JPH0232243Y2 - - Google Patents

Description

[Detailed description of the invention] (a) Technical field of the invention This invention relates to a cursor assembly for an electronically controlled height meter, and is particularly concerned with a cursor assembly that can be moved reliably and smoothly, and that the cursor can be moved reliably and smoothly. When the cursor makes contact with the top of the head of the person to be measured, the electronic device softens the contact shock, electrically detects the contact state, and electrically controls the cursor drive source using the output signal. This relates to a cursor assembly in a controlled height meter.

(b) Prior art and its problems As is well known, an electronically controlled automatic height measuring device consists of a measuring device body equipped with a cursor combined with a measuring main scale, and a mechanically driven cursor on the measuring device body. It is composed of a control section that performs electrical control via a source, and a display section that outputs and displays measured values. The electronically controlled automatic height measurement device allows the subject to:
When the measuring instrument body is placed on the reference footplate, the electric signal is sent to the control section to control the mechanical drive source. The cursor is controlled to move vertically along the measurement pole member, and when it comes into contact with the top of the subject's head, it is electrically detected by means such as a micro switch mechanism, and the cursor is controlled to move in the vertical direction. The mechanical drive source is configured to be controlled by a signal. Conventional electronically controlled height meters have had a difficulty in the combination mechanism between the height meter pole member and the cursor member in terms of reliable and smooth sliding. Furthermore, conventional electronically controlled height meters have many problems in terms of softening the contact shock when the cursor body contacts the top of the subject's head, and outputting the contact state with high accuracy. It had a point.

(c) Technical issues of the present invention Therefore, in order to solve the above-mentioned drawbacks and problems of the conventional electronically controlled height meter, this invention aims to solve the following problems for the pole member of the height meter.
It is an object of the present invention to provide a cursor assembly that can be reliably and smoothly slidably displaced.

Furthermore, this invention not only reduces the contact shock when the cursor contacts the top of the subject's head, but also electrically detects the contact state with high precision and uses the output signal to electrically control the cursor drive source. An object of the present invention is to provide a cursor assembly for an electronically controlled height meter that is controlled automatically.

(d) Technical Means of the Present Invention In order to achieve the above-mentioned object, the present invention specifically includes a drive source operated by an electric command signal, and is mechanically connected to the drive source. A cursor assembly for an electronically controlled height meter, which is assembled so as to be movable vertically up and down on a height meter pole member installed vertically, the cursor assembly being assembled such that it can move vertically up and down on a height meter pole member installed vertically, the distance meter being mounted on one side of the pole member. two bearing assemblies that engage at a distance D, and one bearing assembly that is at the midpoint of the bearing assembly and engages the other side of the pole member; , an engagement support portion that inserts the pole member and is slidable along the pole member; a base end of the engagement support portion that is fixed to a mounting side of the bearing assembly; an arm member having a free end extending outward from the side of the member; the arm member being pivotally connected to the free end side of the arm member via a pivot shaft, and extending along the lower edge of the arm member; a test object contact detection lever member extending toward the side surface of the pole member and having a test object contact reference surface on the lower surface; and a test object contact reference surface of the test object contact detection lever member. stopper means for suspending and supporting the test object contact detection lever member at a constant angle position with respect to the arm member until the test object contact detection lever member comes into contact with the test object; and a light emitting/receiving device provided on the arm member side. and an optical coupling path blocking piece that is provided on the side of the object contact detection lever member and enters into the optical coupling path gap of the light emitter/receiver sensor and blocks the optical coupling path. when the test object contact reference surface of the test object contact detection lever member contacts the test object and the test object contact detection lever member is rotationally displaced; The electronically controlled type detects the displacement of the object contact detection lever member by the detector and outputs an electric signal, and the drive source of the cursor assembly is electrically controlled by the output signal. Constructs a cursor assembly in a height meter.

(e) Embodiments of the present invention A cursor assembly in an electronically controlled height meter according to the present invention will be described in detail below based on embodiments shown in the drawings. The cursor assembly 1 in this invention basically consists of an arm member 2
, a test object contact detection lever member 3, and a detection member 4.
It consists of. The arm member 2 includes an engagement support portion 6 that is slidably assembled with the height meter pole member 5. The engagement support part 6 is
It is composed of three bearing assemblies 7, 8, and 9 that protrude from one side of the arm member 2. Among the three bearing assemblies 7, 8, 9, one pair of the bearing assemblies 7, 8 is spaced apart from each other by a predetermined distance and is engaged with one side surface 5a of the height scale pole member 5. Another bearing assembly 9 is attached to the arm member 2.
is attached to the arm member 2 so as to engage with the other side surface 5b of the height scale pole member 5 at an intermediate position between the pair of bearing assemblies 7, 8. The bearing assembly 7, 8, 9
are of exactly the same form except that the mounting positions are different. The detailed structure of the bearing assembly 7 is shown in FIG. The bearing assembly 7 includes:
The support shaft 11 is attached to the arm member 2 through a bearing roller part 10, a support shaft 11 that rotatably supports the bearing roller part 10, and a threaded part 12 formed at one end of the support shaft 11. It consists of a fixing nut 13. The support shaft 11 is
It is attached to the attachment hole 15 provided in the arm member 2 via the bushing element 14, and the washer 16,
17 and is tightened with a nut 13. The bearing roller 10 is provided with circumferential flange portions 18 and 19 at both ends in the axial direction, and the actual roller dimension L between the flanges is designed to be approximately equal to the side width dimension of the pole member 5 within a sliding range. ing. A photoelectric conversion element 20 is attached to the base side 2a of the arm member 2.
The photoelectric conversion element 20 is a combination of a light emitting element accommodating block 21 and a light receiving element accommodating block 22, separated by a predetermined optical coupling path gap 23.
The optical coupling path of the photoelectric conversion element 20 is installed so as to be orthogonal to the thickness direction of the arm member 2. Furthermore, a stopper bracket member 24 as shown in the drawings is attached to the side surface of the arm member 2, for example. The stopper bracket member 24 is provided with a hole 25 suitable for passing a stopper body to be described later. On the other hand, the free end side 26 of the arm member 2 is provided with a pivot hole 27 that penetrates in the thickness direction of the arm member 2, and one end of the object contact detection lever member 3 is provided with a pivot pin 28. A pair of brackets 30, 30 provided at 29
The test object contact detection lever member 3 is rotatably connected and supported via the test object contact detection lever member 3. The test object contact detection lever member 3 is generally formed in a box shape, and is attached to the floor wall 3.
1 constitutes a flat test object contact reference surface 32. An optical coupling path blocking piece that enters into the optical coupling path gap 23 of the photoelectric conversion element 20 and blocks the optical coupling path with respect to the floor wall upper surface 34 on the free end side 33 of the test object contact detection lever member 3. 35, and a stopper bracket 2 attached to the arm member 2 side.
A stopper body 36 that fits into the hole 25 of No. 4 is attached. A passage blocking piece 38 for the hole 25 of the stopper bracket member 24 is provided on the top portion 37 of the stopper body 36 .

In such a configuration, the cursor assembly 1 is assembled to the height scale pole member 5 via the engagement support portion 6 formed on the arm member 2 so as to be vertically movable up and down. In this state, the object contact detection lever member 3 attached to the arm member 2 is supported by the stopper body in the manner shown in FIG. 2. On the other hand, the optical coupling path blocking piece 35 provided on the test object contact detection lever member 3 is located below the optical coupling path gap 23 of the photoelectric conversion element, and is in a position where it does not block the optical coupling path. . When the person to be measured stands on the reference footplate of the measuring instrument body in this state, an electrical signal is output to detect the climbing, and the mechanical drive source is activated based on the electrical signal. Actuation of the mechanical drive source causes the cursor assembly to move downwardly along the height scale pole member. When the test object contact detection lever member 3 of the cursor assembly contacts the top of the subject's head, the test object contact detection lever member 3
rotates around the pivot point, and the lever member 3
The optical coupling path blocking piece 35 provided on the arm member enters into the optical coupling path gap 23 of the photoelectric conversion element 20 provided on the arm member side, and blocks the optical coupling path of the photoelectric conversion element 20. When the optical coupling path of the photoelectric conversion element 20 is cut off, the output signal turns off the cursor assembly drive source, the cursor assembly stops, and the height value of the subject is memorized and recorded at the stopped position. be done. When the test object contact detection lever member 3 in the cursor assembly contacts the top of the subject's head, the test object contact detection lever member 3
has a rotational stroke range that allows displacement even beyond the optical coupling path blocking point of the optical coupling path blocking piece.

(f) Effects of the present invention The cursor assembly in the electronically controlled height meter of this invention configured as described above is connected to the pole member of the height meter through an engagement support portion having three bearing assemblies. By applying the combined configuration, the sliding displacement of the cursor assembly can be ensured and smoothed, which can be said to be extremely advantageous in this type of automatic measuring instrument. Furthermore, the cursor assembly of the electronically controlled height meter according to this invention not only softens the contact shock when the cursor assembly contacts the top of the subject's head, but also accurately detects the contact state electrically. The cursor drive source is controlled by the output signal of the cursor, and in that respect it can be said to be extremely effective.

[Brief explanation of drawings]

Fig. 1 is a plan view of the cursor assembly in the electronically controlled height meter of this invention, Fig. 2 is a partially cutaway side view of the cursor assembly, and Fig. 3 is an enlarged cross-section taken along the line - in Fig. 2. It is a diagram. 1...Cursor assembly, 2...Arm member, 3
...Test object contact detection lever member, 4...Detection member, 5...Height scale pole member, 6...Engagement support portion, 7, 8, 9...Bearing assembly, 20...
Photoelectric conversion element, 23... Optical coupling path gap, 24, 3
6...stopper, 28...pivot pin, 32...test object contact reference surface, 35...optical coupling path blocking piece.

Claims (1)

[Claims for Utility Model Registration] A device that is equipped with a drive source operated by an electric command signal, is mechanically connected to the drive source, and is vertically raised and lowered on a vertically installed height meter pole member 5. A cursor assembly 1 in an electronically controlled height meter movably combined, comprising two bearing assemblies 7, 8 engaging one side 5a of the pole member 5 at a distance D; one bearing assembly 9 that is at the midpoint of the bearing assemblies 7, 8 and engages with the other side surface 5b of the pole member 5; an engagement support part 6 that holds the member 5 therein and is slidable along the pole member 5; and a bearing assembly 9 in the engagement support part 6.
An arm member 2 comprising a base end 2a fixed to an attachment side of the arm member 2, and a free end 26 extending from the base end 2a toward the outside of the side of the pole member 5.
and a pivot shaft 28 on the free end 26 side of the arm member 2.
The arm member 2 is pivotally connected to the arm member 2 via
a test object contact detection lever member 3 extending toward the side surface 5b of the pole member 5 along the lower edge thereof and having a test object contact reference surface 32 on the lower surface; and the test object contact detection lever member 3. The test object contact detection lever member 3 is suspended and supported at a constant angle position with respect to the arm member 2 until the test object contact reference surface 32 of the lever member 3 contacts the test object. The stopper means 24 and 36, the light emitter/receiver sensor 20 provided on the arm member 2 side, and the light emitter/receiver sensor 20 provided on the test object contact detection lever member 3 side, optically coupling the light emitter/receiver sensor 20. an optical coupling path blocking piece 35 that enters the path gap and blocks the optical coupling path; When the test object contact detection lever member 3 is rotated and displaced when the test object contact detection lever member 3 contacts the test object, the detector 4 detects the displacement of the test object contact detection lever member 3 and generates electricity. A cursor assembly for an electronically controlled height meter, characterized in that a signal is output, and a drive source for the cursor assembly 1 is electrically controlled by the output signal.