the thermo cover 18 and the thermostat 12 use a flame retardant material, and the fire cover covers the fire with a minimum size. Is limited to a phenomenon that occurs only in the space in the thermo cover 18 constituted by the thermo cover 18 and the bottom surface of the thermostat 12, and can prevent ignition and spread of fire to peripheral members. Further, at least the bottom surfaces of the thermo cover 18 and the thermostat 12 do not burn because they are flame retardant.
Further, even if an ignition phenomenon occurs, the wiring hole 18a is at the bottom or below the thermo cover 18 and is the minimum necessary hole through which the wiring can pass, and the flame and sparks of ignition do not come out of the thermo cover 18. .

  In particular, by limiting the ignition phenomenon to the generation phenomenon of the space in the thermo cover 18, it is possible to quickly and easily investigate the failure location and the cause of the burnout by tracking, and the replacement of repair parts can be minimized. Further, since the ignition phenomenon does not reach the entire thermostat 12, it is not necessary to use the frame 8 as the attachment portion of the thermostat 12, the inner wall of the refrigerator main body, and the plate cooler 5 as a flame retardant.

  In the refrigerator configured as described above, the thermostat is housed in the thermostat mounting portion and is separated from the plate cooler by the side surface portion of the thermostat mounting portion. When dew condensation or frost is generated in the cooler, moisture due to the generated dew condensation or frost does not directly touch the thermostat, and tracking can be prevented without taking measures such as a heater.

  Moreover, since the thermostat mounting part is not in contact with the plate cooler, it is not directly cooled by the plate cooler, and since the heat insulating tape is stuck on the side surface of the thermostat mounting part, the thermostat Cooling, condensation, or frost formation on the mounting part is suppressed. Further, since the thermostat is not in contact with the side surface portion of the thermostat mounting portion, the thermostat is not directly cooled from the side surface portion of the plate cooler or the thermostat mounting portion, and the dew condensation or frost formation of the thermostat is suppressed.

  In addition, even if air containing moisture entering from the lower refrigerator compartment convects around the thermostat, moisture condensed or frosted on the thermostat mounting part adheres to the thermostat, or condensation or frost directly forms on the thermostat, Moisture due to condensation or frost is dripped downward, and the connection terminal of the thermostat's electric wiring is at the bottom of the thermostat, and the wiring is taken out below the thermostat, so the dripping moisture does not propagate to the bottom of the thermostat In addition, moisture does not directly contact the thermostat connection terminal, and tracking can be prevented.

  In addition, even if water adhering to the thermostat does not drip from the thermostat, by attaching a thermo cover to the bottom of the thermostat, moisture does not directly touch the connection terminal of the thermostat, and tracking can be prevented.

  In the unlikely event that moisture accumulates inside the thermo cover and moisture contacts the thermostat connection terminal and tracking occurs, the thermo cover can be kept to a minimum size using flame retardant materials for the thermo cover and thermostat. By covering, the flames and sparks of ignition can be limited to the phenomenon occurring in the thermo cover, and ignition and spreading of the surrounding members can be prevented.

Further, since the failure location of the burnout due to tracking is limited within the thermo-cover, the cause can be investigated quickly and easily, and the parts for repair can be replaced with a minimum. Furthermore, since the thermostat is attached to the thermostat with the thermo cover attached to the thermostat, installation work during assembly and removal during repair can be simplified, and the thermostat can be attached to the thermostat when the frame is removed. Since one of the side surfaces of the section is open, the thermostat can be easily attached and detached, and quick assembly and repair can be performed without stopping the refrigerator for a long time.
In addition, for simple inspections and voltage measurements, it is possible to check the work and values by removing only the thermo cover without removing the thermostat.

  In addition, by setting the ignition location and ignition phenomenon within the thermo cover, the general thermostat attachment material, that is, the frame or the inner wall of the refrigerator body, etc., is used as a general material that is not flame retardant. An inexpensive configuration can be obtained.

In addition, the wiring hole through which the wiring of the thermo cover is passed is formed at the bottom or below, so that ignition flames and sparks do not come out of the thermo cover.
Further, by making the wiring hole at the bottom or below, it is possible to prevent dust and the like from entering the inside of the thermo cover.

In addition, since the thermo cover covers the connection terminals of the thermostat necessary to prevent tracking, the thermo cover can be downsized, the amount of flame retardant used is reduced, the material cost is low, and the thermo cover and thermostat are Therefore, a large installation space for the frame body is no longer required.
In addition, the thermostat is also slimmed down with the lateral width seen from the front, such as the flat plate surface of the connection terminal facing the side, and the thermostat is sandwiched between the front and rear of the thermostat mounting part, and the mounting bracket on the front of the thermostat and the body The rear surface is fitted and fixed with the nail of the thermostat mounting portion, and the mounting bracket on the front surface of the thermostat is the same width as the horizontal width of the thermostat, and is arranged above and below the thermostat to make the mounting portion slim.

  In addition, the thermostat is restrained from being cooled directly from the plate cooler by the thermostat mounting part and the heat insulating tape, and the air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and the thermostat body Even if it is cooled and condensed or frosted, the tip of the thermocapillary that senses the temperature is attached to the surface of the plate-like cooler away from the thermostat, so that the thermostat does not malfunction due to a false detection of temperature. Therefore, even if the entire thermostat is not covered with the thermo cover, the thermostat will not malfunction.

  In addition, the thermostat is slimmed, the cover is reduced in size by attaching the thermo cover to the thermostat, and the thermostat mounting is fitted and held between the front and rear of the thermostat mounting part, thereby reducing the space where the thermostat was mounted. In addition, the space between the ice making chamber and the inner wall of the refrigerator main body can be narrowed, the left and right dimensions of the ice making chamber can be expanded, and the internal volume of the ice making chamber can be expanded. Also, instead of expanding the left and right dimensions of the ice making room, the height of the ice making room is not reduced by changing the height of the ice making room, but the height of the lower refrigerating room is expanded to increase the internal volume of the refrigerating room. You can use it.

As described above, the thermo cover of the refrigerator according to the present invention prevents moisture due to condensation or frost from coming into direct contact with the connection terminal of the thermostat by using an inexpensive and simple method without using a heater. At the same time that tracking can be prevented, even if tracking occurs at the connection terminal of the thermostat, a flame retardant is used for the thermo cover, so it is possible to prevent the surrounding members from igniting and spreading fire.
In addition, the thermostat is slimmed down, the cover is reduced in size by mounting the thermo cover on the thermostat, and the thermostat mounting is fitted and held on the front and rear of the thermostat mounting part, reducing the space where the thermostat was mounted. In addition, the space between the ice making chamber and the inner wall of the refrigerator main body can be narrowed, the left and right dimensions of the ice making chamber can be expanded, and the internal volume of the ice making chamber can be expanded. It is also possible to expand the internal volume of the refrigerator compartment by reducing the height dimension of the ice making chamber and increasing the height dimension of the lower refrigerator compartment. Thereby, the place where food is taken in and out and stored can be narrowed, and the place where food is taken in and out and stored can be expanded.

Embodiment 2. FIG.
In the first embodiment, the method of preventing ignition and spread of fire to the peripheral members by the thermo cover is explained even if condensation or frost is formed around the thermostat and moisture enters the thermo cover and tracking occurs. A method for making it difficult for tracking to occur by discharging moisture that has entered the thermo-cover before the occurrence of tracking will be described. FIG. 8 is a front view of a direct-cooling refrigerator according to Embodiment 2 of the present invention, FIG. 9 is a sectional view taken along the line DD of the ice making chamber of FIG. 8, and FIG.

  As in the first embodiment, as shown in FIG. 8, an ice making chamber 4 having a front opening is formed in the refrigerator main body 2 by a plate cooler 5 at the top, and the ice cooler 4 and the lower refrigerator are formed by the plate cooler 5. The chamber 3 is cooled to a predetermined temperature range.

Further, as shown in FIG. 9, a structure in which a thermostat 12 is attached to a thermostat attachment portion 16 in a space connected to the refrigerator compartment 3 on the back side of the right front surface of the frame body 8, and a structure in which the thermocapillary 13 functions as a thermal sensor. The same as in the first embodiment. In addition, the compressor and the power source are connected to the connection terminals 12e and 12f at the bottom of the thermostat 12, and the electrical contacts of the thermostat 12 are opened and closed according to the temperature of the plate cooler 5 to control the operation of the compressor. This is also the same as in the first embodiment.
10A and 10B are explanatory views of the thermo cover 21, and FIG. 10B is a cross-sectional view taken along line EE of FIG. 10A. The thermo cover 21 is attached to the bottom of the thermostat 12, and has a structure in which the connection terminals 12 e and 12 f of the thermostat 12 are accommodated in the thermo cover 21. The electrical wiring 12 g is connected to the connection terminals 12 e and 12 f of the thermostat 12, and the bottom surface of the thermo cover 21. The mounting method and structure for taking out the thermo cover 21 through the wiring hole 21a provided in the same are the same as those in the first embodiment.

Here, when moisture accumulates inside the thermo cover 21, the moisture will contact between the connection terminals of the thermostat 12 to cause tracking. Therefore, the wiring hole 21a of the thermo cover 21 is provided on the bottom surface, and the electrical wiring 12g connected to the connection terminals 12e and 12f is taken out, and at the same time, the bottom surface of the thermo cover 21 is inclined so as to be lowered toward the wiring hole 21a. The water accumulated in the thermo cover 21 can be discharged through the wiring hole 21a. That is, the wiring hole was also used as the drain hole. As a result, moisture does not accumulate in the thermo cover 21, and moisture does not directly contact the connection terminals 12e, 12f of the thermostat 12.
As in the first embodiment, the thermostat 12 and the thermo cover 21 are made of a flame retardant material.

  From the above, as in the first embodiment, when dew condensation or frost formation occurs in the plate-shaped cooler due to the air containing moisture entering from the lower refrigerator compartment around the thermostat, the generated dew condensation or frost formation is caused by the thermostat mounting portion 16. The side surface portion of the thermostat 12 does not adhere to the thermostat 12, and the heat insulation effect of the side surface portion of the thermostat mounting portion 16 prevents the thermostat mounting portion 16 and the thermostat 12 from cooling, dew condensation, or frost formation. Further, even if the thermostat mounting portion 16 or the thermostat 12 is dewed or frosted, the connection terminals 12e and 12f are provided at the bottom of the thermostat 12. Therefore, the dewed or frosted water drops downward, and the connection terminal of the thermostat 12 12e and 12f are not in direct contact with each other, and even if they are not dripped, the thermo cover 21 is attached to the bottom of the thermostat 12 so as to accommodate the connection terminals 12e and 12f, so that the connection terminals 12e and 12f of the thermostat 12 are connected. There is no direct contact.

  However, even if the cooling further proceeds and condensation occurs in the thermo cover 21 or moisture enters the thermostat 12 from the gap of the thermo cover 21, the thermo cover 21 tilts the bottom surface. Since the moisture can be discharged from the wiring hole 21a provided on the bottom surface, the moisture is discharged from the thermo cover 21 without directly accumulating inside the thermo cover 21a, and can directly contact the connection terminals 12e and 12f of the thermostat 12. Absent.

Further, when a problem occurs in the wiring hole 21a, for example, water that should be discharged from the wiring hole 21a freezes and is not discharged, and even if tracking is caused by moisture in the thermo cover 21 and ignition occurs, Since the thermostat 12 uses a flame retardant material, the ignition flame and sparks are limited to the phenomenon generated in the thermo cover 21, and therefore, ignition and spread of the surrounding members can be prevented. Further, the thermo cover 21 and the thermostat 12 themselves are not burned because they are flame retardant.
Further, the wiring hole 21a of the thermo cover 21 is a necessary minimum hole through which wiring is passed and moisture is discharged, so that a flame or spark of ignition does not come out of the thermo cover 18.

  In the refrigerator configured as described above, as in the first embodiment, moisture due to condensation or frost does not directly touch the connection terminal of the thermostat, and tracking can be prevented without taking measures such as a heater.

  In addition, even if moisture enters the thermo cover, the thermo cover has a drain hole that can discharge water, that is, a wiring hole. Water can be discharged without accumulating, and tracking of the thermostat connection terminal can be prevented.

  Furthermore, even if moisture is not discharged from the thermo cover and tracking occurs at the connection terminal of the thermostat, since the flame retardant is used for the thermo cover and the thermostat, it is possible to prevent the peripheral members from being ignited and spread.

Further, since the failure location of the burnout due to tracking is limited within the thermo-cover, the cause can be investigated quickly and easily, and the parts for repair can be replaced with a minimum. Furthermore, since the thermostat is attached to the thermostat with the thermo cover attached to the thermostat, installation work during assembly and removal during repair can be simplified, and the thermostat can be attached to the thermostat when the frame is removed. Since one of the side surfaces of the section is open, the thermostat can be easily attached and detached, and quick assembly and repair can be performed without stopping the refrigerator for a long time.
In addition, for simple inspections and voltage measurements, it is possible to check the work and values by removing only the thermo cover without removing the thermostat.

  In addition, by setting the ignition location and ignition phenomenon within the thermo cover, the general thermostat attachment material, that is, the frame or the inner wall of the refrigerator body, etc., is used as a general material that is not flame retardant. An inexpensive configuration can be obtained.

  In addition, since the thermo cover covers the connection terminals of the thermostat necessary to prevent tracking, the thermo cover can be downsized, the amount of flame retardant used is reduced, the material cost is low, and the thermo cover and thermostat are Therefore, a large installation space is no longer necessary.

  In addition, the thermostat is restrained from being cooled directly from the plate cooler by the thermostat mounting part and the heat insulating tape, and the air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and the thermostat body Even if it is cooled and condensed or frosted, the tip of the thermocapillary that senses the temperature is attached to the surface of the plate-like cooler away from the thermostat, so that the thermostat does not malfunction due to a false detection of temperature. Therefore, even if the entire thermostat is not covered with the thermo cover, the thermostat will not malfunction.

As described above, the thermo cover of the refrigerator according to the present invention prevents moisture from condensation or frost from directly contacting the connection terminal of the thermostat by an inexpensive and simple method without using a heater or the like. Even if moisture enters, it has a structure for discharging the intruded moisture and can prevent tracking of the connection terminal of the thermostat. Even if tracking occurs in the connection terminal of the thermostat, a flame retardant material is used for the thermo cover, so that ignition and spreading of the surrounding members can be prevented.
In addition, by reducing the size of the thermo cover and attaching it to the thermostat, the space where the thermostat was attached was reduced, the space between the ice making room and the inner wall of the refrigerator body was narrowed, and the left and right dimensions of the ice making room were expanded, making the ice making room The internal volume of can be expanded. Further, the internal volume of the refrigerator compartment may be increased by reducing the height dimension of the ice making chamber and increasing the height dimension of the lower refrigerator compartment.

Embodiment 3 FIG.
In the first embodiment, a method for preventing ignition and spread of fire to the peripheral members by the thermo cover even if condensation or frost is formed around the thermostat and moisture enters the thermo cover and tracking occurs. However, a method will be described in which an insulating rib is provided on the thermo cover so as to be disposed between the connection terminals of the thermostat so that the insulation distance between the connection terminals of the thermostat is widened and tracking is less likely to occur. FIG. 11 is a front view of a direct-cooling refrigerator according to Embodiment 3 of the present invention, FIG. 12 is a sectional view taken along line FF of the ice making chamber of FIG. 11, and FIG. 13 is an explanatory view of a thermo cover.

  As in the first embodiment, as shown in FIG. 11, an ice making chamber 4 having a front opening is formed in the refrigerator main body 2 by a plate cooler 5 at the top, and the ice cooler 4 and the lower refrigerator are formed by the plate cooler 5. The chamber 3 is cooled to a predetermined temperature range.

12, the structure in which the thermostat 12 is attached to the thermostat attachment portion 16 in the space connected to the refrigerator compartment 3 on the back side of the right front surface of the frame 8, and the structure in which the thermocapillary 13 functions as a thermal sensor. The same as in the first embodiment. In addition, the compressor and the power source are connected to the connection terminals 12e and 12f at the bottom of the thermostat 12, and the electrical contacts of the thermostat 12 are opened and closed according to the temperature of the plate cooler 5 to control the operation of the compressor. This is also the same as in the first embodiment.
13A and 13B are explanatory views of the thermo cover 22, and FIG. 13B is a cross-sectional view taken along the line GG of FIG. 13A. The thermo cover 22 is attached to the bottom of the thermostat 12, and has a structure in which the connection terminals 12e and 12f of the thermostat 12 are accommodated in the thermo cover 22, and the electrical wiring 12g is connected to the connection terminals 12e and 12f of the thermostat 12 and drawn downward. The mounting method and structure of taking out the thermo cover 22 through the wiring holes 22a and 22b provided in the thermo cover 22 and taking out the thermostat 13 together with the thermocapillary 13 are the same as those in the first embodiment. .
However, the center of the thermo cover 22 is connected to the bottom and side surfaces of the thermo cover 22 so that the thermo cover 22 is divided into two spaces and arranged between the connection terminal A12e and the connection terminal B12f of the thermostat 12. Insulating ribs 22c are provided. The insulating rib 22c serves as a barrier to increase the insulation distance between the connecting terminal A12e and the connecting terminal B12f, and the connecting terminal A12e and the connecting terminal B12f have a structure in which the thermocover 22 is disposed in two separate spaces. Moreover, the wiring connected to each connection terminal is taken out from the thermo cover 22 through a separate wiring hole. For example, the wiring connected to the connection terminal A12e is taken out from the wiring hole 22a, and the wiring connected to the connection terminal B12f is taken out from the wiring hole 22b.
As in the first embodiment, the thermo cover 22 and the thermostat 12 including the insulating rib 22c are made of an insulative flame retardant.

  Therefore, in the same manner as in the first embodiment, when dew condensation or frost is generated in the plate-like cooler due to the air containing moisture entering from the lower refrigerating chamber around the thermostat, the generated dew condensation or frost formation is caused by the thermostat mounting portion 16. The side surface portion does not adhere to the thermostat 12, and due to the heat insulating effect of the side surface portion of the thermostat mounting portion 16, cooling, condensation or frost formation of the thermostat mounting portion 16 and the thermostat 12 is suppressed. Further, even if the thermostat mounting portion 16 or the thermostat 12 is dewed or frosted, the connection terminals 12e and 12f are provided at the bottom of the thermostat 12. Therefore, the dewed or frosted water drops downward, and the connection terminal of the thermostat 12 12e and 12f are not in direct contact with each other, and even if they are not dripped, the thermo cover 21 is attached to the bottom of the thermostat 12 so as to accommodate the connection terminals 12e and 12f, so that the connection terminals 12e and 12f of the thermostat 12 are connected. There is no direct contact.

  However, even if the cooling further proceeds and the condensation in the thermo cover 22 and the moisture that has condensed on the thermostat 12 enter the thermo cover 22 through the gap of the thermo cover 22, the insulating rib 22c provided on the thermo cover 22 is provided. Thus, the connection terminal A12e and the connection terminal B12f of the thermostat 12 are separated from each other, so that moisture enters between the connection terminal A12e and the connection terminal B12f and is prevented from being short-circuited. Moreover, in order to make it short-circuit, a lot of water | moisture content is required, and time will be required until a water | moisture content contacts directly. That is, tracking of the connection terminal of the thermostat 12 is difficult to occur.

Even if sufficient moisture accumulates inside the thermo cover 22 to cause tracking and ignite, the thermo cover 22 and the thermostat 12 are made of an insulating flame retardant. Since it is limited to the phenomenon generated within 22, it is possible to prevent the peripheral members from being ignited and spread. Further, the thermo cover 22 and the thermostat 12 themselves are not burned because they are flame retardant.
Further, the wiring holes 22a and 22b of the thermo cover 22 are the minimum necessary holes for passing the wiring and discharging the moisture while being at the bottom of the thermo cover 21, so that the flame and sparks of ignition do not come out of the thermo cover 22. Absent.

  Moreover, you may add to the thermocover 22 the structure which can discharge | emit water to the bottom face of the thermocover 22 like Embodiment 2. Thereby, while the insulating rib 22c of the thermo cover 22 prevents the moisture from coming into contact between the connection terminals of the thermostat, the moisture in the thermo cover 22 is discharged, and tracking is less likely to occur.

  In the refrigerator configured in this way, as in the first embodiment, moisture due to condensation or frost does not directly touch the connection terminal of the thermostat, and tracking can be prevented without taking measures such as a heater.

  However, even if moisture enters the thermo cover, the insulating ribs provided on the thermo cover separate the thermostat connection terminals to increase the insulation distance, so that tracking of the thermostat connection terminals can be suppressed.

  In addition, even if water contacts over the insulating ribs provided on the thermo cover, adding water to the thermo cover will prevent moisture from accumulating in the thermo cover. And the tracking of the connection terminal of the thermostat can be prevented.

  In addition, even if moisture enters the thermo cover, even if moisture contacts the thermostat connection terminal and tracking occurs, flame retardant materials are used for the thermo cover and thermostat. Ignition and fire spread can be prevented.

Further, since the failure location of the burnout due to tracking is limited within the thermo-cover, the cause can be investigated quickly and easily, and the parts for repair can be replaced with a minimum. Furthermore, since the thermostat is attached to the thermostat with the thermo cover attached to the thermostat, installation work during assembly and removal during repair can be simplified, and the thermostat can be attached to the thermostat when the frame is removed. Since one of the side surfaces of the section is open, the thermostat can be easily attached and detached, and quick assembly and repair can be performed without stopping the refrigerator for a long time.
In addition, for simple inspections and voltage measurements, it is possible to check the work and values by removing only the thermo cover without removing the thermostat.

  In addition, by setting the ignition location and ignition phenomenon within the thermo cover, the general thermostat attachment material, that is, the frame or the inner wall of the refrigerator body, etc., is used as a general material that is not flame retardant. An inexpensive configuration can be obtained.

  In addition, since the thermostat is connected to the connection terminal of the thermostat, the thermo cover can be downsized, the material cost is low, and a large installation space is not required.

  In addition, the thermostat is restrained from being cooled directly from the plate cooler by the thermostat mounting part and the heat insulating tape, and the air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and the thermostat body Even if it is cooled and condensed or frosted, the tip of the thermocapillary that senses the temperature is attached to the surface of the plate-like cooler away from the thermostat, so that the thermostat does not malfunction due to a false detection of temperature. Therefore, even if the entire thermostat is not covered with the thermo cover, the thermostat will not malfunction.

As described above, the thermo cover of the refrigerator according to the present invention prevents moisture from condensation or frost from directly contacting the connection terminal of the thermostat by an inexpensive and simple method without using a heater or the like. Even if moisture permeates, since the insulation distance between the thermostat connection terminals is long, tracking of the thermostat connection terminals can be prevented. In addition, a structure for discharging moisture that has entered the thermo cover can be added to prevent tracking of the connection terminal of the thermostat. In addition, even if tracking occurs in the thermostat connection terminal, since the insulative flame retardant is used for the thermo cover, it is possible to prevent the peripheral members from being ignited and spread.
In addition, by reducing the size of the thermo cover and attaching it to the thermostat, the space where the thermostat was attached was reduced, the space between the ice making room and the inner wall of the refrigerator body was narrowed, and the left and right dimensions of the ice making room were expanded, making the ice making room The internal volume of can be expanded. Further, the internal volume of the refrigerator compartment may be increased by reducing the height dimension of the ice making chamber and increasing the height dimension of the lower refrigerator compartment.

Embodiment 4 FIG.
In the first embodiment, even if condensation or frost forms around the thermostat and moisture enters the thermo cover and tracking occurs, the thermo cover is a flame-retardant material, so the surrounding members are ignited and spread. Although the method of preventing was described, the case where the thermo cover is made of a general material will be described. 14 is a front view of a direct-cooling refrigerator according to Embodiment 4 of the present invention, FIG. 15 is a sectional view taken along the line HH of the ice making chamber of FIG. 14, and FIG. 16 is a sectional view of the thermo cover.

  As in the first embodiment, as shown in FIG. 14, an ice making chamber 4 having a front opening is formed in the refrigerator main body 2 by a plate cooler 5 at the top, and the ice making chamber 4 and the lower refrigerator are formed by the plate cooler 5. The chamber 3 is cooled to a predetermined temperature range.

Further, as shown in FIG. 15, the structure in which the thermostat 12 is attached to the thermostat attachment portion 16 in the space connected to the refrigerator compartment 3 on the back side of the right front surface of the frame 8, and the structure in which the thermocapillary 13 functions as a thermal sensor. The same as in the first embodiment. In addition, the compressor and the power source are connected to the connection terminals 12e and 12f at the bottom of the thermostat 12, and the electrical contacts of the thermostat 12 are opened and closed according to the temperature of the plate cooler 5 to control the operation of the compressor. This is also the same as in the first embodiment.
16A and 16B are explanatory views of the thermo cover 23, and FIG. 16B is a cross-sectional view taken along line JJ of FIG. 10A. The thermo cover 23 is attached to the bottom of the thermostat 12, and has a structure in which the connection terminals 12e and 12f of the thermostat 12 are accommodated in the thermo cover 23. The electrical wiring 12g is connected to the connection terminals 12e and 12f of the thermostat 12, and is drawn downward. The mounting method and structure for taking out together with the thermocapillary 13 through the wiring hole 23a provided in the thermo cover 23 and out of the thermostat mounting portion 16 are also the same as in the first embodiment.
However, the thermo cover 23 is made of a general material, and an incombustible tape 24 such as an aluminum tape is attached so as to cover the outer periphery of the thermo cover 23 as shown in FIG. As in the first embodiment, the thermostat 12 is composed of a flame retardant material.

  Therefore, in the same manner as in the first embodiment, when dew condensation or frost is generated in the plate-like cooler due to the air containing moisture entering from the lower refrigerating chamber around the thermostat, the generated dew condensation or frost formation is caused by the thermostat mounting portion 16. The side surface portion does not adhere to the thermostat 12, and due to the heat insulating effect of the side surface portion of the thermostat mounting portion 16, cooling, condensation or frost formation of the thermostat mounting portion 16 and the thermostat 12 is suppressed. Further, even if the thermostat mounting portion 16 or the thermostat 12 is dewed or frosted, the connection terminals 12e and 12f are provided at the bottom of the thermostat 12. Therefore, the dewed or frosted water drops downward, and the connection terminal of the thermostat 12 12e and 12f are not in direct contact with each other, and even if they are not dripped, the thermo cover 21 is attached to the bottom of the thermostat 12 so as to accommodate the connection terminals 12e and 12f, so that the connection terminals 12e and 12f of the thermostat 12 are connected. There is no direct contact.

  However, the cooling proceeds further, and moisture is accumulated in the thermo cover 23 due to the condensation in the thermo cover 23 or the intrusion of moisture dewed on the thermostat 12 into the thermo cover 23 from the gap of the thermo cover 23, so that the thermostat 12 is connected. When the terminals 12e and 12f come into direct contact with the accumulated water, tracking occurs. However, even if the tracking occurs and the fire is ignited, the nonflammable tape 24 is attached so as to cover the outer periphery of the thermo cover 23. This flame and spark can prevent the peripheral members from being ignited and spread by merely burning the thermo cover 23. Moreover, the thermostat 12 does not burn because it is a flame retardant.

  In the refrigerator configured in this way, as in the first embodiment, moisture due to condensation or frost does not directly touch the connection terminal of the thermostat, and tracking can be prevented without taking measures such as a heater.

Further, since the failure location of the burnout due to tracking is limited within the thermo-cover, the cause can be investigated quickly and easily, and the parts for repair can be replaced with a minimum. Furthermore, since the thermostat is attached to the thermostat with the thermo cover attached to the thermostat, installation work during assembly and removal during repair can be simplified, and the thermostat can be attached to the thermostat when the frame is removed. Since one of the side surfaces of the section is open, the thermostat can be easily attached and detached, and quick assembly and repair can be performed without stopping the refrigerator for a long time.
In addition, for simple inspections and voltage measurements, it is possible to check the work and values by removing only the thermo cover without removing the thermostat.

  In addition, even if moisture enters the thermo cover, even if moisture contacts the thermostat connection terminal and tracking occurs, the nonflammable tape attached to the outer periphery of the thermo cover ignites peripheral members, Fire spread can be prevented.

In addition, by setting the ignition location and ignition phenomenon within the thermo cover, the general thermostat attachment material, that is, the frame or the inner wall of the refrigerator body, etc., is used as a general material that is not flame retardant. An inexpensive configuration can be obtained.
Moreover, since the thermo cover can use general materials without using expensive flame retardant materials, tracking by the thermo cover can be realized at a very low cost.

  In addition, since the thermostat is connected to the connection terminal of the thermostat, the thermo cover can be downsized, the material cost is low, and a large installation space is not required.

  In addition, the thermostat is restrained from being cooled directly from the plate cooler by the thermostat mounting part and the heat insulating tape, and the air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and the thermostat body Even if it is cooled and condensed or frosted, the tip of the thermocapillary that senses the temperature is attached to the surface of the plate-like cooler away from the thermostat, so that the thermostat does not malfunction due to a false detection of temperature. Therefore, even if the entire thermostat is not covered with the thermo cover, the thermostat will not malfunction.

As described above, the thermo cover of the refrigerator according to the present invention prevents moisture from condensation or frost from directly contacting the connection terminal of the thermostat by an inexpensive and simple method without using a heater or the like. Even if moisture enters and tracking occurs in the thermostat connection terminal, the thermo cover is covered with a non-flammable tape, so that ignition and spreading of the peripheral members can be prevented.
In addition, by reducing the size of the thermo cover and attaching it to the thermostat, the space where the thermostat was attached was reduced, the space between the ice making room and the inner wall of the refrigerator body was narrowed, and the left and right dimensions of the ice making room were expanded, making the ice making room The internal volume of can be expanded. Further, the internal volume of the refrigerator compartment may be increased by reducing the height dimension of the ice making chamber and increasing the height dimension of the lower refrigerator compartment.

Embodiment 5 FIG.
In the first embodiment, even if condensation or frost forms around the thermostat and moisture enters the thermo cover and tracking occurs, the thermo cover is a flame-retardant material, so the surrounding members are ignited and spread. Although the method to prevent was demonstrated, the example which took the countermeasure so that it may remove | deviate and fall, even if a thermocover is attached to the bottom part of a thermostat is demonstrated. FIG. 17 is a front view of a direct-cooling refrigerator according to Embodiment 5 of the present invention, FIG. 18 is a sectional view of the ice making chamber of FIG. 17 taken along the line KK, and FIG.

  As in the first embodiment, as shown in FIG. 17, an ice making chamber 4 having a front opening is formed in the refrigerator main body 2 by a plate cooler 5 at the top, and the ice cooler 4 and the refrigeration below are formed by the plate cooler 5. The chamber 3 is cooled to a predetermined temperature range.

Further, as shown in FIG. 18, the structure in which the thermostat 12 is attached to the thermostat attachment portion 16 in the space connected to the refrigerator compartment 3 on the back side of the right front surface of the frame 8, and the structure in which the thermocapillary 13 functions as a thermal sensor. The same as in the first embodiment. In addition, the compressor and the power source are connected to the connection terminals 12e and 12f at the bottom of the thermostat 12, and the electrical contacts of the thermostat 12 are opened and closed according to the temperature of the plate cooler 5 to control the operation of the compressor. This is also the same as in the first embodiment.
19A and 19B are explanatory views of the thermo cover 25, and FIG. 19B is a cross-sectional view taken along line LL in FIG. 19A. The thermo cover 25 is attached to the bottom of the thermostat 12, and has a structure in which the connection terminals 12e and 12f of the thermostat 12 are accommodated in the thermo cover 25. The electrical wiring 12g is connected to the connection terminals 12e and 12f of the thermostat 12, and is drawn downward. The mounting method and structure of taking out together with the thermocapillary 13 through the wiring hole 25a provided in the thermo cover 25 to the outside of the thermostat mounting portion 16 are the same as in the first embodiment.
On the other hand, a claw 25c for fixing the thermocapillary 13 is provided on the side surface of the thermo cover 25. The thermocapillary 13 is connected to the main body 12a of the thermostat 12, and the connected periphery is fixed to the main body 12a so that it does not come off due to tension when wiring and mounting. As in the first embodiment, the thermo cover 25 is fitted and fixed to the bottom of the thermostat 12. At the same time, the claw 25 c of the thermo cover 25 sandwiches the thermo capillary 13 and fixes the thermo cover 25 to the thermo capillary 13. Thereby, when vibration is given to the refrigerator, for example, when the compressor is started, the thermo cover 25 may come off the thermostat 12 and fall off, but it is also fixed by the thermocapillary 13. Therefore, dropout is suppressed.
To remove the thermo cover 25, the claws 25c are widened to remove the thermo capillary 13, and the thermo cover 25 can be removed from the thermostat 12 by removing the fitting and pulling downward as in the first embodiment.
The bottoms of the thermo cover 25 and the thermostat 12 are made of a flame retardant material.

  Therefore, in the same manner as in the first embodiment, when dew condensation or frost is generated in the plate-like cooler due to the air containing moisture entering from the lower refrigerating chamber around the thermostat, the generated dew condensation or frost formation is caused by the thermostat mounting portion 16. The side surface portion does not adhere to the thermostat 12, and due to the heat insulating effect of the side surface portion of the thermostat mounting portion 16, cooling, condensation or frost formation of the thermostat mounting portion 16 and the thermostat 12 is suppressed. Further, even if the thermostat mounting portion 16 or the thermostat 12 is dewed or frosted, the connection terminals 12e and 12f are provided at the bottom of the thermostat 12. Therefore, the dewed or frosted water drops downward, and the connection terminal of the thermostat 12 12e and 12f are not in direct contact with each other, and even if they are not dripped, the thermo cover 21 is attached to the bottom of the thermostat 12 so as to accommodate the connection terminals 12e and 12f, so that the connection terminals 12e and 12f of the thermostat 12 are connected. There is no direct contact.

  However, the thermo cover 25 may come off due to the vibration of the refrigerator and drop off. When the thermo cover 25 is removed, moisture directly contacts the connection terminals 12e and 12f of the thermostat 12 to cause tracking. On the other hand, by fixing the thermocapillary 13 with the claws 25d on the side surface of the thermo cover 25, the thermo cover 25 is prevented from coming off and falling off, and the thermo cover 25 is removed even if the refrigerator is vibrated. It is difficult, and moisture does not enter the thermo cover 25 and the moisture does not directly contact the connection terminals 12e and 12f of the thermostat 12.

Further, a structure capable of discharging water to the bottom surface of the thermo cover 25 may be added to the thermo cover 25 as in the second embodiment. Furthermore, in the same manner as in the third embodiment, the thermo cover 25 may be provided with insulating ribs in order to increase the insulating distance between the connection terminals 12e and 12f of the thermostat 12.
Thereby, while the insulating rib provided in the thermo cover 25 prevents the moisture from contacting between the connection terminals of the thermostat, the moisture in the thermo cover 25 is discharged, and tracking is less likely to occur.

  In the refrigerator configured in this way, as in the first embodiment, moisture due to condensation or frost does not directly touch the connection terminal of the thermostat, and tracking can be prevented without taking measures such as a heater.

  Moreover, even if vibration is given to the refrigerator, the thermo cover is removed and tracking does not occur.

  In addition, even if moisture enters the thermocover, tracking of the connection terminals of the thermostat can be suppressed by adding an insulating rib to the thermocover or adding a structure capable of discharging water to the thermocover.

  In addition, even if moisture enters the thermo cover, even if moisture contacts the thermostat connection terminal and tracking occurs, flame retardant materials are used for the thermo cover and thermostat. Ignition and fire spread can be prevented.

Further, since the failure location of the burnout due to tracking is limited within the thermo-cover, the cause can be investigated quickly and easily, and the parts for repair can be replaced with a minimum. Furthermore, since the thermostat is attached to the thermostat with the thermo cover attached to the thermostat, installation work during assembly and removal during repair can be simplified, and the thermostat can be attached to the thermostat when the frame is removed. Since one of the side surfaces of the section is open, the thermostat can be easily attached and detached, and quick assembly and repair can be performed without stopping the refrigerator for a long time.
In addition, for simple inspections and voltage measurements, it is possible to check the work and values by removing only the thermo cover without removing the thermostat.

  In addition, by setting the ignition location and ignition phenomenon within the thermo cover, the general thermostat attachment material, that is, the frame or the inner wall of the refrigerator body, etc., is used as a general material that is not flame retardant. An inexpensive configuration can be obtained.

  In addition, since the thermostat is connected to the connection terminal of the thermostat, the thermo cover can be downsized, the material cost is low, and a large installation space is not required.

  In addition, the thermostat is restrained from being cooled directly from the plate cooler by the thermostat mounting part and the heat insulating tape, and the air containing moisture entering from the lower refrigerator compartment convects around the thermostat, and the thermostat body Even if it is cooled and condensed or frosted, the tip of the thermocapillary that senses the temperature is attached to the surface of the plate-like cooler away from the thermostat, so that the thermostat does not malfunction due to a false detection of temperature. Therefore, even if the entire thermostat is not covered with the thermo cover, the thermostat will not malfunction.

As described above, the refrigerator thermo cover according to the present invention prevents the moisture of condensation or frost from directly contacting the thermostat connection terminal by using an inexpensive and simple method without using a heater or the like. Even if it is given, it is possible to prevent tracking of the connecting terminal of the thermostat because the thermo cover is prevented from falling off from the thermostat. Further, even when moisture enters the thermo cover, an insulating rib for increasing the insulation distance between the thermostat connection terminals can be provided to prevent tracking of the thermostat connection terminals. In addition, a structure for discharging moisture that has entered the thermo cover can be added to prevent tracking of the connection terminal of the thermostat. In addition, even if tracking occurs in the thermostat connection terminal, since the insulative flame retardant is used for the thermo cover, it is possible to prevent the peripheral members from being ignited and spread.
In addition, by reducing the size of the thermo cover and attaching it to the thermostat, the space where the thermostat was attached was reduced, the space between the ice making room and the inner wall of the refrigerator body was narrowed, and the left and right dimensions of the ice making room were expanded, making the ice making room The internal volume of can be expanded. Further, the internal volume of the refrigerator compartment may be increased by reducing the height dimension of the ice making chamber and increasing the height dimension of the lower refrigerator compartment.

DESCRIPTION OF SYMBOLS 1 Refrigerator 2 Refrigerator main body 3 Refrigerator 4 Ice making room 5 Plate cooler 6 Front door 7 Packing 8 Frame body 9 Door 10 Condenser 11 Compressor 12 Thermostat 12a Main body 12b Front mounting bracket A
12c Front mounting bracket B
12d Dial shaft 12e Connection terminal A
12f connection terminal B
12g Electrical wiring 12h Contact 13 Thermocapillary 15 Dial knob 16 Thermostat mounting portion 16a Front surface portion of thermostat mounting portion 16b Rear surface portion of thermostat mounting portion 16c Left side surface of thermostat mounting portion 17 Space 18 Thermo cover 18a Wiring hole 19 Heat insulating material tape 20 Power supply 21 Thermo cover 21a Wiring hole 22 Thermo cover 22a Wiring hole 22b Wiring hole 22c Insulating rib 23 Thermo cover 23a Wiring hole 24 Nonflammable tape 25 Thermo cover 22a Wiring hole 22d Claw

Claims (10)

A refrigeration room surrounded by the inner wall of the refrigerator main body, an ice making room disposed above the refrigeration room and having a plate-like cooler on the side and provided with an opening on the front surface, and flowing into the plate-like cooler A direct-cooled refrigerator having a space between an inner wall of the refrigerating chamber facing the plate cooler and the plate cooler.
A thermocapillary attached to the plate cooler for sensing the temperature of the plate cooler and a space between the inner wall of the refrigerating chamber facing the plate cooler and the plate cooler The thermocapillary is connected and has a connection terminal for connecting to the compressor at the bottom , a thermostat for energizing and shutting off the compressor according to a temperature sensed by the thermocapillary, and an opening on the upper surface. A thermo cover that inserts the bottom of the thermostat into the part and is attached to the bottom and covers the connection terminal of the thermostat , and
A thermostat mounting portion for mounting the thermostat is provided between the plate cooler and the thermostat of the ice making chamber, and the thermostat mounting portion is disposed at a position not in contact with the plate cooler and is exposed to dew or frost on the thermostat. Refrigerator characterized by suppressing the adhesion . The refrigerator according to claim 1, wherein the thermostat mounting portion is provided so as to cover each surface of the thermostat at a front surface, a rear surface, and a side surface on the plate cooler side . The refrigerator according to claim 1 or 2, wherein the thermostat mounting portion has a heat insulating property . The thermostat mounting portion includes a frame body attached to a peripheral portion of the opening of the ice making chamber, and a side surface provided between the plate cooler of the ice making chamber and the thermostat provided on the frame body. And a rear surface portion provided on the side surface portion and disposed so as to face the frame body, wherein the thermostat is sandwiched and fixed between the frame body and the rear surface portion. The refrigerator according to any one of claims 1 to 3. The refrigerator according to any one of claims 1 to 4, wherein the thermostat is made of a flame retardant material . The refrigerator according to any one of claims 1 to 5, wherein a flame retardant is used for the thermo cover . The thermo cover is provided with the wiring hole in the bottom surface of the thermo cover, and the bottom surface of the thermo cover is inclined so as to be lowered in the direction of the wiring hole, and moisture accumulated in the thermo cover can be discharged from the wiring hole. the refrigerator according to any one of claims 1 to 6, characterized in that the the like. The thermo cover has an insulating rib inside the thermo cover, the insulating rib to any of claims 1 to 7, characterized in that it is arranged approximately halfway between two of the connection terminal to which the thermostat has The refrigerator described. The thermo cover includes a fixing portion for fixing the thermocapillary outside the thermo cover, the thermo capillary fixed to the thermostat is fixed to the fixing portion of the thermo cover, and is fixed to the thermostat. The refrigerator according to any one of claims 1 to 8. The refrigerator according to claim 1, wherein the thermo cover is covered with a nonflammable tape.

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