CN215767894U - Mortar tensile bonding strength detection device - Google Patents

Abstract

The utility model discloses a mortar tensile bonding strength detection device, which comprises a main body assembly and a detection mechanism, wherein the main body assembly comprises a base, a supporting plate, a first baffle, a hydraulic cylinder and a second baffle; the detection mechanism comprises a PLC (programmable logic controller), a tension sensor, a spring, a storage plate and a vibration motor; a support plate is welded on the upper surface of the base, a first baffle plate is fixedly connected to the top of the inner side wall of the support plate, and a hydraulic cylinder is connected to the middle of the lower surface of the first baffle plate through bolt threads; according to the utility model, the mortar is poured into the shell, then the vibration motor vibrates the mortar in the shell to shape the mortar in the shell, and then the hydraulic cylinder and the tension sensor detect the tensile bonding strength of the mortar, so that the mortar can be poured, vibrated and shaped in the supporting plate at the same time, the operation steps are simplified, and the working efficiency is improved.

Description

Mortar tensile bonding strength detection device

Technical Field

The utility model relates to the technical field of mortar tensile bonding strength detection, in particular to a mortar tensile bonding strength detection device.

Background

Mortar is a bonding substance used for building bricks on buildings, is formed by adding water into sand and cementing materials according to a certain proportion, is also called mortar, and is also used as mortar. Common mortar used are cement mortar, mixed mortar, lime mortar and clay mortar;

the existing mortar needs to be subjected to tensile bonding strength detection for ensuring the quality of the mortar after production is completed, and the traditional mortar tensile bonding strength detection device needs to be poured, vibrated and shaped respectively when in use, so that the operation steps are complicated, the working efficiency is influenced, and therefore, the mortar tensile bonding strength detection device is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a mortar tensile bonding strength detection device to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a mortar tensile bonding strength detection device comprises a main body assembly and a detection mechanism, wherein the main body assembly comprises a base, a supporting plate, a first baffle, a hydraulic cylinder and a second baffle;

the detection mechanism comprises a PLC (programmable logic controller), a tension sensor, a spring, a storage plate and a vibration motor;

the utility model discloses a support for the food processor, including base, the last skin weld of base has the backup pad, the first baffle of inside wall top fixedly connected with of backup pad, there is the pneumatic cylinder at the lower surface middle part of first baffle through bolt threaded connection, the even welding of upper surface of base has the spring, the one end that the base was kept away from to the spring welds in the lower surface of putting the thing board, the lower surface middle part of putting the thing board has vibrating motor through bolt threaded connection, the top of putting the thing board is equipped with the casing, the inside wall top threaded connection of casing has T type connecting block, the inside wall bottom threaded connection of casing has the fixed block.

As further preferable in the present technical solution: the middle part of the upper surface of the object placing plate is provided with a tension sensor, and the bottom of the fixed block is in threaded connection with the upper surface of the tension sensor; and detecting the tension data through a tension sensor.

As further preferable in the present technical solution: a piston rod of the hydraulic cylinder is welded with a second baffle, and the bottom of the second baffle is rotatably connected with a connecting column through a bearing; the piston rod of the hydraulic cylinder drives the second baffle to move.

As further preferable in the present technical solution: the top of the outer side wall of the T-shaped connecting block is in threaded connection with the inner side wall of the connecting column, and the lower surface of the T-shaped connecting block is coated with an epoxy resin layer; and the epoxy resin layer is driven to move through the T-shaped connecting block.

As further preferable in the present technical solution: the lower surface of the first baffle is symmetrically welded with four guide rods, and the outer side walls of the four guide rods are all connected to the inner side wall of the second baffle in a sliding manner; the guide rod is used for guiding the moving second baffle plate.

As further preferable in the present technical solution: the top of the front surface of the supporting plate is welded with a fixing plate, the front surface of the fixing plate is provided with a display screen, and one side of the lower surface of the first baffle plate is provided with a PLC (programmable logic controller); by mounting the display screen on the fixing plate, the stability of the display screen in operation is increased.

As further preferable in the present technical solution: the signal output end of the tension sensor is electrically connected with the signal input end of the PLC controller through a wire, the signal output end of the PLC controller is electrically connected with the signal input end of the display screen through a wire, and the electrical output end of the PLC controller is electrically connected with the electrical input end of the hydraulic cylinder through a wire; and receiving the data of the tension sensor through the PLC.

As further preferable in the present technical solution: the bottom of the front surface of the supporting plate is hinged with a cover plate through a rotating shaft, an acrylic plate body is adhered to the inner side wall of the cover plate, ventilation openings are uniformly formed in the outer side wall of the supporting plate, and a filter screen is welded to the inner side wall of each ventilation opening; the air in the supporting plate keeps circulating through the ventilation opening, and dust in the air is intercepted through the arranged filter screen.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, the mortar is poured into the shell, then the vibration motor vibrates the mortar in the shell to shape the mortar in the shell, and then the hydraulic cylinder and the tension sensor detect the tensile bonding strength of the mortar, so that the mortar can be poured, vibrated and shaped in the supporting plate at the same time, the operation steps are simplified, and the working efficiency is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an isometric view of the internal structure of the housing of the present invention;

FIG. 3 is a front view of the present invention;

fig. 4 is a schematic axial side structure of the present invention.

In the figure: 1. a body assembly; 2. a detection mechanism; 101. a base; 102. a support plate; 103. a first baffle plate; 104. a hydraulic cylinder; 105. a second baffle; 201. a PLC controller; 202. a tension sensor; 203. a spring; 204. a storage plate; 205. a vibration motor; 41. a guide bar; 42. connecting columns; 43. a T-shaped connecting block; 44. an epoxy resin layer; 45. a housing; 46. a fixed block; 47. a fixing plate; 48. a display screen; 49. a cover plate; 50. an acrylic plate body; 51. a filter screen; 52. and a vent.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a mortar tensile bonding strength detection device comprises a main body component 1 and a detection mechanism 2, wherein the main body component 1 comprises a base 101, a supporting plate 102, a first baffle 103, a hydraulic cylinder 104 and a second baffle 105;

the detection mechanism 2 comprises a PLC 201, a tension sensor 202, a spring 203, an object placing plate 204 and a vibration motor 205;

the last surface welding of base 101 has backup pad 102, the first baffle 103 of inside wall top fixedly connected with of backup pad 102, there is pneumatic cylinder 104 at the lower surface middle part of first baffle 103 through bolt threaded connection, the even welding of upper surface of base 101 has spring 203, the one end that base 101 was kept away from to spring 203 welds in the lower surface of putting thing board 204, there is vibrating motor 205 at the lower surface middle part of putting thing board 204 through bolt threaded connection, the top of putting thing board 204 is equipped with casing 45, the inside wall top threaded connection of casing 45 has T type connecting block 43, the inside wall bottom threaded connection of casing 45 has fixed block 46.

In this embodiment, specifically: the middle part of the upper surface of the object placing plate 204 is provided with a tension sensor 202, and the bottom of the fixed block 46 is in threaded connection with the upper surface of the tension sensor 202; the tension data is detected by the tension sensor 202, and the fixing block 46 is fixed to the tension sensor 202 by rotating the fixing block 46.

In this embodiment, specifically: a piston rod of the hydraulic cylinder 104 is welded with a second baffle 105, and the bottom of the second baffle 105 is rotatably connected with a connecting column 42 through a bearing; the piston rod of the hydraulic cylinder 104 drives the second baffle 105 to move, and the moving second baffle 105 drives the connecting column 42 to move.

In this embodiment, specifically: the top of the outer side wall of the T-shaped connecting block 43 is in threaded connection with the inner side wall of the connecting column 42, and the lower surface of the T-shaped connecting block 43 is coated with an epoxy resin layer 44; the T-shaped connecting block 43 drives the epoxy resin layer 44 to move, the epoxy resin layer 44 is a high-strength adhesive, and the T-shaped connecting block 43 and the shaped mortar are bonded together through the epoxy resin layer 44.

In this embodiment, specifically: the four guide rods 41 are symmetrically welded on the lower surface of the first baffle plate 103, and the outer side walls of the four guide rods 41 are connected to the inner side wall of the second baffle plate 105 in a sliding manner; the guide rod 41 guides the moving second baffle 105, so that the second baffle 105 is prevented from shifting in motion.

In this embodiment, specifically: a fixing plate 47 is welded on the top of the front surface of the supporting plate 102, a display screen 48 is mounted on the front surface of the fixing plate 47, and a PLC 201 is mounted on one side of the lower surface of the first baffle plate 103; by mounting the display screen 48 on the fixing plate 47, the stability of the display screen 48 in operation is increased.

In this embodiment, specifically: the signal output end of the tension sensor 202 is electrically connected to the signal input end of the PLC controller 201 through a wire, the signal output end of the PLC controller 201 is electrically connected to the signal input end of the display screen 48 through a wire, and the electrical output end of the PLC controller 201 is electrically connected to the electrical input end of the hydraulic cylinder 104 through a wire; the data of the tension sensor 202 is received by the PLC 201, and the data received by the PLC 201 is displayed by the display screen 48.

In this embodiment, specifically: a cover plate 49 is hinged to the bottom of the front surface of the support plate 102 through a rotating shaft, an acrylic plate body 50 is adhered to the inner side wall of the cover plate 49, ventilation openings 52 are uniformly formed in the outer side wall of the support plate 102, and a filter screen 51 is welded to the inner side wall of each ventilation opening 52; make the air in the backup pad 102 keep circulating through vent 52, intercept the dust in the air through the filter screen 51 that sets up, avoided in the dust carries out backup pad 102 through vent 52, bounce the fragment that the back is scattered to the mortar through the apron 49 that sets up and intercept, increased the protection to the staff, the material of the acrylic plate body 50 is transparent material.

In this embodiment, specifically: a switch group for turning on and off the vibration motor 205, the hydraulic cylinder 104, the PLC controller 201, the tension sensor 202 and the display screen 48 is installed on one side of the support plate 102, and the switch group is connected with an external commercial power and used for supplying power to the vibration motor 205, the hydraulic cylinder 104, the PLC controller 201, the tension sensor 202 and the display screen 48.

In this embodiment, specifically: the vibration motor 205 is model JFF-M20; the hydraulic cylinder 104 is MOB-63 × 300-LB; the model of the PLC controller 201 is DF-96D; the model of the tension sensor 202 is SK-LY 101; the display screen 48 is model AML500J 01Z-00.

Working principle or structural principle, when in use, the fixed block 46 is inserted into the shell 45 in a rotating manner, then mortar to be detected is poured into the shell 45, then the fixed block 46 is fixed on the tension sensor 202 by rotating the fixed block 46, then the vibration motor 205 is started to work by the switch group, the working vibration motor 205 drives the object placing plate 204 to vibrate, the vibrating object placing plate 204 drives the spring 203 and the tension sensor 202 to vibrate, the vibrating tension sensor 202 drives the shell 45 to vibrate through the fixed block 46, thereby vibrating the mortar in the shell 45, the vibrating spring 203 performs telescopic motion through vibration, the vibration effect on the mortar in the shell 45 is improved, air in the supporting plate 102 is kept to circulate through the arranged ventilation opening 52, the mortar after vibration in the shell 45 is finished is shaped, after the mortar in the shell 45 is shaped, the T-shaped connecting block 43 is rotated to drive the epoxy resin layer 44 to be inserted into the shell 45, the T-shaped connecting block 43 and the shaped mortar are bonded together through the arranged epoxy resin layer 44, then the connecting column 42 is rotated to enable the top of the T-shaped connecting block 43 to be inserted into the connecting column 42 for fixation, then the shell 45 is rotated to demould the shaped mortar, then the hydraulic cylinder 104, the PLC controller 201, the tension sensor 202 and the display screen 48 are started through the switch group to work, the piston rod of the hydraulic cylinder 104 drives the second baffle 105 to move, the moving second baffle 105 drives the T-shaped connecting block 43 to move through the connecting column 42, the moving T-shaped connecting block 43 drives the shaped mortar to carry out tensile test work, then the tension sensor 202 detects tension data, and then the PLC controller 201 transmits the data to the display screen 48 for display, when the data that the tension sensor 202 detected reach the threshold value or the data that the tension sensor 202 detected clear zero fast, close pneumatic cylinder 104 through PLC controller 201, the fragment that scatters is broken after jumping the mortar through the apron 49 that sets up intercepts, the protection to the staff has been increased, make the staff see through the inside condition of the backup pad 102 that the inferior gram force plate body 50 just can be observed through the inferior gram force plate body 50 that sets up, this device has not only increased the protection to the staff, and make the mortar pour into a mould simultaneously in backup pad 102, vibrate and the design work, the operation steps have been simplified, and the work efficiency is improved.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a mortar tensile bond strength detection device, includes main part subassembly (1) and detection mechanism (2), its characterized in that: the main body assembly (1) comprises a base (101), a supporting plate (102), a first baffle plate (103), a hydraulic cylinder (104) and a second baffle plate (105);

the detection mechanism (2) comprises a PLC (programmable logic controller) controller (201), a tension sensor (202), a spring (203), an object placing plate (204) and a vibration motor (205);

the utility model discloses a solar energy collector, including base (101), the upper surface welding of base (101) has backup pad (102), the first baffle of inside wall top fixedly connected with (103) of backup pad (102), there is pneumatic cylinder (104) at the lower surface middle part of first baffle (103) through bolt threaded connection, the even welding of upper surface of base (101) has spring (203), the one end that base (101) were kept away from in spring (203) welds in the lower surface of putting thing board (204), there is vibrating motor (205) at the lower surface middle part of putting thing board (204) through bolt threaded connection, the top of putting thing board (204) is equipped with casing (45), the inside wall top threaded connection of casing (45) has T type connecting block (43), the inside wall bottom threaded connection of casing (45) has fixed block (46).

2. The mortar tensile bond strength detection apparatus according to claim 1, characterized in that: a tension sensor (202) is installed in the middle of the upper surface of the object placing plate (204), and the bottom of the fixing block (46) is in threaded connection with the upper surface of the tension sensor (202).

3. The mortar tensile bond strength detection apparatus according to claim 2, characterized in that: a piston rod of the hydraulic cylinder (104) is welded with a second baffle (105), and the bottom of the second baffle (105) is rotatably connected with a connecting column (42) through a bearing.

4. The mortar tensile bond strength detection apparatus according to claim 3, characterized in that: the top of the outer side wall of the T-shaped connecting block (43) is in threaded connection with the inner side wall of the connecting column (42), and the lower surface of the T-shaped connecting block (43) is coated with an epoxy resin layer (44).

5. The mortar tensile bond strength detection apparatus according to claim 4, characterized in that: four guide rods (41) are symmetrically welded on the lower surface of the first baffle (103), and the outer side walls of the four guide rods (41) are connected to the inner side wall of the second baffle (105) in a sliding mode.

6. The mortar tensile bond strength detection apparatus according to claim 5, characterized in that: the front surface top welding of backup pad (102) has fixed plate (47), the front surface mounting of fixed plate (47) has display screen (48), PLC controller (201) are installed to the lower surface one side of first baffle (103).

7. The mortar tensile bond strength detection apparatus according to claim 6, characterized in that: the signal output end of the tension sensor (202) is electrically connected to the signal input end of the PLC controller (201) through a wire, the signal output end of the PLC controller (201) is electrically connected to the signal input end of the display screen (48) through a wire, and the electrical output end of the PLC controller (201) is electrically connected to the electrical input end of the hydraulic cylinder (104) through a wire.

8. The mortar tensile bond strength detection apparatus according to claim 7, characterized in that: the utility model discloses a building roof, including backup pad (102), apron (49), vent (52) have evenly been seted up to the inside wall of apron (49), the front surface bottom of backup pad (102) articulates through the pivot has apron (49), the inside wall of apron (49) is stained with the acrylic plate body (50), the inside wall welding of vent (52) has filter screen (51).

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