JP2016125755A - Water supply device of automatic ice-making device, and refrigerator including water supply device - Google Patents

Water supply device of automatic ice-making device, and refrigerator including water supply device Download PDF

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JP2016125755A
JP2016125755A JP2014266757A JP2014266757A JP2016125755A JP 2016125755 A JP2016125755 A JP 2016125755A JP 2014266757 A JP2014266757 A JP 2014266757A JP 2014266757 A JP2014266757 A JP 2014266757A JP 2016125755 A JP2016125755 A JP 2016125755A
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ice making
water
storage container
water storage
container
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JP6474612B2 (en
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範昭 尾花
Noriaki Obana
範昭 尾花
栄生 岩上
Yoshio Iwagami
栄生 岩上
豊嶋 昌志
Masashi Toyoshima
昌志 豊嶋
平石 智一
Tomokazu Hiraishi
智一 平石
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Aqua KK
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Abstract

PROBLEM TO BE SOLVED: To provide a water storage container in which a measurement tank portion is formed just under a main tank portion while defined from the main tank portion in a watertight state by a partitioning body and an annular packing disposed on a peripheral edge portion of the partitioning body so that ice-making water in the main tank portion naturally flows down to the measurement tank portion through a supply hole, and components including the annular packing can be easily removed and assembled to clean the main tank portion and the measurement tank portion, in particular, to provide a constitution capable of easily mounting the water storage container in a normal state, and easily assembling the same in a state of securing a normal seal state even when a flexible annular packing is applied.SOLUTION: A partitioning body is detachably mounted on an annular packing mounted on a packing holding portion, and the annular packing is pressed and held by a cover body mounted on a container body.SELECTED DRAWING: Figure 7

Description

本発明は、冷蔵庫に備えられる自動製氷装置に関し、特に、製氷用水を貯水する貯水容器を含む給水装置に関する。   The present invention relates to an automatic ice making device provided in a refrigerator, and particularly to a water supply device including a water storage container for storing ice making water.

本発明の従来技術として、エアーポンプから吹き出される圧縮空気による減圧効果を利用して、冷蔵庫内に設置される給水タンクから製氷装置の製氷皿へ水を供給する給水装置がある。この給水装置は、エアーポンプから吹き出される圧縮空気が減圧手段を通過するとき生じる減圧によって、給水タンク内の水を液もしくはミスト状態で吸い込み、吸い込んだ液もしくはミストを気液分離手段に導入する。液は気液分離手段に溜まり、ミストは気液分離手段によって空気から分離され液となり、これらが製氷皿へ送液され、製氷が行われるものである(例えば、特許文献1参照)。   As a prior art of the present invention, there is a water supply device that supplies water from a water supply tank installed in a refrigerator to an ice tray of an ice making device using a pressure reducing effect by compressed air blown from an air pump. This water supply device sucks the water in the water supply tank in a liquid or mist state and introduces the sucked liquid or mist into the gas-liquid separation means by the reduced pressure generated when the compressed air blown out from the air pump passes through the pressure reducing means. . The liquid accumulates in the gas-liquid separation means, and the mist is separated from the air by the gas-liquid separation means to become a liquid, which is sent to an ice tray to make ice (for example, see Patent Document 1).

特開2005−326117号公報JP 2005-326117 A

特許文献1記載の発明では、減圧手段を用いるため、給水タンクの上方に、減圧手段と、減圧手段に対し圧縮空気入口通路、給水タンクからの水吸い上げ通路、及び出口通路が必要となり、更に気液分離手段が必要となり、構造が複雑である。
また、給水タンク内の水を減圧手段へ吸い込む吸入管は、浄水ボックスを貫通して蓋に固定である。このため、タンク本体から外した蓋に吸入管と浄水ボックスが付随した状態となり、吸入管と浄水ボックスを洗浄する場合の分解及び組み立てが面倒である。
更に、減圧手段の下流に気液分離手段が必要であること、更に、この気液分離手段は上面が開口のため、塵埃が侵入する虞がある。
In the invention described in Patent Document 1, since the pressure reducing means is used, a pressure reducing means, a compressed air inlet passage for the pressure reducing means, a water suction passage from the water supply tank, and an outlet passage are required above the water supply tank. A liquid separation means is required, and the structure is complicated.
The suction pipe for sucking the water in the water supply tank into the pressure reducing means passes through the water purification box and is fixed to the lid. For this reason, the suction pipe and the water purification box are attached to the lid removed from the tank body, and the disassembly and assembly when cleaning the suction pipe and the water purification box are troublesome.
Further, a gas-liquid separation means is required downstream of the decompression means, and furthermore, since the gas-liquid separation means has an open top surface, dust may enter.

本発明の目的は、貯水容器内に、製氷用水を貯留する主タンク部と、製氷皿に供給すべき予め定める容量の製氷用水を貯留する計量タンク部とを、容易に区画形成でき、且つ、主タンク部と計量タンク部の洗浄をし易い貯水容器を提供することである。   An object of the present invention is to easily form a main tank part for storing ice-making water and a measuring tank part for storing a predetermined volume of ice-making water to be supplied to an ice-making dish in a water storage container, and The object is to provide a water storage container that is easy to clean the main tank section and the measuring tank section.

この目的達成のために、貯水容器内に、製氷用水を貯留する主タンク部と、製氷皿に供給すべき予め定める容量の製氷用水を貯留する計量タンク部とを、前記主タンク部と前記計量タンク部とに連通する供給孔が形成される仕切り体の挿入によって、区画形成する構成とする。そして、前記主タンク部と前記計量タンク部とをシールするパッキン及び仕切り体を、貯水容器内の所定位置への取り付け、並びに取り外しが容易に行える構成の貯水容器を提供する。   To achieve this object, a main tank section for storing ice-making water and a measuring tank section for storing a predetermined volume of ice-making water to be supplied to the ice-making tray are provided in the water storage container. A partition is formed by inserting a partition body in which a supply hole communicating with the tank portion is formed. And the water storage container of the structure which can attach and remove the packing and partition which seal the said main tank part and the said measurement tank part to the predetermined position in a water storage container easily is provided.

本発明は、自動製氷装置の給水装置であって、
製氷用水を貯留する貯水容器は、
上方に開口する開口部を有する容器本体と、
前記容器本体の内部空間を、製氷用水を貯留する主タンク部と、前記自動製氷装置の製氷皿に供給すべき予め定める容量の製氷用水を貯留する計量タンク部とに区画し、前記主タンク部と前記計量タンク部とに連通する供給孔が形成される仕切り体と、
前記仕切り体の周縁部と前記容器本体との間をシールする環状パッキンと、
前記容器本体内の底部に形成され前記環状パッキンを着脱自在に保持するパッキン保持部と、
前記容器本体の開口部に取り付けられ前記容器本体の開口部を塞ぐ蓋体と、を備え、
前記環状パッキンは、前記容器本体への前記蓋体の取り付けにより、前記仕切り体を介して前記パッキン保持部に押圧される
ことを特徴とする。
The present invention is a water supply device of an automatic ice making device,
A water storage container for storing ice-making water is
A container body having an opening opening upward;
The internal space of the container body is partitioned into a main tank section for storing ice making water and a measuring tank section for storing a predetermined volume of ice making water to be supplied to an ice tray of the automatic ice making device, the main tank section And a partition body in which a supply hole communicating with the measuring tank unit is formed,
An annular packing that seals between the peripheral edge of the partition and the container body;
A packing holding part that is formed at the bottom of the container body and holds the annular packing in a detachable manner;
A lid attached to the opening of the container body and closing the opening of the container body,
The annular packing is pressed against the packing holding part via the partition by attaching the lid to the container body.

前記パッキン保持部は、前記計量タンク部の周囲に巡る上方に開口した環状溝と、環状突起とを備え、前記環状パッキンは、前記環状溝に嵌る環状リブと、前記環状突起が嵌る取り付け溝を備えた
ことを特徴とする。
The packing holding part includes an annular groove that opens upward around the circumference of the measuring tank part, and an annular protrusion, and the annular packing has an annular rib that fits into the annular groove and an attachment groove that fits the annular protrusion. It is characterized by having.

前記容器本体は、底壁に前記計量タンク部の領域を形成するための窪みと、前記窪みの前後左右を巡る区画壁に沿って前記パッキン保持部を有し、前記区画壁の内側に前記環状突起を有し、前記区画壁と前記環状突起の間に前記環状溝を形成する
ことを特徴とする。
The container body has a recess for forming a region of the measuring tank portion in a bottom wall, and the packing holding portion along a partition wall that surrounds the front, rear, left, and right of the recess, and the annular body is formed inside the partition wall. It has a projection, and the annular groove is formed between the partition wall and the annular projection.

前記貯水容器を取り出し自在に収容する貯水容器収容部が冷蔵室に形成され、前記製氷皿が製氷部に配置され、
前記計量タンク部へ圧縮空気を送るポンプ装置が前記貯水容器収容部に配置され、
前記貯水容器は、前記貯水容器収容部への収容に伴い、前記ポンプ装置の空気出口に着脱自在に接続される
ことを特徴とする前記給水装置を備えた冷蔵庫。
A water storage container storage part for freely storing the water storage container is formed in a refrigeration chamber, and the ice tray is arranged in the ice making part,
A pump device for sending compressed air to the metering tank is disposed in the water storage container housing;
The refrigerator having the water supply device, wherein the water storage container is detachably connected to an air outlet of the pump device as the water storage container is accommodated in the water storage container accommodating portion.

本発明では、環状パッキンは容器本体内の底部に形成されたパッキン保持部に着脱自在に載置され、仕切り体は、パッキン保持部に保持された環状パッキン上に着脱自在に載置される。そして、環状パッキンは、蓋体を容器本体に取り付けることによって、仕切り体を介して押圧され、圧縮状態に保持される。
このため、環状パッキンを正規の状態に取り付けることが容易となり、環状パッキンが主タンク部と計量タンク部とのシール状態を保ち、計量タンク部の形成が容易となる。
また、貯水容器内を水洗いする場合には、蓋体を外し、仕切り体を取り出した後、環状パッキンをパッキン保持部から取り外すことにより、貯水容器内の各部を水洗いすることが可能となる。
In the present invention, the annular packing is detachably placed on a packing holding portion formed at the bottom of the container body, and the partition is detachably placed on the annular packing held by the packing holding portion. And an annular packing is pressed via a partition body by attaching a cover body to a container main body, and is hold | maintained in a compression state.
For this reason, it becomes easy to attach the annular packing in a regular state, the annular packing keeps the sealed state of the main tank part and the measuring tank part, and the forming of the measuring tank part becomes easy.
In addition, when the inside of the water storage container is washed with water, it is possible to wash each part of the water storage container with water by removing the annular packing from the packing holding part after removing the lid and removing the partition body.

また、本発明では、パッキン保持部は、計量タンク部の周囲に巡る上方に開口した環状溝と環状突起とを備え、環状パッキンは、環状溝に嵌る環状リブと、環状突起が嵌る取り付け溝を備える。それゆえ、環状パッキンが伸長性のある柔軟性のものを採用しても、環状パッキンをパッキン保持部へ上方から押し込み装着できるため、環状パッキンの取り付け及び取り外しが極めて容易となる。   Further, in the present invention, the packing holding portion includes an annular groove and an annular protrusion that open upward around the measuring tank portion, and the annular packing includes an annular rib that fits into the annular groove and an attachment groove that fits the annular projection. Prepare. Therefore, even if the annular packing employs a flexible one having an extensible property, the annular packing can be pushed into the packing holding portion from above and attached, so that the attachment and removal of the annular packing becomes extremely easy.

また、本発明では、容器本体の底壁に形成した窪みによって計量タンク部の領域を形成し、この窪みの前後左右を巡る区画壁に沿ってパッキン保持部を形成する。これによって、パッキン保持部の形成がし易く、パッキン保持部へ上方から環状パッキンを押し込み装着でき、伸長性のある柔軟性の環状パッキンを正規位置に装着し易くなる。このため、仕切り体を介して環状パッキンが押圧され、パッキン保持部に圧縮状態に保持され、計量タンク部の周囲を十分なシール状態に保つことができる。   Moreover, in this invention, the area | region of a measurement tank part is formed with the hollow formed in the bottom wall of a container main body, and a packing holding | maintenance part is formed along the partition wall which goes around the front, back, left, and right of this hollow. Accordingly, the packing holding portion can be easily formed, the annular packing can be pushed into the packing holding portion from above and attached, and the flexible and flexible annular packing can be easily attached at the normal position. For this reason, an annular packing is pressed through a partition body, it is hold | maintained by the packing holding | maintenance part in a compressed state, and the circumference | surroundings of a measurement tank part can be maintained in a sufficient sealing state.

本発明に係る自動製氷装置の給水装置を備えた第1実施形態の冷蔵庫1の正面図である。It is a front view of the refrigerator 1 of 1st Embodiment provided with the water supply apparatus of the automatic ice making apparatus which concerns on this invention. 冷蔵庫1の内部構成を説明するための正面図である。FIG. 3 is a front view for explaining the internal configuration of the refrigerator 1. 冷蔵庫1の縦断側面図である。2 is a longitudinal side view of the refrigerator 1. FIG. 本発明に係る給水装置と自動製氷機との関係を説明するための断面斜視図である。It is a cross-sectional perspective view for demonstrating the relationship between the water supply apparatus which concerns on this invention, and an automatic ice maker. 本発明に係る給水装置の貯水容器のスライド構成を説明するための断面斜視図である。It is a cross-sectional perspective view for demonstrating the slide structure of the water storage container of the water supply apparatus which concerns on this invention. 本発明に係る貯水容器の外観斜視図である。It is an external appearance perspective view of the water storage container which concerns on this invention. 本発明に係る貯水容器の内部構成を説明するための縦断側面図である。It is a vertical side view for demonstrating the internal structure of the water storage container which concerns on this invention. 本発明に係る貯水容器の内部構成を説明するため供給孔部分を断面で示す縦断側面斜視図である。It is a vertical side perspective view which shows a supply hole part in a cross section in order to demonstrate the internal structure of the water storage container which concerns on this invention. 本発明に係る貯水容器の内部構成を説明するため供給孔部分を断面で示す縦断側面図である。It is a vertical side view which shows a supply hole part in a cross section in order to demonstrate the internal structure of the water storage container which concerns on this invention. 本発明に係る貯水容器の分解図斜視図である。It is an exploded view perspective view of the water storage container concerning the present invention. 本発明に係る貯水容器の容器本体の上面斜視図である。It is an upper surface perspective view of the container main body of the water storage container which concerns on this invention. 本発明に係る貯水容器の容器本体の平面図である。It is a top view of the container main body of the water storage container which concerns on this invention. 本発明に係る貯水容器の仕切り体の一方向からの斜視図である。It is a perspective view from one direction of the partition of a water storage container concerning the present invention. 本発明に係る貯水容器の仕切り体の他の方向からの斜視図である。It is a perspective view from the other direction of the partition of a water storage container concerning the present invention. 本発明に係る貯水容器の仕切り体の下方からの斜視図である。It is a perspective view from the lower part of the partition of a water storage container concerning the present invention. 本発明に係る貯水容器の容器本体内に仕切り体を挿入した状態の上面斜視図である。It is an upper surface perspective view of the state which inserted the partition body in the container main body of the water storage container which concerns on this invention. (A)は本発明に係る貯水容器の容器本体内に仕切り体を挿入した状態の平面図であり、(B)は(A)のC円の拡大図である。(A) is a top view of the state which inserted the partition body in the container main body of the water storage container which concerns on this invention, (B) is an enlarged view of C circle of (A). 本発明に係る貯水容器のフロート体の斜視図である。It is a perspective view of the float body of the water storage container which concerns on this invention. 本発明に係る給水装置のフロート体と障壁の関係を説明する供給孔部分の縦断側面図である。It is a vertical side view of the supply hole part explaining the relationship between the float body and the barrier of the water supply apparatus according to the present invention. 本発明に係る給水装置の障壁の他の実施形態を説明する供給孔部分の縦断側面図である。It is a vertical side view of the supply hole part explaining other embodiment of the barrier of the water supply apparatus concerning the present invention. 本発明に係る貯水容器の計量タンク部内の空気排出溝部分を説明するための仕切り体の前後方向の縦断側面図である。It is a vertical side view of the partition body for demonstrating the air discharge groove part in the measurement tank part of the water storage container which concerns on this invention. 本発明に係る貯水容器の計量タンク部内の空気排出溝部分を説明するための仕切り体の左右方向の縦断側面図である。It is a vertical side view in the left-right direction of the partition body for demonstrating the air discharge groove part in the measurement tank part of the water storage container which concerns on this invention. 本発明に係る貯水容器の計量タンク部の前部のパッキン保持部を説明する拡大断面図である。It is an expanded sectional view explaining the packing holding | maintenance part of the front part of the measurement tank part of the water storage container which concerns on this invention. 本発明に係る貯水容器の計量タンク部の後部のパッキン保持部を説明する拡大断面図である。It is an expanded sectional view explaining the packing holding part of the rear part of the measurement tank part of the water storage container which concerns on this invention. 本発明に係る貯水容器の計量タンク部の左側部のパッキン保持部を説明する拡大断面図である。It is an expanded sectional view explaining the packing holding | maintenance part of the left side part of the measurement tank part of the water storage container which concerns on this invention. 本発明に係る貯水容器の計量タンク部の右側部のパッキン保持部を説明する拡大断面図である。It is an expanded sectional view explaining the packing holding | maintenance part of the right side part of the measurement tank part of the water storage container which concerns on this invention. 本発明に係る計量タンク部周縁の環状パッキンの拡大断面図である。It is an expanded sectional view of the annular packing of the circumference of a measuring tank part concerning the present invention. 本発明に係る容器本体内へ取り付けた環状パッキンの上へ仕切り体を挿入する状態の説明用拡大断面図である。It is an expanded sectional view for description of the state which inserts a partition body on the annular packing attached in the container main body which concerns on this invention. 本発明に係る容器本体内で仕切り体が環状パッキンを押圧した状態を説明する拡大断面図である。It is an expanded sectional view explaining the state which the partition body pressed the annular packing within the container main body which concerns on this invention. 本発明に係る貯水容器の容器本体へ蓋体を嵌合する状態を説明する拡大断面図である。It is an expanded sectional view explaining the state which fits a cover body to the container main body of the water storage container which concerns on this invention. 本発明に係る貯水容器の容器本体と蓋体との前側部のシール状態を説明する拡大断面図である。It is an expanded sectional view explaining the seal state of the front side part of the container main body and lid of the water storage container which concerns on this invention. 本発明に係る貯水容器の容器本体と蓋体との左側部、右側部及び後側部のシール状態を説明する拡大断面図である。It is an expanded sectional view explaining the seal state of the left side part, right side part, and rear side part of a container main part and a lid of a water storage container concerning the present invention. 本発明に係る貯水容器の容器本体と蓋体との他のシール形態を説明する拡大断面図である。It is an expanded sectional view explaining the other seal | sticker form of the container main body and cover body of the water storage container which concerns on this invention. 本発明に係るポンプ装置の分解斜視図である。It is a disassembled perspective view of the pump apparatus which concerns on this invention. 本発明に係る空気ポンプユニットとガスケット63Bの関係を説明する外観斜視図である。It is an external appearance perspective view explaining the relationship between the air pump unit which concerns on this invention, and the gasket 63B. 本発明に係るポンプ装置の外観斜視図である。1 is an external perspective view of a pump device according to the present invention. 本発明に係るポンプ装置の内部構成を説明するための縦断側面斜視図である。It is a vertical side perspective view for demonstrating the internal structure of the pump apparatus which concerns on this invention. 本発明に係るポンプ装置のガスケット63Bの後端面と本体ケースの前壁との当接状態を説明するための拡大縦断図である。It is an enlarged vertical sectional view for explaining a contact state between the rear end surface of the gasket 63B of the pump device according to the present invention and the front wall of the main body case. 本発明に係る空気ポンプユニットの背面板を取り外した状態のポンプ装置の背面斜視図である。It is a back perspective view of a pump device in the state where a back plate of an air pump unit concerning the present invention was removed. 本発明に係る空気ポンプユニットの背面板と防塵フィルタの関係を説明する分解斜視図である。It is a disassembled perspective view explaining the relationship between the back plate of the air pump unit which concerns on this invention, and a dustproof filter. 本発明に係る空気ポンプユニットの背面板の上部に防塵フィルタを取り付けた状態の背面板の斜視図である。It is a perspective view of the backplate in the state where the dustproof filter was attached to the upper part of the backplate of the air pump unit concerning the present invention. 本発明に係る空気ポンプユニットの背面板の前面図である。It is a front view of the back board of the air pump unit which concerns on this invention. 図42のA−A断面図である。It is AA sectional drawing of FIG. 本発明に係るポンプ装置の右側面図である。It is a right view of the pump apparatus which concerns on this invention. 図44のB−B断面図である。It is BB sectional drawing of FIG. 第2実施形態の冷蔵庫1の冷蔵室内を示す正面図である。It is a front view which shows the refrigerator compartment of the refrigerator 1 of 2nd Embodiment. 第2実施形態の冷蔵庫1の縦断側面図である。It is a vertical side view of the refrigerator 1 of 2nd Embodiment. 第2実施形態の冷蔵庫1の横断平面図である。It is a cross-sectional plan view of the refrigerator 1 of 2nd Embodiment.

本発明は、自動製氷装置の給水装置であって、製氷用水を貯留する貯水容器は、上方に開口する開口部を有する容器本体と、前記容器本体の内部空間を、製氷用水を貯留する主タンク部と、製氷皿に供給すべき予め定める容量の製氷用水を貯留する計量タンク部とに区画し、前記主タンク部と前記計量タンク部とに連通する供給孔が形成される仕切り体と、前記仕切り体の周縁部と前記容器本体との間をシールする環状パッキンと、前記容器本体内の底部に形成され前記環状パッキンを着脱自在に保持するパッキン保持部と、前記容器本体の開口部に取り付けられ前記容器本体の開口部を塞ぐ蓋体と、を備える。前記環状パッキンと前記仕切り体は、取り外し自在である。前記環状パッキンは、前記容器本体への前記蓋体の取り付けにより前記仕切り体を介して押圧され、前記パッキン保持部に保持される。
以下、本発明に係る自動製氷装置の給水装置の実施形態を説明する。
The present invention is a water supply device for an automatic ice making device, wherein a water storage container for storing ice making water has a container main body having an opening opening upward, and a main tank for storing ice making water in the internal space of the container main body. And a partition body in which a supply hole communicating with the main tank portion and the measurement tank portion is formed, and a measuring tank portion storing a predetermined volume of ice-making water to be supplied to the ice tray. An annular packing that seals between the peripheral edge of the partition and the container main body, a packing holding portion that is formed at the bottom of the container main body and detachably holds the annular packing, and is attached to the opening of the container main body And a lid that closes the opening of the container body. The annular packing and the partition are detachable. The annular packing is pressed through the partition body by the attachment of the lid body to the container body, and is held by the packing holding portion.
Hereinafter, an embodiment of a water supply device of an automatic ice making device according to the present invention will be described.

[第1実施形態]
図1は本発明に係る自動製氷装置の給水装置を備えた第1実施形態の冷蔵庫1を示す正面図であり、図2は冷蔵庫1の内部構成を説明するための正面図であり、
1419593006360_0.ipdl?N0000=231&N0001=85&N0005=hCWQkTjjWItxD3BkR8P7&N0500=4JPA%20417257144%20%20%20%20%20%20%20&N0510=K4u43XlmBPxtbFDJdDvQ&N0552=9&N0553=000005
は冷蔵庫1の縦断側面図である。
[First Embodiment]
FIG. 1 is a front view showing a refrigerator 1 of a first embodiment provided with a water supply device for an automatic ice making device according to the present invention, and FIG. 2 is a front view for explaining the internal configuration of the refrigerator 1.
1419593006360_0.ipdl? N0000 = 231 & N0001 = 85 & N0005 = hCWQkTjjWItxD3BkR8P7 & N0500 = 4JPA% 20417257144% 20% 20% 20% 20% 20% 20% 20 & N0510 = K4u43XlmBPxtbFDJdDvQ & N0553 = 5 & N0552 = 9
FIG. 2 is a longitudinal side view of the refrigerator 1.

以下、図1を基準として、図1の紙面に平行な方向のうち、図1の上下方向を「上下方向」といい、図1の左右方向を「左右方向」という。また図1の紙面に垂直な方向を「前後方向」として説明する。また説明において、上下方向の一方を「上方」といい、他方を「下方」という。左右方向の一方を「左方」といい、他方を「右方」という。前後方向のうち手前方向を「前方」といい、他方を「後方」という。   In the following, with reference to FIG. 1, among the directions parallel to the paper surface of FIG. 1, the vertical direction in FIG. 1 is referred to as “vertical direction”, and the horizontal direction in FIG. The direction perpendicular to the paper surface of FIG. 1 will be described as the “front-rear direction”. In the description, one of the vertical directions is referred to as “upward” and the other is referred to as “downward”. One of the left and right directions is called “left”, and the other is called “right”. The front direction among the front and rear directions is referred to as “front”, and the other is referred to as “rear”.

冷蔵庫1は、前面に開口部が形成される冷蔵庫本体2内を仕切り壁によって区画して複数の貯蔵室を形成し、これら各貯蔵室の前面は扉で開閉できる構成である。冷蔵庫本体2は外箱2Aと内箱2Bとを有し、外箱2Aと内箱2Bとの間に発泡断熱材2Cを充填した断熱構造である。冷蔵庫本体2内には、上から冷蔵室3、冷凍室4、野菜室5の順で各貯蔵室が区画されて設けられる。   The refrigerator 1 has a configuration in which a refrigerator main body 2 having an opening formed on the front surface is partitioned by a partition wall to form a plurality of storage chambers, and the front surfaces of these storage chambers can be opened and closed by doors. The refrigerator main body 2 has an outer box 2A and an inner box 2B, and has a heat insulating structure in which a foam heat insulating material 2C is filled between the outer box 2A and the inner box 2B. In the refrigerator main body 2, the storage rooms are partitioned and provided in the order of the refrigerator compartment 3, the freezer compartment 4, and the vegetable compartment 5 from the top.

冷蔵室3の開口部は、冷蔵庫本体2の一側部に、ヒンジを介して回動自在に取り付けられる冷蔵室扉10によって開閉される。冷凍室4の開口部は、冷蔵庫本体2の一側部にヒンジを介して回動自在に設けられる扉12によって開閉可能に形成される。野菜室5の開口部は、野菜室5内に設けられる左右のレールと左右のローラから成る支持装置18によって前後方向へ引き出し可能に支持される野菜容器15と、野菜容器15の前方に設けられる引き出し式扉11にて閉塞されている。
なお、冷凍室4の開口部は、野菜室5と同様に、冷凍容器、支持装置18、及び引き出し式扉によって前後方向へ引き出し可能に構成してもよい。
The opening part of the refrigerator compartment 3 is opened and closed by the refrigerator compartment door 10 attached to one side part of the refrigerator main body 2 via a hinge so that rotation is possible. The opening of the freezer compartment 4 is formed to be openable and closable by a door 12 that is provided at one side of the refrigerator main body 2 via a hinge so as to be rotatable. The opening of the vegetable compartment 5 is provided in front of the vegetable container 15 and the vegetable container 15 supported so as to be able to be pulled out in the front-rear direction by a support device 18 including left and right rails and left and right rollers provided in the vegetable compartment 5. The drawer door 11 is closed.
In addition, you may comprise the opening part of the freezer compartment 4 like the vegetable compartment 5 so that it can be pulled out in the front-back direction by a freezing container, the support device 18, and a drawer-type door.

冷蔵庫1は、冷凍サイクルを行う冷媒の圧縮機20と、冷凍サイクルの冷媒の凝縮器21と、凝縮器21の熱によって後述する除霜水を蒸発させる蒸発皿22とを含む。圧縮機20、凝縮器21、蒸発皿22は、冷蔵庫本体2の下部に設けられる機械室23に設置される。蒸発皿22は、凝縮器21上に載置され冷蔵庫本体2の前面下部から前方に移動自在に設けられる。   The refrigerator 1 includes a refrigerant compressor 20 that performs a refrigeration cycle, a refrigerant condenser 21 of the refrigeration cycle, and an evaporating dish 22 that evaporates defrosted water, which will be described later, by the heat of the condenser 21. The compressor 20, the condenser 21, and the evaporating dish 22 are installed in a machine room 23 provided in the lower part of the refrigerator body 2. The evaporating dish 22 is placed on the condenser 21 and is provided so as to be movable forward from the front lower portion of the refrigerator body 2.

冷蔵庫1は、冷凍室4の背面部に形成される冷却器室26内に設置される冷凍サイクルの冷却器24と、冷却器24で冷却された冷気を冷蔵室3、冷凍室4、野菜室5へ循環する送風機25と、冷却器24の除霜用ガラス管ヒータ27とをさらに含む。冷却器24の除霜水は、排水管を通って蒸発皿22へ導かれ、蒸発皿22にて蒸発される。   The refrigerator 1 includes a refrigeration cycle cooler 24 installed in a cooler chamber 26 formed on the back surface of the freezer compartment 4, and cold air cooled by the cooler 24 in the refrigerator compartment 3, the freezer compartment 4, and the vegetable compartment. 5 further includes a blower 25 that circulates to 5 and a glass tube heater 27 for defrosting the cooler 24. The defrost water of the cooler 24 is guided to the evaporating dish 22 through the drain pipe and is evaporated in the evaporating dish 22.

冷蔵室3と冷凍室4とは断熱仕切り壁28にて区画される。断熱仕切り壁28は、図4に示すように、インジェクション成形された合成樹脂製の冷蔵室3の底板29と、インジェクション成形された合成樹脂製の冷凍室4の天井板30と、底板29と天井板30との間に挟持される断熱材とによって構成される。断熱材は、予め所定形状に成形された発泡スチロールなどで実現される。断熱仕切り壁28は、冷蔵庫本体2の内箱2Bの左右側壁に前後方向に伸びて形成される溝と、内箱2Bの後壁に形成される溝とに、冷蔵庫本体2の開口部から挿入して取り付けられる。   The refrigerator compartment 3 and the freezer compartment 4 are partitioned by a heat insulating partition wall 28. As shown in FIG. 4, the heat insulating partition wall 28 includes a bottom plate 29 of the refrigerator compartment 3 made of injection-molded synthetic resin, a ceiling plate 30 of the freezer compartment 4 made of injection-molded synthetic resin, and the bottom plate 29 and the ceiling. It is comprised with the heat insulating material clamped between the board | plates 30. FIG. A heat insulating material is implement | achieved by the polystyrene etc. which were shape | molded previously by the predetermined shape. The heat insulating partition wall 28 is inserted from the opening of the refrigerator main body 2 into a groove formed to extend in the front-rear direction on the left and right side walls of the inner box 2B of the refrigerator main body 2 and a groove formed on the rear wall of the inner box 2B. Can be attached.

冷蔵庫1は、背壁部材32を含む。背壁部材32は、冷蔵庫本体2の後方の背壁の前面側に配設される冷蔵室3の背壁部材であり、合成樹脂製背面板とその裏側に取り付けられる発泡スチロール等の断熱材との組み合わせで構成される。背壁部材32は、冷蔵室3の背面側に上下方向の冷気供給通路35と、冷気供給通路35の左右方向にそれぞれ設けられる冷気通路35Aとを形成する。   The refrigerator 1 includes a back wall member 32. The back wall member 32 is a back wall member of the refrigerator compartment 3 disposed on the front side of the back wall behind the refrigerator main body 2, and includes a synthetic resin back plate and a heat insulating material such as foamed polystyrene attached to the back side thereof. Composed of a combination. The back wall member 32 forms a cold air supply passage 35 in the vertical direction on the back side of the refrigerator compartment 3 and a cold air passage 35 </ b> A provided in the left and right direction of the cold air supply passage 35.

断熱仕切り壁28の後部には、断熱仕切り壁28を上下に貫通した冷気供給通路36が形成される。冷気供給通路36は、その下部が送風機25から供給される冷気の導入部であり、上部が冷気供給通路35に連通する。冷気供給通路36にはダンパ装置50が取り付けられる。ダンパ装置50は、冷蔵室3の温度を感知するセンサの検知結果に基づく制御回路部からの指令によって冷気供給通路36を開閉動作する。ダンパ装置50の開閉動作によって、冷気の流量が制御され、冷蔵室3は所定の温度に保たれる。   In the rear part of the heat insulating partition wall 28, a cold air supply passage 36 penetrating up and down the heat insulating partition wall 28 is formed. The lower portion of the cold air supply passage 36 is an introduction portion of the cold air supplied from the blower 25, and the upper portion communicates with the cold air supply passage 35. A damper device 50 is attached to the cold air supply passage 36. The damper device 50 opens and closes the cold air supply passage 36 according to a command from the control circuit unit based on the detection result of the sensor that senses the temperature of the refrigerator compartment 3. The flow rate of the cold air is controlled by the opening / closing operation of the damper device 50, and the refrigerator compartment 3 is maintained at a predetermined temperature.

冷凍室4内は区画板47によって、製氷室を構成する製氷部6と冷凍庫室4Aとに区分される。製氷部6には、自動製氷機7と貯氷箱8が設けられる。自動製氷機7は、電動機構7Aと、電動機構7Aによって前後方向に延びる略水平な軸線上で正転及び逆転する製氷皿7Bを備える。製氷皿7Bの下方には上面が開口する貯氷箱8が配置される。製氷部6は、後述する貯水容器9から供給される製氷用水を凍結させて氷を製造する領域である。製氷部6は、冷凍室4内と略同等の温度、例えば、氷点下20℃前後の冷凍温度領域である。   The inside of the freezer compartment 4 is divided by the partition plate 47 into an ice making unit 6 and a freezer compartment 4A constituting the ice making room. The ice making unit 6 is provided with an automatic ice making machine 7 and an ice storage box 8. The automatic ice making machine 7 includes an electric mechanism 7A and an ice making tray 7B that rotates forward and reverse on a substantially horizontal axis extending in the front-rear direction by the electric mechanism 7A. Below the ice tray 7B, an ice storage box 8 having an open top surface is disposed. The ice making unit 6 is an area for producing ice by freezing ice-making water supplied from a water storage container 9 described later. The ice making unit 6 has a temperature substantially equal to that in the freezer compartment 4, for example, a freezing temperature region around 20 ° C. below freezing point.

製氷皿7Bは、前後方向に長く延びる長手方向を列として、一列に4個、5個、又は6個の製氷小室に区分され、左右2列配置され、8乃至12個の角型氷を作る合成樹脂製である。また、貯氷箱8は、白色、透明、半透明又はその他の色の合成樹脂製であり、左右幅に比して奥行きが長い上面開口の箱状である。   The ice tray 7B is divided into four, five, or six ice making chambers in a row with the longitudinal direction extending in the front-rear direction as a row, and is arranged in two rows on the left and right sides to make 8 to 12 square ice cubes. Made of synthetic resin. The ice storage box 8 is made of a white, transparent, translucent or other color synthetic resin and has a box shape with a top opening that is longer than the left and right width.

製氷部6の左右側壁には、一対のレール6Aが設けられる。貯氷箱8は、レール6Aに前後方向へ引き出し自在に支持される。製氷皿7Bは、電動機構7Aによって回転駆動され、製氷した氷を貯氷箱8に供給する。   A pair of rails 6 </ b> A are provided on the left and right side walls of the ice making unit 6. The ice storage box 8 is supported by the rail 6A so that it can be pulled out in the front-rear direction. The ice tray 7 </ b> B is rotated by the electric mechanism 7 </ b> A and supplies the ice made to the ice storage box 8.

貯氷箱8は、扉12を開くことによって前方へ引き出し可能である。製氷部6と冷凍庫室4Aの開口部は、それぞれ別個の扉にて開閉可能に閉じる構成でもよい。   The ice storage box 8 can be pulled forward by opening the door 12. The opening part of ice making part 6 and freezer compartment 4A may be the composition which can be opened and closed by a separate door, respectively.

図3に示すように、本発明に係る自動製氷装置Aは、自動製氷機7と給水装置Bとを有する。給水装置Bは、貯水容器9と、貯水容器9から製氷用水を送り出すための圧縮空気を貯水容器9へ供給するポンプ装置60とを備える。給水装置Bは、冷蔵室3の一部に設けた貯水容器収容部46に配置する。   As shown in FIG. 3, the automatic ice making device A according to the present invention includes an automatic ice making machine 7 and a water supply device B. The water supply device B includes a water storage container 9 and a pump device 60 that supplies compressed air for sending ice-making water from the water storage container 9 to the water storage container 9. The water supply device B is disposed in a water storage container housing portion 46 provided in a part of the refrigerator compartment 3.

製氷皿7Bへ供給する製氷用水を貯める貯水容器9は、冷蔵室3内を区画壁45で仕切った小室の貯水容器収容部46に配置する。貯水容器収容部46は冷蔵室3の一部領域であり、冷蔵室3は凍結しない例えば2〜4℃の冷却温度に冷却される。このため、貯水容器収容部46も略同等の温度に冷却される。貯水容器9は、冷蔵室3の前面扉10を開いた状態で、底板29の上面をスライド面として、前面の取っ手9Tによって前方へ取り出すことができる。   A water storage container 9 for storing ice-making water to be supplied to the ice tray 7B is disposed in a water storage container accommodating portion 46 in a small chamber in which the refrigerator compartment 3 is partitioned by a partition wall 45. The water storage container accommodating portion 46 is a partial region of the refrigerator compartment 3, and the refrigerator compartment 3 is cooled to a cooling temperature of 2 to 4 ° C., for example, which does not freeze. For this reason, the water storage container accommodating part 46 is also cooled to substantially the same temperature. The water storage container 9 can be taken out forward by a front handle 9T with the upper surface of the bottom plate 29 as a slide surface in a state where the front door 10 of the refrigerator compartment 3 is opened.

貯水容器収容部46と製氷部6は、断熱仕切り壁28にて区画される。断熱仕切り壁28には、給水装置Bから供給する製氷用水が自然流下するように製氷用水供給路51を上下方向に貫通形成する。製氷用水供給路51は、給水管51Pによって、製氷用水供給路51の入り口部を形成する。製氷用水は貯水容器9から製氷用水供給路51を介して自動製氷機7の製氷皿7Bへ供給される。   The water storage container housing part 46 and the ice making part 6 are partitioned by the heat insulating partition wall 28. An ice making water supply passage 51 is formed through the heat insulating partition wall 28 in the vertical direction so that the ice making water supplied from the water supply device B naturally flows down. The ice-making water supply path 51 forms an entrance of the ice-making water supply path 51 by a water supply pipe 51P. The ice making water is supplied from the water storage container 9 to the ice making tray 7B of the automatic ice making machine 7 through the ice making water supply path 51.

先ず、貯水容器9について説明する。
図4は本発明に係る給水装置と自動製氷機との関係を説明するための断面斜視図である。図5は本発明に係る給水装置の貯水容器のスライド構成を説明するための断面斜視図である。図6は本発明に係る貯水容器の外観斜視図である。図7は本発明に係る貯水容器の内部構成を説明するための縦断側面図である。図8は本発明に係る貯水容器の内部構成を説明するため供給孔部分を断面で示す縦断側面斜視図である。図9は本発明に係る貯水容器の内部構成を説明するため供給孔部分を断面で示す縦断側面図である。図10は本発明に係る貯水容器の分解図斜視図である。図11は本発明に係る貯水容器の容器本体の上面斜視図である。図12は本発明に係る貯水容器の容器本体の平面図である。図13は本発明に係る貯水容器の仕切り体の一方向からの斜視図である。図14は本発明に係る貯水容器の仕切り体の他の方向からの斜視図である。図15は本発明に係る貯水容器の仕切り体の下方からの斜視図である。図16は本発明に係る貯水容器の容器本体内に仕切り体を挿入した状態の上面斜視図である。図17(A)は本発明に係る貯水容器の容器本体内に仕切り体を挿入した状態の平面図であり、図17(B)は図17(A)のC円の拡大図である。
First, the water storage container 9 will be described.
FIG. 4 is a cross-sectional perspective view for explaining the relationship between the water supply apparatus and the automatic ice maker according to the present invention. FIG. 5 is a cross-sectional perspective view for explaining the slide configuration of the water storage container of the water supply apparatus according to the present invention. FIG. 6 is an external perspective view of a water storage container according to the present invention. FIG. 7 is a longitudinal side view for explaining the internal structure of the water storage container according to the present invention. FIG. 8 is a vertical side perspective view showing the supply hole portion in cross section for explaining the internal configuration of the water storage container according to the present invention. FIG. 9 is a longitudinal side view showing the supply hole portion in cross section for explaining the internal structure of the water storage container according to the present invention. FIG. 10 is an exploded perspective view of the water storage container according to the present invention. FIG. 11 is a top perspective view of the container body of the water storage container according to the present invention. FIG. 12 is a plan view of the container body of the water storage container according to the present invention. FIG. 13 is a perspective view from one direction of the partition of the water storage container according to the present invention. FIG. 14 is a perspective view from another direction of the partition of the water storage container according to the present invention. FIG. 15 is a perspective view from below of the partition of the water storage container according to the present invention. FIG. 16 is a top perspective view of a state in which a partition body is inserted into the container body of the water storage container according to the present invention. FIG. 17 (A) is a plan view showing a state in which a partition body is inserted into the container body of the water storage container according to the present invention, and FIG. 17 (B) is an enlarged view of a circle C in FIG. 17 (A).

本発明の貯水容器9は、上方に開口する開口部9A2を有する容器本体9Aと、容器本体9Aの開口部9A2に取り付けられ容器本体9Aの開口部9A2を塞ぐ蓋体9Cと、を有する。
貯水容器9は、更に、容器本体9A内に収容され容器本体9Aの内部空間を、製氷用水を貯留する主タンク部90と、製氷皿7Bに供給すべき予め定める容量の製氷用水を貯留する計量タンク部91とに区画し、主タンク部90と計量タンク部91とに連通する供給孔92が形成される仕切り壁を有する。実施形態は、この仕切り壁を容器本体9Aに着脱自在に収容される仕切り体9Bで構成し、仕切り体9Bに主タンク部90と計量タンク部91とに連通する供給孔92が形成される。
貯水容器9は、更に、計量タンク部91に連通する圧縮空気導入部91Aと、計量タンク部91に連通し計量タンク部91内の製氷用水を製氷皿7Bに導く製氷用水導出部91Bと、を有する。圧縮空気導入部91Aへ供給される圧縮空気は、後述のポンプ装置60によって供給される。
The water storage container 9 of the present invention includes a container body 9A having an opening 9A2 that opens upward, and a lid 9C that is attached to the opening 9A2 of the container body 9A and closes the opening 9A2 of the container body 9A.
Further, the water storage container 9 is accommodated in the container main body 9A and the internal space of the container main body 9A is stored in a main tank portion 90 for storing ice-making water and a predetermined volume of ice-making water to be supplied to the ice tray 7B. It has a partition wall that is divided into a tank portion 91 and in which a supply hole 92 that communicates with the main tank portion 90 and the measuring tank portion 91 is formed. In the embodiment, the partition wall is configured by a partition body 9B that is detachably accommodated in the container body 9A, and a supply hole 92 that communicates with the main tank portion 90 and the measuring tank portion 91 is formed in the partition body 9B.
The water storage container 9 further includes a compressed air introducing portion 91A that communicates with the measuring tank unit 91, and an ice making water outlet unit 91B that communicates with the measuring tank unit 91 and guides the ice making water in the measuring tank unit 91 to the ice tray 7B. Have. The compressed air supplied to the compressed air introducing portion 91A is supplied by a pump device 60 described later.

このような構成において、本発明の目的を達成する技術として、貯水容器9は、圧縮空気導入部91Aを計量タンク部91の一側部に配置し、供給孔92と製氷用水導出部91Bを計量タンク部91の他側部に配置する。   In such a configuration, as a technique for achieving the object of the present invention, the water storage container 9 is configured such that the compressed air introduction part 91A is arranged on one side of the measuring tank part 91, and the supply hole 92 and the ice making water outlet part 91B are measured. It arrange | positions in the other side part of the tank part 91. FIG.

また、本発明の目的を達成する技術として、供給孔92は、製氷用水導出部91Bよりも圧縮空気導入部91Aから離間して設けられる。   Further, as a technique for achieving the object of the present invention, the supply hole 92 is provided farther from the compressed air introduction part 91A than the ice making water lead-out part 91B.

また、本発明の目的を達成する技術として、計量タンク部91は、四辺形状の形態をなし、いずれかのコーナ部に圧縮空気導入部91Aを配置し、その対角のコーナ部に供給孔92を配置する。   Further, as a technique for achieving the object of the present invention, the measuring tank portion 91 has a quadrilateral shape, the compressed air introduction portion 91A is disposed at any one of the corner portions, and the supply hole 92 is provided at the diagonal corner portion. Place.

更に、本発明の目的を達成する技術として、仕切り体9Bは、供給孔92と、圧縮空気導入部91Aと、製氷用水導出部91Bを有し、容器本体9A内に着脱自在である。   Furthermore, as a technique for achieving the object of the present invention, the partition 9B has a supply hole 92, a compressed air introduction part 91A, and an ice making water lead-out part 91B, and is detachable in the container body 9A.

以下、本発明の貯水容器9の具体的な構成について説明する。
貯水容器9の形態は、円形状、楕円形状、長円形状、四辺形状、多角形状等の種々の形状、構造のものが適用できる。また、ポンプ装置60の圧縮空気によって製氷皿7Bへ押し出される製氷用水を溜める計量タンク部91の形態も、円形状、楕円形状、長円形状、四辺形状、多角形状等の種々の形態が適用できる。
Hereinafter, a specific configuration of the water storage container 9 of the present invention will be described.
As the form of the water storage container 9, various shapes and structures such as a circular shape, an elliptical shape, an oval shape, a quadrilateral shape, and a polygonal shape can be applied. In addition, various forms such as a circular shape, an elliptical shape, an oval shape, a quadrilateral shape, and a polygonal shape can be applied to the shape of the measuring tank unit 91 that stores the ice-making water pushed out to the ice tray 7B by the compressed air of the pump device 60. .

本発明は、貯水容器9の形態及び計量タンク部91の形態が上記のいずれの形態であっても、貯水容器9は、供給孔92と、計量タンク部91に連通する圧縮空気導入部91Aと、計量タンク部91に連通し計量タンク部91内の製氷用水を製氷皿7Bに導く製氷用水導出部91Bと、を有する。その一つの技術として、圧縮空気導入部91Aを計量タンク部91の一側部に配置し、供給孔92と製氷用水導出部91Bを計量タンク部91の他側部に配置する。   In the present invention, the water storage container 9 includes the supply hole 92 and the compressed air introduction part 91 </ b> A communicating with the measurement tank part 91, regardless of the form of the water storage container 9 and the form of the measurement tank part 91. The ice making water outlet 91B communicates with the measuring tank 91 and guides the ice making water in the measuring tank 91 to the ice tray 7B. As one technique, the compressed air introduction part 91 </ b> A is arranged on one side part of the measuring tank part 91, and the supply hole 92 and the ice making water outlet part 91 </ b> B are arranged on the other side part of the measuring tank part 91.

好ましくは、供給孔92は、製氷用水導出部91Bよりも圧縮空気導入部91Aから離間して設けられる。図17(A)に示すように、圧縮空気導入部91Aの中心に対して、供給孔92の中心までの距離L2が、製氷用水導出部91Bの中心までの距離L1よりも長く遠い位置である。   Preferably, the supply hole 92 is provided farther from the compressed air introduction part 91A than the ice making water lead-out part 91B. As shown in FIG. 17A, the distance L2 to the center of the supply hole 92 is longer than the distance L1 to the center of the ice making water outlet 91B with respect to the center of the compressed air introduction part 91A. .

図12等に示すように、計量タンク部91が、上面視で4個のコーナ部K1〜K4を形成する四辺形状の場合は、いずれかのコーナ部に圧縮空気導入部91Aを配置し、その対角のコーナ部に供給孔92を配置する。   As shown in FIG. 12 and the like, when the measuring tank portion 91 is a quadrilateral shape that forms four corner portions K1 to K4 in a top view, the compressed air introduction portion 91A is disposed in any one of the corner portions, Supply holes 92 are arranged at diagonal corners.

好ましい配置として、4個のコーナ部K1〜K4のうち、一方の辺HRの二つのコーナ部K1、K4のうちの一つのコーナ部K1に、計量タンク部91への圧縮空気導入部91Aを配置する。また、前記一方の辺HRと対向する他方の辺HF側の二つのコーナ部K2、K3のうち、圧縮空気導入部91Aに近い側のコーナ部K2に製氷用水導出部91Bを配置し、圧縮空気導入部91Aから遠い側のコーナ部K3に供給孔92を配置する。   As a preferred arrangement, among the four corner parts K1 to K4, the compressed air introduction part 91A to the measuring tank part 91 is arranged in one corner part K1 of the two corner parts K1 and K4 on one side HR. To do. Of the two corners K2 and K3 on the other side HF facing the one side HR, the ice making water outlet 91B is arranged at the corner K2 near the compressed air introduction part 91A, and the compressed air The supply hole 92 is disposed in the corner portion K3 far from the introduction portion 91A.

図示のように、計量タンク部91が、上面視で4個のコーナ部K1〜K4を形成する矩形状の場合、上面視で一対の短辺HF、HRと一対の長辺HS、HTを有する矩形状をなし、一対の短辺HF、HRと一対の長辺HS、HTが交差するコーナ部のうち、一方の短辺HR側のコーナ部K1、K4のうちの一つのコーナ部K1に計量タンク部91への圧縮空気導入部91Aを配置する。また、他方の短辺HF側のコーナ部K2、K3のうち、圧縮空気導入部91Aに近い側のコーナ部K2に製氷用水導出部91Bを配置し、圧縮空気導入部91Aから遠い側のコーナ部K3に供給孔92を配置する。後述の環状パッキン117も、計量タンク部91の周縁形状と同様に、上面視で一対の短辺と一対の長辺を備える矩形状をなす。   As shown in the figure, when the measuring tank portion 91 has a rectangular shape that forms four corner portions K1 to K4 in a top view, it has a pair of short sides HF and HR and a pair of long sides HS and HT in a top view. Of the corner portion that is rectangular and intersects with the pair of short sides HF and HR and the pair of long sides HS and HT, it is measured at one corner portion K1 of the corner portions K1 and K4 on the short side HR side. A compressed air introduction part 91A to the tank part 91 is arranged. Further, among the corner portions K2 and K3 on the other short side HF side, the ice making water lead-out portion 91B is arranged at the corner portion K2 near the compressed air introduction portion 91A, and the corner portion far from the compressed air introduction portion 91A. A supply hole 92 is disposed in K3. An annular packing 117 described later also has a rectangular shape having a pair of short sides and a pair of long sides in a top view, like the peripheral shape of the measuring tank unit 91.

本発明の貯水容器9は、計量タンク部91から製氷皿7Bへ製氷用水を供給する際、主タンク部90の製氷用水が計量タンク部91へ余分に流下することを低減するために、計量タンク部91の製氷用水の水位に応じて供給孔92を開閉可能に設けられるフロート体93を有する。これによって、計量タンク部91の製氷用水の水位が所定の低水位になるまでは、フロート体93が供給孔92を閉じた状態である。このため、供給孔92を通って主タンク部90から計量タンク部91へ流下することを、フロート体93によって防止できる。更に、供給孔92を通って計量タンク部91に貯留された製氷用水の一部が主タンク部90へ逆流することを、フロート体93によって防止できる。   The water storage container 9 of the present invention is provided with a measuring tank in order to reduce the amount of ice making water in the main tank 90 flowing down to the measuring tank 91 when supplying ice making water from the measuring tank 91 to the ice tray 7B. The float body 93 is provided so that the supply hole 92 can be opened and closed according to the water level of the ice making water in the section 91. As a result, the float 93 closes the supply hole 92 until the ice making water level in the measuring tank unit 91 reaches a predetermined low water level. For this reason, it is possible to prevent the float body 93 from flowing down from the main tank portion 90 to the measuring tank portion 91 through the supply hole 92. Furthermore, the float body 93 can prevent a part of the ice making water stored in the measuring tank portion 91 from passing through the supply hole 92 to flow back to the main tank portion 90.

上記のように、圧縮空気導入部91Aを計量タンク部91の一側部に配置し、供給孔92と製氷用水導出部91Bを計量タンク部91の他側部に配置する。また、計量タンク部91は四辺形状の形態をなし、いずれかのコーナ部に圧縮空気導入部91Aを配置し、その対角のコーナ部に供給孔92を配置する。これによって、供給孔92と製氷用水導出部91Bが、圧縮空気導入部91Aから離間した配置となる。このため、フロート体93に対し、圧縮空気導入部91Aから導入される圧縮空気の影響を低減でき、フロート体93が供給孔92を閉じる動作が安定する。更に、供給孔92を製氷用水導出部91Bよりも圧縮空気導入部91Aから離間して設けることにより、フロート体93の開閉動作を一層安定させることができ、圧縮空気が供給孔92から漏れ出すことを防ぐことができる。   As described above, the compressed air introduction portion 91 </ b> A is disposed on one side portion of the measuring tank portion 91, and the supply hole 92 and the ice making water outlet portion 91 </ b> B are disposed on the other side portion of the measuring tank portion 91. Further, the measuring tank portion 91 has a quadrilateral shape, and the compressed air introduction portion 91A is disposed at one of the corner portions, and the supply hole 92 is disposed at the diagonal corner portion. As a result, the supply hole 92 and the ice making water lead-out portion 91B are arranged apart from the compressed air introduction portion 91A. For this reason, the influence of the compressed air introduced from the compressed air introducing portion 91A can be reduced with respect to the float body 93, and the operation of the float body 93 closing the supply hole 92 is stabilized. Furthermore, by providing the supply hole 92 farther from the compressed air introduction part 91A than the ice making water lead-out part 91B, the opening and closing operation of the float body 93 can be further stabilized, and the compressed air leaks from the supply hole 92. Can be prevented.

貯水容器9の使用性、製作性、主タンク部90の容積の確保、計量タンク部91の容積の確保、冷蔵庫1への収容性、貯水容器9の収容により冷蔵室3を占める容積の減少割合等を考慮した場合、好ましい形態の一つとして、貯水容器9は、左右幅に比して前後方向の長さが長い矩形状形態となる。
以下、この形態の貯水容器9について詳細を記載する。
Usability and manufacturability of the water storage container 9, securing of the volume of the main tank part 90, securing of the volume of the measuring tank part 91, storage capacity in the refrigerator 1, reduction rate of the volume occupying the refrigerator compartment 3 due to the storage of the water storage container 9 In consideration of the above, as one of the preferable modes, the water storage container 9 has a rectangular shape with a length in the front-rear direction longer than the left-right width.
Hereinafter, details of the water storage container 9 of this embodiment will be described.

図示のように、貯水容器9は、短辺側となる左右方向の長さ(横幅)に比して、長辺側となる前後方向の長さ(奥行き)が十分長く、上面視で前後方向に長い矩形状をなし、全体形状が前後方向に長い直
方形状である。
As shown in the drawing, the water storage container 9 has a sufficiently long length (depth) in the front-rear direction on the long side compared to the length in the left-right direction (width) on the short side, and the front-rear direction as viewed from above. The overall shape is a rectangular shape that is long in the front-rear direction.

この形状に合わせて、貯水容器9は、製氷用水を貯留する前後方向に長い主タンク部90を形成する上方に開口する開口部9A2を有する容器本体9Aと、容器本体9A内に挿入され主タンク部90の直下に計量タンク部91を区画形成する仕切り体9Bと、容器本体9Aの開口部9A2を塞ぐように容器本体9Aに着脱自在に取り付ける蓋体9Cとを有する。   In accordance with this shape, the water storage container 9 includes a container main body 9A having an opening 9A2 that opens upward to form a main tank part 90 that is long in the front-rear direction for storing ice-making water, and a main tank inserted into the container main body 9A. A partition body 9B that partitions and forms the measuring tank section 91 immediately below the section 90, and a lid body 9C that is detachably attached to the container body 9A so as to close the opening 9A2 of the container body 9A.

図12に示すように、計量タンク部91は、上面視で、前後方向に長い矩形状をなし、四隅のコーナ部K1〜K4は円弧をなす。図17(A)に示すように、計量タンク部91の一側部、即ち前後に位置する短辺HF、HRのうち後部の短辺HR側に、圧縮空気導入部91Aを配置する。また、計量タンク部91の他側部、即ち前後に位置する短辺HF、HRのうち前部の短辺HF側に、供給孔92と製氷用水導出部91Bを離間配置する。   As shown in FIG. 12, the measuring tank portion 91 has a rectangular shape that is long in the front-rear direction when viewed from above, and the corner portions K1 to K4 at the four corners form an arc. As shown in FIG. 17A, the compressed air introduction part 91A is arranged on one side of the measuring tank part 91, that is, on the short side HR side of the rear part among the short sides HF and HR located in the front and rear. In addition, the supply hole 92 and the ice making water lead-out portion 91 </ b> B are spaced apart from each other on the other side of the measuring tank 91, that is, on the short side HF on the front side of the short sides HF and HR located in the front and rear.

この具体的配置は、図17(A)に示すように、前後に位置する短辺HF、HRのうち、後部の短辺HRの左右コーナ部K1、K4の一方のコーナ部K1に圧縮空気導入部91Aを配置する。また、前部の短辺HFの左右のコーナ部K2、K3のうち、圧縮空気導入部91Aに近い側のコーナ部K2に製氷用水導出部91Bを配置し、圧縮空気導入部91Aから遠い側のコーナ部K3に供給孔92を配置する。製氷用水導出部91Bと供給孔92は、相互に離れた位置にあり、圧縮空気導入部91Aに対して供給孔92が製氷用水導出部91Bよりも遠方配置である。計量タンク部91には、自動製氷機7による1回の製氷に必要な規定量の製氷用水を貯溜する。1回の製氷に要する規定量は、製氷皿7Bが規定水位となる量である。   As shown in FIG. 17A, this specific arrangement is such that compressed air is introduced into one of the left and right corner portions K1 and K4 of the rear short side HR out of the short sides HF and HR positioned in the front and rear. The part 91A is arranged. Further, among the left and right corner portions K2 and K3 of the front short side HF, the ice making water lead-out portion 91B is disposed at the corner portion K2 near the compressed air introduction portion 91A, and the far side from the compressed air introduction portion 91A. The supply hole 92 is disposed in the corner portion K3. The ice making water lead-out portion 91B and the supply hole 92 are located away from each other, and the supply hole 92 is arranged farther from the compressed air introduction portion 91A than the ice making water lead-out portion 91B. The metering tank unit 91 stores a predetermined amount of ice making water necessary for one ice making by the automatic ice making machine 7. The specified amount required for one ice making is the amount that makes the ice tray 7B at the specified water level.

この形態の貯水容器9の場合も、上記同様に、フロート体93に対し、圧縮空気導入部91Aから導入される圧縮空気の影響を低減できることとなり、フロート体93が供給孔92を閉じる動作が安定する。更に、供給孔92を製氷用水導出部91Bよりも圧縮空気導入部91Aから離間して設けることにより、一層安定した動作が得られる。   Also in the case of the water storage container 9 of this form, similarly to the above, the influence of the compressed air introduced from the compressed air introduction portion 91A can be reduced with respect to the float body 93, and the operation of the float body 93 closing the supply hole 92 is stable. To do. Furthermore, by providing the supply hole 92 farther from the compressed air introduction portion 91A than the ice making water outlet portion 91B, a more stable operation can be obtained.

図13〜図15、図17(A)に示すように、供給孔92、圧縮空気導入部91A、及び製氷用水導出部91Bが仕切り体9Bに貫通形成される。このため、供給孔92、圧縮空気導入部91A、及び製氷用水導出部91Bの相互配置が定め易くなる。   As shown in FIGS. 13 to 15 and 17A, a supply hole 92, a compressed air introduction portion 91A, and an ice making water lead-out portion 91B are formed through the partition body 9B. For this reason, it becomes easy to determine the mutual arrangement of the supply hole 92, the compressed air introduction part 91A, and the ice making water outlet part 91B.

図4、図5、及び図7に示すように、ポンプ装置60の圧縮空気を計量タンク部91に導入する圧縮空気導入路94は、仕切り体9Bに貫通形成した圧縮空気導入部91Aと、蓋体9Cから後方へ延出しポンプ装置60の前面の空気吐出口63に着脱自在に接続される圧縮空気誘導パイプ96と、上端部が環状パッキン116を介して圧縮空気誘導パイプ96と連通し下端部が圧縮空気導入部91Aと連通するように、仕切り体9Bに立設した圧縮空気導入パイプ97とで構成する。実施例では、圧縮空気導入パイプ97は、圧縮空気導入部91Aとともに仕切り体9Bに一体成形され、円形状の圧縮空気導入部91Aと同径(成型上緩やかな抜き勾配はある)で、円形状の圧縮空気導入パイプ97が立ち上がる。   As shown in FIGS. 4, 5, and 7, the compressed air introduction passage 94 for introducing the compressed air of the pump device 60 into the metering tank portion 91 includes a compressed air introduction portion 91A formed through the partition body 9B, and a lid. A compressed air induction pipe 96 extending rearward from the body 9C and detachably connected to an air discharge port 63 on the front surface of the pump device 60, and a lower end portion communicating with the compressed air induction pipe 96 via an annular packing 116 at the upper end portion Is constituted by a compressed air introduction pipe 97 erected on the partition body 9B so as to communicate with the compressed air introduction portion 91A. In the embodiment, the compressed air introduction pipe 97 is integrally formed with the partition body 9B together with the compressed air introduction portion 91A, has the same diameter as the circular compressed air introduction portion 91A (there is a gentle draft on the molding), and has a circular shape. Compressed air introduction pipe 97 rises.

計量タンク部91から製氷皿7Bへ向けて製氷用水を導出する製氷用水導出路95は、製氷用水導出部91Bと、下端部が製氷用水導出部91Bに連通するように仕切り体9Bに立設した製氷用水導出パイプ99と、下端部が製氷用水供給路51へ臨むように容器本体9Aに立設した製氷用水誘導パイプ98と、製氷用水導出パイプ99の上端部と製氷用水誘導パイプ98の上端部とを連通する連通路100とで構成する。これによって、製氷用水導出路95は、上方に逆U字状または門型に屈曲した通路を構成する。   An ice making water lead-out path 95 for leading ice making water from the measuring tank portion 91 toward the ice tray 7B is erected on the partition body 9B so that the ice making water lead-out portion 91B communicates with the ice making water lead-out portion 91B. The ice making water lead-out pipe 99, the ice making water guide pipe 98 standing on the container body 9A so that the lower end faces the ice making water supply channel 51, the upper end portion of the ice making water lead pipe 99, and the upper end portion of the ice making water guide pipe 98 And a communication path 100 that communicates with each other. As a result, the ice making water lead-out path 95 forms a path bent upward in an inverted U shape or a gate shape.

図7に示すように、一回の製氷に必要な規定量の製氷用水をポンプ装置60の圧縮空気によって製氷皿7Bへ押し出すために、製氷用水導出パイプ99と連通するように、仕切り体9Bから下方へ延出した出口パイプ99Pの下端の開口でもって、製氷用水導出部91Bが形成される。この出口パイプ99Pの下端の開口は、計量タンク部91の内底面に近接した位置に開口する。容器本体9Aの内底面9A1に相当する計量タンク部91の内底面9A1と、出口パイプ99Pの下端との間に、製氷用水が流出する間隔TPを形成する。実施例では、円形状の製氷用水導出パイプ99と円形状の出口パイプ99Pは、内径が同等の一連のパイプを形成する。このため、円形状の製氷用水導出部91Bと同径(成型上緩やかな抜き勾配はある)で、円形状の出口パイプ99Pが立ち上がり、円形状の製氷用水導出パイプ99に連通する。   As shown in FIG. 7, in order to push out a specified amount of ice making water required for one ice making to the ice making tray 7B by the compressed air of the pump device 60, the partition 9B is connected to the ice making water outlet pipe 99. The ice making water outlet 91B is formed by the opening at the lower end of the outlet pipe 99P extending downward. The opening at the lower end of the outlet pipe 99 </ b> P opens at a position close to the inner bottom surface of the measuring tank portion 91. Between the inner bottom surface 9A1 of the measuring tank portion 91 corresponding to the inner bottom surface 9A1 of the container main body 9A and the lower end of the outlet pipe 99P, an interval TP through which ice making water flows out is formed. In the embodiment, the circular ice making water outlet pipe 99 and the circular outlet pipe 99P form a series of pipes having the same inner diameter. For this reason, the circular outlet pipe 99P rises and communicates with the circular ice making water outlet pipe 99 having the same diameter as that of the circular ice making water outlet 91B (there is a gentle draft for molding).

実施例では、出口パイプ99Pは、製氷用水導出パイプ99と同じ内径で製氷用水導出パイプ99と連通し、仕切り体9Bと一体成形である。   In the embodiment, the outlet pipe 99P communicates with the ice making water outlet pipe 99 with the same inner diameter as the ice making water outlet pipe 99, and is integrally formed with the partition body 9B.

図13〜図17(A)及び(B)に示すように、連通路100は、横方向に延びた筒状体の略下半分を残して上面開口の開渠状連通路である。連通路100は、製氷用水誘導パイプ98の上端部に、四角形状の升状に拡大する上面開口の開渠部100Aと、製氷用水導出パイプ99の上端部から前方に延出する上面開口の開渠部100Bとから構成する。開渠部100Aは、その後壁に切欠き状の連結壁100Mを形成する。開渠部100Bは、底壁及び左右壁が拡大する先端部100Pを有し、その先端部100Pの根元側の外周に連結溝100Nを形成する。   As shown in FIGS. 13 to 17 (A) and 17 (B), the communication path 100 is an open communication path having an upper surface opening, leaving substantially the lower half of the tubular body extending in the lateral direction. The communication path 100 has an opening portion 100A having an upper surface opening that expands in a quadrangular bowl shape at the upper end portion of the ice making water guide pipe 98 and an opening portion of the upper surface opening that extends forward from the upper end portion of the ice making water outlet pipe 99. It is comprised from the collar part 100B. The opening part 100A forms a notch-shaped connecting wall 100M on the wall thereafter. The unfolding part 100B has a tip part 100P where the bottom wall and the left and right walls are enlarged, and a connecting groove 100N is formed on the outer periphery on the base side of the tip part 100P.

図16、図17(A)及び(B)に示すように、容器本体9A内への仕切り体9Bの挿入によって、開渠部100Aに開渠部100Bが載り、連結壁100Mが連結溝100Nに嵌合する。この状態で、開渠部100Bの先端部100Pが開渠部100A内に進入する状態で、両者が連結し、連続した連通路100を形成する。容器本体9Aに取り付けた蓋体9Cによって、連通路100の上面開口が塞がれ、横方向に延びた連通路100となる。連通路100は、製氷用水導出パイプ99側から製氷用水誘導パイプ98側へ向けて低く傾斜する。このため、計量タンク部91から製氷用水供給路51へ向けた製氷用水の流れが良好となり、且つ水切りが良好となる。   As shown in FIGS. 16, 17A and 17B, the opening portion 100B is placed on the opening portion 100A by inserting the partition 9B into the container body 9A, and the connecting wall 100M is placed in the connecting groove 100N. Mating. In this state, the leading end portion 100P of the opening portion 100B enters the opening portion 100A, and both are connected to form a continuous communication path 100. The upper surface opening of the communication path 100 is closed by the lid body 9C attached to the container main body 9A, thereby forming the communication path 100 extending in the lateral direction. The communication path 100 is inclined downward from the ice making water outlet pipe 99 side toward the ice making water guide pipe 98 side. For this reason, the flow of ice making water from the measuring tank unit 91 toward the ice making water supply path 51 is good, and the draining is good.

容器本体9A、仕切り体9B、蓋体9Cを合成樹脂成形する場合、それに関連する圧縮空気導入路94、製氷用水導出路95等を合成樹脂にて一体成形する。この場合、連通路100を含めて製氷用水導出路95全体を暗渠通路とすることは、成形金型や成形方法等が複雑になり、大きなコストアップとなる。上記のように、製氷用水導出路95が上方に逆U字状または門型に屈曲した通路を構成しており、その連通路100は、製氷用水誘導パイプ98側の上面開口の開渠部100Aと、製氷用水導出パイプ99側の上面開口の開渠部100Bで構成するため、上記のように各部を合成樹脂成形する場合も、成形金型や成形方法等が簡単になり、低コスト化が達成できる。   When the container body 9A, the partition body 9B, and the lid body 9C are molded with synthetic resin, the compressed air introduction path 94, the ice making water outlet path 95, and the like related thereto are integrally molded with synthetic resin. In this case, if the entire ice making water outlet path 95 including the communication path 100 is used as a culvert path, a molding die, a molding method, and the like become complicated, resulting in a large cost increase. As described above, the ice making water lead-out path 95 forms a path that is bent upward in an inverted U shape or a gate shape, and the communication path 100 is an opening portion 100A of the upper surface opening on the ice making water guiding pipe 98 side. In addition, since the opening portion 100B of the upper surface opening on the ice making water lead-out pipe 99 side is formed, even when each part is molded with a synthetic resin as described above, the molding die, the molding method, etc. are simplified and the cost is reduced. Can be achieved.

開渠部100Aと開渠部100Bとの連結部に、シール用パッキンを用いる方法もあるが、その場合は、このシール用パッキン部に残った水が腐敗してカビが発生する虞がある。本発明は、上記のように、容器本体9A内への仕切り体9Bの挿入に伴って、開渠部100Aの先端部に開渠部100Bの先端部が載り、開渠部100Bの先端部100Pが開渠部100A内に進入する状態である。このため、シール用パッキンを用いることなく、製氷用水導出路95を流れる製氷用水の水漏れを防止できる。また、容器本体9A内から仕切り体9Bを取り外せば、開渠部100Aと開渠部100Bを洗浄できるため、カビの発生を防ぐことができる。更に、仕切り体9Bの挿入に伴って、開渠部100Aと開渠部100Bの連結ができるため、両開渠部の連結作業が簡素化される。このため、連通路100の部分の連結と分離がし易く、洗浄もし易くなるため、組み立て、分解がし易く、衛生的な連通路100となる。   There is also a method of using a seal packing at the connecting portion between the opening portion 100A and the opening portion 100B, but in this case, water remaining in the sealing packing portion may rot and mold may occur. As described above, according to the present invention, as the partition body 9B is inserted into the container body 9A, the distal end portion of the opening portion 100B is placed on the distal end portion of the opening portion 100A, and the distal end portion 100P of the opening portion 100B. Is a state of entering the opening part 100A. For this reason, it is possible to prevent water leakage of ice making water flowing through the ice making water lead-out path 95 without using seal packing. Moreover, since the opening part 100A and the opening part 100B can be wash | cleaned if the partition body 9B is removed from the container main body 9A, generation | occurrence | production of mold | fungi can be prevented. Furthermore, since the opening part 100A and the opening part 100B can be connected with the insertion of the partition 9B, the connecting operation of both opening parts is simplified. For this reason, it is easy to connect and separate portions of the communication passage 100 and to facilitate cleaning, so that assembly and disassembly are easy and the hygienic communication passage 100 is obtained.

また、製氷用水導出路95が上方に逆U字状または門型に屈曲した通路を構成することにより、製氷部6の冷凍冷気が製氷用水供給路51を上昇して計量タンク部91へ逆流することを抑制できる効果がある。更に、圧縮空気導入路94は、圧縮空気導入部91Aから立ち上がり、製氷用水導出路95は、製氷用水導出部91Bから導出する製氷用水が上昇し下降する流れとなる形態である。このため、貯水容器9を貯水容器収容部46へ収容するときや、冷蔵庫扉10を開閉する際などの振動によって、計量タンク部91の製氷用水が、製氷用水供給路51やポンプ装置60の空気吐出口63へ漏出することを防止できる。
この漏出防止効果の向上のために、連通路100内の底面レベル100L、及び圧縮空気誘導パイプ96の底面レベル96Lは、貯水容器9内の製氷用水満杯レベルWLよりも若干上位とする。貯水容器9内の製氷用水満杯レベルWLは、即ち、主タンク部90の製氷用水満杯レベルであり、給水口104の下部に設けた水平辺104Aのレベルに定めている。
Further, the ice making water lead-out path 95 forms a path that is bent upward in an inverted U shape or a gate shape, so that the refrigerated cold air in the ice making section 6 rises in the ice making water supply path 51 and flows back to the measuring tank section 91. There is an effect that can be suppressed. Further, the compressed air introduction path 94 rises from the compressed air introduction section 91A, and the ice making water outlet path 95 has a form in which the ice making water led out from the ice making water outlet section 91B rises and falls. For this reason, when the water storage container 9 is accommodated in the water storage container accommodating part 46 or when the refrigerator door 10 is opened and closed, the ice making water in the measuring tank part 91 is supplied to the air in the ice making water supply path 51 and the pump device 60. Leakage to the discharge port 63 can be prevented.
In order to improve the leakage prevention effect, the bottom surface level 100L in the communication passage 100 and the bottom surface level 96L of the compressed air guiding pipe 96 are set slightly higher than the ice-making water full level WL in the water storage container 9. The ice making water full level WL in the water storage container 9 is the ice making water full level of the main tank unit 90, and is set at the level of the horizontal side 104 </ b> A provided below the water supply port 104.

次に、供給孔92とフロート体93の関係について説明する。
図15に示すように、供給孔92は矩形状の孔の中央部に拡大部92Aを有する形状である。図17(A)、図18に示すように、フロート体93の上面中央部に、この矩形状の供給孔92を通り抜ける大きさの略T字状の支持部93Aを有する。このため、供給孔92の矩形状に沿って下方から支持部93Aを供給孔92に通した状態で、フロート体93を略90度回すことにより、支持部93Aの上端部の係止辺93Pが、供給孔92の拡大部92Aの上縁部に係止し、フロート体93を落下しない状態に保持する。この状態で、支持部93Aの縦方向軸部93Qが供給孔92の拡大部92Aに遊嵌状態である。このため、フロート体93は、計量タンク部91の水位によって上下動可能である。
Next, the relationship between the supply hole 92 and the float body 93 will be described.
As shown in FIG. 15, the supply hole 92 has a shape having an enlarged portion 92A at the center of a rectangular hole. As shown in FIGS. 17A and 18, the float body 93 has a substantially T-shaped support portion 93 </ b> A having a size that passes through the rectangular supply hole 92 at the center of the upper surface. Therefore, by turning the float body 93 approximately 90 degrees with the support portion 93A passing through the supply hole 92 from below along the rectangular shape of the supply hole 92, the locking side 93P of the upper end portion of the support portion 93A is The floating body 93 is locked to the upper edge portion of the enlarged portion 92A of the supply hole 92, and the float body 93 is held in a state where it does not fall. In this state, the longitudinal shaft portion 93Q of the support portion 93A is loosely fitted to the enlarged portion 92A of the supply hole 92. For this reason, the float body 93 can be moved up and down by the water level of the measuring tank unit 91.

この構成によって、計量タンク部91の水位が所定の満杯状態になる前は、フロート体93が下降しており、主タンク部90の製氷用水が、支持部93Aの周囲から供給孔92を通り、フロート体93の周囲を通って計量タンク部91へ自然流下する。計量タンク部91の水位が満杯へ向けて上昇することにより、フロート体93が上昇し、計量タンク部91が所定の満杯になれば、図19に示すように、フロート体93の上面が、供給孔92の周囲で仕切り体9Bの下面に当接し、供給孔92を閉じる。   With this configuration, before the water level of the measuring tank unit 91 reaches a predetermined full state, the float body 93 is lowered, and the ice making water in the main tank unit 90 passes through the supply hole 92 from the periphery of the support unit 93A, It naturally flows down to the measuring tank portion 91 through the periphery of the float body 93. When the water level of the measuring tank unit 91 rises toward full, the float body 93 rises, and when the measuring tank unit 91 becomes full, the upper surface of the float body 93 is supplied as shown in FIG. The supply hole 92 is closed by contacting the lower surface of the partition 9B around the hole 92.

製氷工程の開始により、ポンプ装置60が稼働し、圧縮空気が圧縮空気導入部91Aから流入し、計量タンク部91の製氷用水を押し出す。この押し出しに伴って計量タンク部91内の水位が徐々に低下するが、計量タンク部91が所定の低水位になるまでは、フロート体93が供給孔92を閉じたままの状態を維持する。このように、フロート体93の浮力を設定する。それによって、計量タンク部91から押し出す規定量を超えた量の製氷用水の押し出しを制限できる。   With the start of the ice making process, the pump device 60 is operated, compressed air flows from the compressed air introduction part 91A, and pushes out the ice making water in the measuring tank part 91. With this extrusion, the water level in the measuring tank unit 91 gradually decreases, but the float body 93 maintains the supply hole 92 in a closed state until the measuring tank unit 91 reaches a predetermined low water level. Thus, the buoyancy of the float body 93 is set. Thereby, it is possible to limit the pushing out of the ice making water in an amount exceeding the specified amount pushed out from the measuring tank unit 91.

計量タンク部91内の水位が低下して所定の低水位になると、フロート体93が供給孔92を開く状態となるが、そのとき、フロート体93が直ちに下降するのではなく、若干遅れて下降する。それは、フロート体93の上面と仕切り体9Bの下面との間に存在する水の付着作用によって、フロート体93が供給孔92を閉じたままの状態を維持する。フロート体93の重量とこの付着作用とのバランスが崩れたとき、この維持作用が無くなり、遂にフロート体93が降下して供給孔92を開く。供給孔92を開くことにより僅かな量が供給孔92から流下しても、その時は既に、計量タンク部91から規定量の略全量の製氷用水が製氷皿7Bへ押し出された状態であるため、この僅かな量が供給孔92から流下しても、規定量の製氷用水の押し出しには殆んど影響しない。   When the water level in the measuring tank unit 91 is lowered to a predetermined low water level, the float body 93 opens the supply hole 92. At this time, the float body 93 does not descend immediately but descends with a slight delay. To do. That is, the float body 93 maintains the state in which the supply hole 92 is closed by the adhesion action of water existing between the upper surface of the float body 93 and the lower surface of the partition body 9B. When the balance between the weight of the float body 93 and the adhesion action is lost, the maintenance action disappears, and the float body 93 finally descends to open the supply hole 92. Even if a small amount flows down from the supply hole 92 by opening the supply hole 92, the specified amount of ice-making water has already been pushed out from the measuring tank unit 91 to the ice-making tray 7 </ b> B. Even if this small amount flows down from the supply hole 92, the extrusion of the specified amount of ice making water is hardly affected.

実施例では、一回の製氷に必要な規定量は80ccであり、計量タンク部91はこの規定量を確保する容積である。一回の製氷に必要な規定量の80ccの押し出しは、空気ポンプ61の稼働時間によって定めている。実施例では、15秒間の稼働によって得ている。   In the embodiment, the prescribed amount required for one ice making is 80 cc, and the measuring tank unit 91 has a volume for securing this prescribed amount. The specified amount of 80 cc required for one ice making is determined by the operating time of the air pump 61. In the embodiment, it is obtained by operating for 15 seconds.

次に、フロート体93による供給孔92の閉止動作の安定化構成について説明する。
図18は本発明に係る貯水容器のフロート体の斜視図、図19は本発明に係る給水装置のフロート体と障壁の関係を説明する供給孔部分の縦断側面図、図20は本発明に係る給水装置の障壁の他の実施形態を説明する供給孔部分の縦断側面図である。
Next, a configuration for stabilizing the closing operation of the supply hole 92 by the float body 93 will be described.
18 is a perspective view of a float body of a water storage container according to the present invention, FIG. 19 is a longitudinal side view of a supply hole portion for explaining the relationship between the float body and a barrier of the water supply apparatus according to the present invention, and FIG. 20 is according to the present invention. It is a vertical side view of the supply hole part explaining other embodiment of the barrier of a water supply apparatus.

圧縮空気によって計量タンク部91から製氷用水を押し出す間、フロート体93が供給孔92を安定的に閉止することが望まれる。しかし、計量タンク部91の製氷用水の水位が低下した状態で、冷蔵庫1からの食品の取り出しや、冷蔵庫1への食品の収容や、またはその他の要因等によって、計量タンク部91の製氷用水が揺動すれば、その影響によってフロート体93が揺動する。この揺動によって、供給孔92が開いた場合、主タンク部90の製氷用水が供給孔92を通って計量タンク部91へ余分に流下することが懸念される。   It is desired that the float body 93 stably closes the supply hole 92 while pushing out the ice-making water from the metering tank unit 91 by the compressed air. However, the ice-making water in the measuring tank unit 91 is reduced by taking out food from the refrigerator 1, storing food in the refrigerator 1, or other factors while the water level of ice-making water in the measuring tank unit 91 is lowered. If it swings, the float body 93 swings due to the influence. If the supply hole 92 is opened by this swinging, there is a concern that ice making water in the main tank unit 90 may flow excessively to the measuring tank unit 91 through the supply hole 92.

上記のような懸念に鑑み、フロート体93が供給孔92を閉止する動作を安定させるために、フロート体93の周囲を囲む障壁121を設ける。
以下、この構成について記載する。
In view of the above concerns, in order to stabilize the operation of the float body 93 closing the supply hole 92, a barrier 121 surrounding the float body 93 is provided.
This configuration will be described below.

図8、図9、図19に示すように、主タンク部90と計量タンク部91とを仕切る仕切り壁である仕切り体9Bに、フロート体93を囲む障壁121を備える。
正規の動作によって、フロート体93が下降して供給孔92を開き、主タンク部90の製氷用水が供給孔92を通して計量タンク部91へ流入するようにする。このために、障壁121の下端部121Bは、計量タンク部91の内底面、即ち容器本体9Aの内底面9A1との間に間隔Gを形成する。この間隔Gによって、製氷用水が計量タンク部91内へ流れ出る製氷用水流出部122を構成する。
As shown in FIGS. 8, 9, and 19, a partition body 9 </ b> B that is a partition wall that partitions the main tank unit 90 and the measurement tank unit 91 is provided with a barrier 121 that surrounds the float body 93.
By the normal operation, the float body 93 is lowered to open the supply hole 92 so that the ice making water in the main tank portion 90 flows into the measuring tank portion 91 through the supply hole 92. For this purpose, the lower end 121B of the barrier 121 forms a gap G between the inner bottom surface of the measuring tank portion 91, that is, the inner bottom surface 9A1 of the container main body 9A. The gap G constitutes an ice making water outflow portion 122 from which ice making water flows into the measuring tank portion 91.

図8、図9、図19に図示の実施例では、フロート体93は、仕切り体9Bから垂下する円形状であり、障壁121も円形状である。障壁121は、仕切り体9Bの下面に一体成形にて形成する。後述のように、仕切り体9Bが容器本体9A内の所定位置に挿入され正規の状態を保った状態で、供給孔92から流下する製氷用水が、フロート体93の周囲の略1mm程度の隙間を通り、間隔Gから計量タンク部91内へスムースに流れる。間隔Gは、この流れが確保できる最少間隔であれば好ましい。実施例では、間隔Gは1mmであるが、0.8mm〜1.5mmの範囲であれば、効果的に目的を達成できる。   In the embodiment shown in FIGS. 8, 9, and 19, the float body 93 has a circular shape depending on the partition 9B, and the barrier 121 has a circular shape. The barrier 121 is formed on the lower surface of the partition 9B by integral molding. As will be described later, while the partition 9B is inserted into a predetermined position in the container body 9A and kept in a normal state, the ice-making water flowing down from the supply hole 92 passes through a gap of about 1 mm around the float body 93. As a result, the air smoothly flows from the gap G into the measuring tank 91. The interval G is preferably the minimum interval that can secure this flow. In the embodiment, the interval G is 1 mm, but the object can be effectively achieved if it is in the range of 0.8 mm to 1.5 mm.

計量タンク部91内が製氷用水に満たされた状態において、圧縮空気導入部91Aから流入する圧縮空気によって計量タンク部91内の製氷用水が押し出され、計量タンク部91内の水位が低下する。その水位が障壁121の下端121Bよりも低下するまでは、障壁121内の水位は低下しないため、図19に示すように、フロート体93が供給孔92を閉じたままである。そして、水位が障壁121の下端121Bよりも低下すると、フロート体93が供給孔92を開く状態となるが、そのとき、フロート体93が直ちに下降するのではなく、若干遅れて下降する。それは、フロート体93の上面と仕切り体9Bの下面との間に存在する水の付着作用によって、フロート体93が供給孔92を閉じたままの状態を維持する。フロート体93の重量とこの付着作用とのバランスが崩れたとき、この維持作用が無くなり、遂にフロート体93が降下して供給孔92を開く。供給孔92を開くことにより僅かな量が供給孔92から流下しても、その時は既に、計量タンク部91から規定量の略全量の製氷用水が製氷皿7Bへ押し出された状態である。   In a state where the inside of the measuring tank unit 91 is filled with ice-making water, the ice-making water in the measuring tank unit 91 is pushed out by the compressed air flowing from the compressed air introducing unit 91A, and the water level in the measuring tank unit 91 is lowered. Until the water level falls below the lower end 121B of the barrier 121, the water level in the barrier 121 does not fall, so the float body 93 remains closed as shown in FIG. When the water level falls below the lower end 121B of the barrier 121, the float body 93 opens the supply hole 92. At that time, the float body 93 does not descend immediately but descends with a slight delay. That is, the float body 93 maintains the state in which the supply hole 92 is closed by the adhesion action of water existing between the upper surface of the float body 93 and the lower surface of the partition body 9B. When the balance between the weight of the float body 93 and the adhesion action is lost, the maintenance action disappears, and the float body 93 finally descends to open the supply hole 92. Even if a small amount flows down from the supply hole 92 by opening the supply hole 92, the specified amount of ice-making water is already pushed out from the measuring tank unit 91 to the ice tray 7B.

このように、フロート体93とその周囲の障壁121によって、圧縮空気によって計量タンク部の製氷用水を押し出す間に、主タンク部から計量タンク部へ製氷用水が流下することを低減できる。   Thus, the float body 93 and the surrounding barrier 121 can reduce the flow of ice making water from the main tank portion to the measuring tank portion while the ice making water is pushed out by the compressed air.

図19に示すように、フロート体93の下面は、障壁121の下端部121Bと同等か僅かに上位置である。これによって、上記のように、障壁121の下端121Bよりも水位が低下するまでは、障壁121内の製氷用水によってフロート体93が供給孔92を閉じた状態を安定的に維持できる。また、フロート体93が降下した状態で、フロート体93の上面と仕切り体9Bとの間に、製氷用水が流れる隙間を確保できる。   As shown in FIG. 19, the lower surface of the float body 93 is equivalent to or slightly above the lower end 121 </ b> B of the barrier 121. As a result, as described above, the state in which the float body 93 closes the supply hole 92 by the ice-making water in the barrier 121 can be stably maintained until the water level falls below the lower end 121B of the barrier 121. Further, it is possible to secure a gap through which ice making water flows between the upper surface of the float body 93 and the partition body 9B in a state where the float body 93 is lowered.

このように、障壁121を設けることによって、計量タンク部91の製氷用水が揺動しても、その影響からフロート体93を保護する。このため、計量タンク部91の水位が、所定の低水位に低下するまで、フロート体93は安定的に供給孔92を閉じる。実施形態では、障壁121の下端121Bよりも水位が低下するまでは、フロート体93が供給孔92を安定的に閉じた状態に維持できる。   Thus, by providing the barrier 121, even if the ice-making water in the measuring tank unit 91 swings, the float body 93 is protected from the influence. For this reason, the float body 93 stably closes the supply hole 92 until the water level of the measuring tank unit 91 is lowered to a predetermined low water level. In the embodiment, the float body 93 can keep the supply hole 92 stably closed until the water level is lower than the lower end 121 </ b> B of the barrier 121.

即ち、障壁121を設けることによって、計量タンク部91の製氷用水の水位が、所定の低水位に低下するまで、フロート体93は安定的に供給孔92を閉じるため、計量タンク部91の製氷用水が揺動しても、余分の製氷用水が、主タンク部90から計量タンク部91へ供給されることが防止できる。   That is, by providing the barrier 121, the float body 93 stably closes the supply hole 92 until the water level of the ice making water in the measuring tank unit 91 is lowered to a predetermined low water level. Even if the oscillates, excess water for ice making can be prevented from being supplied from the main tank unit 90 to the measuring tank unit 91.

図20に示すように、仕切り体9Bから垂下する障壁121の下端が、容器本体9Aの内底面9A1に当接する場合、障壁121の下端の一部に切欠きによって製氷用水流出部122を形成する。この場合、製氷用水流出部122は、圧縮空気導入部91A側の反対側に形成すればよい。   As shown in FIG. 20, when the lower end of the barrier 121 that hangs down from the partition 9 </ b> B comes into contact with the inner bottom surface 9 </ b> A <b> 1 of the container body 9 </ b> A, the ice making water outflow portion 122 is formed by a notch in a part of the lower end of the barrier 121. . In this case, the ice making water outflow portion 122 may be formed on the side opposite to the compressed air introduction portion 91A side.

また、他の形態として、図示しないが、障壁121の全周の略半周部分121Aが、仕切り体9Bから垂下するように、仕切り体9Bと一体成形し、障壁121の全周の残りの略半周部分121Bが、容器本体9Aの内底面9A1から立ち上がるように、容器本体9Aと一体成形する。仕切り体9Bを容器本体9A内に挿入することによって、半周部分121Aと121Bが組み合わさり、障壁121の全周となる構成となる。この場合、121Bの部分の上端は仕切り体9Bに当接し、121Aの部分は、その下端と容器本体9Aの内底面9A1との間に、製氷用水流出部122の間隔Gを形成する。この場合、製氷用水流出部122は、圧縮空気導入部91A側の反対側に形成すればよい。   Further, as another form, although not shown in the figure, the substantially half-circular portion 121A of the entire circumference of the barrier 121 is integrally formed with the partition body 9B so as to hang down from the partition body 9B, and the remaining substantially half-circle of the entire periphery of the barrier 121 is formed. The portion 121B is integrally formed with the container body 9A so that the portion 121B rises from the inner bottom surface 9A1 of the container body 9A. By inserting the partition body 9B into the container main body 9A, the semicircular portions 121A and 121B are combined to form the entire circumference of the barrier 121. In this case, the upper end of the 121B portion abuts against the partition 9B, and the 121A portion forms a gap G of the ice making water outflow portion 122 between the lower end and the inner bottom surface 9A1 of the container main body 9A. In this case, the ice making water outflow portion 122 may be formed on the side opposite to the compressed air introduction portion 91A side.

次に、主タンク部90から計量タンク部91に製氷用水を円滑に供給する技術を説明する。
計量タンク部91に貯留する製氷用水をポンプ装置60の圧縮空気によって良好に押し出すために、計量タンク部91が、容器本体9Aの内底面9A1と仕切り体9Bとの間に形成され、一回の製氷に必要な製氷用水によって計量タンク部91が満杯になる構成とする。この場合、主タンク部90の製氷用水が自然流下にて、供給孔92を通ってフロート体93を押し下げ、計量タンク部91へ流入する際、計量タンク部91内の空気が良好に押し退けられなければ、計量タンク部91を満杯にできない。
Next, a technique for smoothly supplying ice-making water from the main tank unit 90 to the measuring tank unit 91 will be described.
In order to push out the ice-making water stored in the measuring tank unit 91 with the compressed air of the pump device 60, the measuring tank unit 91 is formed between the inner bottom surface 9A1 of the container body 9A and the partition body 9B, and The measuring tank unit 91 is filled with ice-making water necessary for ice making. In this case, when the ice-making water in the main tank 90 is naturally flowing down, the float body 93 is pushed down through the supply hole 92 and flows into the measuring tank 91, so that the air in the measuring tank 91 should be pushed away well. In this case, the measuring tank unit 91 cannot be filled.

これを解決するために、計量タンク部91内の空気を圧縮空気導入部91Aへ逃がす空気排出溝125を、計量タンク部91内の上面に形成している。
図21は本発明に係る貯水容器の計量タンク部内の空気排出溝部分を説明するための仕切り体の前後方向の縦断側面図である。図22は本発明に係る貯水容器の計量タンク部内の空気排出溝部分を説明するための仕切り体の左右方向の縦断側面図である。
In order to solve this problem, an air discharge groove 125 through which the air in the measurement tank unit 91 is released to the compressed air introduction unit 91 </ b> A is formed on the upper surface in the measurement tank unit 91.
FIG. 21 is a longitudinal side view of the partition body in the front-rear direction for explaining the air discharge groove portion in the measuring tank portion of the water storage container according to the present invention. FIG. 22 is a vertical side view of the partition body in the left-right direction for explaining the air discharge groove portion in the measuring tank portion of the water storage container according to the present invention.

図7、図10、図13〜図15、図17(A)、図21、及び図22に示すように、計量タンク部91の上壁は仕切り体9Bであるため、仕切り体9Bの下側面を上方へ膨らませて形成した空気排出溝125が、圧縮空気導入部91Aへ連通する状態である。空気排出溝125の位置は、供給孔92から離れた位置とすべく、圧縮空気導入部91Aと製氷用水導出部91Bが配置される計量タンク部91の側辺に沿った配置であり、出口パイプ99Pの外面から圧縮空気導入パイプ97の中心部へ至る直線状に形成される。   As shown in FIGS. 7, 10, 13 to 15, 17 (A), 21, and 22, the upper wall of the measuring tank unit 91 is the partition 9 </ b> B, and therefore the lower surface of the partition 9 </ b> B. Is a state in which the air discharge groove 125 formed by inflating is communicated with the compressed air introduction portion 91A. The position of the air discharge groove 125 is arranged along the side of the measuring tank 91 where the compressed air introduction part 91A and the ice making water outlet part 91B are arranged so as to be located away from the supply hole 92. It is formed in a straight line extending from the outer surface of 99P to the center of the compressed air introduction pipe 97.

図示のように、空気排出溝125は、圧縮空気導入部91Aの中心部へ向けて徐々に上方に深くなる傾斜溝である。更に圧縮空気導入部91Aへ向かう空気の流れを良好にするために、空気排出溝125の溝幅は、圧縮空気導入部91Aから遠い出口パイプ99P側よりも圧縮空気導入部91A側が広い。好ましい溝幅は、圧縮空気導入部91Aへ向けて徐々に拡がる形状である。図示する実施例の空気排出溝125の形状は、圧縮空気導入部91Aへ向けて徐々に上方に深くなるように傾斜し、溝幅は、圧縮空気導入部91Aへ向けて徐々に拡がる形状である。   As illustrated, the air discharge groove 125 is an inclined groove that gradually deepens upward toward the center of the compressed air introduction portion 91A. Further, in order to improve the flow of air toward the compressed air introduction portion 91A, the groove width of the air discharge groove 125 is wider on the compressed air introduction portion 91A side than the outlet pipe 99P side far from the compressed air introduction portion 91A. A preferable groove width is a shape that gradually expands toward the compressed air introduction portion 91A. The shape of the air discharge groove 125 in the illustrated embodiment is a shape that gradually inclines toward the compressed air introduction portion 91A and gradually widens toward the compressed air introduction portion 91A. .

上記のように、製氷用水導出部91Bは、計量タンク部91の内底面に近接した位置に連通するように出口パイプ99Pが開口し、製氷用水導出部91Bからかなり離れた上方位置に、空気排出溝125が配設される。このため、主タンク部90の製氷用水が自然流下にて計量タンク部91へ流入することに伴って、計量タンク部91内の空気は、空気排出溝125にて圧縮空気導入部91Aから圧縮空気導入パイプ97へ排出され、後述の防塵フィルタ63Dから排出される。   As described above, the ice making water outlet 91B opens the outlet pipe 99P so as to communicate with a position close to the inner bottom surface of the measuring tank 91, and discharges air to an upper position considerably away from the ice making water outlet 91B. A groove 125 is provided. For this reason, as the ice-making water in the main tank 90 flows into the metering tank 91 under a natural flow, the air in the metering tank 91 is compressed from the compressed air introduction part 91A through the air discharge groove 125. It is discharged to the introduction pipe 97 and discharged from a dust filter 63D described later.

この構成によって、主タンク部90の製氷用水が自然流下にて計量タンク部91へ良好に流れ、計量タンク部91が満杯になることに伴って、フロート体93は計量タンク部91の製氷用水によって押し上げられ、フロート体93の上面が供給孔92の周縁に当接して供給孔92を閉じ、主タンク部90から計量タンク部91内への製氷用水の流入がストップする。   With this configuration, the ice making water in the main tank unit 90 flows well to the measuring tank unit 91 under natural flow, and as the measuring tank unit 91 becomes full, the float body 93 is caused by the ice making water in the measuring tank unit 91. The float body 93 is pushed up, the upper surface of the float body 93 comes into contact with the periphery of the supply hole 92 and closes the supply hole 92, and the flow of ice-making water from the main tank unit 90 into the measuring tank unit 91 is stopped.

特に、計量タンク部91に貯留された製氷用水をポンプ装置60の圧縮空気によって押し出す作用が良好に行えるようにするために、一回の製氷に必要な製氷用水によって計量タンク部91が満杯になる構成とする場合にも、この計量タンク部91内の上部に残る空気は、空気排出溝125から圧縮空気導入部91Aへ向けて良好に押し出されるため、計量タンク部91には、一回の製氷に必要な量の製氷用水で満杯状態とすることができる。   In particular, the measuring tank unit 91 is filled with ice-making water necessary for one ice-making in order to allow the ice-making water stored in the measuring tank unit 91 to be pushed out by the compressed air of the pump device 60. Even in the case of the configuration, the air remaining in the upper part in the measuring tank unit 91 is favorably pushed out from the air discharge groove 125 toward the compressed air introducing unit 91A. It can be filled with the necessary amount of ice making water.

なお、図22に示すように、空気排出溝125は、圧縮空気導入部91Aの中心部へ向かう線上において、全長に亘って、中央部を更に上方へ膨出する膨出溝125Aが形成される。膨出溝125Aは、圧縮空気導入部91Aに連通して形成される。   As shown in FIG. 22, the air discharge groove 125 is formed with a bulge groove 125 </ b> A that bulges the center portion further upward over the entire length on the line toward the center portion of the compressed air introduction portion 91 </ b> A. . The bulging groove 125A is formed in communication with the compressed air introduction portion 91A.

空気排出溝125は、圧縮空気導入部91Aに向かうにつれて徐々に上方に傾斜しつつ溝幅も拡開して形成されるので、膨出溝125Aも圧縮空気導入部91Aに向かうにつれて徐々に上方に深く傾斜しつつ溝幅も拡開して形成される。   The air discharge groove 125 is formed so as to be gradually inclined upward while moving toward the compressed air introduction portion 91A, and the groove width is also widened. Therefore, the bulging groove 125A is also gradually raised upward toward the compressed air introduction portion 91A. The groove width is widened while being deeply inclined.

このため、主タンク部90の製氷用水が自然流下にて計量タンク部91へ流入する際に、計量タンク部91内の空気は、空気排出溝125に効率的に集約される。空気排出溝125は膨出溝125Aを有するので、空気排出溝125に集約された計量タンク部91内の空気は、膨出溝125Aに集約され、膨出溝125Aの最も上方位置である圧縮空気導入部91A側に導かれる。   For this reason, when the ice making water in the main tank unit 90 flows into the measuring tank unit 91 under natural flow, the air in the measuring tank unit 91 is efficiently concentrated in the air discharge groove 125. Since the air discharge groove 125 has the bulging groove 125A, the air in the measuring tank portion 91 concentrated in the air discharge groove 125 is concentrated in the bulging groove 125A, and the compressed air that is the uppermost position of the bulging groove 125A. Guided to the introduction portion 91A side.

次に、計量タンク部91の周縁部のシール構成について説明する。
図23は本発明に係る貯水容器の計量タンク部の前部のパッキン保持部を説明する拡大断面図である。図24は本発明に係る貯水容器の計量タンク部の後部のパッキン保持部を説明する拡大断面図である。図25は本発明に係る貯水容器の計量タンク部の左側部のパッキン保持部を説明する拡大断面図である。図26は本発明に係る貯水容器の計量タンク部の右側部のパッキン保持部を説明する拡大断面図である。図27は本発明に係る計量タンク部周縁の環状パッキンの拡大断面図である。図28は本発明に係る容器本体内へ取り付けた環状パッキンの上へ仕切り体を挿入する状態の説明用拡大断面図である。図29は本発明に係る容器本体内で仕切り体が環状パッキンを押圧した状態を説明する拡大断面図である。
Next, the seal configuration of the peripheral part of the measuring tank unit 91 will be described.
FIG. 23 is an enlarged cross-sectional view for explaining the packing holding portion at the front of the measuring tank portion of the water storage container according to the present invention. FIG. 24 is an enlarged cross-sectional view for explaining a packing holding portion at the rear of the measuring tank portion of the water storage container according to the present invention. FIG. 25 is an enlarged cross-sectional view for explaining the packing holding portion on the left side of the measuring tank portion of the water storage container according to the present invention. FIG. 26 is an enlarged cross-sectional view for explaining the packing holding portion on the right side of the measuring tank portion of the water storage container according to the present invention. FIG. 27 is an enlarged cross-sectional view of the annular packing at the periphery of the measuring tank according to the present invention. FIG. 28 is an enlarged cross-sectional view for explaining a state in which the partition body is inserted onto the annular packing attached to the container body according to the present invention. FIG. 29 is an enlarged cross-sectional view illustrating a state in which the partition member presses the annular packing in the container main body according to the present invention.

図示のように、主タンク部90と計量タンク部91とを確実に区画するために、容器本体9Aの内底面9A1と仕切り体9Bとの間に、計量タンク部91の周囲を巡る環状パッキン117を設ける。環状パッキン117は、計量タンク部91の外形を形成する形状であり、計量タンク部91の形態に応じた形態をなす。   As shown in the figure, in order to reliably partition the main tank portion 90 and the measuring tank portion 91, an annular packing 117 surrounding the measuring tank portion 91 is provided between the inner bottom surface 9A1 of the container main body 9A and the partition body 9B. Is provided. The annular packing 117 has a shape that forms the outer shape of the measuring tank unit 91, and has a form corresponding to the form of the measuring tank unit 91.

次に、環状パッキン117による計量タンク部91のシール構成について説明する。
本発明は、貯水容器9内の各部が水洗いできるように、各部が分解し易い構成となっている。このため、計量タンク部91を形成する仕切り体9Bを着脱自在に容器本体9A内に挿入可能であり、それに伴って環状パッキン117も着脱自在である。環状パッキン117は、シール性、着脱性、耐久性等を向上させるために、柔軟性のあるシリコンゴム製である。
Next, the sealing configuration of the measuring tank unit 91 by the annular packing 117 will be described.
In the present invention, each part is easily disassembled so that each part in the water storage container 9 can be washed with water. For this reason, the partition body 9B forming the measuring tank portion 91 can be detachably inserted into the container main body 9A, and the annular packing 117 is also detachable accordingly. The annular packing 117 is made of flexible silicone rubber in order to improve sealing performance, detachability, durability, and the like.

柔軟性のある環状パッキン117によって、主タンク部90と計量タンク部91とが区画されるようにするためには、通常、仕切り体9Bの周縁部へ環状パッキン117を取り付けた状態で、仕切り体9Bを容器本体9A内へ挿入する方式が採られる。この方式では、仕切り体9Bの周縁部には環状パッキン117を保持するために、取り付け溝や取り付けフランジを形成し、その部分へ環状パッキン117を嵌め込むようにして取り付ける。この取り付けの場合、柔軟性のある環状パッキン117は、取り付け操作中に伸張し、その伸長によって余分の部分が生じる。その場合は、環状パッキン117を取り外して再度取り付け操作を行うこととなり、環状パッキン117の取り付け操作を完成させるためには面倒なことである。   In order to divide the main tank portion 90 and the measuring tank portion 91 by the flexible annular packing 117, the partition body is usually attached with the annular packing 117 attached to the peripheral edge of the partition body 9B. A method of inserting 9B into the container main body 9A is adopted. In this system, in order to hold the annular packing 117 on the peripheral portion of the partition body 9B, an attachment groove and an attachment flange are formed, and the annular packing 117 is fitted into that portion. In this attachment, the flexible annular packing 117 is stretched during the attachment operation, which causes an extra part. In that case, the annular packing 117 is removed and the attaching operation is performed again, which is troublesome for completing the attaching operation of the annular packing 117.

また、仕切り体9Bの周縁部に環状パッキン117を正常な状態に取り付けた場合でも、上記のように、容器本体9Aの後壁と左右壁によって囲まれた、上面視で前後方向に長い矩形状の領域に計量タンク部91を形成する場合には、仕切り体9Bを容器本体9Aの後領域の所定位置へ挿入する際、環状パッキン117が容器本体9Aの後壁及び左右壁との摩擦によって、仕切り体9Bを所定位置へ挿入し難く、また、環状パッキン117が容器本体9Aの後壁及び左右壁との摩擦によって、仕切り体9Bから外れることが生じる。   Further, even when the annular packing 117 is attached to the peripheral edge of the partition 9B in a normal state, as described above, it is surrounded by the rear wall and the left and right walls of the container body 9A, and has a rectangular shape that is long in the front-rear direction when viewed from above. When the measuring tank portion 91 is formed in this area, when the partition 9B is inserted into a predetermined position in the rear area of the container body 9A, the annular packing 117 is caused by friction with the rear wall and the left and right walls of the container body 9A. It is difficult to insert the partition body 9B into a predetermined position, and the annular packing 117 is detached from the partition body 9B due to friction with the rear wall and the left and right walls of the container body 9A.

本発明は、このような点に鑑み、柔軟性のあるシリコンゴム製の環状パッキン117を採用する場合でも、正規の状態に取り付けが簡単にでき、正規のシール状態が確保できる構成を提供する。このため、仕切り体9Bを容器本体9Aの後領域の所定位置へ挿入する前に、環状パッキン117を容器本体9Aの後領域の所定位置へ取り付けるためのパッキン保持部90Pを容器本体9A内に環状に形成し、パッキン保持部90Pへの環状パッキン117の取り付け後に、仕切り体9Bを容器本体9Aの後領域の所定位置へ挿入する方式とする。   In view of such a point, the present invention provides a configuration that can be easily attached in a normal state and can ensure a normal seal state even when a flexible silicon rubber annular packing 117 is employed. Therefore, before inserting the partition 9B into a predetermined position in the rear region of the container main body 9A, a packing holding portion 90P for attaching the annular packing 117 to a predetermined position in the rear region of the container main body 9A is annularly formed in the container main body 9A. The partition body 9B is inserted into a predetermined position in the rear region of the container body 9A after the annular packing 117 is attached to the packing holding portion 90P.

その方式に適合する構成を以下に記載する。
図10、図12等に示すように、計量タンク部91は、上面視で、四辺形状の一つである前後方向に長い矩形状をなし、四隅のコーナ部K1〜K4は円弧をなす。これは、容器本体9Aの形状に合わせた形状であり、容器本体9Aの後壁と左右壁とに囲まれた容器本体9Aの後半部領域の略全体に亘って、上面視で前後方向に長い矩形状の計量タンク部91の領域を形成する。図7乃至図9に示すように、この計量タンク部91の領域は、容器本体9Aの後半部領域の底壁を窪ませることによって、その窪みの前後左右を巡る区画壁90Kによって形成される。
A configuration that conforms to the method is described below.
As shown in FIG. 10, FIG. 12, etc., the measuring tank portion 91 has a rectangular shape that is long in the front-rear direction, which is one of the four sides, when viewed from above, and the corner portions K1 to K4 at the four corners form an arc. This is a shape that matches the shape of the container body 9A, and is long in the front-rear direction in the top view over substantially the entire rear half region of the container body 9A surrounded by the rear wall and the left and right walls of the container body 9A. An area of the rectangular measuring tank portion 91 is formed. As shown in FIGS. 7 to 9, the area of the measuring tank portion 91 is formed by a partition wall 90 </ b> K that goes around the front, rear, left and right of the recess by recessing the bottom wall of the rear half region of the container body 9 </ b> A.

上記のように、計量タンク部91は、容器本体9Aの形状に合わせて、上面視で前後方向に長い矩形状をなしており、容器本体9A内を有効利用して計量タンク部91を形成するために、計量タンク部91の前部では、区画壁90Kは容器本体9Aの前記窪みの前壁で形成される。また、計量タンク部91の後部では、区画壁90Kは容器本体9Aの後壁90Bの下部が兼用し、計量タンク部91の左側部では、区画壁90Kは容器本体9Aの左側壁90Rの下部が兼用し、計量タンク部91の右側部では、区画壁90Kは容器本体9Aの右側壁90Lの下部が兼用する構成である。   As described above, the measuring tank unit 91 has a rectangular shape that is long in the front-rear direction when viewed from above according to the shape of the container main body 9A, and the measuring tank unit 91 is formed by effectively using the inside of the container main body 9A. Therefore, in the front part of the measuring tank part 91, the partition wall 90K is formed by the front wall of the said hollow of the container main body 9A. Further, in the rear part of the measuring tank unit 91, the partition wall 90K is also used as the lower part of the rear wall 90B of the container body 9A, and in the left part of the measuring tank unit 91, the partition wall 90K is connected to the lower part of the left wall 90R of the container body 9A. In addition, in the right side portion of the measuring tank portion 91, the partition wall 90K is configured to be shared by the lower portion of the right side wall 90L of the container body 9A.

環状パッキン117は、図7、図8、図9、図27〜図29に示すように、外側環状リブ117R1と内側環状リブ117R2との間に下方に開口した取り付け溝117Dと、上部に外方へ延びるヒレ部117Tと、ヒレ部117Tの根本部に下方に低い段差となるように窪みで形成した肩部117Qを形成する。仕切り体9Bは、環状パッキン117の上面を押圧するように、ヒレ部117Tを押圧するために下面周縁部に形成した押圧フランジ9BFと、その内側に環状の支え突起9BTを形成している。   As shown in FIGS. 7, 8, 9, and 27 to 29, the annular packing 117 includes a mounting groove 117D that opens downward between the outer annular rib 117R1 and the inner annular rib 117R2, and an outwardly outward portion. A fin portion 117T extending to the bottom and a shoulder portion 117Q formed of a depression so as to form a lower step at the bottom of the fin portion 117T are formed. The partition body 9B is formed with a pressing flange 9BF formed on the peripheral edge of the lower surface so as to press the fin portion 117T so as to press the upper surface of the annular packing 117, and an annular support protrusion 9BT inside thereof.

図7、図8、図9、図23〜図26、図28、図29に示すように、容器本体9A内の底部に上記のように形成される前後左右の区画壁90Kに沿って、環状パッキン117を着脱自在に保持するパッキン保持部90Pを形成する。このパッキン保持部90Pは、計量タンク部91の周囲に巡る上方に開口した環状溝90P2を形成する。環状溝90P2は、計量タンク部91を囲むように巡る区画壁90Kと、その内側に並行に上面視で前後方向に長い矩形状で上方に立ち上がる環状突起90P1との間に形成する。更に、環状突起90P1の内側に沿って環状の当接部90P3を形成する。これによって、環状溝90P2は外壁が区画壁90Kであり、内壁が環状突起90P1であり、これらの間に上方に開口する溝として形成される。   As shown in FIGS. 7, 8, 9, 23 to 26, 28, and 29, an annular shape is formed along the front and rear, left and right partition walls 90 </ b> K formed as described above at the bottom of the container body 9 </ b> A. A packing holding portion 90P for holding the packing 117 in a detachable manner is formed. The packing holding portion 90P forms an annular groove 90P2 that opens upward around the circumference of the measuring tank portion 91. The annular groove 90P2 is formed between a partition wall 90K that surrounds the measuring tank portion 91 and an annular protrusion 90P1 that rises upward in a rectangular shape that is long in the front-rear direction in parallel when viewed from above. Further, an annular contact portion 90P3 is formed along the inner side of the annular protrusion 90P1. As a result, the annular groove 90P2 is formed as a groove having an outer wall that is a partition wall 90K and an inner wall that is an annular protrusion 90P1 that opens upward between them.

この構成によって、図7、図8、図9、図28、図29に示すように、環状パッキン117は、容器本体9Aの上面開口から挿入され、環状突起90P1に取り付け溝117Dが嵌る関係によって、外側環状リブ117R1が環状溝90P2に嵌り、内側環状リブ117R2が環状突起90P1の内側に位置する当接部90P3に当接する関係に、パッキン保持部90Pに装着する。この装着によって、環状突起90P1の内側面に形成した係止突起90P11が、取り付け溝117Dに形成した係止溝117D1に嵌り、パッキン保持部90Pからの環状パッキン117の抜け止めとなる。   With this configuration, as shown in FIGS. 7, 8, 9, 28, and 29, the annular packing 117 is inserted from the upper surface opening of the container body 9 </ b> A, and the attachment groove 117 </ b> D is fitted into the annular protrusion 90 </ b> P <b> 1. The outer annular rib 117R1 is fitted into the annular groove 90P2, and the inner annular rib 117R2 is attached to the packing holding portion 90P in such a relationship that it abuts against the abutting portion 90P3 located inside the annular protrusion 90P1. By this mounting, the locking protrusion 90P11 formed on the inner surface of the annular protrusion 90P1 fits into the locking groove 117D1 formed in the attachment groove 117D, and the annular packing 117 is prevented from coming off from the packing holding portion 90P.

この状態で、容器本体9Aの上面開口から仕切り体9Bを、容器本体9Aの後壁と左右壁に沿って、前後左右を巡る区画壁90Kによって囲まれる容器本体9A内の後半部領域に挿入し、仕切り体9Bの下面周縁部の押圧フランジ9BFが環状パッキン117の上面ヒレ部117Tに当接する状態まで押し下げる。この状態で、仕切り体9Bが環状パッキン117上に支持され、環状パッキン117で囲まれた矩形状の領域が、計量タンク部91の領域となる。   In this state, the partition body 9B is inserted from the upper surface opening of the container main body 9A into the rear half region in the container main body 9A surrounded by the partition wall 90K around the front, rear, left and right along the rear wall and the left and right walls of the container main body 9A. Then, the pressing flange 9BF at the peripheral edge of the lower surface of the partition member 9B is pushed down until it comes into contact with the upper fin portion 117T of the annular packing 117. In this state, the partition 9 </ b> B is supported on the annular packing 117, and the rectangular area surrounded by the annular packing 117 is the area of the measuring tank unit 91.

このように環状パッキン117をパッキン保持部90Pに装着し、容器本体9A内に仕切り体9Bを挿入し環状パッキン117上に載置した状態で、後述のように、容器本体9Aに蓋体9Cを被せ、フック装置101によって容器本体9Aと蓋体9Cとを結合する。この結合により、蓋体9Cが仕切り体9Bを押圧し、それに伴って、仕切り体9Bの支え突起9BTが環状パッキン117の肩部117Qに当接し、環状パッキン117が計量タンク部91側である内方へ倒れ込むことを防止しつつ、仕切り体9Bの下面周縁部の押圧フランジ9BFがヒレ部117Tを押圧する。押圧フランジ9BFの先端部は、斜め下方へ屈曲しており、これによってヒレ部117Tの先端部は、押されて弾性変形し下方へ屈曲する。   In this manner, the annular packing 117 is mounted on the packing holding portion 90P, and the partition body 9B is inserted into the container main body 9A and placed on the annular packing 117. As described later, the lid body 9C is attached to the container main body 9A. The container body 9A and the lid body 9C are coupled by the hook device 101. By this connection, the lid body 9C presses the partition body 9B, and accordingly, the support protrusion 9BT of the partition body 9B abuts on the shoulder portion 117Q of the annular packing 117, and the annular packing 117 is on the measuring tank portion 91 side. The pressing flange 9BF at the peripheral edge of the lower surface of the partition member 9B presses the fin portion 117T while preventing it from falling down. The front end portion of the pressing flange 9BF is bent obliquely downward, whereby the front end portion of the fin portion 117T is pushed and elastically deformed and bent downward.

これにより、環状パッキン117が複数個所のシール部を形成するが、主としたシール箇所として、図29に示すように、環状パッキン117は、ヒレ部117Tが屈曲して外側環状リブ117R1の上部に当接すると共に、ヒレ部117Tの外側先端が環状溝90P2の上部で区画壁90Kに密着(これをシール部1という)し、環状突起90P1と取り付け溝117Dとが密着(これをシール部2という)し、外側環状リブ117R1が環状溝90P2の底部に密着(これをシール部3という)し、内側環状リブ117R2が当接部90P3に密着(これをシール部4という)し、環状パッキン117がパッキン保持部90Pに圧縮された状態に保持される。このように、環状パッキン117は、仕切り体9Bの支え突起9BTによって内方への倒れ込みが防止され、且つ、主として、シール部1〜4の4箇所によって4重シールがなされ、環状パッキン117で囲まれた領域に、主タンク部90と水密且つ気密状態に区画された計量タンク部91が形成される。   As a result, the annular packing 117 forms a plurality of seal portions. As shown in FIG. 29, the annular packing 117 is bent at the upper portion of the outer annular rib 117R1 as the fin portion 117T is bent. At the same time, the outer tip of the fin portion 117T is in close contact with the partition wall 90K at the upper portion of the annular groove 90P2 (this is referred to as the seal portion 1), and the annular protrusion 90P1 and the attachment groove 117D are in close contact (this is referred to as the seal portion 2). The outer annular rib 117R1 is in close contact with the bottom of the annular groove 90P2 (this is referred to as the seal portion 3), the inner annular rib 117R2 is in close contact with the contact portion 90P3 (this is referred to as the seal portion 4), and the annular packing 117 is sealed. The compressed state is held in the holding unit 90P. As described above, the annular packing 117 is prevented from falling inward by the support protrusions 9BT of the partition 9B, and is quadruple sealed mainly by the four portions of the seal portions 1 to 4, and is surrounded by the annular packing 117. In this area, the main tank part 90 and the measuring tank part 91 partitioned into a watertight and airtight state are formed.

更に、パッキン保持部90Pは、環状突起90P1と間隔を存して当接部90P3の内方に、内側環状リブ117R2の下部内側を保持する保持突起90P4を備えている。このため、上記のように仕切り体9Bの押圧により、環状パッキン117が押圧されるとき、図29に示しように、環状パッキン117の内側環状リブ117R2の下部が保持突起90P4により保持され、環状パッキン117の下部が内側へずれ込むことが防止でき、柔軟性のある環状パッキン117を正規位置に保持でき、計量タンク部91の周囲のシールが十分となり、計量タンク部91の周囲が、主タンク部90と水密且つ気密状態に区画された領域とすることができる。   Further, the packing holding portion 90P includes a holding projection 90P4 that holds the lower inner side of the inner annular rib 117R2 inside the contact portion 90P3 with a space from the annular projection 90P1. Therefore, when the annular packing 117 is pressed by pressing the partition 9B as described above, the lower portion of the inner annular rib 117R2 of the annular packing 117 is held by the holding projection 90P4 as shown in FIG. It is possible to prevent the lower part of 117 from slipping inward, the flexible annular packing 117 can be held in a normal position, a seal around the measuring tank part 91 is sufficient, and the periphery of the measuring tank part 91 is the main tank part 90. And a water-tight and air-tight area.

上記のように、環状パッキン117を正規位置に保持でき、計量タンク部91の周囲のシールが十分となるため、計量タンク部91の製氷用水の押し出しを空気ポンプ61の圧縮空気により押し出す構造に適するものとなる。   As described above, the annular packing 117 can be held at the normal position, and the seal around the measuring tank unit 91 is sufficient. Therefore, the structure is suitable for a structure in which the water for making ice in the measuring tank unit 91 is pushed out by the compressed air of the air pump 61. It will be a thing.

次に、容器本体9A内への仕切り体9Bの組み立てを説明する。
貯水容器9の組み立てに際して、圧縮空気導入パイプ97の上端開口部に環状パッキン116を装着し、製氷用水誘導パイプ98の下端部周縁に環状パッキン115を装着する。また、上記のように、環状パッキン117を容器本体9A内の計量タンク部91の周縁部を巡るように、パッキン保持部90Pに装着する。
Next, the assembly of the partition body 9B into the container body 9A will be described.
When assembling the water storage container 9, the annular packing 116 is attached to the upper end opening of the compressed air introduction pipe 97, and the annular packing 115 is attached to the periphery of the lower end of the ice making water induction pipe 98. Further, as described above, the annular packing 117 is attached to the packing holding portion 90P so as to go around the peripheral portion of the measuring tank portion 91 in the container main body 9A.

供給孔92にフロート体93を保持した仕切り体9Bを、容器本体9Aの上面開口から容器本体9A内の挿入し、パッキン保持部90Pに装着された環状パッキン117上に載置する。これによって、開渠部100Aの先端部に開渠部100Bの先端部が載る状態にて両者が連結され、連続した開渠状の連通路100が形成される。その状態で容器本体9Aの上面開口を塞ぐように容器本体9Aに蓋体9Cを被せ、フック装置101によって、容器本体9Aと蓋体9Cとを結合する。   The partition body 9B holding the float body 93 in the supply hole 92 is inserted into the container main body 9A from the upper surface opening of the container main body 9A and placed on the annular packing 117 mounted on the packing holding portion 90P. Thereby, both are connected in a state where the tip of the opening part 100B is placed on the tip of the opening part 100A, and a continuous opening-shaped communication path 100 is formed. In this state, the container body 9A is covered with a lid body 9C so as to close the upper surface opening of the container body 9A, and the container body 9A and the lid body 9C are coupled by the hook device 101.

これによって、開渠状の連通路100が蓋体9Cによって覆われると共に、蓋体9Cによって仕切り体9Bが、容器本体9Aの内底面9A1へ向けて押される。これによって、環状パッキン117が、仕切り体9Bとパッキン保持部90Pによって圧縮され、容器本体9Aの内底面と仕切り体9Bとの間に、主タンク部90と確実に区画される状態で計量タンク部91が形成される。   Thus, the open communication path 100 is covered with the lid body 9C, and the partition body 9B is pushed toward the inner bottom surface 9A1 of the container main body 9A by the lid body 9C. Thereby, the annular packing 117 is compressed by the partition body 9B and the packing holding portion 90P, and the measuring tank portion is reliably partitioned from the main tank portion 90 between the inner bottom surface of the container body 9A and the partition body 9B. 91 is formed.

このように、蓋体9Cによって仕切り体9Bが容器本体9Aの内底面9A1へ向けて押圧される。この仕切り体9Bの押圧は、圧縮空気導入パイプ97と圧縮空気誘導パイプ96とが環状パッキン116を介して連結される箇所Pと、蓋体9Cによって連通路100の上面開口が塞がれる箇所Qとによって形成されるが、仕切り体9Bの押圧が平均化するように、仕切り体9Bに立設した支柱部103を設ける。これによって、前記箇所P、前記箇所Q、及びこの支柱部103が三角地点配置となることによって、蓋体9Cによる仕切り体9Bの押圧が平均化し、環状パッキン117が略均等に圧縮され、主タンク部90の直下に、仕切り体9Bと容器本体9Aの内底面9A1との間に、水密且つ気密状態に環状パッキン117で囲まれた計量タンク部91が形成される。   In this way, the partition body 9B is pressed toward the inner bottom surface 9A1 of the container main body 9A by the lid body 9C. The partition 9B is pressed by a place P where the compressed air introduction pipe 97 and the compressed air guide pipe 96 are connected via the annular packing 116, and a place Q where the upper surface opening of the communication passage 100 is blocked by the lid 9C. However, the column portion 103 is provided upright on the partition body 9B so that the pressure on the partition body 9B is averaged. Thereby, the location P, the location Q, and the support pillar portion 103 are arranged in a triangular location, so that the pressing of the partition 9B by the lid 9C is averaged, and the annular packing 117 is compressed substantially evenly. A measuring tank portion 91 surrounded by an annular packing 117 is formed between the partition 9B and the inner bottom surface 9A1 of the container main body 9A in a watertight and airtight state immediately below the portion 90.

このように、蓋体9Cによって仕切り体9Bが保持されるため、仕切り体9Bを容器本体9Aに取り付けるネジ等の固定装置が不要である。このため、蓋体9Cを外せば容器本体9Aから仕切り体9Bを引き上げれば、環状パッキン117も外せるため、蓋体9C、容器本体9A、仕切り体9B、環状パッキン117の洗浄がし易い。また、仕切り体9Bの取り外しによって主タンク部90、計量タンク部91、フロート体93と障壁121の洗浄を容易に行える。更に、製氷用水吐出路95や空気流入部94の洗浄も容易に行えることとなる。   Thus, since the partition body 9B is held by the lid body 9C, a fixing device such as a screw for attaching the partition body 9B to the container main body 9A is unnecessary. For this reason, if the lid body 9C is removed and the partition body 9B is pulled up from the container body 9A, the annular packing 117 can also be removed. Therefore, the lid body 9C, the container body 9A, the partition body 9B, and the annular packing 117 can be easily cleaned. Moreover, the main tank part 90, the measurement tank part 91, the float body 93, and the barrier 121 can be easily cleaned by removing the partition 9B. Furthermore, the ice-making water discharge passage 95 and the air inflow portion 94 can be easily cleaned.

次に、蓋体9Cを容器本体9Aへ取り付ける機構について説明する。
図6、図7、図10に示すように、容器本体9Aと蓋体9Cの左右及び後部に設けたフック装置101によって、容器本体9Aと蓋体9Cとを結合する。また、フック装置101の解除によって、容器本体9Aから蓋体9Cを取り外すことができる。フック装置101は、蓋体9Cに回動作自在に設けたレバー101Aの裏側係止部101Bが、容器本体9Aの係止部101Cに弾性係止することにより、容器本体9Aと蓋体9Cとが結合される。このようなフック装置101は周知の構成である。
Next, a mechanism for attaching the lid 9C to the container body 9A will be described.
As shown in FIGS. 6, 7, and 10, the container body 9 </ b> A and the lid body 9 </ b> C are coupled by the hook devices 101 provided on the left and right sides and the rear part of the container body 9 </ b> A and the lid body 9 </ b> C. Further, the lid body 9C can be removed from the container main body 9A by releasing the hook device 101. In the hook device 101, the container main body 9A and the lid body 9C are connected to each other by the back side latching portion 101B of the lever 101A provided on the lid body 9C so as to be freely turnable and elastically latching to the latching portion 101C of the container main body 9A. Combined. Such a hook device 101 has a known configuration.

次に、容器本体9Aと蓋体9Cとの水シール構造について説明する。
図30は本発明に係る貯水容器の容器本体へ蓋体を嵌合する状態を説明する拡大断面図である。図31は本発明に係る貯水容器の容器本体と蓋体との前部におけるシール状態を説明する拡大断面図である。図32は本発明に係る貯水容器の容器本体と蓋体との左側部、右側部及び後側部のシール状態を説明する拡大断面図である。図33は本発明に係る貯水容器の容器本体と蓋体との他のシール形態を示す拡大断面図である。
Next, a water seal structure between the container main body 9A and the lid body 9C will be described.
FIG. 30 is an enlarged cross-sectional view illustrating a state in which the lid is fitted to the container body of the water storage container according to the present invention. FIG. 31 is an enlarged cross-sectional view illustrating a sealed state at the front part of the container body and the lid of the water storage container according to the present invention. FIG. 32 is an enlarged cross-sectional view illustrating the sealed state of the left side, right side, and rear side of the container body and the lid of the water storage container according to the present invention. FIG. 33 is an enlarged cross-sectional view showing another seal form of the container body and the lid of the water storage container according to the present invention.

貯水容器9を貯水容器収容部46へ設置する場合等において、貯水容器9内に注水した製氷用水が漏れないようにすることが必要である。このために、環状パッキンを設けずに、容器本体9Aと蓋体9Cとの嵌合部がシール構成となっている。以下、このシール構成について記載する。   For example, when the water storage container 9 is installed in the water storage container housing 46, it is necessary to prevent the ice making water injected into the water storage container 9 from leaking. For this reason, the fitting part of the container main body 9A and the lid body 9C has a sealing configuration without providing the annular packing. Hereinafter, this seal configuration will be described.

本発明に係るシール部は、図30〜図33に示すように、容器本体9Aの上面開口周縁部と蓋体9Cの下面周縁部のうち、いずれか一方に係合溝111を形成し、他方に係合溝111に侵入する屈曲可能な係合突起110を設け、係合溝111を構成する壁の上端には係合溝111内へ向かう傾斜面112を備え、係合突起110は、容器本体9Aへの蓋体9Cの取り付け時に、屈曲しつつ傾斜面112を滑り係合溝111内へ進入する関係である。これによって、容器本体9Aの上面開口周縁部と蓋体9Cとは、水密状態に保たれる。   As shown in FIGS. 30 to 33, the seal portion according to the present invention has an engagement groove 111 formed on one of the upper surface opening peripheral portion of the container body 9 </ b> A and the lower surface peripheral portion of the lid body 9 </ b> C, and the other A bendable engaging protrusion 110 that enters the engaging groove 111 is provided at the upper end of the wall, and an inclined surface 112 that goes into the engaging groove 111 is provided at the upper end of the wall that constitutes the engaging groove 111. When the lid 9C is attached to the main body 9A, the inclined surface 112 enters the sliding engagement groove 111 while being bent. Thereby, the upper-surface opening peripheral part of 9 A of container main bodies and the cover body 9C are maintained in a watertight state.

係合突起110のみを屈曲可能な環状に形成することは可能であるが、製作コストが嵩み実用的ではない。そのため、製作が容易で、貯水容器9の形態維持が良好で、取扱いに適すること等を考慮した実施形態として、係合溝111を容器本体9A上面開口周縁部に環状に形成し、容器本体9Aは係合溝111を含む全体形状を安定に保つために硬い合成樹脂製で比較的頑丈に作る。また、係合溝111に対応するように、係合突起110を蓋体9Cの裏側に環状に形成し、蓋体9Cは係合突起110を含む全体をABS樹脂等のような可撓性のある合成樹脂で製作する。また、係合溝111の内側壁111Aの上端には、係合溝111内へ向けて落ち込む方向の傾斜面112を形成する。図7に示すように、圧縮空気誘導パイプ96は、係合突起110よりも上位位置に蓋体9Cから後方へ向けて突出状態に蓋体9Cに一体成形する。   Although it is possible to form only the engaging protrusion 110 in a bendable ring shape, the manufacturing cost is high and it is not practical. Therefore, as an embodiment that is easy to manufacture, maintains the shape of the water storage container 9, is suitable for handling, and the like, the engagement groove 111 is formed in an annular shape at the upper peripheral edge of the upper surface of the container body 9A, and the container body 9A Is made of a hard synthetic resin and relatively sturdy in order to keep the entire shape including the engaging groove 111 stable. Further, an engagement protrusion 110 is formed in an annular shape on the back side of the lid body 9C so as to correspond to the engagement groove 111, and the entire lid body 9C including the engagement protrusion 110 is made of a flexible material such as ABS resin. Made of a certain synthetic resin. In addition, an inclined surface 112 is formed at the upper end of the inner wall 111 </ b> A of the engagement groove 111 so as to fall into the engagement groove 111. As shown in FIG. 7, the compressed air guide pipe 96 is integrally formed in the lid body 9 </ b> C so as to protrude rearward from the lid body 9 </ b> C at a position higher than the engagement protrusion 110.

容器本体9Aへ蓋体9Cを取り付ける際は、容器本体9Aの左右側部及び後部に巡る係合溝111の外側壁111Bの内側に沿って、係合突起110を配置する関係でもって、蓋体9Cを容器本体9Aへ被せる。この状態で係合突起110の先端は、係合溝111の内側壁111Aの上端に形成した係合溝111内へ向かう傾斜面112に当接する。この状態で、フック装置101のレバー101Aを操作して、裏側係止部101Bを容器本体9Aの係止部101Cに弾性係止することにより、容器本体9Aへ蓋体9Cを結合することができる。   When the lid body 9C is attached to the container body 9A, the lid body has a relationship in which the engagement protrusions 110 are arranged along the inner side of the outer wall 111B of the engagement groove 111 that extends to the left and right side portions and the rear portion of the container body 9A. 9C is placed on the container body 9A. In this state, the front end of the engagement protrusion 110 abuts on an inclined surface 112 that is formed at the upper end of the inner wall 111 </ b> A of the engagement groove 111 and extends toward the engagement groove 111. In this state, the lid body 9C can be coupled to the container body 9A by operating the lever 101A of the hook device 101 and elastically locking the back side locking part 101B to the locking part 101C of the container body 9A. .

係合溝111の幅は係合突起110の厚さよりも若干大きく設定するため、このような容器本体9Aへの蓋体9Cの結合操作によって、係合突起110の先端は傾斜面112に当接し、係合突起110が傾斜面112に沿って弾性変形し、それによって係合突起110は、係合溝111内方へ屈曲しつつ係合溝111内へ進入する。   Since the width of the engaging groove 111 is set to be slightly larger than the thickness of the engaging protrusion 110, the tip of the engaging protrusion 110 abuts on the inclined surface 112 by such a coupling operation of the lid body 9C to the container body 9A. The engagement protrusion 110 is elastically deformed along the inclined surface 112, whereby the engagement protrusion 110 enters the engagement groove 111 while being bent inward of the engagement groove 111.

係合突起110は蓋体9Cと同様に可撓性を有するため、上記屈曲に対して復元力が作用する。これによって、貯水容器9の前部分では、図31に示すように、係合突起110の先端部分が、傾斜面112の下部P1で係合溝111の内側壁111Aに当接する。また、貯水容器9の左右部分及び後部分では、図32に示すように、係合突起110の先端部分が、傾斜面112に下部P1部分で係合溝111の内側壁111Aに当接する。これらの当接によって、この部分が、容器本体9Aと蓋体9Cとの嵌合シール部となる。   Since the engaging protrusion 110 is flexible like the lid body 9C, a restoring force acts on the bending. As a result, at the front portion of the water storage container 9, as shown in FIG. 31, the tip end portion of the engagement protrusion 110 abuts against the inner wall 111 </ b> A of the engagement groove 111 at the lower portion P <b> 1 of the inclined surface 112. Further, in the left and right portions and the rear portion of the water storage container 9, as shown in FIG. 32, the tip end portion of the engagement protrusion 110 abuts the inner wall 111A of the engagement groove 111 on the inclined surface 112 at the lower portion P1. By this contact, this portion becomes a fitting seal portion between the container main body 9A and the lid body 9C.

また、容器本体9Aと蓋体9Cとの他のシール形態を図30及び図33に示す。これにおいて、上記同様に、蓋体9Cを容器本体9Aへ被せ、フック装置101のレバー101Aを操作して、裏側係止部101Bを容器本体9Aの係止部101Cに係止することにより、容器本体9Aへ蓋体9Cを結合する。この結合によって、上記同様に、係合突起110の先端は、傾斜面112に沿って弾性変形し、それによって係合突起110は、係合溝111内方へ屈曲しつつ係合溝111内へ進入する。   Further, other seal forms of the container body 9A and the lid body 9C are shown in FIGS. In this case, similarly to the above, the cover body 9C is put on the container main body 9A, the lever 101A of the hook device 101 is operated, and the back side locking portion 101B is locked to the locking portion 101C of the container main body 9A. The lid 9C is coupled to the main body 9A. As a result of this coupling, the tip of the engagement protrusion 110 is elastically deformed along the inclined surface 112 as described above, whereby the engagement protrusion 110 is bent into the engagement groove 111 and into the engagement groove 111. enter in.

係合突起110の先端部分は、傾斜面112の下部P1部分で係合溝111の内側壁111Aに当接する。また、係合突起110の先端部が傾斜面112とは反対側のP2部分で係合溝111の外側壁111Bに当接する場合もある。係合突起110と係合溝111とが当接することにより、容器本体9Aと蓋体9Cとの嵌合シール部となる。係合突起110の先端部が、P1部分及びP2部分の双方で当接する場合は、蓋体9Cと容器本体9Aとの水シール箇所が2か所となり、水シール効果が向上する。   The distal end portion of the engagement protrusion 110 abuts on the inner wall 111 </ b> A of the engagement groove 111 at the lower portion P <b> 1 of the inclined surface 112. In addition, the distal end portion of the engagement protrusion 110 may come into contact with the outer wall 111B of the engagement groove 111 at the P2 portion opposite to the inclined surface 112. When the engagement protrusion 110 and the engagement groove 111 are brought into contact with each other, a fitting seal portion between the container main body 9A and the lid body 9C is formed. When the tip of the engaging protrusion 110 abuts on both the P1 portion and the P2 portion, there are two water sealing portions between the lid body 9C and the container main body 9A, and the water sealing effect is improved.

貯水容器9の左右のフック装置101と後部のフック装置101とを外した状態で、蓋体9Cを取る外す作業がし易いようにするために、図7、図9、図31に示すように、蓋体9Cの前壁9C1と取っ手9Tの後壁9T1との間に、上方に拡がる隙間118を形成している。これによって、左右のフック装置101を外した後に、後部のフック装置101を外し、その状態で容器本体9Aに対して蓋体9Cの後部を持ち上げることによって、蓋体9Cの前壁9C1の下端、即ち係合突起110の前部分と、係合突起110の前部分との当接部を軸部として、隙間118の分だけ蓋体9Cを回動できる。このため、蓋体9Cを容器本体9Aから取り外し易くなる。   As shown in FIGS. 7, 9, and 31, in order to facilitate the work of removing the lid 9 </ b> C with the left and right hook devices 101 and the rear hook device 101 removed of the water storage container 9. A gap 118 extending upward is formed between the front wall 9C1 of the lid 9C and the rear wall 9T1 of the handle 9T. Thus, after removing the left and right hook devices 101, the rear hook device 101 is removed, and in this state, the rear portion of the lid body 9C is lifted with respect to the container body 9A, whereby the lower end of the front wall 9C1 of the lid body 9C, That is, the lid body 9 </ b> C can be rotated by the gap 118 with the contact portion between the front portion of the engagement protrusion 110 and the front portion of the engagement protrusion 110 as a shaft portion. For this reason, it becomes easy to remove the lid 9C from the container main body 9A.

次に、ポンプ装置60について説明する。
図34は本発明に係るポンプ装置の分解斜視図である。図35は本発明に係る空気ポンプユニットとガスケット63Bの関係を説明する外観斜視図である。図36は本発明に係るポンプ装置の外観斜視図である。図37は本発明に係るポンプ装置の構成を説明するための縦断側面斜視図である。図38は本発明に係るポンプ装置のガスケット63Bの後端面と本体ケースの前壁との当接状態を説明するための拡大縦断図である。図39は本発明に係る空気ポンプユニットの背面板を取り外した状態のポンプ装置の背面斜視図である。図40は本発明に係る空気ポンプユニットの背面板と防塵フィルタの関係を説明する分解斜視図である。図41は本発明に係る空気ポンプユニットの背面板の上部に防塵フィルタを取り付けた状態の背面板の斜視図である。図42は本発明に係る空気ポンプユニットの背面板の前面図である。図43は図42のA−A断面図である。図44は本発明に係るポンプ装置の右側面図である。図45は図44のB−B断面図である。
Next, the pump device 60 will be described.
FIG. 34 is an exploded perspective view of the pump device according to the present invention. FIG. 35 is an external perspective view illustrating the relationship between the air pump unit and the gasket 63B according to the present invention. FIG. 36 is an external perspective view of the pump device according to the present invention. FIG. 37 is a longitudinal side perspective view for explaining the configuration of the pump device according to the present invention. FIG. 38 is an enlarged vertical sectional view for explaining a contact state between the rear end surface of the gasket 63B of the pump device according to the present invention and the front wall of the main body case. FIG. 39 is a rear perspective view of the pump device with the rear plate of the air pump unit according to the present invention removed. FIG. 40 is an exploded perspective view for explaining the relationship between the back plate of the air pump unit according to the present invention and the dustproof filter. FIG. 41 is a perspective view of the back plate with a dust filter attached to the top of the back plate of the air pump unit according to the present invention. FIG. 42 is a front view of the back plate of the air pump unit according to the present invention. 43 is a cross-sectional view taken along the line AA of FIG. FIG. 44 is a right side view of the pump device according to the present invention. 45 is a cross-sectional view taken along the line BB of FIG.

ポンプ装置60は、貯水容器収容部46の後部、即ち貯水容器収容部46の奥部に取り付けられる。
図示のように、ポンプ装置60は、空気ポンプユニット60Uが外装ケース65で覆われた構成である。空気ポンプユニット60Uは、空気ポンプ61と、空気ポンプ61から送出される圧縮空気を導出する空気導出路を形成する空気導出パイプ63Aと、不織布の防塵フィルタ63Dとを、合成樹脂製の本体ケース62内に収容した構成である。
The pump device 60 is attached to the rear part of the water storage container housing part 46, that is, the back part of the water storage container housing part 46.
As illustrated, the pump device 60 has a configuration in which an air pump unit 60U is covered with an outer case 65. The air pump unit 60U includes an air pump 61, an air outlet pipe 63A that forms an air outlet path for extracting compressed air delivered from the air pump 61, and a non-woven dustproof filter 63D, and a main body case 62 made of synthetic resin. It is the structure accommodated in the inside.

空気ポンプ61へ取り入れる空気の防塵のために、空気ポンプ61の空気取り入れ口に連通する空気流入路に防塵フィルタ63Dを備えている。本体ケース62は上面と後面が開口し、後述のように、本体ケース62の後面は、本体ケース62に結合される背面板62Rによって塞がれる。また、本体ケース62の上面は背面板62Rに保持する防塵フィルタ63Dによって塞がれる。   In order to prevent dust from being introduced into the air pump 61, a dust filter 63 </ b> D is provided in the air inflow path communicating with the air intake port of the air pump 61. The main body case 62 has an upper surface and a rear surface opened, and the rear surface of the main body case 62 is closed by a back plate 62R coupled to the main body case 62 as described later. Further, the upper surface of the main body case 62 is closed by a dustproof filter 63D held on the back plate 62R.

空気導出パイプ63Aは、上面に空気ポンプ61を取り付ける支持部63A3を形成し、そこから下方へ略垂直に延びる縦方向通路部63A1と、縦方向通路部63A1の下端から略水平に延び本体ケース62の前壁62Fの孔62Dを貫通する横方向通路部63A2とを有する。支持部63A3は、防塵フィルタ63Dの配置位置よりも下方位置において、本体ケース62の左右側壁の上部に前後方向に水平状態に形成した支持溝62M1に、本体ケース62の後面開口から挿入する。   The air outlet pipe 63A forms a support portion 63A3 to which the air pump 61 is attached on the upper surface, and a vertical passage portion 63A1 extending substantially vertically downward therefrom, and a main body case 62 extending substantially horizontally from the lower end of the vertical passage portion 63A1. And a lateral passage portion 63A2 that penetrates the hole 62D of the front wall 62F. The support portion 63A3 is inserted from the rear surface opening of the main body case 62 into a support groove 62M1 formed in a horizontal state in the front-rear direction on the left and right side walls of the main body case 62 at a position below the position where the dust filter 63D is disposed.

ポンプ装置60は、貯水容器9の圧縮空気誘導パイプ96と接続するために、ガスケット63Bを有する。ガスケット63Bは、後述のように、空気ポンプユニット60Uと外装ケース65との間に保持され、ポンプ装置60の前面に突出する。   The pump device 60 has a gasket 63 </ b> B for connection with the compressed air guide pipe 96 of the water storage container 9. As will be described later, the gasket 63B is held between the air pump unit 60U and the outer case 65 and protrudes to the front surface of the pump device 60.

ガスケット63Bは、弾力性を有するシリコンゴム製であり、中央部に空気導出パイプ63Aと弾力性にて接続する空気吐出路63Cを貫通形成する円筒形状をなす。ガスケット63Bは、前側及び後側に開口した円筒形ケース64に収容する。空気吐出路63Cの前部の空気吐出口63は、後述の貯水容器9の圧縮空気誘導パイプ96を気密状態に挿入する挿入部を、弾力性を有する複数の円形の環状リブ63C1によって形成する。   The gasket 63B is made of silicon rubber having elasticity, and has a cylindrical shape that penetrates and forms an air discharge passage 63C that is elastically connected to the air outlet pipe 63A in the center. The gasket 63B is accommodated in a cylindrical case 64 that opens to the front side and the rear side. The air discharge port 63 at the front portion of the air discharge path 63C forms an insertion portion for inserting a compressed air guide pipe 96 of the water storage container 9 described later in an airtight state by a plurality of circular annular ribs 63C1 having elasticity.

空気ポンプ61は、種々の形態があるが、小型化に適したものとして、公知の圧電素子型空気ポンプが適する。圧電素子型空気ポンプ61は、圧電素子を有する振動板を空気導出パイプ63Aの上端の入り口開口に対向配置し、圧電素子に所定周波数の電圧を印加し、振動板の振動によって空気導出パイプ63Aへ圧縮空気を送出する動作を行う。   Although there are various forms of the air pump 61, a known piezoelectric element type air pump is suitable as one suitable for downsizing. The piezoelectric element type air pump 61 has a diaphragm having a piezoelectric element disposed opposite to an inlet opening at the upper end of the air outlet pipe 63A, applies a voltage of a predetermined frequency to the piezoelectric element, and vibrates the diaphragm to the air outlet pipe 63A. The operation of sending out compressed air is performed.

空気ポンプユニット60Uと外装ケース65との組み立てについて説明する。
本体ケース62の上方へ突出した係止突起62Aを外装ケース65の係止爪部65Rに係止し、その状態で、本体ケース62から下方へ突出した取り付け部62Bを外装ケース65の固定部65BへネジNJで固定する。この状態で、ガスケット63Bを収容した円筒形ケース64を外装ケース65の前壁65Fの挿通孔65Aに対応させ、外装ケース65の前方から、円筒形ケース64の外方へ突出した左右一対の係止爪部64Aを、外装ケース65の前壁65Fの挿通孔65Aに形成した左右一対の切欠き部65Cに対応させ、その状態で円筒形ケース64を押し込む。この押し込みによって、ガスケット63Bの後端面に形成した円形状溝に、本体ケース62の前壁62Fに形成した環状突起62F2が嵌合する。更に、本体ケース62の前壁62Fの環状突起62F2の内側と外側位置に形成した円形状の窪み62F1、62F3に、ガスケット63Bの後端面が当接する。
The assembly of the air pump unit 60U and the outer case 65 will be described.
The locking protrusion 62A protruding upward from the main body case 62 is locked to the locking claw portion 65R of the outer case 65, and in this state, the mounting portion 62B protruding downward from the main body case 62 is fixed to the fixing portion 65B of the outer case 65. Fix with a screw NJ. In this state, the cylindrical case 64 containing the gasket 63B is made to correspond to the insertion hole 65A of the front wall 65F of the outer case 65, and a pair of left and right protrusions projecting outward from the cylindrical case 64 from the front of the outer case 65. The pawl portion 64A is made to correspond to the pair of left and right cutout portions 65C formed in the insertion hole 65A of the front wall 65F of the exterior case 65, and the cylindrical case 64 is pushed in that state. By this pushing, the annular protrusion 62F2 formed on the front wall 62F of the main body case 62 is fitted into the circular groove formed on the rear end surface of the gasket 63B. Further, the rear end surface of the gasket 63B comes into contact with circular recesses 62F1 and 62F3 formed at positions inside and outside the annular protrusion 62F2 of the front wall 62F of the main body case 62.

図38に示すように、このように、ガスケット63Bの後端面が、本体ケース62の前壁62Fの窪み62F1、窪み62F3、及び環状突起62F2に当接し、また、空気吐出路63Cの後端縁の全周に前方に窪んで形成した面取りR部63B1と、空気導出パイプ63Aの横方向通路63A2のパイプ先端外周部に前方に突出して形成した角R部63ARを干渉させることで、成形のバラツキによるシール性の悪化を予防することができる。   As shown in FIG. 38, the rear end surface of the gasket 63B thus contacts the recess 62F1, the recess 62F3, and the annular protrusion 62F2 of the front wall 62F of the main body case 62, and the rear end edge of the air discharge path 63C. The chamfered R portion 63B1 formed to be depressed forward on the entire circumference of the pipe and the corner R portion 63AR formed to protrude forward from the outer peripheral portion of the pipe tip of the lateral passage 63A2 of the air outlet pipe 63A interfere with each other. It is possible to prevent the deterioration of the sealing performance due to.

円筒形ケース64内にガスケット63Bを収納した状態で本体ケース62の前壁62Fにガスケット63Bをセットし、外装ケース65内で回転収納する。そして、係止爪部64Aが外装ケース65の前壁65Fの裏側へ回り込むように、円筒形ケース64を回転させる。円筒形ケース64の回転は、円筒形ケース64の前壁64Bに記した符号M1が、外装ケース65の前壁65Fに記した符号M2に対峙する位置まで行う。この位置が、略90度回転した状態である。この状態で、ガスケット63Bが若干圧縮される状態となり、それによって、ガスケット63Bの後端部が本体ケース62の前壁62Fに密着し、空気導出パイプ63Aの横通路部63A2の前端が、ガスケット63Bの空気吐出路63Cの後端に密着し、それによって、空気導出パイプ63Aの横方向通路部63A2と空気吐出路63Cが、一連の略水平方向の空気通路を形成する。このため、ポンプ装置60は、縦方向通路部63A1と、横方向通路部63A2と、空気吐出路63Cとによって、略L字状の空気導出路が形成される。   With the gasket 63B stored in the cylindrical case 64, the gasket 63B is set on the front wall 62F of the main body case 62, and is rotated and stored in the outer case 65. Then, the cylindrical case 64 is rotated so that the locking claw portion 64A goes around to the back side of the front wall 65F of the exterior case 65. The rotation of the cylindrical case 64 is performed until the position where the reference sign M1 indicated on the front wall 64B of the cylindrical case 64 faces the reference sign M2 indicated on the front wall 65F of the exterior case 65. This position is a state rotated approximately 90 degrees. In this state, the gasket 63B is slightly compressed, whereby the rear end portion of the gasket 63B is in close contact with the front wall 62F of the main body case 62, and the front end of the lateral passage portion 63A2 of the air outlet pipe 63A is the gasket 63B. The air discharge passage 63C is in close contact with the rear end of the air discharge passage 63C, whereby the lateral passage portion 63A2 of the air outlet pipe 63A and the air discharge passage 63C form a series of substantially horizontal air passages. For this reason, in the pump device 60, a substantially L-shaped air outlet passage is formed by the longitudinal passage portion 63A1, the lateral passage portion 63A2, and the air discharge passage 63C.

次に、図39乃至図45に基づいて、本体ケース62の上部に防塵フィルタ63Dを配置する構造について説明する。
上記のように、空気ポンプユニット60Uと外装ケース65を組み立てるポンプ装置60は、空気ポンプ61へ取り入れる空気の防塵のために、空気ポンプ61の空気取り入れ口に連通する空気流入路に防塵フィルタ63Dを備えている。この防塵フィルタ63Dは、本体ケース62の後面開口を塞ぐように本体ケース62に結合される背面板62Rの上部に支持される。以下、この構成を詳述する。
Next, based on FIG. 39 thru | or FIG. 45, the structure which arrange | positions the dustproof filter 63D in the upper part of the main body case 62 is demonstrated.
As described above, the pump device 60 that assembles the air pump unit 60U and the outer case 65 is provided with a dustproof filter 63D in the air inflow passage communicating with the air intake port of the air pump 61 in order to prevent dust from being taken into the air pump 61. I have. The dust filter 63D is supported on the upper part of the back plate 62R coupled to the main body case 62 so as to close the rear opening of the main body case 62. Hereinafter, this configuration will be described in detail.

図40に示すように、背面板62Rは合成樹脂製であり、主体部62R1と、主体部62R1の上端部に回動可能に連結するフィルタ保持部62FHを有する。フィルタ保持部62FHは、主体部62R1の上端部に第1ヒンジ部H1で回動可能に連結する第1フィルタ保持部62R2と、第1フィルタ保持部62R2の他端部に第2ヒンジ部H2で回動可能に連結する第2フィルタ保持部62R3と、を有する。第1ヒンジ部H1と第2ヒンジ部H2は、主体部62R1及びフィルタ保持部62FHを合成樹脂で一体成形するとき、同時に肉厚を薄く成形することによって形成される。   As shown in FIG. 40, the back plate 62R is made of synthetic resin, and has a main body portion 62R1 and a filter holding portion 62FH that is rotatably connected to the upper end portion of the main body portion 62R1. The filter holding portion 62FH has a first filter holding portion 62R2 rotatably connected to the upper end portion of the main body portion 62R1 by the first hinge portion H1, and a second hinge portion H2 at the other end of the first filter holding portion 62R2. A second filter holding portion 62R3 that is rotatably connected. The first hinge portion H1 and the second hinge portion H2 are formed by simultaneously forming the main body portion 62R1 and the filter holding portion 62FH with a synthetic resin so as to reduce the thickness.

第1フィルタ保持部62R2は、防塵フィルタ63Dを収容するために窪み形成するフィルタ収容部FKを有する。第2フィルタ保持部62R3は、フィルタ収容部FK内に防塵フィルタ63Dを支持するフィルタ支持部FTを突出形成する。また、第1フィルタ保持部62R2と第2フィルタ保持部62R3は、それぞれ碁盤目状に空気通路AR1とAR2を形成する。このため、空気通路AR1の周囲がフィルタ収容部FKとなり、空気通路AR2の周囲がフィルタ支持部FTとなる。更に、フィルタ保持部62FHは、左右両側に突出して、前後方向に延びるフランジFRを有する。このフランジFRは、実施例では、第1フィルタ保持部62R2と第2フィルタ保持部62R3のそれぞれ左右両側に突出した前後方向に延びるフランジFR1、FR2で構成する。   The first filter holding portion 62R2 has a filter housing portion FK that is formed to be recessed to accommodate the dust filter 63D. The second filter holding part 62R3 protrudes and forms a filter support part FT that supports the dustproof filter 63D in the filter housing part FK. The first filter holding part 62R2 and the second filter holding part 62R3 form air passages AR1 and AR2 in a grid pattern, respectively. For this reason, the periphery of the air passage AR1 becomes the filter housing portion FK, and the periphery of the air passage AR2 becomes the filter support portion FT. Further, the filter holding portion 62FH has a flange FR that protrudes in the left and right sides and extends in the front-rear direction. In the embodiment, the flange FR is constituted by flanges FR1 and FR2 extending in the front-rear direction and protruding from the left and right sides of the first filter holding portion 62R2 and the second filter holding portion 62R3.

第1ヒンジ部H1及び第2ヒンジ部H2によって、主体部62R1に対して第1フィルタ保持部62R2と第2フィルタ保持部62R3を開いた状態で、防塵フィルタ63Dをフィルタ収容部FKに収容する。その状態で、第2ヒンジ部H2によって、第1フィルタ保持部62R2と第2フィルタ保持部62R3を相互に重なり合うように閉じることにより、フィルタ支持部FTがフィルタ収容部FK内に進入し、第1フィルタ保持部62R2と第2フィルタ保持部62R3の間に、防塵フィルタ63Dを挟持する状態となる。第1フィルタ保持部62R2と第2フィルタ保持部62R3が重なり合った状態は、第1フィルタ保持部62R2の第1ヒンジ部H1側に形成する左右の係止爪KT1が、第2フィルタ保持部62R3の左右のフランジFR2の第2ヒンジ部H2の反対側の端部FR21に弾性力で係止することにより保持される。このように防塵フィルタ63Dを保持したフィルタ保持部62FHは、図41及び図43に示すように、防塵フィルタ63Dを介して空気通路AR1とAR2が対峙した状態である。また、左右のフランジFR1、FR2は、相互に重なり合った状態となる。   With the first hinge part H1 and the second hinge part H2, the dust filter 63D is housed in the filter housing part FK with the first filter holding part 62R2 and the second filter holding part 62R3 opened with respect to the main part 62R1. In this state, by closing the first filter holding part 62R2 and the second filter holding part 62R3 so as to overlap each other by the second hinge part H2, the filter support part FT enters the filter housing part FK, and the first The dustproof filter 63D is sandwiched between the filter holding part 62R2 and the second filter holding part 62R3. When the first filter holding part 62R2 and the second filter holding part 62R3 are overlapped, the left and right engaging claws KT1 formed on the first hinge part H1 side of the first filter holding part 62R2 are connected to the second filter holding part 62R3. The left and right flanges FR2 are held by being elastically locked to the end portions FR21 opposite to the second hinge portions H2. As shown in FIGS. 41 and 43, the filter holding portion 62FH holding the dust filter 63D is in a state where the air passages AR1 and AR2 are opposed to each other through the dust filter 63D. Further, the left and right flanges FR1 and FR2 overlap each other.

このように、第1フィルタ保持部62R2と第2フィルタ保持部62R3が重なり合ったフィルタ保持部62FHは、主体部62R1に対し第1ヒンジ部H1によって前方へ略水平状態に回動させる。この回動に伴って、第2フィルタ保持部62R3の後端部に形成する係止爪KT2が、主体部62R1の前面上部に窪み形成する係止部KB1に弾性力で係止することにより、フィルタ保持部62FHは、主体部62R1の上端部に略水平状態に保持される。   Thus, the filter holding part 62FH in which the first filter holding part 62R2 and the second filter holding part 62R3 overlap each other is rotated forward in a substantially horizontal state by the first hinge part H1 with respect to the main part 62R1. Along with this rotation, the locking claw KT2 formed at the rear end portion of the second filter holding portion 62R3 is locked by the elastic force to the locking portion KB1 formed in the upper front portion of the main body portion 62R1. The filter holding portion 62FH is held in a substantially horizontal state at the upper end portion of the main portion 62R1.

このようにフィルタ保持部62FHが主体部62R1の上端部に略水平状態に保持された背面板62Rは、本体ケース62の左右壁の上部に前後方向に略水平状態に形成した支持溝62M2に、左右のフランジFRを本体ケース62の後面開口から挿入する。この挿入に伴って、主体部62R1の周縁部の左右及び下部に突出形成するリブRBが、本体ケース62の左右側壁及び下部壁の内側に沿って侵入する。そして、主体部62R1の下部に形成した係止爪KT3が、本体ケース62の底壁に窪み形成した係止部KB2に弾性力で係止する。また、この挿入に伴って、主体部62R1の左右端部に形成した係止爪KT4が、本体ケース62の左右側壁に窪み形成した係止部KB3に弾性力で係止する。   In this way, the back plate 62R in which the filter holding portion 62FH is held in a substantially horizontal state at the upper end portion of the main body portion 62R1 is formed in a support groove 62M2 formed in a substantially horizontal state in the front-rear direction on the left and right walls of the main body case 62. The left and right flanges FR are inserted from the rear surface opening of the main body case 62. Along with this insertion, ribs RB projecting from the left and right and lower portions of the peripheral edge of the main portion 62R1 enter along the inner sides of the left and right side walls and the lower wall of the main body case 62. Then, the locking claw KT3 formed at the lower portion of the main body 62R1 is locked by an elastic force to the locking portion KB2 formed in the bottom wall of the main body case 62. Further, with this insertion, the locking claws KT4 formed at the left and right end portions of the main body portion 62R1 are locked by the elastic force with the locking portions KB3 formed in the left and right side walls of the main body case 62.

このようにして、背面板62Rの主体部62R1は、本体ケース62の後面開口を塞ぐように、本体ケース62に密着状態で結合すると共に、主体部62R1の内側面が支持部63A3の後端面に密着する。またこの状態で、本体ケース62の上面は、防塵フィルタ63Dを保持するフィルタ保持部62FHによって塞がれる。この状態で、本体ケース62内が、支持部63A3によって上下空間に分離され、空気ポンプ61の空気取り入れ口は、その上部空間に連通する。
空気ポンプ61に採用する公知の圧電素子型空気ポンプは、空気取り入れ口と圧縮空気の空気出口が下面に存在する。このため、空気取り入れ口を前記上部空間に連通する空気通路を、空気ポンプ61と支持部63A3との間の隙間によって形成する。また、空気ポンプ61の空気出口は、空気導出パイプ63Aの上端の入り口開口に連通する。このため、本体ケース62の周辺の空気は、空気通路AR1、防塵フィルタ63D、及び空気通路AR2を順次通過し、空気ポンプ61の空気取り入れ口に流入する。そして、空気ポンプ61で圧縮される圧縮空気は、空気ポンプ61の空気出口から空気導出パイプ63Aへ送出される。
Thus, the main portion 62R1 of the back plate 62R is joined in close contact with the main body case 62 so as to close the rear opening of the main body case 62, and the inner side surface of the main portion 62R1 is connected to the rear end surface of the support portion 63A3. In close contact. Further, in this state, the upper surface of the main body case 62 is closed by the filter holding portion 62FH that holds the dust filter 63D. In this state, the inside of the main body case 62 is separated into upper and lower spaces by the support portion 63A3, and the air intake port of the air pump 61 communicates with the upper space.
A known piezoelectric element type air pump employed in the air pump 61 has an air intake port and an air outlet for compressed air on the lower surface. For this reason, an air passage that communicates the air intake port with the upper space is formed by a gap between the air pump 61 and the support portion 63A3. The air outlet of the air pump 61 communicates with the inlet opening at the upper end of the air outlet pipe 63A. Therefore, the air around the main body case 62 sequentially passes through the air passage AR1, the dust filter 63D, and the air passage AR2, and flows into the air intake port of the air pump 61. The compressed air compressed by the air pump 61 is sent from the air outlet of the air pump 61 to the air outlet pipe 63A.

上記のように、空気ポンプユニット60Uと外装ケース65とが組み立てられたポンプ装置60は、貯水容器収容部46の奥部に設けた取り付け部67へ取り付ける。この取り付け部67は、背壁部材32の一部を後方に窪ませた凹部で形成される。取り付け部67には、ポンプ装置60を載置する支持台部66と、外装ケース65の左右壁の係止爪部65Gを弾性係止する係止部を有する。この係止部は、取り付け部67の左右側壁に形成した係止孔または係止突部で形成する。支持台部66は、冷蔵室3の底板29を上方に屈曲にて形成する。ポンプ装置60を取り付け部67に取り付けるために、ポンプ装置60から背面側に延出したリード線を冷蔵庫本体2側の電源ラインに接続し、この電源接続部分をポンプ装置60の背面側に配置する。支持台部66にポンプ装置60の外装ケース65の底部65Eを載置し、外装ケース65の左右壁の掴み部65Wを指で掴んだ状態で、左右壁の係止爪部65Gを前記係止部に弾性係止する。これにより、取り付け部67にポンプ装置60が取り付けられる。また、取り付け部67の形態は、背壁部材32の一部にポンプ装置60の後部が入り込む開口で形成し、この開口の左右側部に形成した係止部に係止爪部65Gを弾性係止し、支持台部66に外装ケース65の底部65Eを載置する構成でもよい。このような構成を採用することによって、冷蔵室3内で液体がこぼれた場合であっても、ポンプ装置60の背面側に存在する前記電源接続部分に該水が掛かることを防ぐことができる。   As described above, the pump device 60 in which the air pump unit 60 </ b> U and the outer case 65 are assembled is attached to the attachment portion 67 provided at the back of the water storage container housing portion 46. The attachment portion 67 is formed by a concave portion in which a part of the back wall member 32 is recessed rearward. The attachment portion 67 has a support base portion 66 on which the pump device 60 is placed, and a locking portion that elastically locks the locking claw portions 65G on the left and right walls of the outer case 65. This locking portion is formed by locking holes or locking protrusions formed in the left and right side walls of the mounting portion 67. The support base 66 is formed by bending the bottom plate 29 of the refrigerator compartment 3 upward. In order to attach the pump device 60 to the attachment portion 67, the lead wire extending from the pump device 60 to the back side is connected to the power line on the refrigerator body 2 side, and this power connection portion is arranged on the back side of the pump device 60. . The bottom 65E of the outer case 65 of the pump device 60 is placed on the support base 66, and the left and right wall locking claws 65G are locked with the fingers while gripping the right and left wall gripping portions 65W of the outer case 65 with the fingers. Elastically locked to the part. As a result, the pump device 60 is attached to the attachment portion 67. The mounting portion 67 is formed by an opening into which the rear portion of the pump device 60 enters a part of the back wall member 32, and the locking claw portion 65G is elastically engaged with the locking portions formed on the left and right sides of the opening. Alternatively, the bottom 65E of the outer case 65 may be placed on the support base 66. By adopting such a configuration, even when liquid is spilled in the refrigerator compartment 3, it is possible to prevent the water from splashing on the power connection portion existing on the back side of the pump device 60.

ポンプ装置60の取り付けによって、空気吐出路63Cの空気吐出口63が貯水容器収容部46へ向けて露出する状態となる。また、外装ケース65の後面開口を通して、冷気通路35Aまたは冷蔵室3の空気が、防塵フィルタ63Dを通って空気ポンプ61へ吸い込まれる構成となる。   By mounting the pump device 60, the air discharge port 63 of the air discharge path 63 </ b> C is exposed to the water storage container housing 46. Further, the air in the cold air passage 35A or the refrigerator compartment 3 is sucked into the air pump 61 through the dustproof filter 63D through the rear surface opening of the outer case 65.

給水装置Bは、ポンプ装置60を冷蔵庫本体2側に配置し、ポンプ装置60の空気吐出口63へ貯水容器9を着脱自在に接続する構成とし、貯水容器9は、主タンク部90の製氷用水が自然流下にて計量タンク部91へ流入する方式であって、計量タンク部91に貯留された製氷用水をポンプ装置60の圧縮空気によって製氷皿7Bへ押し出す方式である。   The water supply device B has a configuration in which the pump device 60 is disposed on the refrigerator main body 2 side, and the water storage container 9 is detachably connected to the air discharge port 63 of the pump device 60, and the water storage container 9 is water for making ice in the main tank unit 90. Is a system in which the water for ice making stored in the measuring tank section 91 is pushed out to the ice tray 7B by the compressed air of the pump device 60.

この方式において、圧電素子型空気ポンプ61に水が掛かることによって作動不良に至ることが懸念されるため、空気ポンプ61に水が掛からない構成である。即ち、貯水容器9の製氷用水が圧縮空気誘導パイプ96へ逆流しても、空気ポンプ61から空気吐出口63へ至る空気通路を通って、製氷用水が空気ポンプ61へ到達しないように逆流エネルギーを減衰させると共に、空気ポンプ61の圧縮空気はスムースに計量タンク部91へ供給される空気通路構成とする。このため、空気ポンプ61から吐出される空気が、貯水容器9から後方へ略水平状態に突出する圧縮空気誘導パイプ96へ供給される空気通路は、縦方向通路から横方向通路を経て圧縮空気誘導パイプ96へ至る構成である。   In this system, since it is feared that the piezoelectric element-type air pump 61 may be inoperable due to water, the air pump 61 is not covered with water. That is, even if the ice making water in the water storage container 9 flows backward to the compressed air induction pipe 96, the reverse flow energy is reduced so that the ice making water does not reach the air pump 61 through the air passage from the air pump 61 to the air discharge port 63. In addition to the attenuation, the compressed air of the air pump 61 is configured to be smoothly supplied to the measuring tank unit 91. For this reason, the air passage from which the air discharged from the air pump 61 is supplied to the compressed air induction pipe 96 protruding rearward from the water storage container 9 in a substantially horizontal state is guided by the compressed air induction from the longitudinal passage through the transverse passage. The configuration reaches the pipe 96.

具体的には、図4、図37に示すように、空気ポンプ61から吐出される空気が圧縮空気誘導パイプ96へ供給される空気通路は、空気導出パイプ63A内の空気通路と、空気導出パイプ63Aが接続されるガスケット63Bに形成された空気吐出路63Cによって形成される。圧縮空気誘導パイプ96との接続関係、耐久性及び成形のし易さ等を考慮して、ガスケット63Bはシリコンゴム製でもって空気吐出路63Cは直線状に形成し、合成樹脂成形される空気導出パイプ63Aは、L字状に屈曲した空気通路構成とする。   Specifically, as shown in FIGS. 4 and 37, the air passage through which the air discharged from the air pump 61 is supplied to the compressed air induction pipe 96 includes an air passage in the air outlet pipe 63 </ b> A and an air outlet pipe. It is formed by the air discharge path 63C formed in the gasket 63B to which 63A is connected. In consideration of the connection relationship with the compressed air guide pipe 96, durability, ease of molding, etc., the gasket 63B is made of silicon rubber, the air discharge path 63C is formed in a straight line, and the air derived from the synthetic resin is molded. The pipe 63A has an air passage configuration bent in an L shape.

空気導出パイプ63A内の空気通路は、縦方向通路部63A1と横方向通路部63A2でL字状に屈曲した通路構成である。具体的には、下部の横方向通路部63A2は、空気吐出路63Cと共に、圧縮空気誘導パイプ96へ連通する略水平に延びる横方向通路を形成し、横方向通路部63A2から上方へ略垂直に延びる縦方向通路部63A1は、製氷用水の上昇エネルギーが、縦方向通路部63A1と横方向通路部63A2との交差部63A4に衝突して減衰し、残ったエネルギーによって縦方向通路部63A1を上昇しても、空気ポンプ61まで達しない程度の長さの縦方向通路を形成する。この縦方向通路部63A1と横方向通路部63A2の長さは、実施形態の給水装置Bにおいて事前のテストによって確認し設定する。   The air passage in the air outlet pipe 63A has a passage configuration that is bent in an L shape by the longitudinal passage portion 63A1 and the lateral passage portion 63A2. Specifically, the lower lateral passage portion 63A2 and the air discharge passage 63C form a substantially horizontal lateral passage that communicates with the compressed air guide pipe 96, and is substantially vertically upward from the lateral passage portion 63A2. In the extending vertical passage portion 63A1, the rising energy of the ice making water collides with the intersecting portion 63A4 between the vertical passage portion 63A1 and the horizontal passage portion 63A2, and is attenuated, and the remaining energy rises in the vertical passage portion 63A1. However, a longitudinal passage having a length that does not reach the air pump 61 is formed. The lengths of the longitudinal passage portion 63A1 and the lateral passage portion 63A2 are confirmed and set by a preliminary test in the water supply apparatus B of the embodiment.

上記のように、計量タンク部91の圧縮空気導入路94は、空気吐出口63に着脱自在に接続される圧縮空気誘導パイプ96と、仕切り体9Bに貫通形成した圧縮空気導入部91Aと、上端部が圧縮空気誘導パイプ96と連通し下端部が圧縮空気導入部91Aと連通するように、仕切り体9Bに立設した圧縮空気導入パイプ97とによって形成される。   As described above, the compressed air introduction path 94 of the measuring tank unit 91 includes a compressed air induction pipe 96 that is detachably connected to the air discharge port 63, a compressed air introduction portion 91A that is formed through the partition body 9B, and an upper end. It is formed by a compressed air introduction pipe 97 erected on the partition body 9B so that the portion communicates with the compressed air induction pipe 96 and the lower end portion communicates with the compressed air introduction portion 91A.

このため、計量タンク部91の製氷用水がこの圧縮空気導入路94を逆流する経路は、圧縮空気導入部91Aから略垂直状態に設けた圧縮空気導入パイプ97を上昇した後、略水平方向へ延びた圧縮空気誘導パイプ96を通って空気吐出口63に至るため、この圧縮空気導入路94の経路でも製氷用水の逆流エネルギーは減衰され、更に、水平方向へ流れて交差部63A4に衝突して減衰する。実施形態では、図示のように、縦方向通路部63A1は、横方向通路部63A2の略2倍程度で十分効果が発揮できる。   For this reason, the path through which the ice-making water in the metering tank section 91 flows backward through the compressed air introduction path 94 rises from the compressed air introduction section 91A to the compressed air introduction pipe 97 provided in a substantially vertical state, and then extends in a substantially horizontal direction. Since the compressed air guide pipe 96 reaches the air discharge port 63, the reverse flow energy of the ice making water is also attenuated in the compressed air introduction path 94, and further flows in the horizontal direction and collides with the intersection 63A4 to be attenuated. To do. In the embodiment, as shown in the drawing, the longitudinal passage portion 63A1 can exhibit a sufficient effect when it is approximately twice as large as the lateral passage portion 63A2.

次に、小型の空気ポンプ61によって、計量タンク部91から規定量の製氷用水を円滑に押し出す構成を説明する。
ポンプ装置60からの圧縮空気によって、計量タンク部91から規定量の製氷用水を円滑に製氷皿7Bへ供給するために、円形状の圧縮空気導入部91Aの直径が円形状の製氷用水導出部91Bの直径よりも大きい。
Next, a configuration in which a specified amount of ice-making water is smoothly pushed out from the measuring tank unit 91 by the small air pump 61 will be described.
In order to smoothly supply a specified amount of ice making water from the measuring tank unit 91 to the ice tray 7B by the compressed air from the pump device 60, the diameter of the circular compressed air introducing unit 91A is a circular ice making water outlet unit 91B. Larger than the diameter of

これにより、ポンプ装置60からの圧縮空気によって、計量タンク部91の入り口側の圧力と出口側の圧力関係によって、圧電素子型空気ポンプのように、空気吐出圧力が小さい小型の空気ポンプ61であっても、計量タンク部91から製氷用水を押し出す作用が良好となり、計量タンク部91から規定量の製氷用水を円滑に製氷皿7Bへ供給できる。それゆえ、空気ポンプ61も小型の圧電素子振動型が採用できることとなり、空気ポンプ61を貯水容器収容部46の奥部の冷気供給通路35内へ配置することができ、空気ポンプ61の取り付け部の確保が容易となる。
この効果を得るために、圧縮空気導入部91Aと同径で立ち上がる円形状の圧縮空気導入パイプ97の内径が、製氷用水導出部91Bと同径で立ち上がる円形状の製氷用水導出パイプ99の内径よりも大きい。
As a result, the compressed air from the pump device 60 is a small air pump 61 having a small air discharge pressure, such as a piezoelectric element type air pump, due to the pressure relationship between the inlet side and the outlet side of the measuring tank unit 91. However, the action of pushing out the ice-making water from the measuring tank unit 91 is improved, and the specified amount of ice-making water can be smoothly supplied from the measuring tank unit 91 to the ice tray 7B. Therefore, the air pump 61 can also adopt a small piezoelectric element vibration type, and the air pump 61 can be disposed in the cold air supply passage 35 at the back of the water storage container housing portion 46. Ensuring is easy.
In order to obtain this effect, the inner diameter of the circular compressed air introduction pipe 97 rising with the same diameter as the compressed air introduction portion 91A is larger than the inner diameter of the circular ice making water extraction pipe 99 rising with the same diameter as the ice making water outlet portion 91B. Is also big.

次に、貯水容器9内への製氷用水の注入について説明する。
図8、図9等に示すように、蓋体9Cには、その上面前部で主タンク部90に対応する位置に円形状の給水口104が貫通形成されており、この給水口104は手動開閉可能な回転式キャップ105によって閉じられる。容器本体9Aに蓋体9Cを取り付けた状態において、上水道等から給水口104を通して製氷用水を注水する場合、その注水が勢いよく供給孔92へ直接流入すれば、計量タンク部91内に流入する製氷用水が規定量を超える虞がある。これを防止するために、給水口104は供給孔92から遠い位置に配置する構成としている。実施例では、給水口104は、計量タンク部91の上面領域を外れた主タンク部90の前部領域に対応する位置である。これによって、圧縮空気誘導パイプ96から水が噴き出すことを防止することができる。
Next, injection of ice-making water into the water storage container 9 will be described.
As shown in FIGS. 8, 9 and the like, the lid body 9C has a circular water supply port 104 penetratingly formed at a position corresponding to the main tank portion 90 at the front upper surface thereof. It is closed by a rotatable cap 105 that can be opened and closed. In the state where the lid body 9C is attached to the container main body 9A, when water for making ice is poured from the water supply or the like through the water supply port 104, if the water poured directly into the supply hole 92, the ice making flowing into the measuring tank unit 91 will be performed. There is a possibility that the amount of water used exceeds the specified amount. In order to prevent this, the water supply port 104 is arranged at a position far from the supply hole 92. In the embodiment, the water supply port 104 is a position corresponding to the front region of the main tank unit 90 that is out of the upper surface region of the measuring tank unit 91. Thereby, it is possible to prevent water from being ejected from the compressed air guide pipe 96.

これによって、給水口104から上水道等を注水しても、その注水は給水口104直下の主タンク部90に衝突し、注水の勢いが減衰されるため、主タンク部90内の製氷用水は、供給孔92から自然流下で計量タンク部91内に貯留され、規定量が溜まることとなる。
貯水容器9内の製氷用水の満杯レベルWLは、即ち、主タンク部90の製氷用水満杯レベルであり、給水口104の下部に設けた水平辺104Aのレベルに定めている。このため、貯水容器9内に製氷用水が満杯になったか否かは、目視により、満杯レベルWLまで水が入った状態で満杯と判断する。
As a result, even when water is poured from the water supply port 104, the water injection collides with the main tank unit 90 immediately below the water supply port 104, and the momentum of the water injection is attenuated. It is stored in the measuring tank unit 91 under a natural flow from the supply hole 92, and a specified amount is stored.
The ice making water full level WL in the water storage container 9 is the ice making water full level of the main tank unit 90, and is set at the level of the horizontal side 104 </ b> A provided at the lower part of the water supply port 104. For this reason, whether or not the water for ice making is filled in the water storage container 9 is determined to be full when the water is filled up to the full level WL.

図8、図9等に示すように、主タンク部90内には、支持脚120で支持された活性炭119を供給孔92の上方に配置する。これによって、主タンク部90の製氷用水が供給孔92から自然流下で計量タンク部91内へ流入する際に、流動する製氷用水が活性炭119を通過することにより浄化される。   As shown in FIGS. 8 and 9, activated carbon 119 supported by the support legs 120 is disposed above the supply hole 92 in the main tank portion 90. As a result, when the ice making water in the main tank 90 flows into the measuring tank 91 from the supply hole 92 under natural flow, the flowing ice making water is purified by passing through the activated carbon 119.

次に、貯水容器9を貯水容器収容部46の所定位置に設置する手段について説明する。
図5は、本発明に係る給水装置の貯水容器のスライド構成を説明するための断面斜視図である。
実施例では、貯水容器9をスライドにて挿入及び引出可能に構成する。このため、図5〜図11、図16に示すように、貯水容器9の底部の左右両側には、容器本体9Aの底面よりも下方へ突出した脚部9Kを容器本体9Aに一体成形する。左右の脚部9Kは、それぞれ前側脚部9K1と後側脚部9K2を備え、左側の前側脚部9K1と後側脚部9K2は、前後方向の同一直線上に配置する。また、右側の前側脚部9K1と後側脚部9K2も、前後方向の同一直線上に配置する。そして、右側の前側脚部9K1と左側の前側脚部9K1は、左右対称形でもって左右対称配置であり、右側の後側脚部9K1と左側の後側脚部9K1は、左右対称形でもって左右対称配置である。それぞれの前側脚部9K1と後側脚部9K2は、左右両側とも、前後方向に延びた板状でもって一直線上の配置である。
Next, means for installing the water storage container 9 at a predetermined position of the water storage container accommodating portion 46 will be described.
FIG. 5 is a cross-sectional perspective view for explaining the slide configuration of the water storage container of the water supply apparatus according to the present invention.
In the embodiment, the water storage container 9 is configured to be inserted and withdrawn by a slide. For this reason, as shown in FIGS. 5 to 11 and 16, leg portions 9 </ b> K that protrude downward from the bottom surface of the container body 9 </ b> A are integrally formed on the container body 9 </ b> A on both the left and right sides of the bottom of the water storage container 9. Each of the left and right legs 9K includes a front leg 9K1 and a rear leg 9K2, and the left front leg 9K1 and the rear leg 9K2 are arranged on the same straight line in the front-rear direction. Further, the right front leg 9K1 and the rear leg 9K2 are also arranged on the same straight line in the front-rear direction. The right front leg 9K1 and the left front leg 9K1 are symmetrically arranged in a bilaterally symmetrical manner, and the right rear leg 9K1 and the left rear leg 9K1 are symmetrically arranged. It is a symmetrical arrangement. Each of the front leg portion 9K1 and the rear leg portion 9K2 is arranged in a straight line with a plate shape extending in the front-rear direction on both the left and right sides.

容器本体9Aの脚部9Kが貯水容器収容部46の底面をスライドするように、貯水容器収容部46の底面をなす冷蔵室3の底板29の上面がレール部を構成する。このレール部は、底板29の上面に左右の脚部9Kがスライドする溝で形成することもできるが、他の手段によって、貯水容器9の挿入及び引出時の左右のブレを制限することもできる。   The upper surface of the bottom plate 29 of the refrigerating chamber 3 forming the bottom surface of the water storage container housing portion 46 constitutes a rail portion so that the leg portion 9K of the container main body 9A slides on the bottom surface of the water storage container housing portion 46. This rail portion can be formed on the upper surface of the bottom plate 29 by a groove in which the left and right leg portions 9K slide, but by other means, it is possible to limit the left and right blurring when the water storage container 9 is inserted and withdrawn. .

実施例では、貯水容器収容部46の底面の左右に、前後方向に延びた案内壁46Kを冷蔵室3の底板29の屈曲にて形成する。左右の脚部9Kの外側間の寸法よりも、左右の案内壁46K間の寸法は若干広い。このため、左右の案内壁46Kの内側面に沿った貯水容器収容部46の底面が、脚部9Kがスライドするレール部として作用する。   In the embodiment, guide walls 46 </ b> K extending in the front-rear direction are formed by bending the bottom plate 29 of the refrigerator compartment 3 on the left and right sides of the bottom surface of the water storage container housing portion 46. The dimension between the left and right guide walls 46K is slightly larger than the dimension between the outsides of the left and right legs 9K. For this reason, the bottom surface of the water storage container accommodating part 46 along the inner side surface of the left and right guide walls 46K acts as a rail part on which the leg part 9K slides.

このレール部には、貯水容器9が所定位置に収容された状態で、左右の前側脚部9K1と後側脚部9K2が落ち込む窪み46Y1と46Y2が、冷蔵室3の底板29の屈曲にて形成する。
また、貯水容器9が所定位置に収容された状態で、前方へ移動しないようにストッパとして機能する係止段差46Aを、左右の案内壁46K間に、冷蔵室3の底板29の一部を上方へ屈曲して形成する。これによって、左右の案内壁46Kと係止段差46Aとの間の溝46Zが、左右の脚部9Kがスライドするレール部を構成する。
In this rail portion, the recesses 46Y1 and 46Y2 in which the left and right front leg portions 9K1 and the rear leg portions 9K2 fall are formed by bending the bottom plate 29 of the refrigerator compartment 3 in a state where the water storage container 9 is accommodated in a predetermined position. To do.
In addition, with the water storage container 9 housed in a predetermined position, a locking step 46A that functions as a stopper is provided so that it does not move forward, and a part of the bottom plate 29 of the refrigerator compartment 3 is located between the left and right guide walls 46K. Bend to form. Thus, the groove 46Z between the left and right guide walls 46K and the locking step 46A constitutes a rail portion on which the left and right leg portions 9K slide.

この構成において、製氷用水誘導パイプ98の下端部周縁に環状パッキン115を取り付け、所定量の製氷用水を注入した貯水容器9を準備する。この貯水容器9を、左右の溝46Zに左右の後側脚部9K2を挿入する関係で、貯水容器収容部46の底面をスライドさせつつ後方へ挿入する。この挿入によって、左右の前側脚部9K1と後側脚部9K2が、それぞれ対応する窪み46Y1、46Y2へ落ち込む。   In this configuration, an annular packing 115 is attached to the periphery of the lower end of the ice making water guiding pipe 98, and a water storage container 9 into which a predetermined amount of ice making water has been injected is prepared. The water storage container 9 is inserted rearward while sliding the bottom surface of the water storage container accommodating portion 46 in such a relationship that the left and right rear legs 9K2 are inserted into the left and right grooves 46Z. By this insertion, the left and right front legs 9K1 and rear legs 9K2 fall into the corresponding recesses 46Y1, 46Y2.

これによって、ポンプ装置60の前面の空気吐出口63の挿入部63C1に圧縮空気誘導パイプ96が挿入され、ガスケット63Bの環状リブ63C1の弾力性によって気密状態に接続される。この接続された正規の状態にて、容器本体9Aの底面前部に下方へ突出形成した係止部9A3が、係止段差46Aの後側に位置する。これによって、貯水容器9が貯水容器収容部46から前方へ移動することが制限される。この状態は、貯水容器9が貯水容器収容部46の所定位置に設置された状態である。   As a result, the compressed air induction pipe 96 is inserted into the insertion portion 63C1 of the air discharge port 63 on the front surface of the pump device 60, and is connected in an airtight state by the elasticity of the annular rib 63C1 of the gasket 63B. In this connected normal state, the locking portion 9A3 that protrudes downward from the bottom front portion of the container main body 9A is positioned on the rear side of the locking step 46A. As a result, the movement of the water storage container 9 from the water storage container accommodating portion 46 is restricted. This state is a state in which the water storage container 9 is installed at a predetermined position of the water storage container accommodating portion 46.

上記のように冷蔵室3の底板29のように、同一部材に外装ケース65を載置する支持台部66と、貯水容器9のスライド部を形成すれば、ポンプ装置60に対する貯水容器9の挿入及び引き出し動作関係を正規の状態に定め易くなる効果がある。   As described above, like the bottom plate 29 of the refrigerator compartment 3, if the support base 66 for placing the outer case 65 and the slide portion of the water storage container 9 are formed on the same member, the water storage container 9 is inserted into the pump device 60. In addition, there is an effect that it is easy to set the pulling operation relationship to a normal state.

貯水容器9が貯水容器収容部46の所定位置に設置された状態において、製氷用水出口である製氷用水誘導パイプ98の下端部が、製氷用水誘導パイプ98の下端部の直径よりも大きい直径でもって上方に漏斗状に広がった製氷用水供給路51の上端開口へ臨む。この状態で、製氷用水誘導パイプ98の下端部から製氷用水供給路51へ製氷用水が漏れなく導入されるようにするために、製氷用水誘導パイプ98の下端部周縁に取り付けた環状パッキン115が、製氷用水供給路51の上端開口周縁部に当接する関係である。   In a state where the water storage container 9 is installed at a predetermined position of the water storage container accommodating portion 46, the lower end portion of the ice making water guiding pipe 98 that is the ice making water outlet has a diameter larger than the diameter of the lower end portion of the ice making water guiding pipe 98. It faces the upper end opening of the ice-making water supply channel 51 that spreads upward in a funnel shape. In this state, an annular packing 115 attached to the periphery of the lower end portion of the ice making water guiding pipe 98 is provided so that the ice making water is introduced from the lower end portion of the ice making water guiding pipe 98 to the ice making water supply passage 51 without leakage. This is a relationship in contact with the peripheral edge of the upper end opening of the ice-making water supply passage 51.

次に、製氷動作について説明する。
上記のように貯水容器9が貯水容器収容部46の所定位置へ挿入設置された状態で、冷蔵庫1の操作パネル部127に設けた製氷開始スイッチの操作によって、自動製氷機7が製氷動作を開始する。製氷動作開始により、制御部の動作により、製氷皿7Bが所定の状態にあるか否か等の自動製氷機7のプリセット動作が行われる。このプリセット動作の後、空気ポンプ61が所定時間稼働して、圧縮空気が圧縮空気導入路94から計量タンク部91へ流入し、計量タンク部91の製氷用水が製氷用水導出路95へ押し出され、製氷用水供給路51を通って製氷皿7Bの製氷セル7B1のひとつである製氷セル7B11へ導入される。製氷皿7Bの複数の製氷セル7B1は、製氷セル7B1相互の区画壁の上部に形成した連通路にて連通しているため、所定の製氷セル7B11へ導入された製氷用水は、オーバーフローにて前記連通路から順次隣の製氷セル7B1へ流れ、各製氷セル7B1の製氷用水レベルは略均等になる。この状態で、後述のように、赤外線センサ110の検知によって製氷工程が開始し、製氷皿7B内の製氷用水の凍結が可能である。
Next, the ice making operation will be described.
With the water storage container 9 inserted into a predetermined position of the water storage container accommodating portion 46 as described above, the automatic ice making machine 7 starts the ice making operation by operating the ice making start switch provided on the operation panel portion 127 of the refrigerator 1. To do. When the ice making operation is started, a preset operation of the automatic ice making machine 7 such as whether or not the ice tray 7B is in a predetermined state is performed by the operation of the control unit. After this preset operation, the air pump 61 operates for a predetermined time, compressed air flows from the compressed air introduction path 94 to the measuring tank section 91, and ice making water in the measuring tank section 91 is pushed out to the ice making water outlet path 95, Through the ice making water supply path 51, the ice making cell 7B11 is introduced into one of the ice making cells 7B1 of the ice making tray 7B. Since the plurality of ice making cells 7B1 of the ice tray 7B communicate with each other through a communication path formed in the upper part of the partition walls of the ice making cells 7B1, the ice making water introduced into the predetermined ice making cell 7B11 is overflowed. The ice making cells 7B1 sequentially flow from the communication path, and the ice making water levels of the ice making cells 7B1 become substantially equal. In this state, as will be described later, the ice making process is started by detection of the infrared sensor 110, and the ice making water in the ice making tray 7B can be frozen.

図4、図5に示すように、製氷部6の上壁には、製氷皿7Bの製氷セル7B1内に氷が生成されたか否かを検知する赤外線センサ110を配置する。赤外線センサ110は、周知のサーモパイル型の赤外線センサである。サーモパイル型の赤外線センサは、制御部(図示せず)の動作によって、所定の製氷セル7B11内の水の温度を所定周期で測定するものであり、赤外線センサ110によって測定された温度が所定の低温度に達すると、制御部は、製氷皿7B内に氷が生成されたものと判断する。   As shown in FIGS. 4 and 5, an infrared sensor 110 that detects whether or not ice is generated in the ice making cell 7B1 of the ice making tray 7B is disposed on the upper wall of the ice making unit 6. The infrared sensor 110 is a known thermopile type infrared sensor. The thermopile type infrared sensor measures the temperature of water in a predetermined ice making cell 7B11 at a predetermined cycle by the operation of a control unit (not shown), and the temperature measured by the infrared sensor 110 is a predetermined low level. When the temperature is reached, the control unit determines that ice has been generated in the ice tray 7B.

また、計量タンク部91の製氷用水が製氷皿7Bへ導入されたか否かを検知方法は種々あるが、一つの方法として、この赤外線センサ110によって、計量タンク部91の製氷用水が製氷皿7Bへ導入されたか否かを検知できる。その場合、上記のように実施例では、計量タンク部91の規定量80ccを空気ポンプ61の15秒間の稼働によって製氷皿7Bへ押し出す。制御部は15秒経過時に制御部が赤外線センサ110の出力を読み取り、製氷セル7B11内の温度が製氷用水の流入によって所定温度以上に上昇しておれば、給水があったと判断し、製氷動作を開始するようにする。   There are various methods for detecting whether or not the ice making water in the measuring tank unit 91 has been introduced into the ice tray 7B. As one method, the infrared sensor 110 causes the ice making water in the measuring tank unit 91 to be supplied to the ice tray 7B. Whether or not it has been introduced can be detected. In that case, in the embodiment as described above, the specified amount 80 cc of the measuring tank unit 91 is pushed out to the ice tray 7B by the operation of the air pump 61 for 15 seconds. The control unit reads the output of the infrared sensor 110 when 15 seconds have elapsed, and if the temperature in the ice making cell 7B11 has risen to a predetermined temperature or more due to the inflow of ice making water, the control unit determines that water has been supplied and performs ice making operation. Let it start.

赤外線センサ110によって製氷皿7Bへの所定量の給水があったことが検知されたことにより製氷工程が開始し、製氷皿7Bの製氷セル内に氷を生成する。上記のように、製氷皿7B内に氷が生成された温度を赤外線センサ110が検知したとき、制御部の動作によって、電動機構7Aの製氷皿モータを駆動して製氷皿7Bを反転回動して捩りを与え、製氷セル7B1内の氷を下方の貯氷箱8へ落下させた後、再び製氷皿7Bを元の水平状態に戻す。この状態で、再び空気ポンプ61が稼働して、上記同様の製氷工程を開始する。   When the infrared sensor 110 detects that a predetermined amount of water has been supplied to the ice tray 7B, the ice making process starts, and ice is generated in the ice making cell of the ice tray 7B. As described above, when the infrared sensor 110 detects the temperature at which ice is generated in the ice tray 7B, the ice tray motor of the electric mechanism 7A is driven by the operation of the control unit to rotate the ice tray 7B in reverse. The ice making cell 7B1 is dropped into the ice storage box 8 below, and the ice tray 7B is returned to the original horizontal state again. In this state, the air pump 61 is operated again and the ice making process similar to the above is started.

貯水容器9が貯水容器収容部46の所定位置へ挿入設置された状態は、貯水容器収容部46の奥側壁等に配置した位置検知スイッチによって検知することにより検知する方法でもよい。その場合は、位置検知スイッチの信号が制御部へ入力され、製氷動作可能状態となる。この状態で、冷蔵庫の操作パネル部127に設けた製氷開始スイッチの操作によって、上記のように自動製氷機7が製氷動作を開始する。   A state in which the state in which the water storage container 9 is inserted and installed at a predetermined position of the water storage container housing portion 46 may be detected by a position detection switch disposed on the back side wall of the water storage container housing portion 46 or the like. In that case, the signal of the position detection switch is input to the control unit, and the ice making operation is possible. In this state, by operating an ice making start switch provided on the operation panel unit 127 of the refrigerator, the automatic ice making machine 7 starts the ice making operation as described above.

また、この位置検知スイッチを設けない方法もある。それは、製氷開始スイッチを操作して自動製氷機7に製氷動作開始指令を与え、制御部が空気ポンプ61を所定時間(実施例では15秒間)稼働させた後、制御部が赤外線センサ110の出力を読み取り、製氷皿7Bの製氷セル内の温度が製氷用水の流入が無いときの氷点下の温度であれば、給水が無かったと判断し、冷蔵庫1の操作パネル部127に設けたLCDやLED灯などの表示部に表示する。この表示は、貯水容器9が貯水容器収容部46の所定位置へ挿入設置されていないことか、貯水容器9が貯水容器収容部46の所定位置へ挿入設置されているが水切れであることの表示である。   There is also a method in which this position detection switch is not provided. That is, the ice making start switch is operated to give an ice making operation start command to the automatic ice making machine 7, and after the control unit operates the air pump 61 for a predetermined time (15 seconds in the embodiment), the control unit outputs the infrared sensor 110. If the temperature in the ice making cell of the ice tray 7B is below the freezing point when there is no inflow of ice making water, it is determined that there is no water supply, and an LCD or LED lamp provided on the operation panel 127 of the refrigerator 1 On the display. This indication indicates that the water storage container 9 is not inserted and installed at a predetermined position of the water storage container accommodating part 46, or that the water storage container 9 is inserted and installed at a predetermined position of the water storage container accommodating part 46 but is out of water. It is.

自動製氷機7の製氷動作は、貯氷箱8が満杯になったことにより終了する。この満杯状態は、図4に示すように、電動機構7Aによって製氷動作終了ごとに上方から貯氷箱8内へ下降する検氷レバー7Kを設ける。この検氷レバー7Kが貯氷箱8内の氷によって下降が阻止されたとき、電動機構7Aに係る負荷電流の急激な増加を制御部が検出して、貯氷箱8が満杯であると判断する。   The ice making operation of the automatic ice making machine 7 ends when the ice storage box 8 is full. In this full state, as shown in FIG. 4, an ice detecting lever 7K that descends from above into the ice storage box 8 is provided by the electric mechanism 7A every time the ice making operation is completed. When the ice detecting lever 7K is prevented from descending by the ice in the ice storage box 8, the control unit detects a rapid increase in load current related to the electric mechanism 7A, and determines that the ice storage box 8 is full.

貯水容器9への製氷用水補給等の場合は、係止部9A3が係止段差46Aから外れる位置まで、貯水容器9の前面に設けた取っ手9Tによって貯水容器9を持ち上げ、その状態で、貯水容器9を貯水容器収容部46の前方へ引き出すことによって、圧縮空気誘導パイプ96がポンプ装置60の空気吐出口63から離れつつ引き出せる。   In the case of replenishing ice-making water to the water storage container 9, the water storage container 9 is lifted by a handle 9T provided on the front surface of the water storage container 9 until the locking portion 9A3 is disengaged from the locking step 46A. By drawing 9 to the front of the water storage container housing portion 46, the compressed air induction pipe 96 can be pulled out while being separated from the air outlet 63 of the pump device 60.

上記のように、貯水容器9では、容器本体9Aへ取り付ける蓋体9Cによって仕切り体9Bが下方へ押圧されることにより、容器本体9Aの内底面との間に計量タンク部91が形成するため、計量タンク部91の形成が容易となり、且つ、仕切り体9Bを容器本体9Aへ固定する取り付け装置が不要となる。そのため、蓋体9Cを外せば容器本体9Aから仕切り体9Bを引き外せるため、容器本体9A、仕切り体9B及び蓋体9Cの洗浄がし易く、更に、圧縮空気導入路94と製氷用水導出路95の洗浄も容易に行えることとなる。また、貯水容器9を貯水容器収容部46から引き出した状態で、製氷用水供給路51の上端開口が貯水容器収容部46へ露出するため、製氷用水供給路51内の洗浄も容易に行えるようになる。   As described above, in the water storage container 9, since the partition body 9B is pressed downward by the lid body 9C attached to the container body 9A, the measuring tank portion 91 is formed between the inner bottom surface of the container body 9A. The measurement tank unit 91 can be easily formed, and an attachment device for fixing the partition body 9B to the container main body 9A becomes unnecessary. Therefore, since the partition body 9B can be detached from the container body 9A by removing the lid body 9C, the container body 9A, the partition body 9B, and the lid body 9C can be easily cleaned, and the compressed air introduction path 94 and the ice making water lead-out path 95 are also easy to clean. This can be easily performed. Further, since the upper end opening of the ice making water supply passage 51 is exposed to the water storage container receiving portion 46 in a state where the water storage vessel 9 is pulled out from the water storage vessel containing portion 46, the inside of the ice making water supply passage 51 can be easily cleaned. Become.

[第2実施形態]
図46〜図48は、本発明に係る冷蔵庫用自動製氷機の給水装置を備えた実施例2を示す。図46は第2実施形態の冷蔵庫1の冷蔵室内を示す正面図である。図47は第2実施形態の冷蔵庫1の縦断面図である。図48は第2実施形態の冷蔵庫1の横断面図である。これらの図において、冷蔵庫本体2の発泡断熱材2Cは省略した状態である。
[Second Embodiment]
46-48 shows Example 2 provided with the water supply apparatus of the automatic ice maker for refrigerators which concerns on this invention. FIG. 46 is a front view showing the refrigerator compartment of the refrigerator 1 according to the second embodiment. FIG. 47 is a longitudinal sectional view of the refrigerator 1 of the second embodiment. FIG. 48 is a cross-sectional view of the refrigerator 1 according to the second embodiment. In these drawings, the foam insulation 2C of the refrigerator body 2 is omitted.

第2実施形態の冷蔵庫1は、冷蔵庫本体2内は、上部に冷蔵室3、その下に冷凍室4、最下部が野菜室5となるように区画する。第1実施形態の冷蔵庫1と主として異なるところは、冷凍室4内は、下部には、容積の大きい主冷凍室4Sを形成し、上部には、左側に製氷部6、右側に冷凍庫室4Aを区画形成する。製氷部6内には上部に自動製氷機7の製氷皿7Bが配置され、製氷皿7Bの下方には上面開口の貯氷箱8が配置される。   In the refrigerator 1 of the second embodiment, the interior of the refrigerator body 2 is partitioned so that the refrigerator compartment 3 is at the top, the freezer compartment 4 is below it, and the vegetable compartment 5 is at the bottom. The main difference from the refrigerator 1 of the first embodiment is that the freezer compartment 4 has a main freezer compartment 4S having a large volume in the lower part, an ice making unit 6 on the left side, and a freezer room 4A on the right side in the upper part. Compartment formation. An ice making tray 7B of the automatic ice making machine 7 is arranged in the upper part of the ice making unit 6, and an ice storage box 8 having an upper surface opening is arranged below the ice making plate 7B.

この配置において、冷蔵室3の開口部は1枚の扉ではなく、冷蔵室扉10A、10Bにて左右に開く観音開き式である。野菜室5の開口部は、第1実施形態と同様の構成でもって、引き出し式扉11にて閉塞されている。また、製氷部6の開口部は、野菜室5と同様の構成で以って、製氷部6内に設けた左右のレールに対して前後方向へ引き出し可能に支持した貯氷箱8を扉12Aと共に前方へ引き出される引き出し式とする構成である。冷凍庫室4Aの開口部は、野菜室5と同様の構成で以って、冷凍庫室4A内に設けた左右のレールに対して前後方向へ引き出し可能に支持した容器を扉12Bと共に前方へ引き出される引き出し式とする構成である。また、主冷凍室4Sの開口部は、野菜室5と同様の構成で以って、主冷凍室4S内に設けた左右のレールに対して前後方向へ引き出し可能に支持した容器を扉12Cと共に前方へ引き出される引き出し式とする構成である。   In this arrangement, the opening of the refrigerating room 3 is not a single door, but a double door opening type that opens left and right at the refrigerating room doors 10A and 10B. The opening of the vegetable compartment 5 has the same configuration as that of the first embodiment, and is closed by the pull-out door 11. The opening of the ice making unit 6 has the same configuration as that of the vegetable compartment 5, and the ice storage box 8 supported so as to be able to be pulled out in the front-rear direction with respect to the left and right rails provided in the ice making unit 6 together with the door 12A. The structure is a pull-out type that is pulled forward. The opening of the freezer compartment 4A has the same configuration as the vegetable compartment 5, and the container supported so as to be able to be pulled out in the front-rear direction with respect to the left and right rails provided in the freezer compartment 4A is drawn forward together with the door 12B. The structure is a pull-out type. Moreover, the opening part of the main freezer compartment 4S is the structure similar to the vegetable compartment 5, and the container supported so that it can be pulled out in the front-back direction with respect to the left and right rails provided in the main freezer compartment 4S together with the door 12C. The structure is a pull-out type that is pulled forward.

第2実施形態の冷蔵庫1における本発明に係る自動製氷装置の給水装置は、第1実施形態と同様の構成及び同様の作用をするものであるため、第1実施形態と同様の部分には同様の符合を付し、その説明は第1実施形態に準拠するものとする。   Since the water supply device of the automatic ice making device according to the present invention in the refrigerator 1 of the second embodiment has the same configuration and the same action as the first embodiment, the same parts as those of the first embodiment are the same. The description is based on the first embodiment.

本発明は、種々の形態の冷蔵庫に適用して効果があるため、上記第1及び第2実施形態に記載した形態に限らない。このため、本発明の趣旨の範囲内において、種々の形態の冷蔵庫に適用可能である。
また、容器本体9A内を主タンク部90と計量タンク部91とに区画する仕切り体9Bは、本発明の目的が達成され、本発明の効果が得られれば、上記実施形態に記載した形態に限らない。このため、容器本体9A内に主タンク部90を形成する主タンク容器を容器本体9A内に着脱自在に収容し、この主タンク容器の底壁と容器本体9Aの底壁との間に計量タンク部91を形成する形態でもよい。この形態の場合、主タンク容器の底壁が仕切り体9Bに相当し、主タンク部90と計量タンク部91とを仕切る仕切り壁となる。このため、主タンク容器の底壁に、供給孔92を形成し、フロート体93を設け、障壁121を設ければよい。更に、主タンク容器の底壁に、圧縮空気導入路94、製氷用水吐出路95、及び空気排出溝125を設ける構成とする。
Since the present invention is effective when applied to refrigerators of various forms, the present invention is not limited to the forms described in the first and second embodiments. For this reason, it is applicable to the refrigerator of various forms within the meaning of the present invention.
Further, the partition body 9B that divides the inside of the container main body 9A into the main tank portion 90 and the measuring tank portion 91 can achieve the form described in the above embodiment if the object of the present invention is achieved and the effects of the present invention are obtained. Not exclusively. For this reason, the main tank container which forms the main tank part 90 in the container main body 9A is detachably accommodated in the container main body 9A, and the measuring tank is interposed between the bottom wall of the main tank container and the bottom wall of the container main body 9A. The form which forms the part 91 may be sufficient. In the case of this form, the bottom wall of the main tank container corresponds to the partition body 9 </ b> B, and becomes a partition wall that partitions the main tank portion 90 and the measuring tank portion 91. For this reason, the supply hole 92 is formed in the bottom wall of the main tank container, the float body 93 is provided, and the barrier 121 is provided. Further, a compressed air introduction path 94, an ice making water discharge path 95, and an air discharge groove 125 are provided on the bottom wall of the main tank container.

A・・・・・自動製氷装置
B・・・・・給水装置
1・・・・・・冷蔵庫
2・・・・・・冷蔵庫本体
3・・・・・・冷蔵室
4・・・・・・冷凍室
6・・・・・・製氷部
7・・・・・・自動製氷機
7B・・・・・製氷皿
8・・・・・・貯氷箱
9・・・・・・貯水容器
9A・・・・・容器本体
9A3・・・・係止部
9A1・・・・容器本体の内底面
9B・・・・・仕切り体
9BF・・・・押圧フランジ
9BT・・・・支え突起
9C・・・・・蓋体
9T・・・・・取っ手
28・・・・・断熱仕切り壁
32・・・・・冷蔵室の背壁部材
46・・・・・貯水容器収容部
46A・・・・係止段部
51・・・・・製氷用水供給路
60・・・・・ポンプ装置
60U・・・・空気ポンプユニット
61・・・・・空気ポンプ
62・・・・・本体ケース
62FH・・・フィルタ保持部
62M1・・・支持溝
62M2・・・支持溝
62R・・・・背面板
62R1・・・背面板の主体部
62R2・・・第1フィルタ保持部
62R3・・・第2フィルタ保持部
63・・・・・空気吐出口
63A・・・・空気導出パイプ
63A1・・・縦方向通路
63A2・・・横方向通路
63B・・・・ガスケット
63C・・・・空気吐出路
63D・・・・防塵フィルタ
65・・・・・外装ケース
90・・・・・主タンク部
90P・・・・パッキン保持部
90P1・・・環状突起
90P2・・・環状溝
90P3・・・当接部
90P4・・・保持突起
91・・・・・計量タンク部
91A・・・・圧縮空気導入部
91B・・・・製氷用水吐出部
92・・・・・供給孔
93・・・・・フロート体
94・・・・・圧縮空気導入路
95・・・・・製氷用水吐出路
96・・・・・圧縮空気誘導パイプ
97・・・・・圧縮空気導入パイプ
98・・・・・製氷用水誘導パイプ
99・・・・・製氷用水導出パイプ
99P・・・・出口パイプ
100・・・・連通路
100A・・・開渠部
100B・・・開渠部
104・・・・給水口
105・・・・キャップ
110・・・・係合突起
111・・・・係合溝
111A・・・係合溝の内側壁
111B・・・係合溝の外側壁
112・・・・傾斜面
115・・・・環状パッキン
116・・・・環状パッキン
117・・・・環状パッキン
117D・・・取り付け溝
117Q・・・肩部
117R1・・外側環状リブ
117R2・・内側環状リブ
117T・・・ヒレ部
121・・・・障壁
122・・・・製氷用水流出部
125・・・・空気排出溝
125A・・・膨出溝


A ... Automatic ice making equipment B ... Water supply equipment 1 .... Refrigerator 2 .... Refrigerator body 3 .... Refrigerator room 4 .... Freezer compartment 6 ····························································································· Ice tray 8 ... Container body 9A3 ... Locking part 9A1 ... Inner bottom surface of container body 9B ... Partition body 9BF ... Pressing flange 9BT ... Supporting protrusion 9C ... · Lid 9T ··· Handle 28 ··· Insulation partition wall 32 · · · Back wall member of refrigerator compartment 46 · · · Water storage container housing portion 46A · · · Locking step portion 51 ... Water supply path for ice making 60 ... Pump device 60U ... Air pump unit 61 ... Air pump 62 ... Main unit 62FH: Filter holding part 62M1 ... Support groove 62M2 ... Support groove 62R ... Back plate 62R1 ... Main part of back plate 62R2 ... First filter holding part 62R3 ... No. 2 Filter holding part 63 ... Air discharge port 63A ... Air discharge pipe 63A1 ... Vertical passage 63A2 ... Horizontal passage 63B ... Gasket 63C ... Air discharge path 63D ······· Dust-proof filter 65 ··· Outer case 90 ··· Main tank portion 90P ··· Packing holding portion 90P1 ··· Ring protrusion 90P2 · · · annular groove 90P3 ··· Contact portion 90P4 ··· Holding protrusion 91 ··· Metering tank portion 91A ··· Compressed air introduction portion 91B · · · Water discharge portion for ice making 92 ··· Supply hole 93 ··· Float body
94... Compressed air introduction passage 95... Ice making water discharge passage 96... Compressed air induction pipe 97... Compressed air introduction pipe 98. 99 ... Ice making water outlet pipe 99P ··· Outlet pipe 100 ··· Communication path 100A · Opening portion 100B · Opening portion 104 · · · Water supply port 105 ··· Cap 110... Engaging protrusion 111... Engaging groove 111 A... Engaging groove inner wall 111 B... Engaging groove outer wall 112... Inclined surface 115. Packing 116 ... Ring packing 117 ... Ring packing 117D ... Mounting groove 117Q ... Shoulder portion 117R1, Outer ring rib 117R2, Inner ring rib 117T ... Fin section 121 ... Barrier 122 ... Water flow for ice making Part 125 .... air discharge groove 125A ··· bulging groove


Claims (4)

製氷用水を貯留する貯水容器は、
上方に開口する開口部を有する容器本体と、
前記容器本体の内部空間を、製氷用水を貯留する主タンク部と、自動製氷装置の製氷皿に供給すべき予め定める容量の製氷用水を貯留する計量タンク部とに区画し、前記主タンク部と前記計量タンク部とに連通する供給孔が形成される仕切り体と、
前記仕切り体の周縁部と前記容器本体との間をシールする環状パッキンと、
前記容器本体内の底部に形成され前記環状パッキンを着脱自在に保持するパッキン保持部と、
前記容器本体の開口部に取り付けられ前記容器本体の開口部を塞ぐ蓋体と、を備え、
前記環状パッキンは、前記容器本体への前記蓋体の取り付けにより、前記仕切り体を介して前記パッキン保持部に押圧される
ことを特徴とする自動製氷装置の給水装置。
A water storage container for storing ice-making water is
A container body having an opening opening upward;
The internal space of the container body is partitioned into a main tank section for storing ice making water and a measuring tank section for storing a predetermined volume of ice making water to be supplied to an ice making tray of an automatic ice making device, and the main tank section A partition body in which a supply hole communicating with the measuring tank portion is formed;
An annular packing that seals between the peripheral edge of the partition and the container body;
A packing holding part that is formed at the bottom of the container body and holds the annular packing in a detachable manner;
A lid attached to the opening of the container body and closing the opening of the container body,
The water supply device for an automatic ice making device, wherein the annular packing is pressed against the packing holding portion via the partition when the lid is attached to the container body.
前記パッキン保持部は、前記計量タンク部の周囲に巡る上方に開口した環状溝と、環状突起とを備え、前記環状パッキンは、前記環状溝に嵌る環状リブと、前記環状突起が嵌る取り付け溝を備えた
ことを特徴とする請求項1に記載の自動製氷装置の給水装置。
The packing holding part includes an annular groove that opens upward around the circumference of the measuring tank part, and an annular protrusion, and the annular packing has an annular rib that fits into the annular groove and an attachment groove that fits the annular protrusion. The water supply device for an automatic ice making device according to claim 1.
前記容器本体は、底壁に前記計量タンク部の領域を形成するための窪みと、前記窪みの前後左右を巡る区画壁に沿って前記パッキン保持部を有し、前記区画壁の内側に前記環状突起を有し、前記区画壁と前記環状突起の間に前記環状溝を形成する
ことを特徴とする請求項2に記載の自動製氷装置の給水装置。
The container body has a recess for forming a region of the measuring tank portion in a bottom wall, and the packing holding portion along a partition wall that surrounds the front, rear, left, and right of the recess, and the annular body is formed inside the partition wall. The water supply device for an automatic ice making device according to claim 2, further comprising a protrusion, wherein the annular groove is formed between the partition wall and the annular protrusion.
前記貯水容器を取り出し自在に収容する貯水容器収容部が冷蔵室に形成され、前記製氷皿が製氷部に配置され、
前記計量タンク部へ圧縮空気を送るポンプ装置が前記貯水容器収容部に配置され、
前記貯水容器は、前記貯水容器収容部への収容に伴い、前記ポンプ装置の空気出口に着脱自在に接続される
ことを特徴とする請求項1乃至請求項3のいずれかに記載の自動製氷装置の給水装置を備えた冷蔵庫。
A water storage container storage part for freely storing the water storage container is formed in a refrigeration chamber, and the ice tray is arranged in the ice making part,
A pump device for sending compressed air to the metering tank is disposed in the water storage container housing;
The automatic ice making device according to any one of claims 1 to 3, wherein the water storage container is detachably connected to an air outlet of the pump device as the water storage container is accommodated in the water storage container accommodating portion. Refrigerator equipped with a water supply device.
JP2014266757A 2014-12-26 2014-12-26 Water supply device for automatic ice making device and refrigerator equipped with this water supply device Active JP6474612B2 (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113465269A (en) * 2020-03-13 2021-10-01 东芝生活电器株式会社 Refrigerator and water supply tank

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Publication number Priority date Publication date Assignee Title
JPS5364358U (en) * 1976-11-04 1978-05-30
JPH074525A (en) * 1993-06-14 1995-01-10 Casio Comput Co Ltd Waterproof structure for small-size equipment
JP2000217631A (en) * 1999-01-12 2000-08-08 Lir France Case with enclosed closure
JP2003284893A (en) * 2002-03-28 2003-10-07 Nok Corp Seal for washing machine

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5364358U (en) * 1976-11-04 1978-05-30
JPH074525A (en) * 1993-06-14 1995-01-10 Casio Comput Co Ltd Waterproof structure for small-size equipment
JP2000217631A (en) * 1999-01-12 2000-08-08 Lir France Case with enclosed closure
JP2003284893A (en) * 2002-03-28 2003-10-07 Nok Corp Seal for washing machine

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113465269A (en) * 2020-03-13 2021-10-01 东芝生活电器株式会社 Refrigerator and water supply tank
CN113465269B (en) * 2020-03-13 2024-09-20 东芝生活电器株式会社 Refrigerator and water supply tank

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