CN210802297U

CN210802297U - Insulation material thickness detector with telescopic link

Info

Publication number: CN210802297U
Application number: CN201921921057.XU
Authority: CN
Inventors: 葛文
Original assignee: Haian Construction Engineering Quality Testing Center Co ltd
Current assignee: Haian Construction Engineering Quality Testing Center Co ltd
Priority date: 2019-11-08
Filing date: 2019-11-08
Publication date: 2020-06-19
Anticipated expiration: 2029-11-08

Abstract

The utility model discloses an insulation material thickness detector with telescopic link, the inside one end of sleeve is equipped with the push pedal, the inside other end of sleeve is equipped with splint, be equipped with reset spring between push pedal and the splint, reset spring inside center department is equipped with the probe, probe one end is fixed to be located push pedal one side, the probe other end runs through splint, the outside one end of sleeve is connected with the locating plate, the outside center department with the locating plate junction of sleeve is equipped with the pinhole, the outside other end of sleeve is connected with the push rod, the push rod runs through sleeve and push pedal fixed connection, the push rod is embedded to have the scale on the surface, push rod tail end and handle fixed connection, the sleeve below is located perpendicularly to the telescopic link. The utility model discloses a set up the multiunit telescopic link in the sleeve below, operating personnel can adjust the telescopic link when detecting insulation material for operating personnel can place the detector on the plane, avoids the focus unstability when detecting, leads to the probe off normal, and measuring result is inaccurate.

Description

Insulation material thickness detector with telescopic link

Technical Field

The utility model relates to a detection device technical field specifically is an insulation material thickness detection appearance with telescopic link.

Background

At present, in the building construction of China, in order to ensure the construction quality, the thickness of an outer wall heat-insulating layer needs to be detected during acceptance check, and a certain standard is set for the thickness of the heat-insulating layer. The traditional insulation layer thickness detection device adopts a method of acquiring data by a core drilling test to obtain the thickness of an insulation layer, the method is complex to operate, the insulation layer is damaged, the insulation layer needs to be repaired after the measurement is finished, the measurement efficiency is low, and the measurement cost is high. Later, some simple needle type measuring devices are adopted, a common method is that a common steel needle is vertically inserted into the heat insulation material until penetrating through the heat insulation layer, the part of the steel needle, which is immersed into the heat insulation material, has a length, the position of the contact part of the steel needle and the heat insulation layer is recorded, then the distance from the vertex of the steel needle to a recording point is measured by a ruler, the distance is the thickness of the heat insulation layer, and finally the distance is compared with the dimension required by the specification.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an insulation material thickness detector with telescopic link sets up the telescopic link in the detector below to adjust the height of detector and hold the detector below, with the problem of proposing in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a heat insulation material thickness detector with a telescopic rod comprises a sleeve, a probe, a clamping plate, a needle hole, a positioning plate, a push plate, a reset spring, a push rod, a handle, a graduated scale, a telescopic rod and a pad foot, wherein the sleeve is cylindrical, the push plate is arranged at one end inside the sleeve, the clamping plate is arranged at the other end inside the sleeve, the reset spring is arranged between the push plate and the clamping plate, the probe is arranged at the center inside the reset spring, one end of the probe is fixedly arranged on one side of the push plate, the other end of the probe penetrates through the clamping plate, one end outside the sleeve is connected with the positioning plate, the needle hole is arranged at the center of the joint of the sleeve and the positioning plate, the other end outside the sleeve is connected with the push rod, the push rod penetrates through the sleeve and is fixedly connected with the push plate, the graduated scale is embedded, the telescopic rod is arranged below the outer portion of the sleeve and provided with a plurality of groups, the telescopic rod is vertically arranged below the sleeve, and a foot pad is arranged at the lower end of the telescopic rod.

Preferably, the push rods are provided with two groups, each push rod comprises a first push rod and a second push rod, the first push rods are arranged above the second push rods, and the first push rods and the second push rods are of parallel structures.

Preferably, the surface of the first push rod is provided with a first groove, the surface of the second push rod is provided with a second groove, a first glass cover is arranged above the first groove, and a second glass cover is arranged above the second groove.

Preferably, the graduated scale comprises a first graduated scale and a second graduated scale, and the lengths of the first graduated scale and the second graduated scale are the same as the length of the probe.

Preferably, the first graduated scale is arranged in the first groove, and the second graduated scale is arranged in the second groove.

Preferably, one side of the clamping plate close to the positioning plate is provided with a sponge block, and the sponge block is provided with a hole with the same diameter as the pinhole.

Preferably, the telescopic links have four groups, and the maximum stretching length of the telescopic links is greater than the length below the positioning plate.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model discloses a set up the multiunit telescopic link in the sleeve below, operating personnel can adjust the telescopic link when detecting insulation material for operating personnel can place the detector on the plane, avoids the focus unstability when detecting, leads to the probe off normal, and measuring result is inaccurate.

(2) The utility model discloses a locating plate contact building material's one side is perpendicular with the probe, and the pinhole on the combination sleeve inner clamping plate is corresponding with the position of probe, has guaranteed jointly that the probe is perpendicular male when inserting the heat preservation to measuring accuracy nature has been guaranteed.

(3) The utility model discloses a set up two sets of push rods in the sleeve outside, through first push rod and the common thrust of second push rod, reduced operating personnel's the volume that bulldozes, also make propelling more stable the propulsion at the in-process that impels the probe.

(4) The utility model discloses an whether embedded first scale and second scale respectively in first push rod and second push rod can come dual affirmation to measure the position through two scales and have the deviation.

(5) The utility model discloses a set up first glass lid and second glass lid outside first recess and second recess, can avoid the dust to get into in the scale.

(6) The utility model discloses a set up the sponge piece in splint one side that is close to the probe head, withdraw the in-process in the sleeve with the probe after detecting finishing, the sponge can be detached the adhesion at the material on probe surface, has guaranteed the cleanliness of device, has prolonged the life of device.

Drawings

FIG. 1 is a structural diagram of a device for detecting the thickness of a heat insulating material;

FIG. 2 is a view showing the structure of the first push rod;

fig. 3 is a view showing the structure of the second push rod.

In the figure: 1-a sleeve; 2-a probe; 3-clamping the plate; 4-pinhole; 5, positioning a plate; 6-pushing the plate; 7-a return spring; 8-a push rod; 9-a handle; 10-a graduated scale; 11-a telescopic rod; 12-foot pad; 13-a first push rod; 14-a second push rod; 15-a first groove; 16-a second groove; 17-a first scale; 18-a second scale; 19-a first glass cover; 20-a second glass cover; 21-sponge block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, fig. 2 and fig. 3, the present invention provides a technical solution: a heat insulation material thickness detector with a telescopic rod comprises a sleeve 1, a probe 2, a clamping plate 3, a needle hole 4, a positioning plate 5, a push plate 6, a reset spring 7, a push rod 8, a handle 9, a graduated scale 10, a telescopic rod 11 and a pad 12, wherein the sleeve 1 is cylindrical, one end inside the sleeve 1 is provided with the push plate 6, the other end inside the sleeve 1 is provided with the clamping plate 3, one side, close to the positioning plate 5, of the clamping plate 3 is provided with a sponge block 21, a hole with the diameter equal to that of the needle hole 4 is formed in the sponge block 21, the sponge block 21 is arranged on one side, close to the head of the probe 2, of the clamping plate 3, in the process of withdrawing the probe 2 into the sleeve 1 after detection is finished, substances adhered to the surface of the probe 2 can be removed by the sponge, the cleanliness of the device is ensured, the service life of the device is prolonged, the, one end of a probe 2 is fixedly arranged on one side of a push plate 6, the other end of the probe 2 penetrates through a clamping plate 3, one side of the probe contacting with a building material through a positioning plate 5 is perpendicular to the probe 2, a pinhole 4 on the clamping plate 3 in a sleeve 1 corresponds to the position of the probe 2, the probe 2 is ensured to be vertically inserted when being inserted into a heat insulation layer, so that the accuracy of measurement is ensured, one end of the outer part of the sleeve 1 is connected with the positioning plate 5, a pinhole 4 is arranged at the center of the joint of the outer part of the sleeve 1 and the positioning plate 5, the other end of the outer part of the sleeve 1 is connected with a push rod 8, the push rod 8 penetrates through the sleeve 1 and is fixedly connected with the push plate 6, the push rod 8 is provided with two groups, the push rod 8 comprises a first push rod 13 and a second push rod 14, the first push rod 13 is arranged above the second push rod 14, the first push rod 13, the pushing amount of an operator is reduced, the probe 2 is pushed more stably in the process of pushing, a first groove 15 is formed in the surface of a first push rod 13, a second groove 16 is formed in the surface of a second push rod 14, a first glass cover 19 is arranged above the first groove 15, a second glass cover 20 is arranged above the second groove 16, dust can be prevented from entering the graduated scale 10 by arranging the first glass cover 19 and the second glass cover 20 outside the first groove 15 and the second groove 16, the graduated scale 10 is embedded in the surface of the push rod 8 and comprises a first graduated scale 17 and a second graduated scale 18, the lengths of the first graduated scale 17 and the second graduated scale 18 are the same as the length of the probe 2, the first graduated scale 17 is arranged in the first groove 15, the second graduated scale 18 is arranged in the second groove 16, and the first graduated scale 17 and the second graduated scale 18 are respectively embedded in the first push rod 13 and the second push rod 14, whether there is the deviation in the double confirmation measuring position of coming through two

scale

10, 8 tail ends of push rod and 9 fixed connection of handle, 1 outside below of sleeve is equipped with telescopic link 11, telescopic link 11 is equipped with the multiunit, sleeve 1 below is located perpendicularly to

telescopic link

11, 11 lower extremes of telescopic link are equipped with and fill up

foot

12, 11 total four groups of telescopic link, the maximum tensile length of telescopic link 11 is greater than the length of 5 below of locating plate, through set up multiunit telescopic link 11 in sleeve 1 below, operating personnel is when detecting insulation material, can adjust telescopic link 11, make operating personnel can place the detector on the plane, avoid when detecting that the focus is unstable, lead to 2 off normal of probe, measuring result is inaccurate.

Application method

When the heat insulation material to be detected is high, the telescopic rod 11 is adjusted, the height of the sleeve 1 is adjusted, whether the probe 2 is flush with the end face of the sleeve 1 where the positioning plate 5 is located is checked before use, and at the moment, zero marks of the first graduated scale 17 and the second graduated scale 18 are flush with the end face of the sleeve 1 close to the graduated scale 10; attaching the positioning plate 5 to the selected detection point of the heat-insulating layer of the outer wall of the building, pressing the handle 9 to enable the handle 9 to push the first push rod 13 and the second push rod 14, so as to drive the push plate 6 to push the return spring, inserting the probe 2 into the heat-insulating layer until the probe cannot be pushed, reading the readings of the first graduated scale 17 and the second graduated scale 18, and determining whether the readings are consistent or not, wherein the consistent readings are the thickness of the heat-insulating layer; the handle 9 is held to pull the device out of the thermal insulation layer, and the probe 2 is retracted into the sleeve 1.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an insulation material thickness detection appearance with telescopic link which characterized in that: comprises a sleeve, a probe, a clamping plate, a needle hole, a positioning plate, a push plate, a reset spring, a push rod, a handle, a graduated scale, a telescopic rod and a pad foot, wherein the sleeve is cylindrical, the push plate is arranged at one end inside the sleeve, the clamping plate is arranged at the other end inside the sleeve, the reset spring is arranged between the push plate and the clamping plate, the probe is arranged at the center inside the reset spring, one end of the probe is fixedly arranged on one side of the push plate, the other end of the probe penetrates through the clamping plate, one end outside the sleeve is connected with the positioning plate, the needle hole is arranged at the center of the joint of the sleeve and the positioning plate, the other end outside the sleeve is connected with the push rod, the push rod penetrates through the sleeve and is fixedly connected with the push plate, the graduated scale is embedded on the surface of the push, the telescopic link is equipped with the multiunit, the telescopic link is located perpendicularly sleeve below, the telescopic link lower extreme is equipped with the pad foot.

2. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 1, wherein: the push rods are provided with two groups and comprise a first push rod and a second push rod, the first push rod is arranged above the second push rod, and the first push rod and the second push rod are of parallel structures.

3. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 2, wherein: the glass push rod is characterized in that a first groove is formed in the surface of the first push rod, a second groove is formed in the surface of the second push rod, a first glass cover is arranged above the first groove, and a second glass cover is arranged above the second groove.

4. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 3, wherein: the graduated scale comprises a first graduated scale and a second graduated scale, and the lengths of the first graduated scale and the second graduated scale are the same as the length of the probe.

5. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 4, wherein: the first graduated scale is arranged in the first groove, and the second graduated scale is arranged in the second groove.

6. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 1, wherein: one side of the clamping plate, which is close to the positioning plate, is provided with a sponge block, and the sponge block is provided with a hole with the diameter equal to that of the pinhole.

7. The instrument for detecting the thickness of the thermal insulation material with the telescopic rod as claimed in claim 1, wherein: the telescopic links are four groups in total, and the maximum stretching length of the telescopic links is greater than the length below the positioning plate.