CN215064848U - Food processor of weighing - Google Patents

Abstract

The utility model discloses a food processor who weighs, including base and the body of setting on the base, still include weighing unit and display element. Wherein one end of the weighing unit is arranged below the base and supports the food processor, and the other end of the weighing unit penetrates through the base and extends into the base to be detachably connected with the base so as to measure the weight change of the food processor; the display unit is arranged on the side face of the body, is electrically connected with the weighing unit and displays the reading of the weighing unit. The food processor weighs the weight of food added into the food processor through the weighing unit and displays the reading through the display unit, so that the stability of the food processor in the weighing process is guaranteed, the weighing precision is improved, and convenience is brought to a user to read data, so that the food processor is more convenient to use and more accurate in data.

Description

Food processor of weighing

Technical Field

The utility model relates to a food processor field, in particular to food processor that can weigh.

Background

The existing food processor can help to process food, and greatly simplifies the process of preparing cuisine. However, the recipe has certain requirements on the weight of each ingredient, and the weight of each food is often required to be accurately controlled in order to make delicious cuisine, so that the weight of the food needs to be measured by a food processor in the process of processing the food. In the prior art, the food processor generally arranges an electronic scale below a container for placing food to weigh the food, but the design often causes the reading to be inconvenient, and the stability of the food processor in the weighing process is difficult to ensure, resulting in low measuring precision.

Accordingly, the prior art is yet to be improved and developed.

SUMMERY OF THE UTILITY MODEL

In view of the not enough of above-mentioned prior art, the utility model aims at providing a food processor that can weigh, it is inconvenient to the reading of weighing of food to aim at solving among the prior art food processor, and is difficult to guarantee the stability of the process of weighing, leads to the problem that measurement accuracy is not high.

The technical scheme of the utility model as follows:

a food processor capable of weighing, comprising a base, a body arranged on the base and a container arranged on the body, wherein, further comprising:

one end of the weighing unit is arranged below the base and supports the food processor, and the other end of the weighing unit penetrates through the base and extends into the base to be detachably connected with the base so as to measure the weight change of the food processor;

and the display unit is arranged on the side surface of the body, is electrically connected with the weighing unit and displays the reading of the weighing unit.

The food processor capable of weighing, wherein the weighing unit comprises:

the bottom end of the support is arranged below the base and supports the food processor, and the top end of the support penetrates through the base and extends into the base;

the sensor is arranged in the base and is detachably connected with the top end of the bracket;

the sensor top cap, the sensor top cap sets up inside the base, the sensor top cap cover the sensor and with the base can be dismantled and be connected, the sensor centre gripping is in the sensor top cap with between the base.

The food processor capable of weighing is characterized in that a second screw hole is formed in the support, a second through hole is formed in the position, corresponding to the second screw hole, of the sensor, a second screw penetrates through the second through hole and then is screwed into the second screw hole, and the sensor is detachably connected with the support.

The food processor capable of weighing is characterized in that a first screw hole is formed in the base, a first through hole is formed in the position, corresponding to the first screw hole, of the sensor top cover, a first screw penetrates through the first through hole and then is screwed into the first screw hole, the sensor top cover is detachably connected with the base, and the sensor is clamped between the sensor top cover and the base.

The food processor that can weigh, wherein, the bottom of support is equipped with the slipmat, avoids the food processor to take place the displacement.

The food processor capable of weighing comprises a plurality of weighing units, wherein the weighing units are symmetrically arranged and support the food processor so as to ensure the stability of the food processor.

The food processor that can weigh, wherein, the display element is the angle of inclination and upwards shows with vertical direction, makes things convenient for the user to observe the reading.

The food processor capable of weighing, wherein the display unit comprises:

the display screen is used for displaying the reading of the weighing unit;

and the control key is arranged on the display screen and is used for controlling the display content of the display screen.

The food processor that can weigh, wherein, the base is inside to be fixed to be equipped with a balancing weight, the balancing weight increases the weight of base, in order to avoid the food processor removes at work.

Compared with the prior art, the utility model provides a food processor that can weigh, including the base, set up the body on the base, set up the weighing unit and set up in the display element below the base, wherein one end of the weighing unit sets up below the base and supports the food processor, the other end of the weighing unit passes the base and stretches into the base inside with the base can be dismantled and be connected in order to measure the weight change of the food processor; the display unit is arranged on the side face of the body, is electrically connected with the weighing unit and displays the reading of the weighing unit. The food processor weighs the weight of food added into the food processor through the weighing unit and displays the reading through the display unit, so that the stability of the food processor in the weighing process is guaranteed, the weighing precision is improved, and convenience is brought to a user to read data, so that the food processor is more convenient to use and more accurate in data.

Drawings

Fig. 1 is a perspective view of the food processor capable of weighing according to the present invention.

Fig. 2 is a schematic view of a base of the food processor capable of weighing according to the present invention.

Fig. 3 is a schematic view of an assembled weighing unit of the food processor of the present invention capable of weighing.

Fig. 4 is an exploded view of a weighing unit of the food processor capable of weighing according to the present invention.

Fig. 5 is an exploded view of a weighing unit of the food processor capable of weighing according to the present invention.

Fig. 6 is an exploded view of the weighing unit of the food processor of the present invention in another orientation that can be weighed.

Fig. 7 is a front view of the food processor of the present invention capable of weighing.

Fig. 8 is a cross-sectional view of the base of the food processor of the present invention that can be weighed.

Detailed Description

The utility model provides a food processor that can weigh, for making the utility model discloses a purpose, technical scheme and effect are clearer, more clear and definite, following right the utility model discloses further detailed description. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that the terms "center", "upper", "lower", "left", "right", "inner", "outer", "vertical", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the structures referred to must have a specific orientation or must be constructed in a specific orientation, and should not be construed as limiting the present invention.

In addition, the articles "a" and "the" may refer broadly to the singular or plural unless the context specifically states otherwise. If there is a description in an embodiment of the present invention referring to "first", "second", etc., the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides a food processor that can weigh, as shown in fig. 1, food processor that can weigh includes base 200, sets up the weighing unit 300 of base below sets up body 100 on the base 200 sets up container 400 on the body 100 and setting are in the display element 110 of body 100 side. The display unit 110 is electrically connected to the weighing unit 300 to display the reading of the weighing unit 300. Optionally, there is a platform on the body 100 for placing the container 400, and the container 400 is used for holding food. Alternatively, the container 400 is a bowl. As shown in fig. 2, one end of the weighing unit 300 is disposed under the base 200 to support the food processor, and the other end of the weighing unit 300 passes through the base 200 to extend into the interior of the base 200 and is detachably coupled to the base 200 to measure the weight change of the food processor. After the food is placed in the container 400, the interaction force between the weighing unit 300 and the base 200 is changed, so that the weight of the food is weighed, and the reading of the weight data is displayed to the user through the display unit 110. Since the weighing device 300 is not placed directly under the container 400 for weighing, but measures the change of the interaction force between the whole food processor and the weighing device 300, the weighing reading will not change due to different placing positions of the food in the container 400 or different placing positions of the container 400 on the body 100, thereby avoiding the influence of instability or deviation on the precision of the weighing quantity and realizing the accurate measurement of the weight of the food.

As shown in FIG. 4, the weighing cell 300 includes a sensor top cover 310, a sensor 320, and a bracket 330. As shown in fig. 3, a base through hole 220 is formed in the base 200, the base through hole is matched with the top end of the bracket 330 in shape, the bottom end of the bracket 330 is disposed below the base 200 to support the food processor, and the top end of the bracket 330 penetrates through the base through hole 220 and extends into the base. The sensor 320 is disposed inside the base 200, and the sensor 320 is detachably connected to the top end of the bracket 330. The size of the sensor 320 is slightly larger than the base through hole 220 to prevent the sensor 320 from falling off the base through hole 220. The sensor top cover 310 is disposed inside the base 200 above the sensor 320, and as shown in fig. 8, the sensor top cover 310 covers the sensor 320 and is detachably connected to the base 200, thereby clamping the sensor 320 between the sensor top cover 310 and the base 200. After the food is put into the food processor, the base 200 moves downward due to the change of the weight, the sensor top cover 310 moves downward following the base 200, and the sensor 320 and the bracket 330 remain stationary. Because the sensor 320 is clamped between the sensor top cover 310 and the base 200, the sensor 320 does not slide relatively, and the change of the interaction force between the sensor top cover 310 and the sensor 320 after the food is added, namely the change of the interaction force between the food processor and the weighing device 300, can be measured, so that the data of the weight of the food can be obtained through measurement, the accuracy is high, and the influence of deviation is avoided.

As shown in fig. 3, a second screw hole 331 is formed at the top end of the bracket 330, a second through hole 321 is formed in the sensor 320 corresponding to the second screw hole 331, and the second through hole 321 and the second screw hole 331 have the same size. The sensor 320 is placed at the top end of the bracket 330, the second through hole 321 is correspondingly matched with the second screw hole 331, and the second screw 322 is screwed into the second screw hole 331 after passing through the second through hole 321, as shown in fig. 5, so as to ensure that the sensor 320 is firmly locked at the top end of the bracket 330, so as to realize the detachable connection of the sensor 320 and the bracket 330, thereby reducing the weighing error caused by shaking, deviation and the like in the weighing process, and improving the weighing precision. Preferably, two second screw holes 331 and two second through holes 321 are correspondingly provided, and the sensor 320 and the bracket 330 are connected by two second screws 322, so that the connection between the sensor 320 and the bracket 330 is more stable. When the trouble needs the maintenance, will second screw 322 back of unscrewing can be right sensor 320 is changed, convenient and fast does benefit to the use.

As shown in fig. 4, a first screw hole 230 is formed around the base through hole 220, a first through hole 312 is formed in the sensor top cover 310 corresponding to the first screw hole 230, and the first through hole 312 has the same size as the first screw hole 230. The sensor top cover 310 is placed above the sensor 320, the first through hole 312 is correspondingly matched with the first screw hole 230, the sensor 320 is clamped between the sensor top cover 310 and the base 200, and the first screw 311 is screwed into the first screw hole 230 after passing through the first through hole 312, as shown in fig. 2, so that the sensor top cover 310 and the base 200 are detachably connected, the sensor 320 is ensured to be stably clamped between the sensor top cover 310 and the base 200, and the influence of instability on weighing precision is avoided. Preferably, the middle portion of the sensor top cover 310 protrudes upwards to form a hollow accommodating space to accommodate the screw head of the second screw 322, so that when the sensor top cover 310 covers the sensor 320, the sensor 320 cannot be clamped between the sensor top cover 310 and the base 200 because the sensor top cover 310 abuts against the second screw 322. Preferably, four first screw holes 230 and four first through holes 312 are correspondingly provided, and the four first screw holes 230 and the four first through holes 312 are arranged according to four corners of a rectangle, and four first screws 311 are used to connect the sensor top cover 310 and the base 200, so as to realize stable connection between the sensor top cover 310 and the base 200, ensure reliable clamping of the sensor 320 by the sensor top cover 310 and the base 200, and prevent the sensor 320 from sliding relatively. Because the sensor 320 is clamped between the sensor top cover 310 and the base 200, after food is added, the sensor 320 can measure the change of the interaction force between the sensor top cover 310 and the sensor 320, namely the change of the interaction force between the food processor and the weighing device 300, so that the data of the weight of the food can be measured, the accuracy is high, and the influence of deviation is avoided.

Optionally, as shown in fig. 6, a non-slip pad 332 is disposed on the bottom surface of the bracket 330 to ensure that the bracket 330 does not slide relative to the ground when supporting the food processor, so as to increase the stability of the weighing unit 300 and reduce the displacement of the food processor, thereby avoiding the problem of slipping or shaking during the weighing process and improving the weighing precision and stability. Preferably, the non-slip mat is made of silica gel.

Optionally, several weighing units 300 are provided in the food processor while supporting the food processor to prevent the food processor from shaking during weighing. Preferably, four weighing units 300 are provided in the food processor, the four weighing units 300 are arranged in mirror symmetry with respect to the symmetry axis of the base 200, so as to ensure stable support of the food processor by the weighing units 300, and when food is added, the four sensors 320 measure weight change at the same time, thereby improving the stability of the food processor and the precision of weighing measurement.

Optionally, as shown in fig. 2, a weight 210 is disposed in the base 200. The weight 210 is a metal weight. By adding the balancing weight 210, the weight of the whole food processor is increased, and the body 100 or the base 200 is not required to be manufactured by using a die-casting alloy shell, so that the food processor is prevented from tilting or moving in work due to the overlarge weight of food after the food is added, the necessary stability of the food processor is kept, the cost is saved, and the influence on weighing is reduced. Preferably, the weight block 210 has an axisymmetric shape corresponding to a symmetry axis of the base 200, and the weight block 210 is disposed between the weighing units 300 that are symmetrically disposed.

As shown in fig. 1 and 7, the display unit 110 is disposed at a side of the body 100, and the display unit 110 forms an included angle with the vertical direction and displays upward, so that a user can read a weight reading without bending down or squatting down to make the sight line parallel to the display unit 110, thereby facilitating use. The display unit 110 is electrically connected to the weighing cell 300 so as to read and display a weighing reading of the sensor 320 in the weighing cell 300. When the sensor 320 in the weighing unit 300 measures the change of the interaction force between the food processor and the weighing unit 300, thereby determining the weight of the added food, the display unit 300 can instantly display the reading, and the weight reading is conveniently read by the user by displaying in an oblique upward direction.

Further, as shown in fig. 7, the display unit 110 includes a display screen 111 and control keys 112. The display screen 111 can be an LCD screen, and the display screen 111 and the vertical direction form an included angle and display upwards, so that a user can read display contents conveniently. The control key 112 realizes control of the display content of the display screen 111, including power on, power off, zero clearing, unit switching, and the like. Further, the display unit 110 further includes an alarm device, when the weighed food exceeds the measuring range, the display screen 111 displays "O-LD" indicating overload, and the alarm device gives an alarm sound to remind the user that the current food is overloaded. Optionally, the range is 5300 g.

The operation of the food processor capable of weighing according to the present invention will be briefly described with reference to the specific embodiments. The food processor is first placed on a flat surface and the reading on the display unit 110 is cleared, at which time the weighing unit 300 contacts the flat surface and supports the food processor, with the weighing unit 300 and the food processor remaining relatively stationary. The food to be processed is placed in the container 400, at which time the food processor has a tendency to displace downwards due to the weight increase, but the bracket 330 of the weighing unit 300 remains stationary supported on a plane, and the sensor 320 detachably connected to the bracket 330 also remains stationary and abuts against the sensor top cover 330 detachably connected to the base 200, thereby supporting the base 200, and thus the entire food processor, so that the food processor remains stable. The sensor 320 senses and measures a change in interaction force with the sensor top cover 310, which is a change in gravity of the food processor, i.e., the weight of the added food can be measured by the change in interaction force. The weight data measured by the sensor 320 is transmitted to the display unit 110, and the readings are displayed on the display unit 110. Since the display unit 110 is inclined at an angle with respect to the vertical direction and displays toward the upper side, the user can read the weight reading without bending down or squatting down, thereby grasping the specific weight of the added food. Consequently food processor that can weigh had both guaranteed the stability of weighing the in-process, had improved the precision of weighing data, convenience of customers reads data simultaneously for it is more convenient to use, and data are more accurate.

To sum up, the utility model provides a food processor that can weigh, including base and the body of setting on the base, still include weighing unit and display element. Wherein one end of the weighing unit is arranged below the base and supports the food processor, and the other end of the weighing unit penetrates through the base and extends into the base to be detachably connected with the base so as to measure the weight change of the food processor; the display unit is arranged on the side face of the body, is electrically connected with the weighing unit and displays the reading of the weighing unit. The food processor weighs the weight of food added into the food processor through the weighing unit and displays the reading through the display unit, so that the stability of the food processor in the weighing process is guaranteed, the weighing precision is improved, and convenience is brought to a user to read data, so that the food processor is more convenient to use and more accurate in data.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (9)

1. The utility model provides a food processor who weighs, includes the base, sets up body on the base and setting up container on the body which characterized in that still includes:

one end of the weighing unit is arranged below the base and supports the food processor, and the other end of the weighing unit penetrates through the base and extends into the base to be detachably connected with the base so as to measure the weight change of the food processor;

and the display unit is arranged on the side surface of the body, is electrically connected with the weighing unit and displays the reading of the weighing unit.

2. The weighed food processor of claim 1, wherein the weighing unit comprises:

the bottom end of the support is arranged below the base and supports the food processor, and the top end of the support penetrates through the base and extends into the base;

the sensor is arranged in the base and is detachably connected with the top end of the bracket;

the sensor top cap, the sensor top cap sets up inside the base, the sensor top cap cover the sensor and with the base can be dismantled and be connected, the sensor centre gripping is in the sensor top cap with between the base.

3. The food processor of claim 2, wherein the bracket has a second screw hole, the sensor has a second through hole corresponding to the second screw hole, and a second screw passes through the second through hole and is screwed into the second screw hole, thereby achieving detachable connection of the sensor and the bracket.

4. The food processor of claim 3, wherein the base has a first threaded hole, the sensor top cover has a first through hole corresponding to the first threaded hole, and a first screw passes through the first through hole and is threaded into the first threaded hole to removably attach the sensor top cover to the base and retain the sensor between the sensor top cover and the base.

5. The weighed food processor of claim 2, wherein the bottom end of the rack is provided with a non-slip pad to prevent displacement of the food processor.

6. The weighed food processor of claim 2, comprising a number of said weighing cells symmetrically arranged and supporting said food processor to ensure stability of said food processor.

7. The weighted food processor of claim 1, wherein the display unit is angled from vertical and is displayed facing upward to facilitate viewing of the reading by a user.

8. The weighed food processor of claim 7, wherein the display unit comprises:

the display screen is used for displaying the reading of the weighing unit;

and the control key is arranged on the display screen and is used for controlling the display content of the display screen.

9. The weighted food processor of claim 1, wherein a weight is secured within the base, the weight increasing the weight of the base to prevent the food processor from moving during operation.

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