KR101193815B1 - Geared motor for refrigerator - Google Patents

Abstract

[PROBLEMS] To provide a freezer gear motor that can be operated as it is in a freezer, and has a high operating efficiency and can greatly increase its life at low cost.
RESOLUTION In the freezer gear motor 10 which operates in a freezer as a gear motor which integrated the motor 12 and the reducer 14, the input shaft 16 of the reducer 14 is sealed in the freezer. Cryogenic oil seal (first oil seal) 30 having a temperature characteristic that can be achieved, and the cryogenic oil seal 30 is mounted inside the speed reducer, and has a low temperature side temperature limit higher than that of the first oil seal. At least two oil seals of the low temperature (or room temperature) oil seal (second oil seal) 32 are provided.

Description

Gear motor for refrigerator

This application claims priority based on Japanese Patent Application No. 2009-289820, filed December 21, 2009. The entire contents of that application are incorporated by reference in this specification.

The present invention relates to a gear motor for use in a freezer.

Since the inside of the freezer for storing fresh food and the like is set at a cryogenic temperature, a storage shelf or a conveying stand which is installed to be movable in the inside of the freezer can perform any operation of the gear motor which is the driving source in any form. You need to secure it. However, the "gear motor" according to the present invention includes both a motor and a speed reducer directly integrated at the design stage, and a post integrated one using a coupling or the like.

In patent document 1, the thermostat which accommodated a gear motor in the thermostat box with a heating means is provided. In this thermostat, the heating means is operated when the temperature in the thermobox falls to a predetermined control temperature.

Japanese Unexamined Patent Publication No. 2005-300085

However, the above-described technique with a thermal insulation device requires a thermal insulation box or a heating control device in addition to the gear motor. In addition, when the gear motor is not used for a long time, the thermostat is always operated so that the gear motor can be used immediately at any time. Of course, when it is clear that the gearmotor will not be used for a long time, it is also possible to turn off the power of the thermostat each time. In this case, however, in using the gear motor, the operation itself is started unless the gear motor is warmed by the heating means by the heating means to wait until the grease or the like can function properly. There was also a problem that can not.

Therefore, it is conceivable to design a gear motor that can be used as it is in a freezer by using a lubricant and an oil seal developed to be used at a lower temperature. However, when the oil seal which is excellent in low temperature sealing performance is employed and the technique of directly using the gear motor in the freezer without heating, warming or warming up, in practice, lubricant rarely leaks from the oil seal part. It has been confirmed that a problem arises that something can happen.

The present invention has been made based on the intellectual findings obtained by closely examining the cause of the oil leakage in such a situation, and it is possible to operate as it is in a freezer without installing a thermostat or heating means. In addition, the task is to obtain a gear motor for a freezer that can have a high operating efficiency and greatly increase the life at low cost.

The present invention relates to a gear motor for a freezer which operates in a freezer as a gear motor integrating a motor and a reducer, the first oil seal having a temperature characteristic capable of sealing the rotating shaft of the reducer in the freezer, and the first oil seal. The above problems are solved by providing at least two oil seals of a second oil seal which is mounted inside the reducer of the oil seal and has a lower temperature limit temperature than the first oil seal.

The inventors have investigated the cause of oil leakage in the freezer gear motor, and as one of several possible causes, it is confirmed that the durability of the oil seal due to the wear powder (dust) of the gears in the reducer is reduced. It became. As a countermeasure, according to the present invention, a second oil seal having a lower temperature limit temperature than that of the first oil seal with respect to the first oil seal having a temperature characteristic capable of sealing the rotating shaft of the reducer in the freezer on purpose. Is installed inside the gearhead.

The reason for this is that, as a result of repeated investigations into the cause, it was confirmed that the main cause of the wear powder generation in the freezer gear motor is likely to be "test operation at room temperature". In this type of freezer gear motor, there are many cases in which a test operation is performed outside the freezer (that is, at room temperature) at the time of introduction or maintenance. Even if it is not normal temperature, a trial run may be performed in the freezer, even if it did not fall to the original freezing temperature. If a large amount of abrasion powder (dust) generated in this process is the cause, it is better to provide the dust removal as a lower temperature limit temperature than the oil seal having good characteristics under cryogenic temperature (target freezing temperature of the refrigerator). The oil seals having higher temperature characteristics than the oil seals correspond.

That is, by installing the oil seal usable in a higher temperature environment than the first oil seal, the first oil seal basically secures the sealing function during operation at cryogenic temperature in the freezer, and then the second oil seal, for example, by the second oil seal. Even in the case of carrying out a test run or the like outside, it is possible to exert a good sealing performance inherent in the second oil seal (including dust removal). In addition, oil seals whose low temperature limit temperature is not cryogenic are generally low cost. In addition, since the second oil seal has a characteristic that the low temperature side limit temperature is higher than that of the first oil seal, the second oil seal hardens during operation (under cryogenic conditions in a freezer) and the tendency of the squeeze force to be lower than that of the first oil seal. Has For this reason, at the time of operation in a freezer, virtually only the urgent force of the 1st oil seal will be in a state which acts on an axis | shaft, the energy loss by a stiffness and a slide is reduced, and dust (by the presence of the 2nd oil seal itself) is dusted. While collecting most of the, it is also possible to obtain an extremely beneficial advantage of maintaining high operating efficiency.

In this sense, when viewed from the viewpoint of "tensile force", the present invention relates to a "gear motor for a freezer which operates in a freezer as a gear motor incorporating a motor and a reducer, wherein the rotation shaft of the speed reducer is in the freezer. At least two kinds of a first oil seal having a sealable long-acting property and a second oil seal mounted inside the speed reducer of the first oil seal and having a shorter force characteristic smaller than the first oil seal in the freezer. It may be regarded as a gear motor for a freezer, characterized by having an oil seal.

According to the present invention, it is possible to obtain a gear motor for a freezer that can be operated as it is in a freezer, and has a high operating efficiency and can greatly increase the service life at low cost.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows an example of the gear motor for freezers to which the operation method which concerns on embodiment of this invention is applied.
2 is an enlarged cross-sectional view of an oil seal on the input side of the freezer gear motor.

EMBODIMENT OF THE INVENTION Hereinafter, based on drawing, the example of embodiment of this invention is described in detail.

1 is a cross-sectional view of a freezer gear motor according to an example of the embodiment of the present invention. 2 is an enlarged cross-sectional view of an oil seal portion. However, the target freezing temperature of a freezer (not shown) is -25 ° C in this example.

This freezer gear motor 10 integrates the motor 12 and the reducer 14 by fastening the motor casing 12A and the reducer casing 14A with bolts 11. In the case of a "gear motor", in general, as in this embodiment, the motor 12 and the reducer 14 are often referred to as being integrated (from the design stage), but the gear motor according to the present invention is often referred to. For example, an independently designed motor and a reducer may be integrated through a coupling or connecting bolt. When there is a situation in which oil does not want to leak out of the speed reducer (for example, in a coupling), the present invention can be similarly applied.

The reduction gear 14 meshes with the input shaft (rotation shaft) 16 of the motor 12 of the motor 12, the hypoid pinion 18 integrally formed in the input shaft 16, and the hypoid pinion 18. Hypoid gear 20 is provided. The hypoid gear 20 is attached to the intermediate shaft 22, and the intermediate pinion 24 formed integrally with the intermediate shaft 22 is engaged with the output gear 26. The rotation of the output gear 26 is output to the outside as the rotation of the output shaft 27.

In the gear motor 10 which concerns on this embodiment, the input shaft 16 of the reducer 14 is the cryogenic oil seal (1st oil seal) 30 which consists of silicone rubber, and the normal temperature oil seal which consists of acrylic rubber (2nd) The oil seal is sealed by two oil seals (32) (details will be described later). However, the output side of the reducer 14 is sealed only by the cryogenic oil seal 36 (of the same material as the input side) disposed adjacent to the bearing 34 of the output shaft 27. That is, in this example, the present invention is not applied to the output side of the speed reducer 14. This is because, on the output side, the rotational speed is low, and damage due to abrasion powder is hardly a problem, and thus the cost is reduced. However, of course, this invention may be applied to the seal of an output shaft (rotary shaft), and the improvement of the sealing performance and the increase of the oil seal life can be acquired.

As enlarged in FIG. 2, both the cryogenic oil seal 30 and the normal temperature oil seal 32 have a simple structure mainly having the main ribs 30A and 32A (without auxiliary ribs), thereby reducing costs. It is. In addition, in this invention, the specific structure of a 1st, 2nd oil seal is not limited to this example, For example, the structure which has an auxiliary lip is more effective at the point of dust removal.

The cryogenic oil seal 30 on the input side is disposed adjacent to the bearing 28 of the input shaft 16. In this embodiment, as described above, it is formed of silicone rubber. The silicone rubber has a temperature characteristic capable of sealing the reducer at the target freezing temperature of the freezer (having a long force characteristic capable of sealing the reducer at the target freezing temperature of the freezer). Here, what is called "for cryogenic temperature" by all means is for the following reasons. That is, the original inventor used the oil seal of acrylic rubber for the purpose of using it for the 1st oil seal of the gear motor for freezers of the target freezing temperature of -25 degreeC. However, in the early stages of operation, stiffness remains, and oil leakage rarely occurs due to this, which is presumed to be poorly followed by subtle shaking or vibration of the shaft. For this reason, it is because the cryogenic silicone rubber which is more excellent in low temperature sealing performance than the acrylic rubber was employ | adopted. This is a unique feature of simple O-rings and other freezer gearmotors. In the case of application to an oil seal of an input shaft that rotates at a high speed, as in the present embodiment, for example, the cryogenic oil seal that is guaranteed to be used at least at-(T + 10) ° C when the target freezing temperature is -T ° C. It is preferable to employ. The silicone rubber has a sufficiently low temperature sealing characteristic (resistance force characteristic) with respect to the target freezing temperature of -25 ° C, so that problems such as initial stiffness do not occur even if the direct operation is started without warming operation. Do not.

The low temperature side temperature limit (low temperature sealing property) of an oil seal is subtly (sometimes large) differing in the structure of the oil seal, the shape of a lip, the kind and quantity of additives, etc., even if the main materials are the same. For this reason, it is a fact that each company sets or designates the allowable temperature with respect to the specific material unique to each company. From this point of view, as long as the catalog of each company is viewed, nitrile rubber, besides silicone rubber, is also resistant to mineral oil-based oils and has abrasion resistance, and thus corresponds to the use of a freezer gear motor. In addition, ethylene propylene rubber, styrene butadiene rubber, ethylene tetrafluoride resin, fabric, and the like also have good low temperature properties as the raw material of the cryogenic oil seal of the present invention.

On the other hand, the oil seal 32 for room temperature uses acrylic rubber as mentioned above in this embodiment. For example, according to the catalog by NOK Corporation, although acrylic rubber is -25 degreeC the limit temperature of the low temperature side specified by the specification, it uses together with the cryogenic oil seal 30 of silicone rubber like this embodiment. This is because rather good properties can be obtained (compared to listing two cryogenic oil seals). In other words, the acrylic rubber has a lower temperature at the low temperature side than the silicone rubber (the limit temperature at the low temperature side of the same catalog is -60 ° C), and is rather silicone rubber when the gear motor is operated in a temperature environment other than the original freezer. This is because better long-acting characteristics and slide characteristics can be obtained.

Next, the operation of the gear motor 10 will be described.

In the operation of the gear motor 10 at a cryogenic temperature in a normal freezer, the cryogenic oil seal 30 functions effectively, so that a good sealing performance can be obtained. At this time, the oil seal 32 for room temperature collects most of the dust. However, since the hardness is high (because of the cryogenic high), the oil seal hardly exhibits the original functions, and thus the slide loss hardly occurs. In spite of being installed, the driving efficiency can be kept high and the amount of heat generated can be kept small.

In the test operation during the introduction of the gear motor 10 or during maintenance, the oil seal 32 for room temperature can reliably prevent dust such as wear powder from moving to the cryogenic oil seal 30 side. . Moreover, cost reduction is also aimed at the structure which arranges two cryogenic oil seals 30 together.

The effect that the oil seal 32 for room temperature effectively prevents dust from interfering with the slide surface of the cryogenic oil seal 30 and rotates together, contributes greatly to the increase in the life of the cryogenic oil seal 30. In particular, when the object to be sealed is the rotating shaft of the reduction gear, especially the input shaft 12 which rotates at high speed, the effect becomes remarkable.

In the present embodiment, however, acrylic rubber, which is an oil seal for room temperature, is used as the second oil seal, and dust is preferably removed, high efficiency (low loss) operation is realized, and the cost is reduced. In the present invention, the second oil seal does not necessarily need to be “for room temperature”, and in other words, if the low temperature side temperature is higher than the main cryogenic oil seal (first oil seal), or has a smaller long-acting force characteristic, The kind is not particularly limited. For example, silicone rubber as the first oil seal for cryogenic use (e.g., the low temperature limit temperature is -60 ° C according to the catalog of NOK Co., Ltd. mentioned above), and nitrile rubber as the second oil seal (low temperature limit according to the same catalog of the same company) The temperature may be a combination of −40 ° C.).

In addition, in the said embodiment, although the 1st and 2nd oil seals were each arrange | positioned one by one (two in total), 3 or more types or 3 or more types may be sufficient. The combination may also be, for example, A) for cryogenic temperature, for quasi-low temperature, for quasi-low temperature, or for B) for cryogenic, quasi-low temperature, or room temperature. , C) A combination of "for cryogenic", "for normal temperature" and "for normal temperature" may be used. In this example, from A) to C), from "Importance of sealing performance including dust removal of operation in a freezer", "Dust removal at the time of test operation at room temperature etc. & Improvement of operation efficiency in a freezer & Low cost ”. However, among these, in particular, the combination of B) is preferable in that the user can flexibly respond even if the target freezing temperature of the user's freezer is unclear (whatever the target freezing temperature). Of course, in either case, the sealing performance is improved in both the freezer operation and the test operation, rather than the two examples.

In addition, as mentioned above, the structure of a 1st, 2nd oil seal is not limited to the said example, For example, the structure of the plural lip provided with auxiliary lip for dust removal other than a main lip may be sufficient.

10... Freezer Gear Motor
12... motor
14 ... reducer
30 ... Cryogenic Oil Seal (First Oil Seal)
32 ... Room temperature oil seal (2nd oil seal)

Claims (6)

In a freezer gear motor which operates in a freezer as a gear motor integrating a motor and a reducer,
A first oil seal having a temperature characteristic capable of sealing the rotating shaft of the reducer in the freezer;
A second oil seal mounted inside the speed reducer of the first oil seal and having a lower temperature limit temperature than the first oil seal;
With at least two oil seals
Gear motor for freezer, characterized in that. In a freezer gear motor which operates in a freezer as a gear motor integrating a motor and a reducer,
A first oil seal having a strong force characteristic capable of sealing a rotation shaft portion of the reducer in the freezer;
A second oil seal mounted inside the speed reducer of the first oil seal and having a lesser force characteristic than the first oil seal in the freezer;
With at least two oil seals
Gear motor for freezer, characterized in that. The method according to claim 1 or 2,
The first oil seal is selected from silicone rubber and nitrile rubber
Gear motor for freezer, characterized in that. The method according to claim 1 or 2,
The low temperature side temperature limit of the second oil seal is higher than the target freezing temperature of the freezer.
Gear motor for freezer, characterized in that. The method of claim 4,
The second oil seal is oil seal for room temperature
Gear motor for freezer, characterized in that. The method according to claim 1 or 2,
The second oil seal is selected from acrylic rubber and nitrile rubber
Gear motor for freezer, characterized in that.

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