CN213588464U - Freezing fat-reducing device - Google Patents

Abstract

The utility model provides a freezing fat device that subtracts, freezing fat device that subtracts includes: the refrigerator comprises a first refrigeration component, a first cold guide component, a second refrigeration component, a second cold guide component and a temperature detection component; the first refrigeration component is in heat conduction connection with the first cold conduction component, and the second refrigeration component is in heat conduction connection with the second cold conduction component; the second cold-conducting component is provided with a first inner cavity, the first inner cavity is used for accommodating a predetermined object, and the temperature detection component is used for detecting the skin surface temperature of the predetermined object; the temperature detection component is configured to obtain a preset temperature of a preset object based on refrigeration of the first refrigeration component; the second cooling component cools according to a preset power curve so as to maintain the skin surface temperature of the predetermined object at a preset temperature. The freezing effect can thereby be ensured and the risk of frostbite of the skin during the freezing process can be reduced.

Description

Freezing fat-reducing device

Technical Field

The utility model relates to the technical field of medical equipment, in particular to freezing fat reduction device.

Background

Traditional non-invasive treatments for removing excess fat include topical medications, weight loss medications, regular exercise, diet, or these treatments, which may be ineffective or even impossible in some cases. In addition, weight loss in selective regions of the human body is not generally achieved using a comprehensive or systemic method of weight loss. The non-invasiveness, effectiveness and selectivity of fat reduction by freezing can be utilized to solve the above disadvantages.

The refrigeration mode that is used for subcutaneous fat reduction at present is mostly semiconductor refrigeration, and semiconductor refrigeration has small, and the cooling is quick, control advantage such as easy, but because the characteristic of semiconductor self leads to, its cooling becomes slow under the circumstances of cold and hot face difference in temperature grow, in other words the difference in temperature of semiconductor hot side and cold side is big more, and the cooling is slow more, and this just causes semiconductor low temperature section cooling time to occupy the most of whole cooling time. On the other hand, the non-temperature-controllable freezing process may cause skin frostbite, and the temperature suitable for freezing and fat reduction of each person is different due to the difference of the physique of each person, which are the defects of the current products.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a freezing fat device that subtracts to solve the problem that current freezing fat device that subtracts exists.

In order to solve the technical problem, the utility model provides a freezing fat reduction device, it includes: the refrigerator comprises a first refrigeration component, a first cold guide component, a second refrigeration component, a second cold guide component and a temperature detection component;

the first refrigeration component is in heat conduction connection with the first cold conduction component, the second refrigeration component is in heat conduction connection with the second cold conduction component, and the first cold conduction component is arranged on the far end side of the second cold conduction component; the second cold-guiding component is provided with a first inner cavity used for accommodating a predetermined object, and the temperature detection component is used for detecting the skin surface temperature of the predetermined object;

the temperature detection part is configured to acquire a preset temperature of the predetermined object based on the refrigeration of the first refrigeration part; the second cooling component is configured to cool according to a preset power curve to maintain the skin surface temperature of the predetermined subject at the preset temperature.

Optionally, in the frozen fat reduction device, the first cold conducting part has a second inner cavity, and the second inner cavity is communicated with the first inner cavity and used for accommodating the predetermined object.

Optionally, the frozen fat reduction device further comprises a heat insulation sheet, and the heat insulation sheet is detachably arranged in the second inner cavity or the first inner cavity; the heat insulating sheet is configured to insulate the predetermined object from the second cold-conducting part in the process of being cooled by the first cooling part to obtain the preset temperature.

Optionally, in the fat reduction freezing device, the heat insulation sheet is further configured to remove the insulation of the predetermined object from the second cold guiding component after the preset temperature is obtained by the first cooling component.

Optionally, the freezing fat reduction device further comprises a negative pressure connection unit, and the negative pressure connection unit is communicated with the first inner cavity and used for connecting negative pressure to the first inner cavity.

Optionally, in the fat reducing device for freezing, the first refrigeration component includes a semiconductor refrigeration block or a heat exchange head, and the second refrigeration component includes a semiconductor refrigeration block or a heat exchange head.

Optionally, in the frozen fat reduction device, the first cold guide part and the second cold guide part are connected through a flexible material.

Optionally, in the frozen fat reduction device, the preset temperature is set according to an anti-jump point of the skin surface temperature of the predetermined subject or a predetermined safe temperature.

Optionally, in the frozen fat-reducing device, the first cooling part is configured to stop cooling after the preset temperature is obtained by cooling through the first cooling part.

Optionally, in the frozen fat-reducing device, the second cooling component is further configured to cool the second cooling component to pre-cool the second cooling guide component in the process of cooling by the first cooling component to obtain the preset temperature.

Optionally, in the freezing fat-reducing device, the power curve includes a first power section, a second power section and a third power section which are connected in sequence, and the second cooling component is configured to cool in the first power section, so that the second cold-conducting component precools and reduces to a standby temperature; refrigerating in the second power section to maintain the second cold conducting part at the standby temperature; cooling in the third power section to reduce the skin surface temperature of the predetermined subject; wherein the power of the second refrigeration component in the first power section is greater than the power of the second refrigeration component in the second power section; and the power of the second refrigeration component in the third power section is greater than the power of the second refrigeration component in the second power section.

In summary, the present invention provides a freezing fat-reducing device, wherein the freezing fat-reducing device comprises: the refrigerator comprises a first refrigeration component, a first cold guide component, a second refrigeration component, a second cold guide component and a temperature detection component; the first refrigeration component is in heat conduction connection with the first cold conduction component, the second refrigeration component is in heat conduction connection with the second cold conduction component, and the first cold conduction component is arranged on the far end side of the second cold conduction component; the second cold-guiding component is provided with a first inner cavity used for accommodating a predetermined object, and the temperature detection component is used for detecting the skin surface temperature of the predetermined object; the temperature detection part is configured to acquire a preset temperature of the predetermined object based on the refrigeration of the first refrigeration part; the second cooling component is configured to cool according to a preset power curve to maintain the skin surface temperature of the predetermined subject at the preset temperature.

With this configuration, by refrigerating the predetermined object by the first refrigerating part, a customized preset temperature of the predetermined object can be obtained, and the second refrigerating part is refrigerated according to a preset power curve so that the skin surface temperature of the predetermined object is maintained at the preset temperature, the refrigerating effect can be ensured, and the risk of frostbite on the skin during the refrigerating process can be reduced. In addition, the second refrigerating part refrigerates according to a preset power curve, and the treatment time can be shortened.

Drawings

Those skilled in the art will appreciate that the drawings are provided for a better understanding of the invention and do not constitute any limitation on the scope of the invention. Wherein:

fig. 1 is a schematic top view of a module of a frozen fat reduction device according to an embodiment of the present invention;

fig. 2 is a schematic side view of a module of a frozen fat reduction device according to an embodiment of the present invention;

fig. 3 is a schematic view of a cooling curve according to an embodiment of the present invention;

FIG. 4 is a schematic view of a cooling curve according to another embodiment of the present invention;

fig. 5 is a schematic view of a top view of a fat reduction freezer according to an embodiment of the present invention;

fig. 6 is a schematic front view of a freezing fat-reducing device according to an embodiment of the present invention;

fig. 7 is a schematic side view of a frozen fat reduction device according to an embodiment of the present invention;

fig. 8 is a schematic bottom view of a frozen fat reduction device according to an embodiment of the present invention.

In the drawings:

110 — a first refrigeration component; 120-a first cold-conducting part; 210-a second refrigeration component; 220-a second cold conducting part; 300-a negative pressure connection unit; p1 — first power segment; p2 — second power segment; p3-third power segment; p4-fourth power segment; p5-fifth power segment.

Detailed Description

To make the objects, advantages and features of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments. It is to be noted that the drawings are in simplified form and are not to scale, but rather are provided for the purpose of facilitating and distinctly claiming the embodiments of the present invention. Further, the structures illustrated in the drawings are often part of actual structures. In particular, the drawings may have different emphasis points and may sometimes be scaled differently.

As used in this application, the singular forms "a", "an" and "the" include plural referents, the term "or" is generally employed in a sense including "and/or," the terms "a", "an" and "the" are generally employed in a sense including "at least one", the terms "at least two" and "two or more" are generally employed in a sense including "two or more", and moreover, the terms "first", "second" and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or imply that there is a number of technical features being indicated. Thus, the features defined as "first", "second", "third" may explicitly or implicitly include one or at least two of such features, the term "proximal" generally being the end near the operator, the term "distal" generally being the end near the patient, i.e. near the skin to be treated cryogenically, the terms "end" and "other end" and "proximal" and "distal" generally referring to the corresponding two parts, which include not only the end points, the terms "mounted", "connected" and "connected" being understood broadly, e.g. as being either fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. Furthermore, as used in the present application, the disposition of an element with another element generally only means that there is a connection, coupling, fit, or drive relationship between the two elements, and the connection, coupling, fit, or drive between the two elements may be direct or indirect through intermediate elements, and is not to be understood as indicating or implying any spatial relationship between the two elements, i.e., an element may be in any orientation within, outside, above, below, or to one side of another element unless the content clearly dictates otherwise. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

The core idea of the utility model is to provide a freezing fat-reducing device to solve the problem that the existing freezing fat-reducing device exists.

The following description refers to the accompanying drawings.

Referring to fig. 1 to 8, fig. 1 is a schematic top view of a module of a freezing fat-reducing device according to an embodiment of the present invention; fig. 2 is a schematic side view of a module of a frozen fat reduction device according to an embodiment of the present invention; fig. 3 is a schematic view of a cooling curve according to an embodiment of the present invention; FIG. 4 is a schematic view of a cooling curve according to another embodiment of the present invention; fig. 5 is a schematic view of a top view of a fat reduction freezer according to an embodiment of the present invention; fig. 6 is a schematic front view of a freezing fat-reducing device according to an embodiment of the present invention; fig. 7 is a schematic side view of a frozen fat reduction device according to an embodiment of the present invention; fig. 8 is a schematic bottom view of a frozen fat reduction device according to an embodiment of the present invention.

As shown in fig. 1 and 2, an embodiment of the present invention provides a freezing fat-reducing device, which includes: a first cooling part 110, a first cold-conducting part 120, a second cooling part 210, a second cold-conducting part 220, and a temperature detecting part (not shown). The first cooling part 110 is in heat conduction connection with the first cold guiding part 120, the second cooling part 210 is in heat conduction connection with the second cold guiding part 220, and the first cold guiding part 120 is arranged at the far end side of the second cold guiding part 220; the second cold guiding member 220 has a first inner cavity for accommodating a predetermined subject, and the temperature detecting member is for detecting the skin surface temperature of the predetermined subject.

Fig. 5 to 8 show an exemplary embodiment of a frozen fat reduction device, which will be described below with a predetermined portion of a human body as a predetermined object. The cryo-lipid-lowering device has an axis perpendicular to the skin (perpendicular to the plane of the paper in fig. 5), and optionally, the first cold conducting member 120 has a second lumen in communication with the first lumen for receiving the predetermined subject. The axial height of the first cold guiding member 120 is smaller, so that the second inner cavity forms a flat shape. In the example shown in fig. 5 to 8, the first cooling element 120 has a generally oblong cross-section with an open distal end for placement on the skin such that the skin can be drawn into the second lumen from the open distal end. In other embodiments, the first cold-conducting part 120 can also be a plate, which directly abuts the skin without the second lumen. Optionally, the first cooling component 110 is attached to the distal end side of the first cold guiding component 120 and is in heat conduction connection with the first cold guiding component 120, for example, the first cooling component 110 is attached to the first cold guiding component 120 by heat conduction silicone grease, so as to achieve heat conduction connection. The first cooling member 110 may include, for example, a semiconductor cooling block or a heat exchange head, which enables cooling and transfers cooling to the skin through the first cold conduction member 120. In the example shown in fig. 5 to 8, the first cooling part 110 includes two heat exchange heads each having a coolant flow inlet and a coolant flow outlet, and the coolant can flow in the heat exchange heads to remove heat, thereby cooling. The specific structure of the heat exchange head, the type, flow rate and flow velocity of the cooling liquid, etc. can be reasonably set by those skilled in the art according to the prior art, and will not be further described herein. Of course, in other embodiments, the first cooling member 110 may also include a semiconductor cooling block.

The second cooling guide member 220 is disposed adjacent to the proximal side of the first cooling guide member 120, and the axial height of the second cooling guide member 220 is greater than the axial height of the first cooling guide member 120, so that the first lumen is formed in a cylindrical shape. Further, the first cold guiding member 120 and the second cold guiding member 220 are connected by a flexible material (e.g., a malleable material such as silicone). In the example shown in fig. 5 to 8, the second cooling guide member 220 has a generally oblong cross-section, and the second cooling guide member 220 preferably has a cross-section smaller than that of the first cooling guide member 120, and the distal end of the first lumen communicates with the proximal end of the second lumen. More preferably, the first cold guiding member 120 is coaxially arranged with the second cold guiding member 220. In practice, after being sucked into the second lumen, the skin can be further sucked into the first lumen from the junction of the first lumen and the second lumen. If the first cold conducting member 120 is a plate member, it has an inner hole through which skin is sucked into the first inner chamber. It should be noted that the shape of the first cold guiding member 120 and the second cold guiding member 220 in the present embodiment is not limited in particular, the oval cross-section in the above exemplary embodiment is only an example and should not be considered as a limitation to the shape of the first cold guiding member 120 and the second cold guiding member 220, and those skilled in the art can select other shapes such as oval, round, or rectangular with rounded corners according to the prior art.

Optionally, the second cooling component 210 is attached to a sidewall of the second cooling conducting component 220 in a radial direction or attached to a proximal side of the second cooling conducting component 220 in an axial direction, and is in heat-conducting connection with the second cooling conducting component 220. The second cooling member 210, like the first cooling member 110, may include a semiconductor cooling block or a heat exchange head, for example, to transfer cooling energy to the skin through the second cooling directing member 220. In the exemplary embodiment shown in fig. 5 to 8, the second cooling unit 210 includes two heat exchanging heads disposed opposite to each other, and please refer to the description of the first cooling unit 110, which is not repeated herein.

Optionally, the temperature detecting component is configured to obtain a preset temperature of the predetermined object based on the cooling of the first cooling component 110. Preferably, the preset temperature can be obtained by acquiring the change of the skin surface temperature of the predetermined object. Optionally, the temperature detecting component includes a first temperature detecting unit, and the first temperature detecting unit may include an external independent temperature sensor, or an additional temperature sensor integrally disposed in the second inner cavity and/or the first inner cavity, and is capable of detecting and acquiring a surface temperature of the skin, particularly a surface temperature of a portion of the skin that is sucked into the second inner cavity or the first inner cavity and is in contact with the first cold guiding component 120 or the second cold guiding component 220, respectively. In some embodiments, the temperature sensing component may include two temperature sensors for sensing the temperature of the skin surface drawn into the second lumen and the first lumen, respectively. In other embodiments, the temperature detection component may include only one temperature sensor, and the temperature sensor may be used to detect the skin surface temperature drawn into the second lumen and the first lumen, respectively. Optionally, the temperature detecting component further includes a second temperature detecting unit, which is capable of detecting and acquiring the temperatures of the first cold guiding component 120 and the second cold guiding component 220 (i.e. the temperature of the treatment surface), where the temperatures of the first cold guiding component 120 and the second cold guiding component 220 refer to the temperature of the end of the first cold guiding component 120 connected to the first cooling component 110 and the temperature of the end of the second cold guiding component 220 connected to the second cooling component 120, i.e. the temperatures of the first cooling component 110 and the second cooling component 120, respectively. In some embodiments, the skin surface temperature may be indirectly obtained by detecting the temperature of the treatment surface through the second temperature detection unit, unlike the first temperature detection unit which directly detects the skin surface temperature. Similarly, the second temperature detection unit may also include one or two temperature sensors, and the specific arrangement position and the temperature measurement form thereof are not limited.

Optionally, the freezing fat reduction device further includes a negative pressure connection unit 300, and the negative pressure connection unit 300 is communicated with the first inner cavity and is used for accessing a negative pressure to the first inner cavity. In some embodiments, the negative pressure connection unit 300 may be, for example, a negative pressure connection hole disposed at the proximal side of the second cold guiding member 220, and the negative pressure connection hole may be connected with the external negative pressure end through a connection pipe, so that the negative pressure may be provided in the first lumen, and the skin may be sucked into the first lumen. The negative pressure end can be an external vacuum pump or a negative pressure pipeline which is centrally provided by a building.

The temperature detection component is configured to acquire the change condition of the skin surface temperature of the predetermined object in the second inner cavity based on the refrigeration of the first refrigeration component 110, so as to obtain the preset temperature of the predetermined object; the second cooling component 210 is configured to cool according to a preset power curve to maintain the skin surface temperature of the predetermined subject at the preset temperature. The cooling of the first cooling component 110 can be regarded as a test cooling of the skin surface. The inventor finds that when the skin surface of a human body is cooled by freezing, the release of latent heat of the human body can cause the temperature on the skin surface to rebound. The rebound point of the temperature is used as the preset temperature of the freezing treatment, so that the safety and the effectiveness are better, and the skin can not be frostbitten. Different people have different latent heat release amounts, so that the preset temperature customized for the human body difference can be obtained through the trial cooling detection of the first cooling part 110 on the skin surface. In other embodiments, the preset temperature may be set according to a predetermined safe temperature in addition to the debounce point of the skin surface temperature of the predetermined subject. Specifically, the safe temperature is the temperature initially set by the freezing fat-reducing device, and in some cases, when latent heat is not detected, the bounce point of the skin temperature may not be obtained, and at this time, the preset temperature may be set to be the fixed safe temperature, so as to perform the next stage of the freezing treatment. Further, after the preset temperature is obtained, the skin is cooled to the preset temperature by the second refrigerating part 210 for treatment. Alternatively, the first temperature detection unit can be used for directly detecting to obtain the debounce point of the skin surface temperature, and the second temperature detection unit can be used for indirectly obtaining the debounce point of the skin surface temperature in a mode of detecting the temperature of the treatment surface.

With this configuration, a customized preset temperature of a predetermined subject can be obtained by a trial cooling detection of the skin surface temperature of the predetermined subject using the first cooling part 110, and the second cooling part cools according to a preset power curve so that the skin surface temperature of the predetermined subject is maintained at the preset temperature, so that the freezing effect can be secured and the risk of frostbite of the skin during the freezing process can be reduced. In addition, the second refrigerating part refrigerates according to a preset power curve, and the treatment time can be shortened.

Preferably, the frozen fat reduction device further comprises a heat insulation sheet (not shown), wherein the heat insulation sheet is detachably arranged in the second inner cavity or the first inner cavity; the heat insulating sheet is configured to insulate the predetermined object from the second cold guiding part 220 in the process of being cooled by the first cooling part 110 to obtain the preset temperature. Further, the heat insulating sheet is configured to remove the insulation of the predetermined object from the second cold guiding member 220 after the preset temperature is obtained by the first cooling member 110. As described above, the using method of the freezing fat-reducing device provided by the embodiment includes two stages, the first stage is a test cooling detection that the first cooling part 110 is used for cooling to obtain a preset temperature, so as to obtain the preset temperature of the predetermined object; the second stage is to perform a cryotherapy on the predetermined subject using the second cold guiding member 220 to maintain the skin surface temperature of the predetermined subject at the preset temperature. The thermal insulation sheet is configured to isolate the second cold guiding component 220 from the skin in the first stage, and during the test cooling detection in the first stage, the second cooling component 210 may also start cooling so as to pre-cool the second cold guiding component 220, while the skin is isolated from the second cold guiding component 220 by the thermal insulation sheet and is not affected by the second cold guiding component 220. After the first stage is completed, the heat insulation sheet can be removed, and the pre-cooled second cold guide component 220 can immediately start to perform freezing and cooling on the skin, so that the treatment time is effectively shortened. Optionally, the heat insulation sheet may be a sheet with a thermal conductivity less than 0.5, and may be removed from the second cavity or the first cavity by being sucked by the negative pressure. Specifically, negative pressure is introduced into the first inner cavity through the negative pressure connection unit 300, so that the heat insulation sheet can be removed from the first inner cavity through the negative pressure connection unit 300.

Optionally, the first cooling component 110 is configured to stop cooling after the preset temperature is obtained by cooling the first cooling component 110. In the first stage, the first refrigeration component 110 refrigerates, the temperature detection component acquires a bounce point of the skin temperature, or the first refrigeration component 110 stops refrigerating after the bounce point is not acquired and the safety temperature is taken as a preset temperature, and waits for the skin to be heated to the room temperature.

The steps of using the cryo-lipid reduction device are described below in connection with fig. 3 and 4 by two exemplary embodiments.

Fig. 3 shows a cooling curve of an exemplary embodiment, the using step of the freezing and fat-reducing device is mainly divided into two stages, the first stage is a test cooling test using the first cooling component 110 to cool to obtain a preset temperature, and the second stage is a freezing treatment of the predetermined subject using the second cooling-leading component 220 to maintain the skin surface temperature of the predetermined subject at the preset temperature. A curve a is a change in the skin surface temperature detected by the temperature detecting means, wherein the curve a is shown only in the first stage and is not shown in the second stage; curve B shows the temperature variation of the second cold guiding member 220.

In the first stage S1, the first cooling component 110 starts cooling, so that the first cooling conducting component 120 is cooled to a certain predetermined temperature T (for example, -13 ℃), the skin surface temperature is lowered, a rebound occurs when latent heat is released, the temperature of the rebound point is recorded, a preset temperature Ts (i.e. a reference target treatment temperature) is provided for the next formal treatment, and then the first cooling component 110 is turned off to cool, so that the skin surface is reversely heated to room temperature. It should be understood that if the temperature of the anti-trip point cannot be obtained by the refrigeration of the first refrigeration component 110, the preset safe temperature is taken as the preset temperature Ts. At the same time when the first cooling part 110 starts cooling, the second cooling part 210 also starts cooling, so that the second cold guiding part 220 is cooled to a standby temperature less than the preset temperature Ts and maintained. At this time, the second cold guiding member 220 does not affect the skin surface due to the existence of the heat insulating sheet. More specifically, in the first phase, the power curve of the second cooling component 210 includes a first power segment P1 and a second power segment P2 connected in sequence, and the second cooling component 210 cools in the first power segment P1, so that the second cold guiding component 220 precools and reduces to the standby temperature; the second cooling part 210 cools at the second power segment P2, so that the second cold guiding part is maintained at the standby temperature. It is understood that the power of the second cooling element 210 in the first power stage P1 is greater than the power of the second cooling element 210 in the second power stage P2. Because the power of the first power segment P1 is relatively large, the temperature of the second cold-conducting component 220 is quickly reduced, and the second cold-conducting component 220 is precooled, so that the treatment time can be effectively reduced.

In the second stage S2, the power curve of the second cooling unit 210 includes a third power segment P3, the third power segment P3 is connected to the second power segment P2, and the power of the second cooling unit 210 in the third power segment P3 is greater than the power of the second cooling unit 210 in the second power segment P2. After the heat insulating sheet is removed and the freeze treatment is started, the second cooling unit 210 increases the cooling power and cools at the power of the third power stage P3 to lower the skin surface temperature of the predetermined subject. In an alternative embodiment, the power of the second cooling part 210 in the third power segment P3 is the maximum cooling power, so that the skin surface temperature can be rapidly decreased after the actual start of the freezing treatment, in order to reduce the treatment time.

Further, the power curve of the second cooling component 210 further includes a fourth power segment P4 and a fifth power segment P5, when the skin temperature approaches the preset temperature Ts, the second cooling component 210 reduces the cooling power, and cools according to the power of the fourth power segment P4, so that the temperature of the skin surface gradually approaches the preset temperature Ts. After the temperature of the skin surface reaches the preset temperature Ts, the second cooling component 210 increases the cooling power again, and cools according to the power of the fifth power segment P5, so that the temperature of the skin surface is maintained at the preset temperature Ts. With the configuration, the whole freezing treatment process is different from person to person, so that the safety risk is reduced and the treatment time is shortened while the maximum curative effect is obtained.

Fig. 4 shows a cooling curve of another exemplary embodiment, which is different from the exemplary embodiment shown in fig. 3 in that in the first stage, at the same time when the first cooling component 110 starts cooling, the second cooling component 210 also starts cooling, so that the second cold-conducting component 220 is cooled to a standby temperature higher than the preset temperature Ts and maintained. Preferably, the standby temperature is less than 0 ℃.

In the second stage, the power curve of the second cooling component 210 includes the third power stage P3 and the fifth power stage P5, and may not include the fourth power stage P4. Specifically, since the standby temperature is higher than the preset temperature Ts, after the heat insulation sheet is removed and the skin is sucked into the first inner cavity, the temperature of the second cold guide component 220 does not cause damage such as frostbite on the skin surface, and only the second cold guide component 210 needs to operate according to the power of the third power segment P3 to cool the skin surface until the temperature of the skin surface reaches the preset temperature Ts, and then the second cold guide component 210 operates according to the power of the fifth power segment P5 to maintain the temperature of the skin surface at the preset temperature Ts. The temperature of the second cold guiding member 220 of this example is always higher than the preset temperature Ts, so that the damage such as frostbite to the skin is avoided. To further reduce the treatment time, it may be considered to set the standby temperature to a value close to the preset temperature Ts.

Based on the above-mentioned frozen fat reduction device, the present embodiment further provides a readable storage medium, on which a program is stored, and in some embodiments, the readable storage medium may be integrated on the frozen fat reduction device, and in other embodiments, the readable storage medium may be disposed on another hardware carrier independent of the frozen fat reduction device. The program on the readable storage medium when executed implements:

driving the first cooling component 110 to cool, and obtaining a change condition of the skin surface temperature of the predetermined object (for example, a change condition of the skin surface temperature sucked into the second cavity) corresponding to the first cooling conducting component in heat conduction connection with the first cooling component 110, so as to obtain a preset temperature of the predetermined object; and driving the second cooling component 210 to cool according to a preset power curve, so that the skin surface temperature of the predetermined subject in the first inner cavity of the second cold guiding component 220 in heat conduction connection with the second cooling component 210 is maintained at the preset temperature.

Further, the program when executed further implements: in the process of driving the first cooling component 110 to cool so as to obtain the preset temperature, the second cooling component 210 is driven to cool, so that the second cold guiding component 220 precools.

Further, the program when executed further implements: driving the second cooling component 210 to cool at the first power segment P1, so that the second cold guiding component 220 is lowered to the standby temperature; driving the second cooling component 210 to cool at the second power segment P2, so that the second cold guiding component 220 is maintained at the standby temperature; driving the second cooling component 210 to cool in the third power segment P3, so as to lower the skin surface temperature of the predetermined subject; wherein the power of the first power segment P1 is greater than the power of the second power segment P2; and the power of the third power segment P3 is greater than that of the second power segment P2.

Optionally, the program further implements, when executed: after the first cooling part 210 is driven to cool to obtain the preset temperature, the negative pressure connection unit 300 is driven to connect negative pressure to the first inner cavity, so that the predetermined object is absorbed into the first inner cavity.

Optionally, the program further implements, when executed: after the first refrigeration component 210 is driven to refrigerate to obtain the preset temperature, the first refrigeration component 210 is driven to stop refrigerating.

It will be understood by those skilled in the art that the program stored in the readable storage medium, when executed, can control the on/off and power of each refrigeration component by sending a control signal to the driving device, and can also obtain the temperature value of each part by communicating with the temperature detection unit, which are all known in the art and will not be described herein.

In summary, the present invention provides a freezing fat-reducing device, wherein the freezing fat-reducing device comprises: the refrigerator comprises a first refrigeration component, a first cold guide component, a second refrigeration component, a second cold guide component and a temperature detection component; the first refrigeration component is in heat conduction connection with the first cold conduction component, the second refrigeration component is in heat conduction connection with the second cold conduction component, and the first cold conduction component is arranged on the far end side of the second cold conduction component; the second cold-guiding component is provided with a first inner cavity used for accommodating a predetermined object, and the temperature detection component is used for detecting the skin surface temperature of the predetermined object; the temperature detection part is configured to acquire a preset temperature of the predetermined object based on the refrigeration of the first refrigeration part; the second cooling component is configured to cool according to a preset power curve to maintain the skin surface temperature of the predetermined subject at the preset temperature. With this configuration, a customized preset temperature of the predetermined subject can be obtained by a trial cooling detection of the skin surface temperature of the predetermined subject by the first cooling part, and the second cooling part cools according to a preset power curve so that the skin surface temperature of the predetermined subject is maintained at the preset temperature, so that the freezing effect can be ensured and the risk of frostbite on the skin during the freezing process can be reduced. In addition, the second refrigerating part refrigerates according to a preset power curve, and the treatment time can be shortened.

The above description is only for the preferred embodiment of the present invention and is not intended to limit the scope of the present invention, and any modification and modification made by those skilled in the art according to the above disclosure are all within the scope of the claims.

Claims (11)

1. A frozen fat reduction device, comprising: the refrigerator comprises a first refrigeration component, a first cold guide component, a second refrigeration component, a second cold guide component and a temperature detection component;

the first refrigeration component is in heat conduction connection with the first cold conduction component, the second refrigeration component is in heat conduction connection with the second cold conduction component, and the first cold conduction component is arranged on the far end side of the second cold conduction component; the second cold-guiding component is provided with a first inner cavity used for accommodating a predetermined object, and the temperature detection component is used for detecting the skin surface temperature of the predetermined object;

the temperature detection part is configured to acquire a preset temperature of the predetermined object based on the refrigeration of the first refrigeration part; the second cooling component is configured to cool according to a preset power curve to maintain the skin surface temperature of the predetermined subject at the preset temperature.

2. A frozen fat reduction device as defined in claim 1, wherein the first cold conductor member has a second interior chamber in communication with the first interior chamber for receiving the predetermined object.

3. The frozen fat reduction device of claim 2, further comprising a thermal shield removably disposed in the second interior chamber or the first interior chamber; the heat insulating sheet is configured to insulate the predetermined object from the second cold-conducting part in the process of being cooled by the first cooling part to obtain the preset temperature.

4. The frozen fat reduction device of claim 3, wherein the thermal insulating sheet is further configured to remove the insulation of the predetermined object from the second cold conductive member after the preset temperature is obtained by the first cooling member.

5. The frozen fat reduction device of claim 1, further comprising a negative pressure connection unit in communication with the first interior chamber for accessing a negative pressure to the first interior chamber.

6. The frozen fat reduction device of claim 1, wherein the first refrigeration component comprises a semiconductor refrigeration block or a heat exchange head and the second refrigeration component comprises a semiconductor refrigeration block or a heat exchange head.

7. The frozen fat reduction device of claim 1, wherein the first cold conducting part and the second cold conducting part are connected by a flexible material.

8. The frozen fat reduction device of claim 1, wherein the preset temperature is set according to an anti-trip point of the skin surface temperature of the predetermined subject or a predetermined safe temperature.

9. The frozen fat reduction device of claim 1, wherein the first cooling component is configured to stop cooling after the preset temperature is obtained by cooling by the first cooling component.

10. The frozen fat reduction device of claim 1, wherein the second cooling component is further configured to pre-cool the second cold sink component during cooling by the first cooling component to achieve the preset temperature.

11. The frozen fat reduction device according to claim 10, wherein the power curve comprises a first power segment, a second power segment and a third power segment connected in sequence, and the second cooling component is configured to cool in the first power segment, so that the second cooling-guiding component can be pre-cooled to a standby temperature; refrigerating in the second power section to maintain the second cold conducting part at the standby temperature; cooling in the third power section to reduce the skin surface temperature of the predetermined subject; wherein the power of the second refrigeration component in the first power section is greater than the power of the second refrigeration component in the second power section; and the power of the second refrigeration component in the third power section is greater than the power of the second refrigeration component in the second power section.

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