KR101132752B1 - Device for meaursing fat using ultrasonic - Google Patents

Abstract

The present invention allows to measure the fat of the local area of the human body or the back fat of the pig by the method using ultrasound, while reducing the cost of the product with easy and simple configuration of the measurement operation, while measuring the value measured at the fat measurement The present invention relates to a fat measuring device using ultrasonic waves, which provides convenience for use by adding a function of pausing, storing, and displaying. The display unit displays the measured fat thickness and the like on the top of a rectangle, and selects automatic or manual measurement. A main body including a setting part for selecting and inputting a measurement start or the like, a handle part formed at a lower end, and a first connector formed at one side of a rear surface of the handle part to mount the ultrasonic probe; And an ultrasonic probe formed in a cylindrical shape, including an ultrasonic generator for emitting ultrasonic waves and receiving reflected waves, and a second connector formed at the other end and inserted into the first connector of the main body.

Description

Device for meaursing fat using ultrasonic

The present invention relates to an apparatus for measuring fat of humans or animals, and more particularly, it is possible to measure the fat of local parts of the human body or the back fat of a pig by a method using ultrasonic waves, but the measurement operation is easy and simple. The present invention relates to a fat measuring device using ultrasonic waves, which provides convenience for use by reducing the product cost and adding a function of pausing and storing measured values when measuring fat.

As is well known, as a product for measuring the thickness of the back fat of a pig, a back fat measuring instrument using ultrasonic waves has become popular.

The reason for measuring the fat thickness, such as animals such as pigs is intended to grasp the shipping time, it is possible to determine the optimal shipping time according to the thickness of the fat layer.

The ultrasonic fat measuring device is largely divided into expensive measuring equipment for analyzing and displaying an image (fat distribution state) by using ultrasonic waves, and measuring equipment for displaying the value of fat thickness according to the back fat measurement of pigs in the field.

In addition, the ultrasonic fat measuring device is a situation in which the main body is connected to the cable and the ultrasonic probe (probe) portion of the product is sold.

Therefore, when measuring the back fat of a pig, one measurer uses an ultrasonic probe and applies cooking oil (substituted with ultrasonic gel) to the pig's blood, and performs a measurement operation. The phenomenon that the value needs to be confirmed occurred, which was caused by the inconvenience of not matching the reality of the farmhouse.

In addition, since the main body and the ultrasonic probe are connected with a cable, the cable is twisted during the measurement operation.

In addition, the conventional ultrasonic fat analyzer has a problem in that the measured fat thickness value is output in real time, so that the value should always be observed. This is because there was no function to stop and output the current measured value.

The present invention has been invented in view of the above-described problems, but an object of the present invention is to measure the fat of a local part of a person or the back fat of a pig by a method using ultrasonic waves, but the measurement operation is easy. In addition, it provides a fat measuring device using ultrasound that provides convenience in use by reducing the product cost with a simple configuration and adding a function of pausing and storing the measured value when measuring fat.

In another aspect, the present invention provides a fat measuring apparatus using ultrasonic waves to separate only the ultrasonic probe from the main body to enable a fat measurement wirelessly.

The present invention for achieving the above object is a rectangular shape, the upper part of the display unit for displaying the measured fat thickness, etc., the setting unit for selecting and inputting the automatic measurement or manual measurement, or the start of the measurement, and the bottom A main body including a handle part and a first connector formed at one side of a rear surface of the handle part to mount the ultrasonic probe; It is characterized by consisting of an ultrasonic probe formed in a cylindrical shape, including an ultrasonic generator for emitting ultrasonic waves and receiving a reflected wave formed at the tip, and a second connector formed at the other end and inserted into the first connector of the main body.

In addition, the first connector and the second connector of the ultrasonic probe according to the invention is characterized in that consisting of a BNC connector.

In another aspect, the present invention, the ultrasonic probe including an ultrasonic wave generator for generating an ultrasonic wave having a predetermined frequency and receiving the reflected wave corresponding to the ultrasonic wave; A duplexer which is switched to transmit a pulse signal for generating an ultrasonic wave to the ultrasonic wave generator, or receives and transmits an ultrasonic wave reflected from the ultrasonic wave generator, and a pulse generator for generating and outputting a pulse signal for generating ultrasonic waves to the duplexer. And a preamplifier for amplifying and outputting the weak ultrasonic reflected wave output through the duplexer to a predetermined size, a gain adjusting unit for controlling and outputting the gain of the ultrasonic reflected wave output from the duplexer, and switching the duplexer to control the switching. Outputs the ultrasonic wave generation signal to the ultrasonic wave generation unit or receives the ultrasonic wave reflected by the ultrasonic wave generation unit, the pulse generator performs a pulse signal output command for the ultrasonic oscillation, the ultrasonic wave input through the gain control unit 18 Calculate fat thickness measured using echo A control unit for displaying the stored fat, a display unit for displaying the measured fat thickness numerically, a storage unit for temporarily storing the measured fat thickness data, at least an automatic measurement selection button, a manual measurement selection button And a main body including a setting unit for inputting a key command corresponding to the key command according to the measurement start button.

In addition, the manual measurement method using the manual measurement selection button according to the present invention is characterized in that the thickness of the fat in the area where the ultrasonic generator is in contact with the display unit, so that the display value is maintained in a stopped state.

In addition, the ultrasonic probe according to the present invention includes a probe wireless transmission and reception unit for wirelessly receiving the ultrasonic wave generation signal transmitted from the main body to transmit to the ultrasonic wave generation unit, the ultrasonic wave signal received from the ultrasonic wave generation unit to transmit the signal to the main body; The apparatus further includes an ultrasonic generator and a battery for supplying operation power to the probe wireless transceiver, and the main body is connected to a front end of the duplexer 15 to process an ultrasonic wave signal input from the duplexer to the ultrasonic probe. The apparatus may further include a main body wireless transceiver configured to wirelessly transmit and receive ultrasonic reflected waves transmitted from the ultrasonic probe to the duplexer.

In addition, the ultrasonic generator according to the present invention is characterized in that it is composed of a plurality of ultrasonic generators for performing a different frequency output.

As described above, the present invention allows to measure the fat of a local part of human body or the back fat of a pig by using an ultrasonic method, but the measurement operation is easy, and at the same time reduce the product cost with a simple configuration, measure the fat measurement The convenience of use is provided by adding a function of pausing, storing and displaying the set value.

In addition, the present invention can be separated by only the ultrasonic probe from the main body to perform a fat measurement wirelessly, it provides a convenience to eliminate the cable during the measurement.

1 and 2 is a block diagram of a fat measuring apparatus using ultrasonic waves according to the present invention,
3 is a configuration diagram showing a state in which the ultrasonic probe is separated from the main body in FIG.
4 is a circuit block diagram of a fat measuring apparatus using ultrasonic waves according to the present invention;
5 is a circuit block diagram of an essential part of a fat measuring apparatus using ultrasonic waves according to another embodiment of the present invention;
6 and 7 are circuit block diagrams and configuration diagrams of an ultrasonic wave generator according to another exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 and 2 is a block diagram of a fat measuring apparatus using ultrasonic waves according to the present invention, Figure 3 is a block diagram showing a state in which the ultrasonic probe is separated from the main body.

As shown, the fat measuring apparatus using the ultrasonic wave according to the present invention,

It is composed of the main body 10 and the ultrasonic probe 20.

The main body 10 has a rectangular shape of a size that can be grasped by a hand, and the display unit 11 for displaying the measured fat thickness and the like on the upper end, and selecting and inputting an automatic measurement or a manual measurement, or a measurement start. It includes a setting unit 12, a handle 13 formed at the bottom, and a first connector 14 is formed on one side of the rear surface of the handle 13 is mounted to the ultrasonic probe 20.

The ultrasonic probe 20 has a cylindrical shape, is formed at the tip portion of the ultrasonic wave generator 21 for emitting ultrasonic waves and receiving reflected waves, and is formed at the other end and inserted into the first connector 14 of the main body 10. The second connector 22 is composed of.

Here, the first connector 14 of the main body 10 and the second connector 22 of the ultrasonic probe 20 are preferably composed of a BNC connector.

Therefore, the user measures the fat by contacting the ultrasonic generator 21 of the ultrasonic probe 20 to the back of the pig or the local part of the human body to be measured by holding the handle 13.

In addition, as will be described later, the ultrasonic probe 20 is configured to be separated from the main body 10 to enable wireless communication, so that the fat can be measured using the ultrasonic probe 20 remotely from the main body 10. Can be.

4 is a circuit block diagram of a fat measuring apparatus using ultrasonic waves according to the present invention.

As shown, the circuit configuration of the fat measuring apparatus using ultrasonic waves according to the present invention,

It consists of a circuit configuration of the ultrasonic probe 20 and the main body 10.

First, the ultrasonic probe 20,

Ultrasonic generator 21 is included. The ultrasonic wave generator 21 generates ultrasonic waves having a constant frequency and receives reflected waves corresponding thereto.

In addition, the main body 10,

Duplexer (15), pulse generator (16), preamplifier (17), gain adjuster (18), control unit (19), display unit (11), storage unit (19a), setting unit (12) And a power supply unit 19b.

The duplexer 15 is switched to transmit a pulse signal for generating an ultrasonic wave to the ultrasonic wave generator 21 or to receive and transmit an ultrasonic wave reflected from the ultrasonic wave generator 21.

The pulse generator 16 generates and outputs a pulse signal for generating ultrasonic waves to the duplexer 15.

The preamplifier 17 amplifies and outputs the weak ultrasonic reflected wave output through the duplexer 15 to a predetermined size.

The gain adjusting unit 18 adjusts and outputs a gain of the ultrasonic reflected wave output from the duplexer 15.

The control unit 19 switches the duplexer 15 to control the output of the ultrasonic generation signal to the ultrasonic generator 21 or receive the ultrasonic wave reflected by the ultrasonic generator 21, the pulse generator ( 16, a pulse signal output command for ultrasonic oscillation is performed, and the thickness of fat measured using the ultrasonic reflection wave input through the gain control unit 18 is calculated, stored, and displayed.

The display unit 11 displays the measured fat thickness by numerical value.

The storage unit 19a temporarily stores the measured thickness data of fat.

The setting unit 12 has at least three function buttons.

The function button of the setting unit 12 includes an automatic measurement selection button, a manual measurement selection button and a measurement start button.

Here, the automatic measurement selection button is a button for automatically measuring the fat thickness, selecting the automatic measurement selection button, pressing the measurement start button of the fat measured by the ultrasonic generator 21 of the ultrasonic probe 20 The thickness is displayed in real time by the display section 11. Therefore, in this case, the measured value displayed on the display unit 11 is also changed in real time according to the measuring portion to which the ultrasonic probe 20 is moved.

In addition, the manual measurement selection button is a button for manually measuring the fat thickness, by selecting the manual measurement selection button, and pressing the measurement start button of the area where the ultrasonic generator 21 of the ultrasonic probe 20 is in contact The thickness of fat is indicated by the display section 11 and this display value is kept stationary. Therefore, in this case, even if the ultrasonic probe 20 is moved, the previously stored value is continuously output unless the measurement start button is pressed again.

According to the present invention, by providing the manual measurement selection button, it is possible to display and maintain the fat measurement value of the desired area, to provide a very convenient function when measuring the fat thickness. The power supply unit 19b receives an external commercial power source and supplies operation power to each circuit unit, which may provide a configuration that can be used in the field by replacing the rechargeable battery.

It looks at the overall operation of the fat measuring apparatus using the present invention configured as described above.

First, when power is applied to the main body 10, the power supply unit 19b supplies operating power to each circuit portion of the main body 10, and at the same time, the ultrasonic probe 20 through the first connector 14 and the second connector 22. The power supply is also supplied to the circuit part of the circuit.

After selecting the automatic measurement selection button of the setting unit 12 and pressing the measurement start button, the fat thickness measurement operation using the ultrasonic wave is started.

In this case, the user (measurer) makes the ultrasonic probe 20 to contact a local site of the human body or a site of measurement of an animal for measuring fat.

When the key input signal through the setting unit 12 is input to the control unit 19, the control unit 19 switches the duplexer 15 to the ultrasonic generation mode, and at the same time to generate the ultrasonic wave to the pulse generator 16 It oscillates a pulse signal for

The pulse signal generated from the pulse generator 16 is transmitted to the ultrasonic generator 21 of the ultrasonic probe 20 through the duplexer 15, so that the ultrasonic generator 21 oscillates the ultrasonic wave to the outside. .

The ultrasonic wave oscillated from the ultrasonic wave generator 21 passes through the fat formed on the measurement target and is reflected at a portion other than the fat to receive the reflected wave. At this time, the controller 19 switches the duplexer 15 to the ultrasonic reception mode.

Therefore, the ultrasonic reflected wave generated in response to the oscillation of the ultrasonic wave is received by the ultrasonic generator 21, and the reflected wave is transmitted to the preamplifier 17 through the duplexer 15.

The preamplifier 17 amplifies the weak ultrasonic wave reflected through the duplexer 15 to a predetermined magnitude and outputs the amplified ultrasonic wave to the gain control unit 18.

The gain adjusting unit 18 adjusts the gain of the ultrasonic reflected wave output from the preamplifier 17 and outputs the gain to the control unit 19.

The control unit 19 calculates the thickness of the fat measured using the ultrasonic reflection wave input through the gain control unit 18, stores it in the storage unit 19a, and then displays it on the display unit 11.

Therefore, the user can check in real time the fat thickness of the measurement target area in contact with the ultrasonic generator 21 of the ultrasonic probe 20.

On the other hand, in the process of measuring the fat thickness, in the case of selecting the manual measurement by pressing the manual measurement selection button, only when the start button of the setting unit 12, the ultrasonic generator 21 of the ultrasonic probe 20 Indicates the fat thickness value of the site that is currently in contact with the display unit 11, and maintains this state.

Thereafter, only when the key input of the start button is present again, the ultrasonic wave generator 21 again measures and displays the fat thickness value of the currently contacted part. Even in this case, the current measured value is temporarily stored and output to the display unit 11.

Therefore, the user can conveniently check the fat measurement value of the desired area without changing the measurement value even if the ultrasonic probe 20 is moved.

5 is a circuit block diagram of an essential part of a fat measuring apparatus using ultrasonic waves according to another embodiment of the present invention.

According to another embodiment of the present invention,

The main body 10A and the ultrasonic probe 20A are separated to implement wireless communication with each other.

Therefore, the ultrasonic probe 20A further includes a probe wireless transmitter / receiver 23 and a battery 24.

The probe wireless transmitter / receiver 23 wirelessly receives the ultrasonic wave generation signal transmitted from the main body 10A and transmits the ultrasonic wave generation signal to the ultrasonic wave generation unit 21, and processes the ultrasonic reflected wave received from the ultrasonic wave generation unit 21 by signal processing. Radio transmission is performed at 10A.

The battery 24 supplies operating power to each circuit unit of the ultrasonic probe 20A, that is, the ultrasonic generator 21 and the probe wireless transceiver 23.

In addition, the main body 10A includes a main body wireless transceiver 15a connected to the front end of the duplexer 15.

The main body wireless transceiver 15a performs a signal processing on an ultrasonic wave generation signal input from the duplexer 15 of the main body 10A and wirelessly transmits the generated ultrasonic signal to the ultrasonic probe 20A. The ultrasonic wave has been wirelessly transmitted from the ultrasonic probe 20A. The reflected wave is received and transmitted to the duplexer 15.

Therefore, the user can detach the ultrasonic probe 20A from the main body 10A and wirelessly measure the thickness of the fat.

6 and 7 are circuit block diagrams and configuration diagrams of an ultrasonic wave generator according to another exemplary embodiment of the present invention.

According to another embodiment of the present invention, the ultrasonic generator 21A is configured in plural, and outputs different frequencies, thereby averaging the measured values according to the ultrasonic signals (frequency) measured by the ultrasonic generators. By deriving the results, it is configured to increase the accuracy and reliability of the measurement.

That is, as shown in FIGS. 6 and 7, the ultrasonic generator 21A is transferred to the first ultrasonic generator 21-1, the second ultrasonic generator 21-2, and the third ultrasonic generator 21-3. And by measuring the values of the ultrasonic signals output to the three ultrasonic generators differently from each other and averaging these values.

Here, three ultrasonic generators are taken as examples, but they can be added or subtracted as much as possible.

10: main body 11: display unit
12: setting part 13: handle
14: first connector 15: duplexer
15a: main unit wireless transmitter and receiver 16: pulse generator
17: preamplifier 18: gain control unit
19: control unit 19a: storage unit
19b: power supply 20, 20A: ultrasonic probe 21, 21A, 21-1, 21-2, 21-3: ultrasonic generator
22: second connector 23: probe radio transmitter and receiver
24: battery

Claims (6)

delete delete An ultrasonic probe including an ultrasonic wave generator for generating ultrasonic waves having a predetermined frequency and receiving reflected waves correspondingly; And
A duplexer which is switched to transmit a pulse signal for generating an ultrasonic wave to the ultrasonic wave generator, or receives and transmits an ultrasonic wave reflected from the ultrasonic wave generator, and a pulse generator for generating and outputting a pulse signal for generating ultrasonic waves to the duplexer. And a preamplifier for amplifying and outputting the weak ultrasonic reflected wave output through the duplexer to a predetermined size, a gain adjusting unit for controlling and outputting the gain of the ultrasonic reflected wave output from the duplexer, and switching the duplexer to control the switching. Outputs the ultrasonic wave generation signal to the ultrasonic wave generation unit or receives the ultrasonic wave reflected by the ultrasonic wave generation unit, the pulse generator performs a pulse signal output command for the ultrasonic oscillation, the ultrasonic wave input through the gain control unit 18 Calculate fat thickness measured using echo A control unit for storing and displaying the data, a display unit for displaying the measured fat thickness numerically, a storage unit for temporarily storing the measured fat thickness data, at least an automatic measurement selection button, a manual measurement selection button And a main body including a setting unit which has a measurement start button and inputs a corresponding key command to the control unit.
The method of claim 3, wherein
Manual measurement method through the manual measurement selection button,
A fat measuring apparatus using ultrasonic waves, characterized in that the thickness of the fat of the area in contact with the ultrasonic generator is displayed on the display unit, the display value is to maintain a stationary state. The method of claim 3, wherein
The ultrasonic probe wirelessly receives the ultrasonic wave generation signal transmitted from the main body and transmits the ultrasonic wave generation signal to the ultrasonic wave generation unit, and transmits the ultrasonic wave reflected by the ultrasonic wave generation unit to the main body by signal processing. Further comprising a battery for supplying the operating power to the probe wireless transceiver,
The main body, which is connected to the front end of the duplexer 15, the ultrasonic signal generated from the duplexer signal processing and transmitted to the ultrasonic probe, and receives the ultrasonic reflection wave transmitted from the ultrasonic probe to the duplexer The main body fat measuring apparatus using ultrasonic waves, characterized in that it further comprises a wireless transceiver.
The method of claim 3, wherein
The ultrasonic generator is a fat measurement apparatus using ultrasonic waves, characterized in that composed of a plurality of ultrasonic generators for performing a different frequency output.

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