RU2387933C1 - Refrigerator - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention refers to refrigerator containing automatic door opening device and intended to facilitate the refrigerator door opening owing to double force created with a solenoid for detachment of sealing gasket and in order to overcome the force created by the spring of door shutting mechanism. Refrigerator includes the door which closes the first opening of the food-storage compartment, a switch which is brought into action by the user, and door opening device which is brought into action with a switch so that the door can be opened. Door opening device includes a solenoid made of helically wound wire located around the tube; core which moves in the tube in axial direction under influence of attractive force created with solenoid, ejector rod which is fixed on front end of the core and ejects the door forward in order to open it, in which the solenoid has two or more peaks in the curve of the created force, depending on the movement distance of the core.

EFFECT: simplifying the refrigerator door opening process.

9 cl, 15 dwg

Description

The present invention relates to a refrigerator comprising an automatic door opener for a retractable door fixed to a food storage container or for a casement door.

In recent years, the volume for storing food in the refrigerator, as well as its height and width, has been increasing due to large changes in lifestyle regarding products. This contributes to an increase in the height, width and depth of the casement doors of the fresh food storage chamber, which contains food storage compartments on the inner surface, as well as an increase in the sliding doors of the freezer and the vegetable storage chamber. As the number of products that are stored and the size of the doors is larger, opening the doors requires more effort when opening the doors manually, so opening can be tiring for older people or weak women. Therefore, some improvement is needed in this regard.

For the fresh food storage chamber, which is the largest, a pair of casement doors in the form of a French door or a door opener was selected that turns on when the user presses the plug-in switch on the outer surface of the door so as to actuate the solenoid, which pushes the pusher out and open the swing door by pushing the inner surface of the door out of the refrigerator body. Such refrigerators are sold and have gained a reputation as refrigerators in which doors open easily. In addition, a refrigerator was proposed comprising a door opener for swing doors in the form of a French door. See, for example, JP-2003-83676 A (Japanese Publication No. 2003-83676 of a Patent Application). The mechanism for opening a door for sash doors is quite simple, and the sash doors open easily when the pushing position relative to the door hinge and the pushing force are calculated accordingly. In contrast, a mechanism for opening a door for sliding doors of a vegetable storage chamber and a freezer requires a large pushing stroke to push along a straight line and is different from the rotational movement of a wing door. In addition, the sliding door is equipped with a mechanism for the spontaneous closing of the door to close the door, which bounced and opened slightly after the user abruptly pushed the door. To create such mechanisms for spontaneous closing of the door, the very rear parts of the guides for the sliding containers are tilted back down in some areas, or in other cases, springs for sliding the doors are installed.

Thus, to open the doors with the force generated by the solenoid, it is necessary to overcome not only the force of magnetic attraction to disengage the gasket of the door containing the magnet from the door frame, but also it is necessary to overcome the force for the attraction of the spring created by the mechanism to move the door, or another effort must be overcome. Thus, there are many peaks in the drag force on the curve representing the relationship between the drag force and the extension distance. However, the conventional solenoid used in the device to open the door has only a single peak of the generated force on the curve showing the relationship between the generated force and the retractable distance. Thus, in order to eliminate such a plurality of peaks of the resistance force in various extension positions, it is necessary to select a solenoid having a large power of creating force. For the formation of a solenoid with such a very high power, the dimensions of the solenoid become too large, so its installation in the refrigerator becomes difficult. In addition, if the extension speed becomes too high due to the very high power of the solenoid, the door opening speed becomes too high and the door may hit the user. In addition, the volume of the coiled wire in a spiral becomes too large, and the cost of the solenoid may be too high.

As a device for opening a door, a mechanism with an electric motor in place of the solenoid can be used. However, due to the mechanism using the electric motor, the door opening speed will be too low, and the pushing force will be rather weak. Thus, a mechanism using an electric motor is worse in speed and efficiency of opening a door than a solenoid.

Based on the foregoing, the goal is to create a refrigerator equipped with a mechanism for opening the door, due to which the generated force can vary depending on the magnitude of the load, which changes when the position of the opening door is changed in such a way as to ensure easy use, the dimensions of the solenoid become small, which allows easy installation in the refrigerator, and the cost of creating a mechanism is saved.

The refrigerator of the present invention includes: a door (9) that closes the front opening of the chamber (5) for storing products, a switch (16) that is operated by the user, and a device (15) for opening the door, which is located in the main body (1) the refrigerator so as to face the inner surface of the door (9) and is actuated by a switch (16) so as to open the door (9), and the device (15) for opening the door contains a solenoid (18) formed from wound spiral wire races laid around the tube (21), the core (22), which moves axially in the tube (21) under the action of the attractive force created by the solenoid (18), the ejector rod (23), which is fixed to the front end of the core (22) and pushes the door (9) is forward and opens in which the solenoid (18) has two or more peaks on the curve of the generated force, which depends on the distance of movement of the core (22).

In accordance with this design, the force generated by the solenoid changes in accordance with the change in load during the opening of the door, and the load depends on the distance between the door and the main body of the refrigerator. In this way, effective force generation and full utilization of the force generated during door opening are ensured. As a result, a smooth and convenient opening is automatically ensured, and the dimensions of the solenoid become small to ensure easy installation in the refrigerator, and the cost of the device for opening the door is also reduced.

The invention will now be explained in more detail with reference to the accompanying drawings, in which:

figure 1 depicts a partial perspective view of the refrigerator, illustrating the door of the freezer, which is open, and its surrounding elements;

figure 2 is a partial view of the refrigerator, illustrating the door of the freezer, which is closed, and its surrounding elements;

figure 3 is a perspective partial view with a spatial separation of the details of the refrigerator, illustrating a device for opening a door with its surrounding elements shown in figure 2;

4 is a view in horizontal section of the device for opening the door shown in figure 3, illustrating the state when the door of the freezer is closed;

5 is a graph illustrating a curve of the force generated by a solenoid in a device for opening a door, and a load curve for opening a door of a freezer depending on the displacement of the core of the solenoid;

6A and 6B are respectively a side view and a perspective view of the auxiliary yoke of the solenoid in the first example;

7 is a partial sectional side view illustrating the main part of the device for opening a door containing an auxiliary yoke of the first example;

figa and 8B, respectively, a side view and a perspective view of the auxiliary yoke of the solenoid in the second example;

Fig.9 is a side view of the auxiliary yoke of the solenoid in the third example;

figure 10 is a side view of the auxiliary yoke of the solenoid in the fourth example;

11 is a side view of the auxiliary yoke of the solenoid in the fifth example;

12 is a side view of the auxiliary yoke of the solenoid in the sixth example; and

13 is a side view of the auxiliary yoke of the solenoid in the seventh example.

An embodiment of the present invention will now be described with reference to the drawings. FIG. 1 is a partial perspective view of a refrigerator, illustrating a freezer door that is open, and surrounding elements in accordance with this embodiment, and FIG. 2 is a vertical sectional view of a portion of a refrigerator that is shown in FIG. The insulating body as the main body 1 of the refrigerator is formed of an inner case and an insulating material, such as foam polymer, filled between the inner and outer cases made of plate steel. The inner part of the main body 1 is divided into a chamber 2 for storing fresh products in the upper part, a chamber 3 for the formation of ice on the left side and a chamber 4 with temperature switchable on the right side, which are located under the chamber 2 for storing fresh products, which is separated from them by horizontal an insulating wall, and a freezer 5 at the bottom. The door is separately located on the front opening of each of these chambers to close it. An un illustrated vegetable compartment is located at the bottom of chamber 2 for storing fresh produce.

The opening of the chamber 2 for storing fresh food, which is the largest in volume for storing food, is hermetically sealed with a pair of casement doors as a French door and a door gasket containing a magnet fixed along the edge of each casement door. Each of the wing doors of the fresh food storage chamber is equipped with a mechanism for opening the door to open the door by actuating the solenoid in response to touching the user of a portion of the front surface of the door. Similarly to the chamber 2 for storing fresh products, the hole of each of the chambers 3 for ice formation, the temperature controlled chambers 4 and the freezer 5 is hermetically sealed with a door gasket 6 containing a magnet fixed along the edge of the corresponding door. Each of the doors of the ice chamber 3, the temperature controlled chamber 4 and the freezing chamber 5 is made in the form of a sliding door connected to a pair of support frames 7, which are located on the right and left sides, and a pair of support frames 7 supports a food storage container and supported by a pair of guide devices mounted on the inner side walls of the main body 1 so as to move in the forward-backward direction.

In the freezer 5 there are three containers for storing food. The main container 8 for storing products of the freezer 3 has the form of a box without an upper wall to form an upper hole and has a large depth. The flange of the main food storage container 8 is formed along almost the entire edge of its upper opening and supports a middle container 10 that has a relatively shallow depth and whose leading edge is pressed back so that a one-liter milk box for ice formation and / or another tall bottle or packaging can be placed at the front end of the food storage container 8. Between each of the support frames 7 and the inner side wall of the freezing chamber 5, a movable guide mechanism 11 is formed from one or more movable guides, and a fixed guide is located. When the door 9 of the freezer is fully extended under the action of the movable guide mechanisms 11, the middle container 10 extends completely with the main container 8 for storing food until the rear end of the middle container 10 comes forward of the front opening of the freezer 5, and thus the upper hole of the middle container 10 is fully protruded. The middle container 10 is able to move back and forth along the flange of the main food storage container 8 so that the upper opening of the main food storage container 8 is opened and closed by moving and extending the middle container 10.

Above the main and middle containers 8 and 10 for storing products, there is an upper container 12 for storing products, which can be extended and retracted independently of the door 9 of the freezer. The upper food storage container 12 is supported to move back and forth on its flange along the edge of the opening of the container 12, directly using a pair of non-illustrated support guides that are formed as an inner protrusion on the inner side walls of the freezer 5, and not by support frames 7 attached to the door 9 of the freezer. Thus, the weight of the upper container 12 for storing products and products contained therein is not loaded on the guide mechanism 11. As a result, only after the door 9 of the freezer has been extended, does the upper food storage container 12 separately extend by gripping and pulling the handle formed on the front the end portion of the upper food storage container 12, and the upper food storage container 12 can be pushed in front of the door 9 of the freezer.

As shown in FIG. 3, the door opening device 15 is located in the central part between the right and left sides of the horizontal partition 13, which separates the freezing chamber 5 from the ice forming chamber 3 and the temperature-changing chamber 4 located on top. In the illustrated embodiment, the horizontal partition 13 is only a partition and a support for forming edges abutting the laying of chambers 3-5, and for extending and sliding the main and upper containers 8 and 12 for storing products and is not a heat-insulating wall filled with insulating material. To arrange the device 15 for opening the door on such a horizontal partition 13, a space is used that is not used to store food.

The device 15 for opening the door is activated at the moment when the user's hand touches and slightly presses the quasi-sensor switch 16, which is made in the form of a magnetic lever on the handle 9A on the front surface of the door 9 of the freezer, as a result of the integrated circuit working with the hole and control through a microcomputer. The door opening device 15, shown in horizontal section in Fig. 4, comprises a main yoke 17 that forms the outer case of the double-shell cylindrical structure and its annular end walls, a brass cylindrical tube 21, which forms the inner case of the double-shell cylindrical structure, solenoid 18 which is located in the cylindrical space between the housings between the main yoke 17 and the brass cylindrical tube 21 and is formed from a molded polymer spirally wound around g of the frame, the front and rear auxiliary yokes 19 and 20, which are located on the outer surface of the brass cylindrical tube 21, respectively, on its front and rear parts, a core 22, which is formed of magnetic material and is drawn into the solenoid 18 when it is under electric current, so that it is able to move horizontal in the brass cylindrical tube 21 in its axial direction, and the ejector rod 23, which is securely inserted into the front end portion of the core 22. The device 15 for opening Ia door secured by screws in the housing of the solenoid 24, which is mounted in a partition 13 which extends in a direction from the rear to the front of the refrigerator, and a rubber sleeve or other cushioning layer disposed between the device 15 for opening the door 24 and the housing.

In the illustrated example, the core 22 and the ejector rod 23, which are connected to each other, are located in the freezer below the heat-insulating wall and, thus, can be connected by ice as a result of the formation of frost caused by the passage of air from the outside. To prevent such an icy connection and the resulting driving obstacle, the upper opening of the main body 24A of the solenoid body 24 is sealed by the solenoid cover 25 and the gap from the edge of the baffle hole 24B in the solenoid body 24 to the cylindrical surface of the core 22, which moves back and forth sealed to isolate the freezer 5 from moisture. As shown in FIG. 3, the baffle 24B is formed from the front end parts of the main body 24A and the solenoid cover 25. In addition, the silicone rubber bellows seal 26 covers the entire front protruding portion of the ejector rod 23 so as to allow the ejector rod 23 to protrude forward. The ejector head 27 made of synthetic plastic is positioned so that the front end portion of the bellows seal 26 is located between the ejector head 27 and the ejector rod 23. In the initial state shown in FIG. 4, the rear end of the core 22 abuts against the rear wall 24C of the main body 24A of the solenoid body 24.

When the solenoid 18 is under electric current, horizontal forward movement of the core 22 causes the ejector rod 23 to protrude forward. Then, the ejector rod 23 pushes the engaging protrusions 27A that protrude upward from the rear end of the ejector head 27 to engage the ejector rod 23, where the front end of the bellows seal 26 is located between the rod and the ejector head 23 and 27 (see FIG. 2- 3). Thus, the front end portion of the ejector head 27 protrudes and pushes toward the rear surface of the freezer door 9. Thus, the ejector head 27 is formed separately with the ejector rod 23, and the ejector head 27 is pushed toward its engaging protrusions 27A. Thus, a coaxial arrangement between the core 22 and the ejector head 27 is not required, and thus, the ejector rod 23 does not need to be bent. In addition, the position of the solenoid 18 is freely adjustable, so that the solenoid 18 is effectively located completely in the space not used for storage of products.

The rear end of the core 22 is connected to the end of the coil spring in the form of a return spring 28, so that the core 22 is constantly pushed in the backward direction, which is opposite to the direction in which the core 22 moves and protrudes under the action of the solenoid 18. When the electric current is disconnected through the solenoid 18, the rod 23 of the ejector is pushed back under the action of the spring 28 return to the inner part of the brass cylindrical tube 21. The entire device 15 for opening the door, which contains the head 27 of the ejector I, located in the front part of the solenoid housing 24, is completely closed by the polymer cover body 29 in such a way as to prevent the passage of cooled air and damage by external force and to prevent contact of the user's hand with the electrically conductive part.

As shown in FIG. 1, a door switch 30 formed of a reed switch or other proximity switch is located in the lower corner portion of the front end portion of the main body 1 to counter the rear surface of the freezer door 9. When the freezer door 9 slides and closes, the door switch is driven by the magnetic force of the door gasket containing a magnet fixed to the rear surface of the freezer door 9. Thus, the closed state or open state of the door 9 is recorded. The door switch 30, registering the closed state, is used not only to control the rotation of the fan to circulate the cooled air in the chambers, but also to prevent the spontaneous actuation of the device 15 for opening the door when the door 9 is open. Thus, while the door 9 is open, the solenoid will not be energized, even when the quasi-sensor switch 16 is activated, and thus the danger of spontaneous protrusion of the ejector head 27 is prevented. The device 15 for opening the door can be activated only if the door 9 is completely closed.

To open the door 9 of the freezer, the touch switch or quasi-sensor switch 16 on the handle 9A is actuated by touching or pressing by the user, if only the door switch 30 has registered the closed state of the door 9. Then, a current is passed through the solenoid 18 through the solenoid 18 to for one second. When the solenoid is excited, its core is pushed forward against the force exerted by the return spring 28 to open the door 9.

For a sliding door, such as freezer door 9, insufficient pushing of the door will cause the door to incompletely close and leave a gap between the door and the main body 1. In other cases, pushing the door too hard will cause the door to bounce due to the pressure of the compressed air in the chamber and also leave a gap between the door and the main body 1. To prevent the door from being left in such a half-closed position, the non-illustrated retract spring is located in each of the movable guide mechanisms 11 for pulling back and spontaneous closing of the door 9 of the freezer. Under the action of the force closing the door, the retraction springs, the door in the half-closed state closes and / or the completely closed state of the door is held.

As a result, when it is necessary to open the door 9 of the freezer, which is a retractable door, the load curve for opening the door shows two peaks, which respectively correspond to the uncoupling of the door gasket 6 containing the magnet from the main body 1 at the beginning and overcoming the force of the retraction springs later . Thus, the device 15 for opening the door should create a force that overcomes such a variable load at each offset position of the core 22.

The force generated by the solenoid 18 is a magnetic force and depends on the density of the magnetic flux. If the magnetic conductive material for forming the magnetic circuit of the solenoid 18 is iron or its alloy or other soft magnetic material, the magnetic force increases with an increase in the magnetic permeability of the material and an increase in the cross section of the magnetic conductor. If the solenoid 18 is made of a spiral-wound copper wire, the magnetic force increases with the number of turns of the spiral-wound copper wire and the diameter of the wire and, thus, is proportional to the product of the number of turns and the electric current, which is expressed in ampere-turns. In any of these methods of increasing the magnetic force, the weight and dimensions of the solenoid itself increase. To eliminate many peaks in the load curve using a conventional solenoid having only one peak in the excitation force curve, the total value of the excitation force will become very large. As the size of the solenoid increases, more space will be required to install the solenoid and, thus, reduced storage space for products. In addition, an increase in the force generated by the solenoid will cause excessive speed and force to open the door and may cause a collision with the user. In addition, the cost of the solenoid will become very high.

Based on the above, the solenoid 18 in this embodiment is made in the form of a cylindrical tube 21 with a through hole in which the core 22 moves, and is not an attractor in which the core abuts against a stationary attractor, and the exciting force reaches its maximum during such an abutment. In addition, the solenoid 18 in this embodiment contains on its front and rear parts two cylindrical auxiliary yokes 19 and 20, each of which has a corresponding shape and size. Thus, an exception is ensured by creating an effort of two load peaks during opening of the door 9 of the freezer.

Figure 5 depicts a curve of the load depending on the distance of the displacement of the door from the main body and the curve of the force of the solenoid 18 in a detailed example. As shown in FIG. 5, the distance from the fully raised position “F” (open position) to the zero position “C” (closed position) relative to the front end of the ejector head 27 is 46 mm in a detailed example. The load for opening the door immediately after leaving the position with the zero ledge will be at least the load to overcome the force of magnetic attraction between the door gasket 6 containing the magnet and the steel plates of the main body 1. The first peak LB of the load for uncoupling is position "B" protruding 8 mm, which is located at a distance of 38 mm from the fully protruding position "F". The first peak LB load is at around 30 N in the control curve (thin solid line in FIG. 5), which displays a hypothetical state without taking into account the friction force and weight of the door, container and products contained therein. The first peak LB load is at around 50 N on the curve (dashed line in FIG. 5) of the actually measured values. For such actually measured values, the load immediately after uncoupling will be equal to the sum of the friction force and weight, as well as the force of magnetic attraction, and will be in the range from directly below 30 N to much more than 20 N. The second peak of the LA load is within the position protruding by 20 30 mm, and, specifically, with the position "A" protruding 27 mm, which is located at a distance of 11 mm from the fully protruding position "F". The second peak LA load is formed by the force generated by the pushing springs, and is at around 35 N.

To eliminate this picture of load changes, the solenoid in a detailed example creates a force that depends on the position on the curve shown by the bold solid line in FIG. 5. The first peak SB of the force generated by the solenoid is in position "B", protruding 8 mm (38 mm from "F"), and at around 55 N, and the second peak SA of the force created by the solenoid is in position "A", projecting 35 mm (11 mm from "F" and 27 mm from "B") and at around 45 N. These values of the force generated by the solenoid are obtained when a voltage of 85 V is applied to the solenoid 18, and thus can be increased or changed by application, for example, a voltage of 100 V.

6A and 6B are a side view and a perspective view of a front auxiliary yoke 19 in the first example. The front auxiliary yoke 19 comprises a pair of rectangular cut parts 31 that are depressed from the rear end of the yoke 19, which is otherwise cylindrical, in opposite positions with respect to the axis of the yoke 19. Each of the cut parts 31 contains angled parts at the front end.

7 depicts a door opening device 15 comprising a front auxiliary yoke 19 of the first example shown in FIGS. 6A and 6B. 7, dashed lines indicate the position of the core 22 corresponding to the initial or zero position “C”. The core 22 moves forward from such a zero position “C” so that the front end 22A of the core 22 approaches the trailing edges 19A of the front auxiliary yoke 19. Then, the maximum force exerted by the solenoid is at the minimum distance between the front end 22A and the trailing edges 19A. Due to the cut out parts 31, the other and second peaks in the force exerted by the solenoid are in a position in which the front end 22A of the core 22 reaches the leading edges 31B of the cut out parts 31. The value of the second peak SA is set smaller than the value of the first peak SB, the ratio corresponds to the ratio sizes between trailing edges 19A and leading edges 31B. Similarly, the circumferential and axial dimensions (width and recess length) of the cut out parts 31 and the axial size (length) of the front auxiliary yoke 19 are set in accordance with the distance between the positions of the two load peaks LA and LB. In a detailed example, the size between the trailing edges 19A and the leading edges 31B is set to 27 mm, which is equal to the distance between the first and second maximum load values LA and LB.

The rectangular shape of the cut out parts 31 having angled parts at their front ends is advantageous when creating a second peak SA of the force generated by the solenoid, which is sharp and distinct, since the minimum distance between the front end 22A and the trailing edges 19A occurs in only one position moving the core 22. Thus, it is easy to appropriately eliminate the sharp increase and decrease in the force created by the retraction spring.

The user touches and lightly presses the quasi-sensor switch 16 of the freezer door 9, then a current flows through the solenoid 18, and the core 22 is drawn into the brass cylindrical tube 21 by overcoming the force exerted by the retract spring, and then the ejector rod 23 is moved forward to push the engaging protrusions 27A the ejector head 27, and thus the ejector head 27 projects forward, pushing the rear surface of the freezer door 9, and opens it. The first peak SB of the force generated by the solenoid, at a value of 55 N, is used to overcome the magnetic attraction and uncoupling the door gasket 6 containing the magnet from the edge of the opening of the main body 1. The second peak SA of the force generated by the solenoid at 45 N is used to overcome the force for spontaneous closing of the door of the retraction springs in order to open the door 9. By this action, the door 9 opens after moving the core 22 by 50-60 mm while the solenoid 18 is under current to ensure The distance of movement of the door 9 in the range from 200 mm to 300 mm due to the moment of inertia, which accumulates in the door 9 and the container and the product contained therein, due to the difference between the load and the door opening force generated by the solenoid. After this, at the second peak SB, no more force is applied to the door automatically generated by the retraction springs to be applied to the door 9 of the freezer, and only the friction force in the movable guide mechanisms 11 is applied to the door 9, which moves forward. Thus, further opening of the door 9 is carried out by means of a slight muscular effort of the user as easily as the user easily places and removes products.

In a detailed example, the duration of the solenoid 18 under current is one second, and the solenoid 18 is not an attractor in which the core 22 collides with a stationary attractor. Thus, the sound of shock will not occur. After completion of the ejection movement of the core 22 to ensure the protrusion of the head of the ejector 27, the power supply to the solenoid 18 is stopped, and the core 22 is returned back to its original position under the action of the force generated by the return spring 28. The initial position of the core 22, shown in figure 4, is equal to the zero position, in which the front end of the ejector head 27 is on the plane of the front surface of the edge of the hole of the main body 1.

Figa and 8B depict a side view and a perspective view of the front auxiliary yoke 19 'in the second example in accordance with the change in the shape of the cut parts. In the second example, the leading edge 31B of the cut parts 31 is in the form of a semicircle. 9A and 9B are a side view and a perspective view of the front auxiliary yoke 19 ″ in the third example, in which the front edge 31B of the cut parts 31 is inclined from the circumferential direction to form a part that is obliquely angled at the front end. According to the second and third examples, the second peak SB of the force generated by the solenoid becomes smoother, rounded and wider, so that the force created by the solenoid increases and decreases more evenly as the door 9 of the freezer is moved. Thus, the second and third examples are suitable for the design of the freezer, in which the retraction springs slowly and smoothly come out, for example, out of engagement with the elements of the movable guide mechanisms 11.

10 shows a front auxiliary yoke 19 * in a fourth example. In this example, a pair of protrusion edges 31C are formed on each of the cut portions 31 of the front auxiliary yoke, which is otherwise similar to the yoke, for example, in the first example, to form the first, second, and third peaks of force exerted by the solenoid, respectively, using trailing edges 19A, the edges 31C of the protrusions and the leading edges 31B. 11 depicts a front auxiliary yoke 19 ** in the fifth example, which consists of three separate elements 49A, 49B and 49C, and two of them 49A and 49B have slots 51 to form quasi-cut out portions 31 containing protrusion edges 31C when three separate element 49A, 49B and 49C are essentially located next to each other. The front auxiliary yoke 19 ** in this example is otherwise similar to the yoke of the fourth example.

12 depicts the front auxiliary yoke 59 in the sixth example, which consists of two separate cylindrical rings 59A and 59B, which differ from each other by the wall thickness and are located next to each other. In detail, the thickness of the front ring 59A is greater than the thickness of the rear ring 59B, and an annular stepped portion 59C is formed between them. According to this design, a second peak SA of the force generated by the solenoid is formed on the stepped portion 59C. 13 depicts a front auxiliary yoke 59 'in a seventh example, which consists of two separate cylindrical rings 59A' and 59B ', which are distinguished from each other by magnetic permeability and are located next to each other. In detail, the magnetic permeability of the front ring 59A 'is greater than the magnetic permeability of the rear ring 59B'. Thus, many peaks are formed due to the force generated by the solenoid.

The door opener in each of the examples and embodiments can be used not only for the sliding door of the refrigerator, as specifically explained above, but also for the swing door of the refrigerator, to provide two or three peaks of force generated by the solenoid. For example, two peaks are designed, respectively, to disengage the door gasket 6 containing the magnet, and to overcome the force to close the door of the mechanism for spontaneous closing of the door, which is designed to prevent the door from being half closed. For casement doors in the form of a French door, a second peak in the force generated by the solenoid can be set for the rotational movement of the central element abutting against the gasket on the inner edge of any of the casement door pair.

Claims (9)

1. A refrigerator comprising a door (9) that closes a front opening of a chamber (5) for storing products; a switch (16) that is actuated by the user; and a device (15) for opening the door, which is located in the main body (1) of the refrigerator so as to face the inner surface of the door (9), and is actuated by a switch (16) so as to open the door (9); and the device (15) for opening the door contains a solenoid (18) formed from a spiral-wound wire located around the tube (21); a core (22), which moves axially in the tube (21) under the action of the attracting force created by the solenoid (18); an ejector rod (23) that is fixed to the front end of the core (22) and pushes the door (9) forward to open it, in which the solenoid (18) has two or more peaks on the curve of the generated force, depending on the distance of movement of the core (22) ) 2. The refrigerator according to claim 1, in which the two peaks on the curve of the generated force are respectively set to disengage the gasket (6) of the door containing the magnet from the main body (1), and to overcome the force directed backward, the mechanism for spontaneous closing of the door , which is designed to prevent the door from being half closed at the moment the door is closed (9). 3. The refrigerator according to claim 1 or 2, in which the core (22) is arranged to move in the tube (21) and is designed so as not to collide with a stationary attractor, the solenoid (18) is equipped with front and rear cylindrical auxiliary yokes (19) , 20), and the front auxiliary yoke (19) is made for the formation of these two or more peaks on the curve. 4. The refrigerator according to claim 3, in which the front auxiliary yoke (19) contains a cut-out part (31) with a recess in the axial direction from the rear end of the front auxiliary yoke (19), which is used to form these two peaks on the curve. 5. The refrigerator according to claim 4, in which the cut out part (31) is made in the form of a rectangle having two angled parts at the front end. 6. The refrigerator according to claim 4, in which the front edge (31B) of the cut out part (31) is inclined from the direction along the circumference or made in the form of an arc of a circle, or rounded. 7. The refrigerator according to claim 3, in which the front auxiliary yoke (19) contains a cut part (31) with a recess in the axial direction from the rear end of the front auxiliary yoke (19), the cut part (31) contains one or more edges (31C) protrusions for the formation of one or more peaks on the curve of the force created by the solenoid (18). 8. The refrigerator according to claim 3, in which the wall thickness of the front auxiliary yoke (19) is changed in the axial direction so as to form these two or more peaks. 9. The refrigerator according to claim 3, in which the front auxiliary yoke (19) contains two or more parts that are magnetic permeability and are located next to the axial direction so as to form these two or more peaks.

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