RU155084U1 - BOTTLE HEATER WITH CONTROL MECHANISM FOR ROTARY INPUT DEVICE - Google Patents

Abstract

1. A bottle heater (1) comprising a rotatable control handle (11), a thermostat (3) having a rotary input device (4), and a control mechanism comprising a flexible connection (12) that rotationally connects the control handle to rotary input device, so that the axis (X-X) of rotation of the control handle can be placed parallel to the axis (YY) of rotation of the rotary input device. 2. The heater (1) according to claim 1, wherein the flexible connection (12) comprises a first cartridge (13) that is connected to a control handle (11), a second cartridge (14) that is connected to an input rotary device (4), and a connecting an element (15) which rotatably connects the first and second cartridges. 3. The heater (1) according to claim 2, in which the connecting element (15) is connected to the first cartridge (13) with the possibility of rotation around the first axis of rotation (Z1-Z1) and the second axis of rotation (Z2-Z2), which is perpendicular to the first rotation axis, and connected to the second cartridge (14) with the possibility of rotation around the third axis of rotation (Z3-Z3) and the fourth axis of rotation (Z4-Z4), which is perpendicular to the third axis of rotation. 4. The heater (1) according to claim 3, in which the first cartridge (13) contains a first recess (13B), while the second cartridge (14) contains a second recess (14B), and the connecting element (15) contains distal ends that are made with the possibility of placement in the first and second recesses, respectively. 5. The heater (1) according to claim 3 or 4, in which one of the elements is either the first cartridge (13) or the first end of the connecting element (15) contains at least one groove (13C), while the other of the element�

Description

FIELD OF THE INVENTION This useful model relates to a bottle warmer comprising a thermostat having a rotary input device and a control mechanism for a rotary input device of the thermostat.

BACKGROUND OF THE INVENTION

Bottle warmers are widely used to heat bottles with milk for use by infants. Known bottle warmers contain a heating element that is controlled by a thermostat. The thermostat includes a control knob that is connected to the rotary thermostat input device via a rigid rod so that the temperature of the bottle warmer can be adjusted to the desired temperature by turning the control knob. It is important that the temperature of the bottle warmer can be precisely controlled so that the milk is heated and maintained at a temperature that is safe for infants to consume.

ESSENCE OF A USEFUL MODEL

It has been found that factors such as manufacturing tolerances, thermal expansion or deviation of the constituent elements of bottle warmers known in the art can lead to misalignment of the axis of rotation of the rotary input device and the axis of rotation of the control handle when such bottle warmers are assembled. This can cause a radial force to be applied to the rigid shaft, which results in a force applied to the rotary input device, which can change the temperature setting of the thermostat. Consequently, milk may not be heated to a temperature selected by the user, but instead may be heated to a temperature that is unsafe for use by infants. Moreover, misalignment of the rotation axes of the rotary input device and the control handle may result in the control handle being positioned such that a gap arises between the control handle and the bottle warmer body. This gap can collect dirt and foreign particles unhygienically.

The purpose of the utility model is to provide a bottle warmer having a control mechanism that substantially reduces or overcomes the problems mentioned above.

According to this utility model, a bottle warmer is provided comprising a rotatable control knob, a thermostat having a rotary input device, and a control mechanism comprising a flexible connection that rotatably connects the control knob to the rotary input device such that the axis of rotation control knobs may be placed parallel to the axis of rotation of the rotary input device. Therefore, the control handle can be easily and reliably connected to the rotary input device, even if factors such as manufacturing tolerances, thermal expansion or deviation of the constituent elements of the control mechanism result in misalignment of the axes of the rotary input device and the control handle.

In one embodiment, the flexible connection comprises a first cartridge that is connected to a control handle, a second cartridge that is connected to a rotary input device, and a connecting element that rotatably connects the first and second cartridges. The rotary movement of the connecting element relative to the first and second cartridges allows misaligned alignment of the control handle and the rotary input device. In addition, the control handle, the connecting element and the first and second cartridges can be connected to each other to form a control mechanism before connecting the control mechanism to the rotary input device, thereby increasing the ease of manufacture. In one embodiment, the connecting member is pivotally coupled to a first cartridge about a first pivot axis and a second pivot axis that is perpendicular to the first pivot axis, and pivotally coupled to a second cartridge about a third pivot axis and a fourth pivot axis, which is perpendicular to the third axis of rotation. The first cartridge can be made as a unit with the control handle so that the assembly of the control mechanism is simplified.

In one embodiment, the first cartridge comprises a first recess, and the second cartridge contains a second recess, and the connecting element comprises distal ends that are arranged to fit into the first and second recesses, respectively. Therefore, the distal ends of the connecting element are limited from moving in the radial direction of the rotary input device and the control handle by means of a portion of the first and second cartridges on the periphery of each recess.

In one embodiment, one of the first cartridge and the first end of the connecting element contains at least one groove, and the other one of the first cartridge and the first end of the connecting element contains a pair of protrusions that are designed to slide into such or every groove. In one embodiment, one of the second cartridge and the second end of the connecting element contains at least one groove, and the other of the second cartridge and the second end of the connecting element contains a pair of protrusions that are configured to slide into one or each groove. The sliding engagement of the protrusions in this or each groove allows the control handle to slide relative to the rotary input device in its axial direction so that the distance between them can be adjusted.

In one embodiment, the flexible joint comprises a dual cardan joint. It has been found that a double gimbal allows a relatively large radial displacement between the rotational axes of the control handle and the rotary input device, is relatively inexpensive to manufacture, and can be made using injection molding and is thus relatively easy to manufacture in large volumes. Moreover, the dual cardan joint can provide high torsional rigidity so that a predetermined rotation of the control knob will result in a similarly sized and predictable rotation of the rotary input device.

The control mechanism makes it possible to connect the control knob to the rotary input device of the thermostat so that the rotation axes of the rotary input device and the control knobs are misaligned and non-parallel, without applying a radial force to the rotary input device, which can cause a change in the temperature setting of the thermostat. Therefore, a bias error in the relationship between the rotational position of the control knob and the temperature setting of the bottle warmer is excluded.

In one embodiment, the flexible joint comprises heat-insulating material for insulating the control handle from the rotatable thermostat input device. Therefore, when the bottle warmer is heated, the heat-insulating material of the flexible joint will limit the transfer of heat generated to the control handle. Therefore, the risk of burning the user when he touches the control handle is reduced.

In one embodiment, the bottle warmer comprises a housing, and the control handle is arranged to fit close to the housing. The housing may comprise a portion of the circular wall, and the control handle may comprise a surface that is arranged to fit closely to the portion of the circular wall. Consequently, the control knob is prevented from moving in a radial direction relative to the housing. This prevents a gap between the control handle and the bottle warmer body, which would otherwise collect dirt and foreign particles in an unhygienic manner. Moreover, limiting the control knob in the radial direction relative to the housing prevents damage to the rotary thermostat input device if the user accidentally applies a radial force to the control knob.

These and other aspects of the utility model will be apparent from and will be explained with reference to the embodiments described hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the utility model will now be described only as an example with reference to the accompanying drawings, in which:

Figure 1 is a perspective view of a known bottle warmer;

Figure 2 is a perspective view with a neckline of a bottle warmer of Figure 1;

Figure 3 is a top sectional view of the bottle warmer of Figure 1;

Figure 4 is a perspective view of a bottle warmer containing a control mechanism in accordance with an embodiment of the utility model;

Figure 5 is a perspective view with a cutout of the bottle warmer of Figure 4;

Figure 6 is an alternative perspective view with a cutout of the bottle warmer of Figure 4;

Figure 7 is a perspective view with exploded view of the control mechanism of the heater for the bottles of Figure 4;

Figure 8 is an assembled perspective view of the control mechanism of the bottle warmer of Figure 4;

Figure 9 is a sectional side view of the bottle warmer of Figure 4; and

Figure 10 is a top sectional view of the bottle warmer of Figure 4.

DETAILED DESCRIPTION OF EMBODIMENTS

Referring now to Figures 1-3, a known bottle warmer 1 is shown. The bottle heater comprises a housing 2 and a thermostat 3. The thermostat 3 is mounted inside the housing 2 and includes a rotary input device 4 that is rotatable to control the temperature of the bottle heater 1.

The housing 2 of the bottle heater 1 comprises a first housing portion 5 and a second housing portion 6. The first semicircular wall portion 5A extends from the outer surface of the first housing portion 5 and the semicircular wall portion 6A extends from the outer surface of the second housing portion 6. First housing portion 5 and the second casing section 6 are connected to each other to form the casing 2 so that the first semicircular wall section 5A and the second semicircular wall section 6A are mated to form a cr corner wall.

The first body portion 5 comprises an inner wall 7, which has a semicircular indentation recess 7A. The second casing section 6 comprises an inner wall (not shown) that has a semicircular indentation (not shown) that is aligned with a semicircular recess 7A of the inner wall 7 of the first casing 5 to form a round hole (not shown) when the first casing section 5 and the second case section 6 are connected to each other.

The thermostat 3 includes a control mechanism 1A, which has a control handle 8, which is integral with the tubular element 8A and aligned with it coaxially. The tubular element 8A is connected to the rotary input device 4 of the thermostat 3 by means of a rigid rod 9. The tubular element 8A comprises a section 8B of reduced diameter having a flange portion 8C extending radially from it. To mount the control handle 8 on the bottle heater 1, the reduced diameter section 8B of the tubular element 8A is placed in a semicircular recess 7A in the inner wall 7 of the first body section 5. The first body section 5 and the second body section 6 are then connected to each other to form a body 2 so that the reduced diameter section 8B is placed in a circular hole formed between the inner walls 7 of the first body portion 5a and the second body portion 6, and the flange portion 8C of the tubular electric element 8A is placed opposite the inner surfaces of the inner walls 7. Therefore, if the control knob 8 is forced to move axially from the housing 2, in this case, the flange portion 8C is forced to move to the inner walls 7, thereby preventing the control knob 8 from being separated from the housing 2.

The thermostat 3 is mounted inside the first case section 5 on a bracket (not shown) until the first case section 5 and the second case section 6 are connected. The thermostat 3 comprises a base 3A with a holding plate 3B and a control plate 3C extending from it. The screw actuator 4A is rotatably mounted on the holding plate 3B and is forced to move toward the control plate 3C to apply bending force thereto. The amount of bending force applied to the control plate 3C controls the temperature of the bottle warmer 1. The screw actuator 4A is connected to the rotary input device 4 so that when the rotary input device 4 is rotated, the screw actuator 4A also rotates and thus moves axially to or from the control plate 3C, depending on the direction of rotation of the rotary device 4 input, thereby changing the bending force applied to the control plate 3C, and thus the temperature of the bottle warmer 1. Therefore, the temperature of the bottle heater 1 can be controlled by rotating the control knob 8, which is rotatably connected to the rotary input device 4 by means of a rigid rod 9, wherein each angular position of the control handle 8 relative to the housing 2 represents a different temperature of the bottle heater 1. The relationship between the rotational position of the control handle 8 relative to the housing 2 and the temperature of the bottle heater 1 is graphically indicated to the user by aligning a mark (not shown) on the control handle 8 with a visual indicator 2B provided on the housing 2 around the circular wall portion 2A.

When the bottle warmer 1 is assembled, it is desirable that the axis of rotation of the rotary input device 4 is aligned coaxially with the central axis of the round hole in the housing 2. However, factors such as manufacturing tolerances, thermal expansion of the various components of the bottle warmer 1, or bracket deflection (not shown), which mounts the thermostat 3 in the housing 2, can lead to misalignment of the axes of the rotary input device 4 and the round hole.

If the rotation axis of the rotary input device 4 and the central axis of the round hole are not coaxial, in this case, when the control handle 8 is mounted on the rotary input device 4 by means of a rigid rod 9, the reduced diameter section 8B may be forced to move to the edge portion of the circular hole in the housing 2 This may cause the housing 2 to exert a force on the reduced diameter section 8B and, therefore, the rigid shaft 9 in its radial direction, causing a bending force to be applied to the holding plate 3B, which causes the holding plate 3B, and thus the screw actuator 4A, to move to the control plate 3C. This is undesirable since the resulting bending of the control plate 3C would cause a change in the temperature setting of the thermostat 3, thus a bias error is introduced into the relationship between the angular position of the control handle 8 and the temperature of the bottle heater 1. Therefore, if the user turned the control knob 8 to align the label (not shown) of the control knob 8 with a visual indicator 2B on the housing 2 to select the temperature level of the bottle heater 1, the resulting temperature of the bottle heater 1 would be different from the temperature shown by the visual indicator 2B. This can be dangerous, as the bottle warmer 1 can heat the milk contained in the bottle, which is heated to a temperature that is not safe for consumption by the infant. In addition, the rigid rod 9, prompted to move to the edge of the circular hole in the housing 2, can lead to increased friction between the control handle 8 and the housing 2, which can lead to excessive force required to rotate the control handle 8.

In order to eliminate the radial force exerted on the rigid rod 9 and, therefore, the temperature offset error introduced if the rotation axis of the rotary input device 4 and the central axis of the circular hole in the housing 2 are misaligned, one solution is to increase the diameter of the circular hole. In this configuration, even if there is a large displacement between the axis of rotation of the rotary input device 4 and the central axis of the round hole, the reduced diameter section 8B of the tubular member 8A will not be prompted to move to the edge of the round hole in the housing 2. Therefore, the housing 2 will not be applied the radial force to the rigid rod 9, and thus the holding plate 3B of the thermostat 3 will not bend, and thus, the temperature offset error will not be introduced. However, such a configuration would result in a control handle 8 that is free to radially move the rigid rod 9, and therefore, the control handle 8 may stagger when rotated by the user. In addition, a gap G may be formed between the control handle 8 and the housing 2, which is ugly and can unhygienically collect dirt and foreign particles. Moreover, the gap G between the control handle 8 and the housing 2 may result in improper alignment of the mark of the control handle 8 with the visual indicator 2B provided on the housing 2, which may lead to incorrect display of the temperature of the bottle heater 1 to the user.

Referring now to Figures 4-9, a bottle warmer 10 is shown in accordance with an embodiment of the utility model. Bottle warmer 10 comprises a housing 2 and a thermostat 3, which have some features similar to those described with respect to the known bottle warmer 1 described above, with the same features retaining the same reference position. The thermostat 3 is mounted inside the housing 2 and contains a rotary input device 4, which is rotary to regulate the temperature of the heater 10 for bottles.

The thermostat 3 includes a control mechanism 10A, which has a control knob 11 that is connected to the rotary input device 4 of the thermostat 3 by means of a flexible connection 12. The flexible connection 12 contains a double cardan connection, which includes a first cartridge 13, a second cartridge 14 and a connecting element 15 The first cartridge 13 is made integrally with the control handle 11 and aligned coaxially with the axis of rotation XX of the control handle 11. The second cartridge 14 is mounted on the rotary input device 4 by means of adhesive and aligned along the Y-Y axis of rotation of the rotary input device 4. The first cartridge 13 comprises a tubular wall 13A with a recess 13B formed therein. Similarly, the second cartridge 14 comprises a tubular wall 14A with a recess 14B formed therein. The first pair of grooves 13C is formed in diametrically opposite portions of the tubular wall 13A of the first cartridge 13 at its end, which is distal relative to the control handle 11. A second pair of slots 14C is formed in diametrically opposite portions of the tubular wall 14A of the second cartridge 14 at its end, which is distal relative to the rotary device 4 of the input 4.

The connecting element 15 comprises an elongated element 15A with a first pair of protrusions 15B and a second pair of protrusions 15C. The first pair of protrusions 15B extends from opposite sides of the elongated member 15A and is placed at its first end. A second pair of protrusions 15C extends from opposite sides of the elongated member 15A at its second end distal to the first end.

As in the case of the known bottle heater 1 described above, the case 2 of the bottle heater 10 of the presently described embodiment of the utility model comprises a first body portion 5 and a second body portion 6. In addition, the housing 2 comprises a first semicircular wall portion 5A and a second semicircular wall portion 6A that mates to form a circular wall portion 2A when the first cabinet portion 5 and the second cabinet portion 6 are connected to form the housing 2. The first cabinet portion 5 with holds the inner wall 7, which has a semicircular indentation recess 7A. The second casing section 6 comprises an inner wall (not shown) that has a semicircular indentation (not shown) that is aligned with a semicircular recess 7A of the inner wall 7 of the first casing 5 to form a round hole (not shown) when the first casing section 5 and the second case section 6 are connected to each other.

The control handle 11 comprises an inner rib 11A, which is adapted to be placed on the inner surface of the circular wall portion 2A when the control handle 11 is mounted on the bottle warmer 10. The interaction between the inner rib 11A and the circular wall portion 2A allows the control handle 11 to rotate relative to the housing 2 about the rotation axis X-X of the control handle 11, while limiting the control handle 11 from moving relative to the housing 2 in the radial direction of the control handle 11.

The first cartridge 13 of the flexible joint 12 comprises a section 16 of reduced diameter having a flange portion 16A extending radially from it. When the control handle 11 is mounted on the bottle warmer 10, the reduced diameter section 16 of the first cartridge 13 is placed in a circular hole formed in the housing 2, so that the control handle 11 is supported by the housing 2 in the radial direction of the control handle 11. The curved outer surface of the reduced diameter section 16 is placed close to the curved surfaces of the inner walls 7 on the periphery of the circular hole to prevent radial movement of the control handle 11 relative to the housing 2. In addition, when the control handle 11 is mounted on the housing 2, the flange portion 16A of the first cartridge 13 is placed on the inner surface of each of the inner walls 7. Therefore, if the control handle 11 is forced to move axially from the housing, then the flange The core portion 16A is forced to move toward the inner walls 7, and thus, the handle 11 is separated from the housing 2.

The limitation of the control handle 11 in the radial and axial directions relative to the housing 2, prevents the formation of a gap between the control handle 11 and the housing 2. Preventing a gap between the control handle 11 and the housing 2 is desirable, as it prevents the collection of dirt and foreign particles between them, which may to be unhygienic. In addition, maintaining the control handle 11 in its axial and radial directions prevents damage to the rotary input device 4 of the thermostat 3 if the user accidentally applies a radial or axial force to the control handle 11.

When the bottle warmer 10 is assembled, the thermostat 3 is mounted inside the first body portion 5 on a bracket (not shown). The first end of the elongated member 15A is then housed in a recess 13B in the first cartridge 13, which is connected to the thermostat 3, so that the first pair of protrusions 15B is slidable in the first pair of grooves 13C. The control handle 11 is then mounted on the housing 2 in the manner described above, so that the inner edge 11A of the control handle 11 is placed close to the inner surface of the circular wall portion 2A. When the control handle 11 is mounted on the housing 2, the second end of the elongated element 15A is placed in the recess 14B of the second cartridge 14, which is connected to the control handle 11, so that the second pair of protrusions 15C is slidably placed in the second pair of grooves 14C.

Since the first pair of protrusions 15B is placed by the first pair of grooves 13C, rotation of the first cartridge 13 will cause its tubular wall 13A to exert a force on the first pair of protrusions 15B so that the connecting member 15 rotates. This will cause a second pair of protrusions 15C to apply force to the tubular wall 14A of the second cartridge 14 so that the second cartridge 14 rotates. Consequently, the flexible connection 12 rotatably connects the control knob 11 with the rotary input device 4 of the thermostat 3, and thus the temperature of the bottle heater 10 can be adjusted by rotating the control knob 11, with each angular position of the control knob 11 representing a different temperature of the heater 10 for bottles. The relationship between the rotational position of the control handle 11 relative to the housing 2 and the temperature of the bottle heater 10 is graphically indicated to the user by aligning the mark 11B on the control handle 11 with a visual indicator 2B provided on the housing 2 around the circular wall portion 2A.

The first pair of protrusions 15B of the connecting member 15 is rotatable about their central axis in the first pair of grooves 13C so that the connecting member 15 is rotatable relative to the first cartridge 13 about the first rotation axis Z1-Z1. In addition, the first pair of protrusions 15B is able to slide in the first pair of grooves 13C so that the connecting member 15 is rotatable relative to the first cartridge 13 about the second axis of rotation Z2-Z2, which is perpendicular to the first axis of rotation Z1-Z1. Similarly, the second pair of protrusions 15C of the connecting member 15 is rotatable about their central axis in the second pair of slots 14C so that the connecting member 15 is rotatable relative to the second cartridge 14 around the third rotation axis Z3-Z3. In addition, the second pair of protrusions 15C is able to slide in the second pair of grooves 14C so that the connecting member 15 is rotatable relative to the second cartridge 14 around the fourth axis of rotation Z4-Z4, which is perpendicular to the third axis of rotation Z3-Z3.

The first pivot axis Z1-Z1 and the second pivot axis Z2-Z2 allow the connecting member 15 to rotate with the first chuck 13, and thus the control handle 11, without requiring parallel or coaxial alignment of the axis of rotation of the connecting member 15 with the axis of rotation XX of the handle 11 management. Similarly, the third pivot axis Z3-Z3 and the fourth pivot axis Z4-Z4 allow the connecting member 15 to rotate with the second cartridge 14, and thus with the rotary input device 4, without requiring parallel or coaxial alignment of the axis of rotation of the connecting member 15 s the axis of rotation YY of the rotary input device 4. Therefore, the flexible connection 12 between the control handle 11 and the input rotary device 4 enables the control handle 11 to be connected to the input rotary device 4 without the need for coaxial alignment of the axis of rotation X-X of the control handle 11 with the rotation axis Y-Y of the rotary input device 4.

When the thermostat 3 is mounted on the first body portion 5 during assembly of the bottle warmer 10, the rotation axis YY of the rotary input device 4 can be positioned so that it is not coaxial with the central axis of the round hole in the housing 2. This deviation may be due to, for example , manufacturing tolerances, thermal expansion of the various constituent elements of the bottle heater 10 or the deflection of the bracket (not shown) that holds the thermostat 3 in place in the housing 2. However, unlike the hard The rod 9 of the known bottle heater 1 described above, the flexible connection 12 of the bottle heater 10 of the presently described embodiment of the utility model enables the control handle 11 to be mounted on the rotary input device 4 so that the rotation axis XX of the control handle 11 and the axis YY the rotations of the input rotary device 4 are shifted from each other by a radial displacement R. This means that the control handle 11 can be mounted on the housing 2 so that the section 16 of a reduced diameter ra is placed close to the curved surfaces of the inner walls 7 on the periphery of the circular hole to prevent radial movement of the control handle 11, without applying a radial force to the casing 2 of the reduced diameter section 16. Therefore, the retaining plate 3B does not bend towards the control plate 3C of the thermostat 3, and thus, the thermostat 3 mounted on the housing 2 so that the rotation axis YY of the rotary input device 4 is not coaxial with the central axis of the circular hole to bias errors in the relationship between the rotational position of the control handle 11 and the temperature of the bottle heater 10. In addition, the control handle 11 can be mounted on the housing 2 so that the inner rib 11A is placed close to the inner surface of the circular wall portion 2A, and a gap is not formed between the control handle 11 and the housing 2, thereby preventing dirt and foreign particles from collecting between the housing 2 and control knob 11.

It should be understood that “flexible connection” refers to any connection capable of rotationally connecting the control handle 11 to the rotary input device 4, without requiring that the rotation axis XX of the control handle 11 and the rotation axis YY of the rotary input device 4 be parallel and / or coaxially aligned. Although in the above-described embodiments, the flexible joint 12 comprises a double cardan joint, in alternative embodiments (not shown) the flexible joint 12 may comprise other types of joint that enable the non-parallel rotary joint of the control handle 11 and the rotary input device 4. Examples of such flexible joints include a cardan joint, a Schmitt joint, a universal joint, an Oldham coupling, a Röpppp joint, or a Thompson joint. It was found that these compounds have high torsional rigidity and, therefore, minimize the error in the relationship between the rotational position of the control handle 11 and the temperature of the bottle heater 10.

In one embodiment, the flexible joint 12 comprises a heat-insulating material, for example polystyrene, fiberglass or cellulose, so that heat transfer from the body 2 of the bottle warmer 10 to the control handle 11 is reduced.

Although in the above embodiment, the first pair of protrusions 15B and the second pair of protrusions 15C are provided on the elongate member 15A, and the first pair of grooves 13C and the second pair of grooves 14C are provided on the first cartridge 13 and second cartridge 14, respectively, in an alternative embodiment (not shown ) the first and second pairs of protrusions are provided on the first and second cartridges, respectively, and the first and second pairs of grooves are provided on the elongated element.

In the above embodiments, the flexible joint 12 comprises a double cardan joint having a first pair of protrusions 15B and a second pair of protrusions 15C, which are respectively arranged in the first pair of grooves 13C and the second pair of grooves 14C to enable the elongate member 15A to rotate to the first cartridge 13 around the first pivot axis Z1-Z1 and the second pivot axis Z2-Z2, and pivotally connected to the second cartridge 14 about the third pivot axis Z3-Z3 and the fourth pivot axis Z4-Z4. The sliding engagement of the first pair of protrusions 15B and the second pair of protrusions 15C in the first pair of grooves 13C and the second pair of grooves 14C, respectively, allows the distance between the first cartridge 13 and the second cartridge 14 in the axial direction of the rotary input device 4 to be adjusted. Therefore, the control handle 11 can be moved towards the housing 2 so that there is no gap between them, regardless of the radial displacement R between the axis of rotation X-X of the control handle 11 and the axis of rotation Y-Y of the rotary input device 4. In addition, the above configuration of the flexible joint 12 is inexpensive, can be manufactured using injection molding, and thus is relatively easy to manufacture in large volumes and allows a relatively large radial displacement R. Moreover, the flexible joint 12 described above has a high torsional rigidity and, therefore, a predetermined rotation of the control handle 11 will result in a similar and predictable rotation of the input rotary device 4, and thus, the flexible joint 12 reduces the error in the relationship between the rotational position of the control handle 11 and the temperature of the bottle warmer 10.

The pivoting movement of the connecting member 15 relative to the first cartridge 13 around the first rotation axis Z1-Z1 and the second rotation axis Z2-Z2 and relative to the second cartridge 14 about the third rotation axis Z3-Z3 and the fourth rotation axis Z4-Z4 can be achieved using an alternative dual-gimbal design compounds relative to the structure described above. In one such embodiment (not shown), the first cartridge is pivotally coupled to a first intermediate member about a first pivot axis that is perpendicular to the axis of rotation of the control handle. The first end of the connecting element is rotatably connected to the first intermediate element about a second axis of rotation, which is perpendicular to the first axis of rotation and the axis of rotation of the control handle. The second end of the connecting element is rotatably connected to the second intermediate element about a third axis of rotation, which is perpendicular to the axis of rotation of the rotary input device. The second cartridge is rotatably connected to the second intermediate element about a fourth axis of rotation, which is perpendicular to the third axis of rotation and the axis of rotation of the rotary input device.

In other embodiments (not shown), the flexible joint comprises a spring or stretch of elastic material that connects the first and second cartridges and can be bent to allow misaligned, non-parallel alignment of the rotational axes of the control handle and rotary input device. Such flexible joints can be inexpensive to manufacture, although they have less torsional rigidity and, thus, can lead to errors between the rotational position of the control handle and the temperature of the bottle warmer.

Although in the above embodiments, the first cartridge 13 is integral with the control handle 11, in alternative embodiments (not shown) the first cartridge 13 is mounted on the control handle 11 by adhesive or snap fit or interference fit. Although in the above embodiment, the second cartridge 14 is installed on the rotary input device 4 using adhesive in alternative embodiments (not shown), the second cartridge 14 is installed on the rotary input device 4 by means of a snap fit or interference fit, or as a unit with him.

It should be understood that the term “comprising” does not exclude other elements or steps, and that the singular does not exclude a plurality. A single node can perform the functions of several objects listed in the utility model formula. The simple fact that certain measures are set forth in mutually different dependent claims of a utility model does not mean that a combination of these measures cannot be used as an advantage. Any reference positions in the utility model formula should not be construed as limiting the scope of the utility model formula.

Although the utility model formula has been formulated in this application for specific combinations of features, it should be understood that the scope of the description of the present utility model also includes any new features or any new feature combinations disclosed herein, either explicitly or implicitly, or any generalization thereof. regardless of whether or not it refers to the same disclosure, as currently stated in any paragraph of the utility model formula, and whether it solves any or all of the same technical problems or not, it solves mye primary disclosure. Applicants are thus cautioned that a new utility model formula may be formulated for such features and / or combinations of features during consideration of this application or any additional application arising from it.

Claims (11)

1. A bottle heater (1) comprising a rotatable control handle (11), a thermostat (3) having a rotary input device (4), and a control mechanism comprising a flexible connection (12) that rotationally connects the control handle to rotary input device, so that the axis (X-X) of rotation of the control handle can be placed parallel to the axis (YY) of rotation of the rotary input device. 2. The heater (1) according to claim 1, wherein the flexible connection (12) comprises a first cartridge (13) that is connected to a control handle (11), a second cartridge (14) that is connected to an input rotary device (4), and a connecting element (15) which rotatably connects the first and second cartridges. 3. The heater (1) according to claim 2, in which the connecting element (15) is connected to the first cartridge (13) with the possibility of rotation around the first axis of rotation (Z1-Z1) and the second axis of rotation (Z2-Z2), which is perpendicular relative to the first axis of rotation, and connected to the second cartridge (14) with the possibility of rotation around the third axis of rotation (Z3-Z3) and the fourth axis of rotation (Z4-Z4), which is perpendicular to the third axis of rotation. 4. The heater (1) according to claim 3, in which the first cartridge (13) contains a first recess (13B), while the second cartridge (14) contains a second recess (14B), and the connecting element (15) contains distal ends that made with the possibility of placement in the first and second recesses, respectively. 5. The heater (1) according to claim 3 or 4, in which one of the elements is either the first cartridge (13) or the first end of the connecting element (15) contains at least one groove (13C), the other of elements - either the first cartridge or the first end of the connecting element contains a pair of protrusions (15B), which are designed to be placed with the possibility of sliding into one or each groove. 6. The heater (1) according to claim 3, in which one of the elements is either a second cartridge (14) or the second end of the connecting element (15) contains at least one groove (14C), and the other of the elements either the second cartridge or the second end of the connecting element contains a pair of protrusions (15C), which are designed to be placed with the possibility of sliding into one or each groove. 7. The heater (1) according to claim 2, in which the first cartridge (13) is made as a unit with the control handle (11). 8. The heater (1) according to claim 1, wherein the flexible joint (12) comprises a double cardan joint. 9. A heater (1) according to claim 1, wherein the flexible joint (12) comprises a heat insulating material. 10. The heater according to claim 1, comprising a housing (2), wherein the control handle (11) is configured to be placed close to the housing. 11. The heater according to claim 10, in which the housing (2) contains a section (2A) with a circular wall, while the control handle (11) contains a surface (11A), which is arranged to be placed close to the section with a circular wall.

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